WO2013165953A1 - Cubic ionic conductor ceramics for alkali ion batteries - Google Patents
Cubic ionic conductor ceramics for alkali ion batteries Download PDFInfo
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- WO2013165953A1 WO2013165953A1 PCT/US2013/038771 US2013038771W WO2013165953A1 WO 2013165953 A1 WO2013165953 A1 WO 2013165953A1 US 2013038771 W US2013038771 W US 2013038771W WO 2013165953 A1 WO2013165953 A1 WO 2013165953A1
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Definitions
- the present invention relates to electrochemical storage devices containing an electrolyte with high ionic conductivity, low impedance, and high thermal stability. More particularly, this invention relates to the design, synthesis and application of novel cubic ionic conductor compounds, as exemplified by nitridophosphate type compounds such as Na 3 _ x Li y V(P0 3 )3N which act as an electrode for alkali ion batteries, or as a solid state electrolyte for battery or other electrochemical applications.
- nitridophosphate type compounds such as Na 3 _ x Li y V(P0 3 )3N which act as an electrode for alkali ion batteries, or as a solid state electrolyte for battery or other electrochemical applications.
- lithium-ion batteries are the most promising candidates that meet these criteria due to their higher gravimetric and volumetric energy densities compared to other rechargeable battery systems such as lead- acid, nickel-cadmium and nickel-metal hydride batteries.
- Conventional lithium-ion batteries are fabricated with a lithium-containing cathode and a metallic lithium or carbon-based anode.
- conventional lithium-ion batteries still show substantial limitations in energy and power density due to the design of their cathodes.
- One alternative to using a lithium-containing cathode and a metallic lithium or carbon-based anode is to use a sodium-ion battery with a sodium-containing cathode and a sodium-accepting anode to take advantage of the lower cost and greater abundance of sodium relative to lithium, especially for large-scale energy storage applications.
- a sodium-ion battery with a sodium-containing cathode and a sodium-accepting anode to take advantage of the lower cost and greater abundance of sodium relative to lithium, especially for large-scale energy storage applications.
- a second alternative which has also proven to be more practical is to start with a sodium-containing cathode and to utilize a good Li-ion electrolyte to cycle it against a lithium-containing anode (such as Li metal), resulting in the electrochemical removal of Na from the cathode followed by the electrochemically-driven intercalation of Li into the cathode.
- Hybrid-ion battery performance which is competitive with Li-ion battery performance has been demonstrated in systems that include Na 2 FeP0 4 F, Na 3 V 2 (P0 4 ) 2 F 3 and Li 2 NaV 2 (P0 4 ) 3 .
- cubic ionic conductor compounds that can be employed as an electrode in electrochemical storage and ionic conduction applications.
- These cubic ionic conductor (or "CUBICON") compounds have the framework formula (1) and a general formula (2)
- CUBICON is a family of the nitridophosphate compounds having a general formula (3)
- These compounds are known to form the cubic ionic conductor framework with A and M independently selected from a set of monopositive (Na, K), dipositive (Mg, Mn, Fe, Co), or tripositive (Al, Ga, In, Ti, V, Cr, Mn, Fe) cations.
- M is a framework cation in octahedral coordination
- A is a variable number of non-framework cations inserted into the open space within this framework.
- the total A and M cations is no more than four ⁇ i.e., x ⁇ 3), and the sum of the charges of these four cations is +6 giving a net neutral composition ⁇ e.g., Na 3 Ti(P0 3 ) 3 N or Na 2 Fe 2 (P0 3 ) 3 N).
- the total A and M cations is more than four, whereby the oxidation state of M is reduced below its starting state, while the sum of the charges of these cations is still +6 giving a net neutral composition.
- additional cations having the above (1+, 2+, 3+) or different charges or chemical species, such as neutral or ionic small molecules, can be incorporated into this structure.
- the cubic ionic conductor material has a sodium cation, a transition metal nitridophosphate anion framework, and a lithium cation that can be reversibly intercalated and de-intercalated within the crystal structure, with a variable formula such as Li2- x NaV(P0 3 )3N (0 ⁇ x ⁇ 2).
- An electrode preferably a cathode, is composed of a cubic ionic conductor compound having a framework of formula (1), a conductive additive, e.g., carbon black, and a binder, e.g., polyvinylidene difluoride.
- a conductive additive e.g., carbon black
- a binder e.g., polyvinylidene difluoride.
- the composition of the nitridophosphate compound, additive, and binder is about 50% to 100% of the nitridophosphate compound, 0%> to 30%> of additive, and 0%> to 20%> of binder.
- the composition of the nitridophosphate, additive, and binder is about 80: 10: 10.
- an electrochemical cell i.e., a battery, having a cathode, an anode, and an electrolyte solution.
- the electrochemical cell is a lithium-ion battery, a hybrid-ion battery, or a sodium-ion battery having a cathode composed of the disclosed cubic ionic conductor compound, preferably a nitridophosphate compound.
- the electrochemical cell can be of other types such as a semisolid flow cell (SSFC) batteries, in which a nitridophosphate electrode is produced by suspending particles in an electrolyte solution, rather than being cast as a solid film.
- SSFC semisolid flow cell
- nitridophosphate electrode is produced by suspending particles in an electrolyte solution, rather than being cast as a solid film.
- these cubic ionic conductor compounds can also be utilized as solid state electrolytes in which they serve as a membrane or layer with high ionic conductivity but low electronic conductivity.
- the cubic ionic conductor compounds can also serve as the separator between electrodes in batteries, or as a coating for electrode active material in batteries. It is believed that the most suitable elemental components for ionic conductivity
- the nitridophosphate, as the cubic ionic conductor compound will be substantially composed of one or a mixture of these elements.
- urea CO(NH 2 )2
- PON just solid phosphorous oxynitride
- NH 3 ammonia gas
- the method generally has the steps of (1) mixing stoichiometric amounts of metal oxide, a metaphosphate, and urea, (2) heating the mixture under flowing ammonia gas to about 350 °C at a rate of about 300 °C/hour, and (3) heating the mixture to about 700 to 800 °C under flowing ammonia.
- the mixing of stoichiometric amounts of metal oxide, a metaphosphate, and urea can be accomplished by grinding or by using a vibratory ball mill.
- the time and temperature of the reaction may be adjusted accordingly without departing from the scope and spirit of the invention.
- the mixture is heated at about 350 °C under flowing ammonia gas for several hours and at about 700 to 800 °C for about 10 to 30 hours under flowing ammonia.
- the reaction product is preferably subjected to grinding.
- substantially pure nitridophosphate compound(s) can be synthesized based on a solid state mechanism using urea (CO(NH 2 )2) as a solid nitrogen source, optionally with a polymeric precursor (Pechini-type), a substantially pure nitridophosphate compound(s) can also be synthesized based on a solid state mechanism utilizing a phosphorus source other than PON or NaP0 3 .
- FIG. 1A and IB are schematic illustrations of a cubic ionic conductor building block of a I ⁇ io trimer containing three tetrahedra and the trimer's three neighboring octahedra (viewed in two different orientations) for a representative nitridophosphate, Na 3 VP 3 0 N, an example of an AsMI ⁇ Xw cubic ion conductor.
- FIG. 1C is a schematic illustration of the octahedral M cation coordination in the cubic ionic conductor structure of Na 3 VP 3 0 N. Each 3 ⁇ 4 octahedron is connected to three different ⁇ trimers by two bridging anions connected to two different 73 ⁇ 4 tetrahedra within the trimer.
- FIG. 2 A is a schematic illustration of the framework structure (MT3X10) of the cubic ionic conductor phase with the composition of Na 3 V(P0 3 ) 3 N with Na atoms omitted for clarity.
- FIG. 2B is a schematic illustration of the full structure (A3MT3X10) of the cubic ionic conductor phase with the composition of Na 3 V(P0 3 ) 3 N shown in FIG. 2A with the A species (Na atoms) shown inside the ⁇ framework.
- FIG. 3A is a schematic illustration of the framework structure of the cubic ionic conductor phase of Na 2 Fe 2 (P0 3 ) 3 N with Na atoms omitted, and the Fe2 octahedron opened to reveal the Fe2 atom that sits on the position corresponding to the Na2 site of the Na 3 V(P0 3 ) 3 N structure.
- FIG. 3B is a schematic illustration of the framework structure of the cubic ionic conductor phase of Na 2 Fe 2 (P0 3 ) 3 N shown in FIG. 3A including the Na atoms, which sit on the positions corresponding to the Nal and Na3 sites in Na 3 V(P0 3 ) 3 N.
- FIG. 4A is a plot of X-ray diffraction patterns of Na 3 V(P0 3 ) 3 N obtained by a conventional solid state synthesis from different synthesis temperatures for 20 hours. From top to bottom: (1) 700 °C with urea; (2) 850 °C; (3) 800 °C; (4) 750 °C; (5) 700 °C; and (6) 675 °C.
- FIG. 4B is a plot of X-ray diffraction (XRD) patterns of Na 3 V(P0 3 ) 3 N obtained from different sintering times at 700 °C. From top to bottom: (1) 25 hours, (2) 20 hours, and (3) 12 hours.
- XRD X-ray diffraction
- FIG. 4C is a plot of an XRD pattern of Na 3 V(P0 3 ) 3 N obtained from urea- added (100% molar ratio) starting material which was heated to 600 °C for 20 hours, with the reaction product washed by distilled water prior to X-ray analysis.
- FIG. 5A is a plot of X-ray diffraction patterns of Na 3 Ti(P0 3 ) 3 N obtained by a conventional solid state synthesis at different sintering temperatures. From bottom to top: (1) 700 °C; (2) 750 °C; (3) 800 °C; and (4) 750 °C with a distilled water wash.
- FIG. 5B is a plot of X-ray diffraction patterns of Na 3 Ti(P0 3 ) 3 N obtained by a conventional solid state synthesis at 750 °C. From top to bottom: (1) 25 hours, (2) 20 hours, and (3) 12 hours.
- FIG. 5C is a plot of an X-ray diffraction pattern of Na 3 Ti(P0 3 ) 3 N obtained from urea-added starting materials and washed by diluted HC1 (1 : 10) solution.
- FIG. 6A is a plot of XRD patterns of Na 3 V(P0 3 ) 3 N synthesized by different methods, including from bottom to top (a) a conventional solid state synthesis at 700 °C for 20 hours, (b) a solid state synthesis with urea added in an equimolar amount relative to vanadium and heating at 600 °C for 20 hours (c) a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours (d) a sol-gel method and heating at 650 °C for 15 hours.
- FIG. 6B is a plot of X-ray diffraction patterns of Na 3 Ti(P0 3 ) 3 N synthesized by methods including from bottom to top (a) a conventional solid state synthesis at 750 °C for 20 hours, (b) a solid state synthesis with urea added in an equimolar amount relative to titanium and heating at 700 °C for 20 hours (c) a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours.
- Pattern (d) is the partially desodiated sample, Na 3 _ x Ti(P0 3 ) 3 N with x ⁇ 0.6, that resulted from washing the product of the conventional solid state reaction with diluted HC1 (1 : 10), which exhibits a prominent 002 peak at around 18 degrees two-theta.
- FIG. 7 is a plot of X-ray diffraction patterns of Na 2 Fe 2 (P0 3 )3N synthesized by different methods, including from bottom to top (a) a conventional solid state synthesis and heating at 650 °C for 20 hours and (b) using a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours.
- FIG. 8 A is a plot of cycling performance of a hybrid-ion battery made with a Na 3 Ti(P0 3 ) 3 N cathode and a Li metal anode which was measured between 2.5V and 4.5V at C/10 rate during the first charge-discharge cycle.
- FIG. 8B is a plot of cycling performance of a hybrid-ion battery made with a Na 3 Ti(P0 3 ) 3 N cathode and a Li metal anode which was measured between 2.5V and 4.5V at C/10 rate over the first three charge-discharge cycles.
- FIG. 8C is a plot of cycle life performance over 20 cycles of a hybrid-ion battery made with a Na 3 Ti(P0 3 ) 3 N cathode and a Li metal anode which was measured between 2.5V and 4.5V at a C/5 rate.
- FIG. 9 is a plot of cycling performance of a hybrid-ion battery made from
- FIG. 10A is a plot of cycling performance of a sodium-ion battery made with a Na 3 Ti(P0 3 ) 3 N cathode (acetate method) and a Na metal anode which was measured between 2.0V and 3.5V at a C/10 rate. The low voltage plateau around 2.1 V is due to the response of a Na 3 Ti 2 (P0 4 ) 3 impurity phase.
- FIG. 10B is a plot of cycling performance lifetime of a sodium-ion battery made with a Na 3 V(P03)3N cathode (urea added solid state reaction) and a Na metal anode which was measured between 2.5V and 4.2V at a C/20 rate.
- FIG. 11 is a spectrum of X-ray diffraction patterns of the in-situ heating of the HCl-washed Na3_ x Ti(P03)3N sample with an X-ray wavelength of 0.3196 A. (Data were collected with a 2D area detector and a temperature increasing rate of 2 °C/min up to 850 °C, and with a final scan at room temperature at the end of the run).
- FIG. 12A is an SEM image of the as-prepared Na 3 Ti(P0 3 ) 3 N sample obtained from the reaction (750 °C, 20 hours, flowing ⁇ 3 ⁇ 4) of NaPC"3 and Ti0 2 (rutile, micrometer particles) starting materials.
- FIG. 12B is an SEM image of the as-prepared Na 3 Ti(P0 3 ) 3 N sample obtained by reacting (650 °C, 15 hours, flowing NH 3 ) the starting materials of Na(CH 3 COO), (NH 4 ) 2 HP0 4 , and Ti0 2 (rutile, ⁇ 32nm particle).
- FIG. 13A is an SEM image of the as-prepared Na 3 V(P0 3 ) 3 N sample obtained from a solid state synthetic route (700 °C, 20 hours, flowing NH 3 ) using NaPC"3 and V 2 C"5 as starting materials.
- FIG. 13B is an SEM image of the as-prepared Na 3 V(P0 3 ) 3 N sample obtained using the Pechini method (final reaction at 650 °C for 20 hours, flowing NH 3 ) with NaPC"3, NH 4 VC"3 and citric acid used as starting materials.
- FIG. 14 is an SEM image of the as-prepared Na 2 Fe 2 (PC"3) 3 N sample obtained from a solid state synthetic route (600 °C, 20 hours, flowing NH 3 ) using NaPC"3, Fe 2 C"3 and (NH 4 ) 2 HP0 4 as starting materials.
- FIG. 15A is a plot of the XANES spectra obtained for Na 3 Ti(P0 3 ) 3 N before and after sodium removal. The oxidation state of Ti approached 4+ after desodiation, indicating that the removal of Na is nearly complete or complete.
- FIG. 15B is a plot showing EXAFS analysis of the Ti X-ray absorption edge for Na 3 Ti(P0 3 ) 3 N.
- the local environment of Ti is not substantially changed by desodiation, suggesting that the cubic ionic conductor structure is preserved during the process of Na removal.
- FIG. 16A is a plot of the in situ XANES spectrum obtained for
- FIG. 16B is a plot of the in situ XANES spectrum obtained for
- FIG. 17A is a plot of electrochemical performance of Na 3 VP 3 0 N cathode cycled against Li metal. Voltage charge/discharge curve with capacity retention of Na 3 VP 3 C" 9 N versus Li + /Li cycled between 1 V and 4.9 V at C/36. The first cycle is shown in black and the second cycle is shown in red.
- FIG. 17B is a plot of the gravimetric capacity of the Na 3 V(P0 3 ) 3 N system shown in FIG. 17A, which increases beyond the theoretical capacity for cycling V ⁇ V 5+ after the first charge cycle.
- FIG. 18A is a plot of the electrochemical performance (charge/discharge) of Li 3 V(P0 3 ) 3 N cathode cycled against Li + /Li between 2 V and 4.2 V at C/15, corresponding to current density of 0.02mA/cm .
- FIG. 18B is a plot of the gravimetric capacity (up to 10 cycles) of the
- Li 3 V(P0 3 ) 3 N system shown in FIG. 18A cycled against Li + /Li between 2 V and 4.2 V at C/15.
- FIG. 19A is a plot of the electrochemical performance (charge/discharge) of Li 2+x Ti(P0 3 ) 3 N cathode cycled against Li + /Li between 1.5 V and 3.2 V at C/15, corresponding to current density of 0.015 mA/cm .
- FIG. 19B is a plot of the gravimetric capacity (up to 10 cycles) the
- Li 2+x Ti(P0 3 ) 3 N system shown in FIG. 19A cycled against Li + /Li between 1.5 V and 3.2 V at C/15.
- FIG. 20A is a plot of the electrochemical performance (charge/discharge) of Li x Fe 2 (P0 3 ) 3 N cathode cycled against Li + /Li between 1.5 V and 3.2 V at C/15, corresponding to current density of 0.012mA/cm .
- FIG. 20B is a plot of the gravimetric capacity (up to 20 cycles) of the
- Li x Fe 2 (P0 3 ) 3 N system shown in FIG. 20A cycled against Li + /Li 1.5 V and 3.2 V at C/15.
- a cubic ionic conductor compound is disclosed that can be employed as an electrode or electrolyte in electrochemical storage and ionic conduction applications.
- CUBic Ionic CONductor (or "CUBICON”) compounds have the framework formula (1)
- [MTsXjof- (1) having a space group which is either P2i3 or slightly distorted form of this space group and a general formula (2), where M is one or more charged cations in octahedral coordination, T is one or more cations that adopt tetrahedral coordination, and X denotes anions.
- the framework has a net negative charge of -n.
- the framework belongs to the same structural family as Na 3 Ti(P03)3N as evidenced by a T3X10 trimer of TX 4 tetrahedra sharing one common anion, organized around an octahedral M3 ⁇ 4 site such that each M3 ⁇ 4 octahedron is connected to three different T 3 X 10 trimers by two bridging anions that connect to two different 73 ⁇ 4 tetrahedra within the trimer.
- a variable number of additional chemical species, A can fit into the open space within this framework with the constraint that they provide charge balance and have a net charge of +n.
- the A species are cations, and even more preferable that the A species are one or more monopositive cations, it is also expected that neutral species or even anions could be accommodated in this framework.
- the A species can be relatively loosely bound and can move through a lattice such as an electrode lattice, demonstrating good ionic conduction that makes this family of compounds useful for electrochemical applications.
- cubic ionic conductor compounds examples include nitridophosphates such as Na 3 Al(P0 3 )3N, Na 3 Ti(P0 3 )3N, ⁇ &3 ⁇ ( ⁇ 0 3 ) 3 ⁇ , K 3 Ti(P0 3 ) 3 N, K 3 V(P0 3 ) 3 N, Na 2 Mg 2 (P03)3N and Na 2 Fe 2 (P03)3N, desodiated nitridophosphate compounds such as Na 2 Ti(P03)3N and NaiV(P03)3N, and Li-intercalated nitridophosphates such as LiNa 2 Ti(P03)3N and Li 2 NaiV(P03)3N.
- nitridophosphates such as Na 3 Al(P0 3 )3N, Na 3 Ti(P0 3 )3N, ⁇ &3 ⁇ ( ⁇ 0 3 ) 3 ⁇ , K 3 Ti(P0 3 ) 3 N, K 3 V(P0 3 )
- cubic ionic conductor compounds include Na 2 (NH 4 )Ti(P0 3 )3N, Na 2 AgTi(P0 3 ) 3 N, Li 3 V(P0 3 ) 3 N, Li 2 Fe 2 (P0 3 )3N, Na 2 . 5 FeVo.5(P0 3 )3N, Na 3 Mo(P0 3 ) 3 N, Na 2 V 2 (Si0 3 ) 3 N, NaFe(S0 3 ) 3 N, and Na3V(S0 2 N)3N.
- nitridophosphate compounds will be recognized as still belonging to the cubic ionic conductor family if the nitridophosphate compound undergoes tetrahedral changes such as from P0 3 N to P0 4 , P0 2 N 2 , PON 3 , PN 4 , Si0 4 , V0 4 , Mo0 4 , V0 3 N, S0 3 N, S1O 3 N, etc.
- nitridophosphates are preferred.
- the present cubic ionic conductor compound(s), and preferably the crystalline or semi-crystalline form of these compounds are also encompassed in an electrode, which can be used in the production of one or more electrochemical systems.
- methods of synthesizing the cubic ionic conductor compounds are disclosed. It is to be understood, however, that those skilled in the art may develop other structural and functional modifications without significantly departing from the scope of the disclosed invention.
- the nitridophosphate is a preferred embodiment of the CUBICON compound having a framework disclosed in formula (1) with a general formula (2) that can be employed as an electrode or electrolyte in electrochemical storage and ionic conduction applications.
- the nitridophosphate material can form crystalline particles described by a general formula (3),
- x ⁇ 3.
- x is between 0 and 3.
- x is between 1 and 3.
- x is between 2 and 3, and in even more preferred embodiment x is about 3.
- x can be greater than 3 for the nitridophosphate material of formula (3) that can accept excess ions.
- M is a framework cation in octahedral coordination
- A are non-framework cations inserted into the open space within this framework.
- a M are mobile cations and A 1 are immobile cations).
- the mobile A cations are preferably wholly or partially monopositive cations and can be mobile under ambient conditions or can become mobile at elevated temperature or at non-equilibrium electrochemical potentials. In contrast, the more highly charged M cation(s) help preserve the framework and do not freely diffuse through the solid.
- the mobile A cations can potentially be intercalated or de-intercalated when the cubic ionic conductor compound contains redox-active cations.
- the mobile cation A is preferably selected from one or more monopositive cations or cationic functional groups: hydrogen (H), lithium (Li), sodium (Na), potassium (K), silver (Ag), copper (Cu), ammonium (NH 4 ) and hydronium (H 3 O).
- the mobile A cations can be divalent.
- the immobile cation A and the framework cation M are independently selected from one or more cations that can be accommodated in the structure, such as Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Zn, Cu, Al, Ga, In, Mg, and Ca.
- the presence of [(P0 3 ) 3 N] 6 ⁇ anion and the unique crystal structure of these compounds provide desirable electrochemical properties that allow cation mobility and reversible electrochemical cycling.
- the nitridophosphate compound(s) form crystalline structure showing excellent capacity ⁇ e.g., 140 mAh/g for Na 3 _ x Li x V(P0 ) N (0 ⁇ x ⁇ 2)) at a high working potential (e.g., 4.1 V for Na 3 _ x Li x V(P0 3 ) 3 N vs. 3.4 V for LiFeP0 4 ).
- the ability to reduce M to oxidation states lower than its starting state enables the structure to accept excess mobile cations, which can further increase the theoretical capacity of the nitridophosphate compound(s). (e.g., 233 mAh/g for Li 3 NaVP 3 0 9 N (V 2+ ⁇ V 5+ ) vs. 158 mAh/g for Li 2 NaVP 3 0 9 N (V 3+ ⁇ V 5+ )).
- the crystalline particles of nitridophosphate compounds have a cubic non- centrosymmetric structure with the space group of P2i3.
- the [(P0 3 ) 3 N] 6 ⁇ anion in these compounds is formed by three P0 3 N tetrahedra sharing one N vertex as illustrated in FIG. 1A and IB of a representative nitridophosphate Na 3 VP 3 C>9N.
- the building block of the nitridophosphate is a (P0 3 ) 3 N (or ⁇ 3 (3 ⁇ 4 ⁇ ), trimer of three tetrahedra that are connected to three neighboring octahedra via corner-shared oxygens, where each pair of tetrahedra share two corners of a V0 6 octahedron.
- the M cation has octahedral coordination in the cubic ionic conductor structure as shown in FIG. 1C.
- Each corner of the MX octahedron is shared with a Z3 ⁇ 4 tetrahedron, allowing connections with two neighboring tetrahedra in each of three different T 3 X 10 trimers of tetrahedra.
- the framework structure of the cubic ionic conductor allows free movement of Na atoms from A sites and replacement of these atoms with, for example, Li.
- the structure has three different A sites for non-framework (or intercalated) cation occupancy (e.g., Nal, Na2, Na3) when x is 3.
- non-framework (or intercalated) cation occupancy e.g., Nal, Na2, Na3
- other mobile cations may or may not occupy the same A sites of the crystalline nitridophosphate compounds, particularly, since other monopositive cations, such as Li or K, have different sizes and/or bonding preferences as compared to Na.
- the non-framework Na sites can potentially also be occupied by cations with different charges.
- the cations occupying the A sites can be removed from the nitridophosphate compounds of formula (3) by electrochemical and/or chemical techniques known in the art to produce typically substoichiometric compounds that provide reversible storage capacity. While the crystal structure remains cubic, it is also possible without departing from the scope of this invention that the symmetry of the substoichiometric compounds can be different from that of the stoichiometric material. Such a change in symmetry may also occur for chemically substituted or doped nitridophosphate compounds. Since there is known variation in the type and position of the A and M cations, the structure of the nitridophosphate compound is best defined by the connectivity of its tetrahedral units.
- compounds can be recognized as belonging to this nitridophosphate structural family if they share the same network topology of tetrahedral units as the structure prototype of Na 3 Al(P0 3 ) 3 N illustrated in FIG. 1.
- Compounds recognized as still belonging to this nitridophosphate family include replacement of P0 3 N with P0 4 , P0 2 N 2 , PON 3 , PN 4 , Si0 4 , V0 4 , Mo0 4 , V0 3 N, S0 3 N, Si0 3 N, etc., so long as the network topology remains intact. While it is preferred that the nitridophosphate compound(s) of formula (3) are partially or fully crystalline, it is possible that this compound can also be amorphous.
- synthesis reactions designed to give products of formula Na 3 Mn(P0 3 ) 3 N do not give X-ray diffraction peaks characteristic of a crystalline phase even after heating at temperatures as high as 800 °C. This suggests that the components of the nitridophosphate structural family may also exist without a well-defined network topology.
- M is selected from Al, Sc, Ti, V, Cr, Mn, Fe, Ga, In, or a mixture of these cations, such as A1(III)/V(III), or as a mixture of cations whose average valence is three, such as Mg(II)/V(IV).
- a stoichiometric sodium nitridophosphate compound can have a formula Na 3 Ti(P0 3 ) 3 N (5) or Na 3 V(P0 3 ) 3 N (6). The sodium, however, can be removed from these nitridophosphate compounds by electrochemical and/or chemical techniques known in the art to produce Na 3 _ x (P0 3 ) 3 N
- lithium (Li) can be introduced into the nitridophosphate compounds of formula (7) to produce lithium-containing materials having formula: Na 3 _ x Liy (P0 3 ) 3 N (8) that show reversible storage capacity.
- these lithium-containing materials can be reversibly intercalated and de- intercalated with Li in a manner that is useful for batteries.
- Li- ion battery materials if the Li was directly inserted during the synthesis, or hybrid ion battery materials if Na was electro chemically de-intercalation prior to Li insertion.
- the number of Li cations that can be intercalated into these compounds can range between 0 and x.
- the process can occur at a potential voltage prescribed by the selected redox-active metal (M).
- M redox-active metal
- the potential voltage to intercalate Li if the M atom is Ti is about 2.8 V (vs. Li metal)
- the potential voltage to intercalate Li if the M atom is V is about 4.1 V (vs. Li metal).
- the potentials are approximate, as the each potential will vary depending on the exact state of charge/discharge (i.e. precise value of x), as well as the chosen charge rate, the battery fabrication process, and a number of other variables.
- the nitridophosphate compound of formula (3) has two mobile sodium (Na) cations per formula unit as the non-framework species A, one redox-active immobile cation (A 1 ) per formula unit also as the non- framework species A and one redox-active framework cation (M) per formula unit.
- the immobile redox-active cations A 1 and M have an average oxidation state of 2+, resulting in a charge-balanced compound.
- This nitridophosphate compound is described by a formula (9),
- a 1 and M are selected from Mg, V, Cr, Mn, Fe, Co, Ni, Zn, Ca, or a mixture of these cations.
- a 1 and M are selected from the same chemical species (e.g., Na 2 Fe 2 (P03)3N), although A 1 and M can be different as well.
- the sodium can be removed to produce a nitridophosphate compound with a formula (10), where x indicates the degree of substoichiometry with a maximum theoretical value dependent on the transition metals employed as A 1 and M.
- Lithium (Li) can be introduced into the nitridophosphate compounds of formula (10) to produce lithium based materials having formula: Na 2 _ x Li 4 (P03)3N (11) that show reversible storage capacity.
- the nitridophosphate compound of formula (3) can accept excess mobile ions by reducing the oxidation state of M below its starting state.
- the nitridophosphate compound that can accept excess mobile ions has formula: A 3+x M z - w (P0 3 ) 3 N (12), where a combination of A3 +X M Z ⁇ W yields a net charge of +6, z is the starting oxidation state of M, and w is a reduction in the oxidation state defined as 0 ⁇ w ⁇ 2, preferably 0 ⁇ w ⁇ l .
- x is between 0 and 3.
- x is between 0 and 2.
- x is between 0 and 1.
- M is a framework cation that can reduce its oxidation state below the starting state in order to accommodate the excess mobile ions (A), such as V, Cr, Mn, Ti, Co, Ni, and Fe.
- the mobile cation A is preferably selected from one or more monopositive cations or cationic functional groups: H, Li, Na, K, Ag, Cu, NH 4 and H3O. However, it is also envisioned that the mobile A cations can be divalent.
- M is vanadium (V) and the nitridophosphate compound that can accept excess mobile ions has formula,
- the theoretical capacity of such nitridophosphate compound ⁇ e.g., Li NaVP 3 (3 ⁇ 4N, -233 niAh/g; V 2+ ⁇ V 5+ ) is substantially greater than that of a compound at its initial oxidation state ⁇ e.g., Li 2 NaVP30 N, -158 niAh/g; V ⁇ ⁇ V 5 ).
- these compounds can be produced with potassium (K) ⁇ i.e., K 3 _ x Li y Na z (P0 3 ) 3 N and (14 and 15). Since the potassium will expand the crystal lattice of these compounds, it is believed that these compounds will have improved Na and/or Li mobility and improved battery charge/discharge rate performance.
- the nitridophosphate compound of formula (3) has three lithium (Li) cations per formula unit as the non-framework species A and one or more metals on the single framework site M with a net oxidation state that results in a charge -balanced compound.
- This nitridophosphate compound is described by a formula (16),
- M is selected from Al, Sc, Ti, V, Cr, Mn, Fe, Ga,
- a stoichiometric lithium nitridophosphate compound can have a formula Li 3 Ti(P0 3 ) 3 N, Li 3 V(P0 3 ) 3 N, Li 3 Al(P0 3 ) 3 N, Li 2 Mg 2 (P0 3 ) 3 N, Li x Fe 2 (P0 3 ) 3 , or Li 2+x Ti(P0 3 ) 3 N where x indicates the degree of substoichiometry with a maximum theoretical value dependent on the transition metal employed in M.
- these lithium version materials may increase the theoretical capacity of the materials by about 15%, which is advantageous for energy storage.
- the nitridophosphate compound can further be doped with other elemental (cations, anions, or neutral) and molecular species (with a radius of less than 2 A) in a manner that preserves the framework of the cubic ionic conductor compound.
- the elements which can substitute on the octahedral M sites of the framework include Li, Na, Mg, Al, Si, P, S, Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Ga, Ge, Zr, Nb, Mo, Tc, Ru, Rh, Pd, Ag, Cd, In, Sn, Sb, Hf, Ta, W, Re, Os, Ir, Pt, Au, and Hg.
- Some species which may populate the A sites and others which will reside within the voids of the framework include, but are not limited to, H, H 2 0, H3O, OH, NH 3 , NH 4 , N 2 , 0 2 , Li, Na, K, Rb, Cs, Be, Mg, Ca, Sr, Ba, Al, Si, P, S, Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Ga, Ge, Zr, Nb, Mo, Tc, Ru, Rh, Pd, Ag, Cd, In, Sn, Sb, Hf, Ta, W, Re, Os, Ir, Pt, Au, and Hg.
- a sites can be substituted with Y, La, Zr, Hf, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Th, Pa, U, Np, and Pu. Substitutions can be incorporated into the tetrahedral TX 4 group in a number of different ways.
- T B, N, Al, Si, P, S, CI, Ga, Ge, As, Se, In, Sn, Sb, Te, TI, Pb, Bi, Po
- T Ag, Co, Cr, Cu, Fe, Mn, Mo, Ni, Re, Ru, Ti, V, W, Zn, Zr.
- P0 3 N tetrahedra which are constituents of the nitridophosphate compounds
- other mixed or substituted 73 ⁇ 4 groups in which oxygen is substituted by another /?-block anion e.g., B, C, N, F, etc.
- groups such as P0 2 N 2 , PON 3 , PN 4 , P0 3 S, P0 3 F, PO2F2, PO2CI2, S0 3 N, S0 3 F, S0 3 C1, Si0 3 N, Si0 2 N 2 , SiON 3 , and SiN 4 .
- the electrochemical cell has an outer case made of metal or other material(s) or composite(s).
- the electrochemical cell is preferably a nonaqueous battery for the high power applications, though aqueous batteries may be preferred for stationary power applications where material cost is the primary concern.
- the case holds a positive electrode (cathode); a negative electrode (anode); a separator and an electrolyte solution, where the present cubic ionic conductor material(s) can be used in production of the cathode or anode.
- the electrochemical cell is a lithium-ion battery having a cathode composed of a nitridophosphate compound of the present invention.
- the electrochemical cell is a hybrid-ion battery having a cathode composed of a nitridophosphate compound of the present invention.
- the electrochemical cell is a sodium-ion battery having a cathode composed of a nitridophosphate compound of the present invention.
- the nitridophosphate compound of the present invention is used for ionic conduction.
- both the anode and cathode are formed from materials that allow lithium migration.
- lithium ions move through the electrolyte from the negative electrode to the positive electrode and insert into the cubic ionic conductor crystalline particles.
- the lithium ions move back to the anode from the cathode.
- both the anode and the cathode are in contact with an organic solvent that acts as the electrolyte.
- the electrolyte is composed of one or more salts, one or more solvents, and, optionally, one or more additives, or may alternatively be a solid state electrolyte consisting of an ionic conductor which could be lithium phosphorus oxynitride (LiPON), a sodium super-ionic conductor (NASICON), a lithium super-ionic conductor (LISICON), sulfonated tetrafluoroethylene polymer (NAFION), ⁇ "-alumina or another similar material.
- the cubic ionic conductor (or "CUBICON"), such as a nitridophosphate, can be used as a solid state electrolyte.
- cubic ionic conductor compound of formula (2) and preferably nitridophosphate of formula (3)
- cubic ionic conductor compound of formula (2) can provide a high capacity, reversible cycling, and performance high specific energy density. It is contemplated that the gravimetric capacity of the cathode containing the nitridophosphate material(s) of formula (3) are between 50 and 250 mAh g "1 , the Coulombic efficiency is between 50% and 100% and the cycling life is more than 10 cycles.
- the cathode is composed of a nitridophosphate compound, a conductive additive, and a binder.
- the composition of the nitridophosphate compound, additive, and binder is about 50% to 100% of the nitridophosphate compound, 0% to 30% of additive, and 0% to 20% of binder.
- the composition of the nitridophosphate compound, additive, and binder is 80: 10: 10.
- Another preferred embodiment is as the cathode in a flow battery cell (Bartolozzi et al, J. Power Sources, 27, 219, 1989; U.S. Pat. Publ. No.
- the electrode may include the cubic ionic conductor materials of formulae
- the cathode in addition to the cubic ionic conductor material the cathode may also have at least one other lithium mixed metal oxide (Li-MMO) made out of a material capable of serving as a cathode in a Li-ion battery or a Li-ion conductor.
- Li-MMO lithium mixed metal oxide
- materials such as NASICON (such as Na 3 M 2 (P0 4 )3 with M typically being a 3d transition metal) and LISICON (such as Li 3 M 2 (P04)3 with M typically being a 3d transition metal) can be used as these compounds have been observed to occur as impurities or degradation products when producing or utilizing nitridophosphate compounds.
- transition metal oxides such as Mn0 2 and V 2 0 5 ; transition metal sulfides such as FeS 2 , MoS 2 , and TiS 2 ; and conducting or non-conducting polymer binders such as polyaniline, polypyrrole, polyvinylidene fluoride, styrene-butadiene rubber, polyamide or melamine resin, and combinations thereof may also be present as performance-enhancing additives.
- the full-cell capacity is between 50 and 300 mAh g "1 .
- the anode may contain lithium metal, carbon, silicon, or a carbon-, lithium, or silicon-based alloy.
- the carbon may be in the form of graphite such as, for example, mesophase carbon microbeads (MCMB).
- Lithium metal anodes may be lithium mixed metal oxide (MMOs) such as LiMn0 2 and Li 4 Ti50i 2 . Alloys of lithium with transition or other metals (including metalloids) may be used, including LiAl, LiZn, Li 3 Bi, Li 3 Cd, Li 3 Sd, Li 4 Si, Li 4 . 4 Pb, Li 4 . 4 Sn, LiC 6 , Li 3 FeN 2 , Li 2 . 6 Coo.
- the anode may further comprise another metal oxide including SnO, Sn0 2 , GeO, Ge0 2 , ln 2 0, ln 2 0 3 , PbO, Pb0 2 , Pb 2 0 3 , Pb 3 0 4 , Ag 2 0, AgO, Ag 2 0 3 , Sb 2 0 3 , Sb 2 0 4 , Sb 2 0 5 , SiO, ZnO, CoO, NiO, FeO, and combinations of these metal oxides.
- the anode may further comprise a polymeric binder.
- the binder may be polyvinylidene fluoride, styrene-butadiene rubber, polyamide or melamine resin, and combinations of these binders.
- the cubic ionic conductor materials can also be successfully applied to other electrochemical cells, such as hybrid electrochemical cells (HEC), supercapacitors, fuel cells, redox-flow batteries, and other ionic conductors.
- HEC hybrid electrochemical cells
- supercapacitors fuel cells
- redox-flow batteries and other ionic conductors.
- nitridophosphate compound(s) having a formula (3) by employing a solid state or a polymeric complex method.
- One aspect of these methods is how the nitrogen and phosphorus are provided (i.e. nitrogen via a solid precursor such as phosphorus oxynitride (PON) or a gaseous precursor such as ammonia (NH 3 ), which can be provided directly as a gas or indirectly through the decomposition of a solid species).
- a solid precursor such as phosphorus oxynitride (PON) or a gaseous precursor such as ammonia (NH 3 )
- a traditional solid state method includes mixing (by grinding or using a vibratory ball mill) stoichiometric amounts of a metal oxide and either a metaphosphate (e.g., sodium metaphosphate, NaP0 3 ) or phosphorus oxynitride (PON) as well as optionally adding ammonium phosphate (NH4H2PO4) or metal phosphate PO4 (e.g. Na 3 P0 4 , FeP0 4 ) precursors to balance the stoichiometry, and heating the mixture to about 600 °C to 800 °C for about a day under flowing ammonia (NH 3 ) gas in a tube furnace.
- a metaphosphate e.g., sodium metaphosphate, NaP0 3
- PON phosphorus oxynitride
- NH4H2PO4 ammonium phosphate
- metal phosphate PO4 e.g. Na 3 P0 4 , FeP0 4
- the disclosed more effective method for synthesizing substantially pure nitridophosphate compound(s) of formula (3) based on solid state methodology, including a Pechini-type method relies on adding urea (CH 4 N 2 0) in a preferred embodiment or any another precursor (e.g., melamine) which decomposes to release NH 3 locally to the mixture of reactants.
- the method generally includes (1) mixing stoichiometric amounts of metal oxide, a metaphosphate, and urea, (2) heating the mixture under flowing ammonia gas to about 350 °C at a rate of about 300 °C/hour, and (3) heating the mixture to about 700 to 800 °C under flowing ammonia.
- the mixing of stoichiometric amounts of metal oxide, a metaphosphate, and urea can be accomplished by grinding or by using a vibratory ball mill.
- the urea typically has a mole fraction of 10 - 90% of the starting mixture, with a most preferred embodiment of 33 mole %.
- the time and temperature of the reaction may be adjusted accordingly without departing from the scope and spirit of the invention.
- the reaction temperatures range from 500 - 900 °C.
- Another embodiment is directed to a method for synthesizing substantially pure nitridophosphate compound(s) of formula (3) based on a solid state synthesis utilizing a phosphorus source other than PON or NaP0 3 .
- the method generally has the steps of (1) mixing stoichiometric amounts of metal oxide, e.g., Fe 2 0 3 , sodium acetate (NaOCH 2 CH 3 ), and diammonium hydrogen phosphate [( ⁇ 4 ) 2 ⁇ 4 ] together, preferably at Na:M:P molar ratio of 2:2:3; (2) heating the mixture to about 350 °C, and (3) heating the mixture to about 600 °C under flowing ammonia.
- metal oxide e.g., Fe 2 0 3 , sodium acetate (NaOCH 2 CH 3 )
- diammonium hydrogen phosphate [( ⁇ 4 ) 2 ⁇ 4 ] preferably at Na:M:P molar ratio of 2:2:3
- the mixture is preferably ball milled prior to each step of heating.
- the time and temperature of the reaction may be adjusted accordingly without departing from the scope and spirit of the invention.
- iron oxide (Fe 2 0 3 ), sodium acetate (NaOCH 2 CH 3 ), and diammonium hydrogen phosphate [(NH 4 ) 2 HP0 4 ] are mixed together in a Na:Fe:P molar ratio of 2:2:3 by either grinding or vibratory ball milling and heated at about 350 °C for about 8 hours.
- the mixture is preferably ground again and heated at 600 °C for 20 hours under flowing ammonia (NH 3 ) gas. It is believed that this method offers advantages in terms of the reaction time, reaction temperature, and product particle size.
- Yet another embodiment is directed to a method for synthesizing substantially pure nitridophosphate compound(s) of formula (3) based a polymer complex method (or Pechini-type method).
- the method generally involves (1) dissolving stoichiometric amounts of sodium metaphosphate, metal ammonia, e.g., ammonium vanadate, citric acid and urea in water, preferably at a molar ratio of 3: 1 :2: 1; (2) heating the solution at about 60-90 °C for 1 to 10 hours, (3) drying the resulting solution to obtain a dried gel; (4) grinding or ball-milling the dried gel; (5) heating the dried gel to about 400 °C in air for about 10-20 hours; (6) heating the resulting material at about 600-800 °C for about 10-20 hours under flowing ammonia gas. Based on the selection of the transition metals, the method can be modified to accommodate appropriate duration and temperature in order to produce the desired nitridophosphate.
- metal ammonia e.g.
- Another embodiment is directed to a method of forming the nitridophosphate compounds of formula (16).
- the method generally involves converting (at least partially) sodium in the compounds of formulas (5) - (11) into lithium through ion-exchange.
- various ion-exchange agents can be used, such as (i) LiBr in acetonitrile, (ii) a eutectic mixture of LiNOs/LiCl, or (iii) a large excess of LiBr or LiCl.
- LiBr in acetonitrile is especially suitable for nitridophosphate compound of formula (16) where M is Ti due to the higher sodium-ion mobility at moderate temperature.
- the ion-exchange agent alone, the nitridophosphate compound with sodium ion therein, or a combination of the ion-exchange agent and the nitridophosphate compound can be heated up.
- the ion-exchange agent is the eutectic mixture of LiNOs/LiCl
- the mixture can be heated up to the melting point of the salt mixture.
- the mixture of nitridophosphate and LiBr/LiCl can be heated up to around 200-400 °C ⁇ e.g., about 300 °C) for 10 to 20 hours. In some embodiments, it may be necessary to repeat the ion exchange process for several cycles, preferably 2 to 4, in order to obtain complete exchange of sodium with lithium.
- This example illustrates the synthesis of Na 3 V(P0 3 ) 3 N using the conventional solid state synthesis method of prior art.
- Sodium metaphosphate, NaP0 3 (Fisher Scientific, 99.0%) was milled with vanadium oxide, V 2 O 5 , (Alfa Aesar, 99.9%) in a vibratory ball mill for 90 minutes in a Na: V molar ratio of 3 : 1.
- the mixture was heated at 350 °C/hour up to 850 °C, and reacted at that temperature for 20 hours in a tube furnace (Thermo Scientific Lindberg/Blue M Mini-Mite) under flowing NH 3 gas (see FIG. 4A (2-6)).
- the final product was identified by X-ray diffraction to primarily contain the cubic phase Na 3 V(P0 ) N.
- This example illustrates the synthesis of Na 3 V(P0 3 ) 3 N.
- Sodium metaphosphate, NaP0 3 was ball-milled with vanadium oxide, V 2 O 5 , and urea, CO(NH 2 ) 2 , for 90 minutes in a Na:V:urea molar ratio of 3: 1 :2.
- the temperature of the mixture was raised at a rate of about 350 °C/hour up to about 700 °C and heated at 700 °C for 25 hours, 20 hours, or 12 hours in a tube furnace under flowing NH 3 gas (see FIG. 4B).
- the final product was identified by X-ray diffraction to primarily contain the cubic phase Na 3 V(P0 3 ) 3 N.
- This example illustrates the synthesis of Na 3 V(P0 3 )3N.
- Sodium metaphosphate, NaPC"3 was ball-milled with vanadium oxide, V2O5, and urea, CO(NH 2 )2, for 90 minutes in a Na:V:urea molar ratio of 3: 1 :2.
- the mixture was heated at 300 °C/hour up to about 350 °C and held at that temperature for 5 hours in a tube furnace under flowing NH 3 gas.
- the reaction product was then reground and heated at 350 °C/h up to about 700 °C for 20 hours in a tube furnace under flowing NH 3 gas, resulting in a product of higher purity than the products of Example 1 and Example 2.
- the final product was identified by X-ray diffraction.
- This example illustrates the synthesis of Na 3 V(PC"3)3N using a solid state synthesis utilizing a phosphorus source other than PON or NaPC ⁇ .
- the diammonium hydrogen phosphate [(NH 4 ) 2 HP0 4 ] was mixed with vanadium oxide (V 2 0 5 ) and sodium acetate at a molar ratio of 2:2:3 by vibratory ball milling with an ascorbic acid as an additive.
- the mixture was calcined at a temperature of 350 °C for 8 hours under flowing nitrogen (N 2 ) gas.
- the reaction product was further heated at 650 °C for 15 hours under flowing ammonia (NH 3 ) gas.
- the final product was identified by X-ray diffraction.
- This example illustrates the synthesis of Na 3 V(PC"3) 3 N using a sol-gel method (Pechini-type).
- Sodium metaphosphate, (NaPC ⁇ ), ammonium vanadate (NH 4 VO 3 ), citric acid, and urea were dissolved in 150 ml of water in the molar ratio of 3: 1 :2: 1.
- This solution was stirred at 80 °C for about 5 hours.
- the obtained orange solution was further dried in a box furnace at 120 °C for 20 hours.
- the dried gel was then reground and heated to 400 °C in air for about 15 hours.
- the resulting material was heated at 650 °C for 15 hours in a tube furnace under flowing NH 3 gas to produce Na 3 V(P0 3 ) 3 N.
- the X-ray diffraction patterns of the final products were collected in a theta-theta configuration using a Bruker D8 Advance diffractometer utilizing Cu Ka radiation and a 192 channel LynxEye position sensitive detector.
- the primary and secondary radii were set at 300 mm, and a variable divergence slit width of 12 mm was used.
- FIG. 6A is a plot of XRD patterns of Na 3 V(P0 3 ) 3 N synthesized by different methods, including (a) a conventional solid state synthesis at 700 °C for 20 hours (Example 1), (b) a solid state synthesis with urea added in an equimolar amount relative to vanadium and heating at 600 °C for 20 hours (Example 3); (c) a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours (Example 4); and (d) a sol-gel method and heating at 650 °C for 15 hours (Example 5).
- the methods disclosed in Examples 3-5 appear to be superior to the convention method of Example 1.
- Na 3 V2(P0 4 ) 3 was found to be the major impurity for products obtained from all synthesis conditions, although a small amount of unreacted V2O5 can also be found in the lowest temperature (600 °C and 700 °C) syntheses (see FIG. 4A).
- a rock salt phase vanadium nitride or vanadium oxynitride
- Sintering at 700 C for 20 hours has been found to be an appropriate synthesis condition for this method according to the X-ray diffraction patterns shown in FIG. 4B.
- urea is ball-milled with the starting materials (NaP0 3 and V 2 O 5 ) and the mixture is gently heated to the synthesis temperature (600 °C to 700 °C), the decomposition products from urea can not only reduce the oxygen concentration around the starting materials, but can also increase its contact area with the nitrogen source. Including urea together with the NaP0 3 and V2O5 starting materials helped to reduce the fraction of Na 3 V2(P0 4 ) 3 in the final product, a result attributed to these effects. Another interesting result was that adding large amounts (typically a molar excess relative to the M transition metal) of urea to the starting materials can actually reduce the minimum required synthesis temperature to 600 °C.
- FIGs. 13A and 13B are the SEM images of the Na 3 V(P0 3 ) 3 N samples obtained from a conventional solid state synthetic route and obtained using Pechini method.
- the conventional synthesis produces large particles that are generally 1 - 10 microns ( ⁇ ) in width.
- the ability of these particles to be electro chemically cycled to intercalate and de-intercalate both sodium and lithium ions indicates that this phase has a substantial ionic conductivity for Na and for Li even at room temperature.
- the reaction product of the Pechini method results in smaller particles (typically less than 3 microns in width, and less than one micron thick), which is expected to lead to improved performance in electrochemical devices due to the smaller diffusion distances required for both ions and electrons.
- This example illustrates the synthesis of Na 3 Ti(P0 3 ) 3 N using a conventional solid state method.
- Sodium metaphosphate (Fisher Scientific, 99.0%) was ball-milled with titanium dioxide (either rutile or anatase form, Alfa Aesar, 99.5%)) for 90 minutes (min) in a Na:Ti molar ratio of 3 : 1.
- the mixture was heated at 350 °C/h up to 800 °C, and held at that temperature for 20 hours in a tube furnace under flowing NH 3 gas (see FIG. 5A).
- the final product was identified by X-ray diffraction to primarily contain the cubic phase Na 3 Ti(P0 3 ) 3 N.
- This example illustrates the synthesis of Na 3 Ti(P0 3 ) 3 N.
- Sodium metaphosphate, NaP0 3 was ball-milled with Ti0 2 , and urea, CO(NH 2 ) 2 , for 90 min in a Na:Ti:urea molar ratio of 3: 1 :2.
- the temperature of the mixture was raised at a rate of about 350 °C/hour and heated at 750 °C for 25 hours, 20 hours, or 12 hours in a tube furnace under flowing NH 3 gas (see FIG. 5B).
- the final product was identified by X-ray diffraction to primarily contain the cubic phase Na 3 Ti(P0 3 ) 3 N.
- This example illustrates the synthesis of Na 3 Ti(P0 3 ) 3 N.
- Sodium metaphosphate, titanium dioxide (either rutile or anatase), and urea were ball-milled together for 90 minutes in a Na:Ti:urea molar ratio of 3: 1 :2.
- the mixture was heated at 350 °C/h up to 750 °C for 20 hours in a tube furnace under flowing NH 3 gas.
- the resulting product had higher purity than the products of Examples 5 and 6.
- the final product was identified by X-ray diffraction to primarily contain the cubic phase Na 3 Ti(P0 3 ) 3 N.
- This example illustrates the synthesis of Na 3 Ti(P0 3 ) 3 N using a solid state synthesis utilizing a phosphorus source other than PON or NaP0 3 .
- the diammonium hydrogen phosphate [(TNiH 4 ) 2 HP0 4 ] was mixed with titanium oxide (Ti0 2 ) and sodium acetate at a molar ratio of 2:2:3 by vibratory ball milling with an ascorbic acid as an additive.
- the mixture was calcined at a temperature of 350 °C for 8 hours under flowing of nitrogen (N 2 ) gas.
- the reaction product was further heated at 650 °C for 15 hours under flowing ammonia (NH 3 ) gas.
- the final product was identified by X-ray diffraction.
- the plot shows the X-ray diffraction patterns of Na 3 Ti(P0 3 ) 3 N synthesized by different methods, including (a) a conventional solid state synthesis at 750 °C for 20 hours (see Example 7), (b) a solid state synthesis with urea added in an equimolar amount relative to titanium and heating at 700 °C for 20 hours (see Example 9), (c) a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours (see Example 10).
- Pattern (d) is the partially desodiated sample, Na3_ x Ti(P03)3N with x ⁇ 0.6, that resulted from washing the product of the conventional solid state reaction with diluted HC1 (1 : 10), and which exhibits a prominent 002 peak at around 18 degrees two- theta.
- the major impurity is found to be NASICON-type Na 3 Ti 2 (P0 4 )3. It was possible to eliminate Na3Ti 2 (P0 4 )3 as an impurity in the final product by washing with dilute hydrochloride acid (1 : 10 by volume) solution.
- FIG. 5C shows the X-ray diffraction pattern of the diluted HCl-washed Na3Ti(PC"3)3N sample, which can be indexed in a simple cubic phase with the cell parameter around 9.514 A.
- FIG. 12A illustrates an SEM image of the Na 3 Ti(P0 3 ) 3 N sample obtained from the conventional solid state reaction (750 °C, 20 hours, flowing NH 3 ) of NaPC"3 and Ti0 2 (rutile, micrometer particles) starting materials.
- FIG. 12B illustrates the SEM image of the Na3Ti(PC"3)3N sample obtained by reacting (650 °C, 15 hours, flowing NH 3 ) the starting materials of Na(CH 3 COO), (NH4) 2 HP0 4 , and Ti0 2 (rutile, ⁇ 32nm particle). Relatively large (1 - 5 micron width), faceted particles are obtained by the conventional solid state reaction route. With the acetate precursor, smaller spherical particles about 1 micron in diameter are the primary reaction product. The smaller size of these particles is expected to enhance the rate performance of samples prepared in this manner.
- This example illustrates the synthesis of Na 2 Fe 2 (P03)3N using a conventional solid state method.
- Sodium metaphosphate (Fisher Scientific, 99.0%) was ball-milled with ferric iron oxide (Fe 2 03) (Alfa Aesar) for 90 min in a Na:Fe molar ratio of 1 : 1.
- the mixture was heated at 350 °C/h up to 600 °C, and held at that temperature for 20 hours in a tube furnace under flowing NH 3 gas.
- the final product was identified by X- ray diffraction to primarily contain the cubic phase Na 2 Fe 2 (P0 3 ) 3 N (see FIG. 7(a)).
- This example illustrates the synthesis of Na 2 Fe 2 (P0 3 ) 3 N.
- Sodium metaphosphate, ferric iron oxide, Fe 2 0 3 , and diammonium phosphate, ( ⁇ 4 ) 2 ⁇ 0 4 were ball-milled together for 90 min in a Na:Fe:diammonium phosphate molar ratio of 2:2: 1.
- the mixture was heated at 300 °C/hour up to 350 °C and held there for 5 hours in a tube furnace under flowing NH 3 gas.
- the product was then heated at 300 °C/h up to 600 °C and reacted at that temperature for 20 hours in a tube furnace under flowing NH 3 gas.
- FIG. 14 shows the SEM image of the obtained Na 2 Fe 2 (P0 3 ) 3 N.
- This example illustrates a production of a battery with Na 3 V(P0 3 ) 3 N as a cathode.
- the reaction product from Example 3 was ball-milled with carbon black in an 8: 1 weight ratio. This mixture was then combined with PVDF (polyvinylidene fluoride) in a 9: 1 weight ratio.
- An appropriate amount of NMP (N-Methyl-2-Pyrrolidone) was added to the mixture as the solvent to form a thick slurry.
- the slurry was then painted on an aluminum (Al) foil, with a thickness of about 5 ⁇ and a loading of about 2 - 3 mg/cm , and the whole foil was dried in a vacuum oven at 80° C for about 12 hours.
- the cycling performance was evaluated inside 2032-type coin cells, using lithium metal as the anode and a commercial Samsung electrolyte (1M LiPF 6 in ethylene carbonate/dimethyl carbonate solution). The cycling was carried out between 2.0 V and _i_ 2
- This example illustrates a production of a battery with Na 3 Ti(P0 3 ) 3 N as a cathode.
- the reaction product from Example 9 was ball-milled with carbon black and graphite in a 16: 1 : 1 weight ratio. This mixture was then mixed with PVDF (polyvinylidene fluoride) in a 9: 1 weight ratio. A minimal amount of NMP (N-Methyl-2- Pyrrolidone) was added to the mixture as the solvent to form a slurry. The slurry was then painted on an Al foil, with a thickness of about 10 ⁇ , and the whole foil was dried in a vacuum drying oven at 80° C for 10 hours.
- NMP N-Methyl-2- Pyrrolidone
- the cycling performance was evaluated inside 2032-type coin cells, using lithium metal as the anode and a commercial Samsung electrolyte (1M LiPF 6 in ethylene carbonate/dimethyl carbonate solution). The cycling was carried out between 2.0 V and 4.5 V at room temperature at a C/10 rate as shown in FIG. 8.
- FIG. 9 Cycling performance of a vanadium nitridophosphate battery made according to Example 14 is shown in FIG. 9.
- the cycling was carried out at a C/8 rate (charging or discharging of the theoretical capacity in 8 hours) between 2.5 V and 5 V.
- FIG 9 shows that the battery has a large initial storage capacity which persists over a number of cycles.
- Na is removed from the compound leaving a material with an approximate composition of NaiV(P0 3 ) 3 N.
- Li is intercalated into this compound giving an approximate final composition of NaiLi 2 V(P0 3 ) 3 N, and a composition during cycling which can be generically described as Na 3 _ x Li x V(P0 3 ) 3 N (0 ⁇ x ⁇ 2).
- the observed charge storage capacity of this material is as large as 120-140 mAh/g [essentially achieving its theoretical capacity of 145 mAh/g, calculated with respect to the starting composition of Na 3 V(P0 3 ) 3 N)], while the working potential of the battery is about 4.1 V.
- the actual gravimetric energy density of this compound is about the same as LiFeP0 4 when cycled against a Li or C anode. It is believed, however, that this nitridophosphate should exceed the gravimetric energy density of LiFeP0 4 when cycled against a higher potential anode such as Li 4 TisOi 2 .
- FIG. 8 Cycling performance of a titanium nitridophosphate battery made according to Example 15 is shown in FIG. 8, having a substantial initial storage capacity which persists over a number of cycles.
- Na is removed from the compound leaving a material with an approximate composition of Na 2 Ti(P0 3 ) 3 N.
- Li is intercalated into this compound giving an approximate final composition of Na 2 LiiTi(P0 3 ) 3 N.
- FIG. 8B the capacity is slowly decreasing over the first three charge-discharge cycles.
- the cycle life performance over 20 cycles shows good capacity retention as illustrated in FIG. 8C. Electrochemical features below -2.5V are primarily due to a NASICON-type minority phase of Na 3 V 2 (P0 4 ) 3 .
- composition during cycling can be generically described as
- Li charge storage capacity of this material is typically 50-70 mAh/g, which is close to its ideal theoretical capacity of 73 mAh/g [calculated with reference to the initial formula of Na 3 Ti(P0 3 ) 3 N)], while the working potential of the battery is about 2.8 V.
- the refined crystal structure confirms the expected cubic non-centrosymmetric structure with the space group of P2i3, and that the N(P0 3 ) 3 6" anion in these compounds is formed by three P0 3 N tetrahedral sharing one N vertex. These anions are connected to Ti0 6 octahedral through an O vertex. There are three different sodium sites in the structure which are fully occupied.
- An in-situ X-ray diffraction study of Na 3 Ti(P0 3 ) 3 N can provide useful information on the thermal stability, phase transformation processes, sodium deficiency, and sodium mobility over a wide range of temperatures.
- the in-situ X-ray diffraction patterns were collected at X-7B beam line at NSLS with the wavelength of 0.3196 A. The experiment was carried out between 25 °C and 850 °C with temperature increasing at a rate of 2 °C/min. After heating at 850 °C for half an hour, the sample was then cooled down to room temperature.
- FIG. 11 shows the in-situ XRD patterns of the heating process of Na 3 _ x Ti(P0 3 ) 3 N in the air.
- a powder sample was loaded into a 0.5 mm capillary and was spun at about 5000 rpm to reduce preferred orientation effects.
- the Rietveld refinement on this data was carried out using the TOP AS program with a pseudo-Voigt type peak shape.
- the single crystal structure of Na 3 Ti(P0 3 ) 3 N was chosen as the starting model in this refinement. Similar to the structure of Na 3 Ti(P0 3 ) 3 N, three different sodium sites can be found in the structure of Na 3 V(P0 3 ) 3 N. All of them sit at separate 4a symmetry sites and have significantly different B-factors, which perhaps indicates a different sodium binding energy and mobility for the different sites.
- This example illustrates the preparation of the vanadium based nitridophosphate that can accommodate excess mobile cations.
- the starting materials NaP0 3 (Fisher Scientific, n ⁇ 6), V 2 0 5 (Alfa Aesar, 99.6%) and urea were ball milled for 120 min in the molar ratio of 3.05:0.5:2.
- the starting materials were ball milled for 120 minutes at the molar ratio of 3: 1 :2.
- the compound Na 3 VP 3 0 N could be produced by heating this mixture to temperatures in the range of 600 °C to 800 °C and holding until the reaction was complete (typically 10 - 20 hrs).
- the final product was identified by X-ray diffraction to primarily contain the cubic phase Na 3 V(P0 3 ) 3 N.
- This example illustrates a production of a 2032-type coin cell battery with
- Example 21 The powdered reaction product from Example 21 was ball milled with carbon black (acetylene black) in a mass ratio of 8: 1 for 3 hours. PVDF (polyvinylidene difluoride) was then added into the mixture in a 1 :9 weight ratio. An appropriate amount of NMP (l-Methyl-2-pyrrolidinone) was added as a solvent to the well mixed powder to form a thick slurry. The slurry was then casted on an Al foil with the thickness of about 5 ⁇ . The foil was then dried in a vacuum oven at 80 °C for 12 hours.
- carbon black acetylene black
- PVDF polyvinylidene difluoride
- NMP l-Methyl-2-pyrrolidinone
- the dried foil was cut into several disc shape electrodes with the area of about 0.8 cm2 /each, and a typical active material loading of 5-6 mg/cm .
- a 2032-type coin cell battery was assembled in an Ar (Argon) filled glove box.
- 1M LiPF 6 dissolved in EC/DMC with a 1 :2 mass ratio (ethylene carbonate / dimethyl carbonate) was used as electrolyte and a lithium metal foil was used as the anode.
- the galvanostatic cycling of Na 3 VP 3 (3 ⁇ 4N/Li battery was carried out on an Arbin BTU-2000 cycler between 1.0 V and 4.9 V (versus Li + /Li) at a C/36 rate, corresponding to 0.045 mA/cm 2 .
- Example 21 has been confirmed by in situ XANES (X-ray absorption near edge spectroscopy) data which can probe the valence state of vanadium (V).
- vanadium starts in a 3+ oxidation state in pristine NasVPsOgN, and then is oxidized during charging to a valence near 5+ at the end of charging (Scan 29) compared to reference compounds for V 3+ (V 2 O 3 ), V 4+ (V0 2 ), and V 5+ (V 2 0 5 ).
- V is reduced and by the end of discharge (Scan 55) the V oxidation state has been reduced below the 3+ state when compared to both the pristine compound and the V 2 O 3 reference.
- the measured capacity during the first discharge is 165 mAh/g, exceeding the 144 mA/g theoretical capacity of Na 3 VP 3 C"9N for the V 5+ V 3+ reduction processes.
- This excess capacity is retained in subsequent cycles as shown in FIG. 17B. Without being bound by theory, it is believed that this excess capacity occurs due to the insertion of excess Li + ions (which are small), rather than the insertion of Na + ions (which are larger).
- the conditions may exist for the insertion of excess Na + ions, for instance, within the larger structural framework, such as K M IU P 0 9 N compounds that are expanded due to the very large size of K + ions.
- Na 2 Mg 2 P30 N was synthesized by ball-milling sodium metaphosphate with magnesium oxide (MgO) (Alfa Aesar, 99.5%) and ammonium phosphate (90%; dibasic) for 90 minutes at a molar ratio of 2:2: 1.
- MgO magnesium oxide
- ammonium phosphate 90%; dibasic
- the mixture was heated at the rate of 100 °C/h up to 800 °C and maintained at that temperature for 20 hours in a tube furnace under a flow of ammonium gas.
- the final product was identified by x-ray diffraction to contain the cubic phase Na 2 Mg 2 (P03)3N.
- Example 23 and LiBr were mixed in a molar ratio of 1 : 10.
- the mixture was heated up to 320 °C for 20 hours in a tube furnace under a flow of N 2 gas.
- the product was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio. This process was repeated 3 times.
- the final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter of about 8.9 A. This phase was identified to be Li 3 AlP 3 0 9 N.
- This example illustrates the synthesis of Li 3 _ x Na x AlP 3 09N.
- Na 3 AlP 3 (3 ⁇ 4N of Example 24 and a eutectic mixture of LiN0 3 /LiCl were mixed at a molar ratio of 1 : 10. The mixture was heated up to about 290 °C for about 10 h in a tube furnace under a flow of nitrogen gas. The product was washed with water and phosphoric acid and then mixed with another batch of fresh LiN0 3 /LiCl in the same molar ratio as before. This process was repeated 2 times. The final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter about 9.0 A. This phase was identified to be Li 3 _ x Na x AlP 3 0 9 N.
- Example 1 and LiBr were mixed in a molar ratio of 1 : 10.
- the mixture was heated up to about 320 °C for about 20 hours in a tube furnace under a flow of nitrogen gas.
- the product was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio as before. This process was repeated 4 times.
- the final product was identified by X-ray diffraction and was found to contain a cubic phase with lattice parameter about 9.15 A. This phase was identified to be Li 3 VP 3 C"9N.
- This example illustrates a production of a battery with Li 3 VP 3 C"9N as a cathode.
- the reaction product from Example 28 was mixed with carbon black and PVDF (polyvinylidene fluoride) in a 6:3: 1 weight ratio.
- a minimal amount of NMP (N-Methyl- 2-Pyrrolidone) was added to the mixture as the solvent to form a thick slurry.
- the slurry was then painted on an aluminum (Al) foil, with a thickness of about 5 ⁇ , and the whole foil was dried in a vacuum oven at 80 °C for about 6 hours. After that, the dried foil was cut into several round electrodes with the area of about 0.806 cm /each.
- the cycling performance was evaluated inside of 2032-type coin cells, using lithium metal as the anode and commercial Samsung electrolyte (1M LiPF 6 in ethylene carbonate/dimethyl carbonate solution) the electrolyte.
- the cycling was carried out between 2.0 V and 4.2 V
- FIG. 18A shows the first and second charge-discharge profiles of Li 3 VP 3 C"9N cycled against Li + /Li between 2 V and 4.2 V at C/15.
- the electrochemical active potential was found to be centered at about 3.8 V.
- a lithium ion can be reversibly cycled within the structure within this voltage window, corresponding to a specific capacity of about 73 mAh/g as illustrated in FIG. 18B.
- This example illustrates the synthesis of Li 2+x TiP309N.
- Na 3 TiP 3 09N of Example 7 and LiBr were mixed in a molar ratio of 1 : 10.
- the mixture was heated up to about 320 °C for about 20 hours in a tube furnace under a flow of N 2 gas.
- the product was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio. This process was repeated 3 times.
- the final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter about 9.30 A. This phase was identified to be Li 2+x TiP 3 0 9 N.
- Example 7 (0.005 mol) was mixed with LiBr in acetonitrile solution (1 M, 20 ml), the mixture was sealed in a glass vial in a glove box and then heated up to about 75 °C for 5 days. The product was washed with acetonitrile and methanol several times. The final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter about 9.30 A. This phase was identified to be Li 2+x TiP 3 09N.
- This example illustrates a production of a battery with Li 2+x TiP 3 09N as a cathode.
- the reaction product from Example 30 was mixed with carbon black and PVDF (polyvinylidene fluoride) in a 6:3: 1 weight ratio.
- a minimal amount of NMP (N-Methyl- 2-Pyrrolidone) was added to the mixture as the solvent to form a slurry.
- the slurry was then painted on an aluminum (Al) foil, with a thickness of about 5 ⁇ , and the whole foil was dried in a vacuum drying oven at about 80 °C for about 10 hours. After that, the dried foil was cut into several round electrodes with the area of about 0.806 cm /each.
- FIG. 19A shows the first and second voltage charge-discharge profiles of Li 2+x TiP 3 ()9N cycled against Li + /Li between 1.5 V and 3.2 V at C/15. During lithium insertion/extraction, a solid solution type reaction has been found with the active redox potential centered at about 2.5 V.
- the cycling performance of Li 2+x TiP 3 0 N shown in FIG. 19B confirms that lithium ions can be reversibly inserted/extracted within the structure of this nitridophosphate.
- Example 25 and LiBr were mixed in a molar ratio of 1 : 10.
- the mixture was heated up to about 320 °C for about 20 hours in a tube furnace under a flow of N 2 gas.
- the product was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio as before. This process was repeated 4 times.
- the final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter about 9.12 A. This phase was identified to be Li 2 Mg 2 P 3 0 9 N.
- Example 13 and LiBr were mixed in a molar ratio of 1 : 10.
- the mixture was heated up to about 300 °C for about 20 hours in a tube furnace under a flow of N 2 gas.
- the product was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio as before. This process was repeated 3 times.
- the final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter about 9.10 A. This phase was identified to be Li x Fe 2 P30 N.
- This example illustrates a production of a battery with Li x Fe 2 P30 N as a cathode.
- the reaction product from Example 34 was mixed with carbon black and PVDF (polyvinylidene fluoride) in a 6:3: 1 weight ratio.
- a minimal amount of NMP (N-Methyl- 2-Pyrrolidone) was added to the mixture as the solvent to form a thick slurry.
- the slurry was then painted on an aluminum (Al) foil, with a thickness of about 5 ⁇ , and the whole foil was dried in a vacuum oven at about 80 °C for about 6h. After that, the dried foil was cut into several round electrodes with the area of about 0.806 cm /each.
- the cycling performance was evaluated inside of 2032-type coin cells, using lithium metal as the anode and commercial Samsung electrolyte (1M LiPF 6 in ethylene carbonate/dimethyl carbonate solution) as the electrolyte.
- the cycling was carried out between 2.0 V and 4.2
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Abstract
The present invention relates to novel compositions, electrodes, electrochemical storage devices (batteries) and ionic conduction devices that use cubic ionic conductor ("CUBICON") compounds, preferably nitridophosphate compounds. The cubic ionic conductor compound have a framework formula [MT
3
X
10
]
n
- (1) and a general formula A
x
MT
3
X
10 (2), where M is a cation in octahedral coordination, T is a cation in tetrahedral coordination, X is an anion, and the framework has a net negative charge of -n and can accept excess ions, where a variable number of potentially mobile additional chemical species, A, can fit into the open space within this framework with a net charge of +n.
Description
TITLE
CUBIC IONIC CONDUCTOR CERAMICS FOR ALKALI ION BATTERIES CROSS-REFERENCE TO A RELATED APPLICATION
[0001] This application claims the benefit under 35 U.S.C. 119(e) of U.S.
Provisional Application No. 61/640,114 filed on April 30, 2012 and U.S. Provisional Application No. 61/809,198 filed on April 5, 2013. The content of both applications are incorporated herein in their entirety.
STATEMENT OF GOVERNMENT LICENSE RIGHTS
[0002] The present invention was made with government support under award number DE-SC0001294 made to the Northeastern Center for Chemical Energy Storage under EFRC program awarded by the U.S. Department of Energy and under contract number DE-AC02-98CH10886 also awarded by the U. S. Department of Energy. The United States government has certain rights in the invention.
FIELD OF THE INVENTION
[0003] The present invention relates to electrochemical storage devices containing an electrolyte with high ionic conductivity, low impedance, and high thermal stability. More particularly, this invention relates to the design, synthesis and application of novel cubic ionic conductor compounds, as exemplified by nitridophosphate type compounds such as Na3_xLiyV(P03)3N which act as an electrode for alkali ion batteries, or as a solid state electrolyte for battery or other electrochemical applications.
BACKGROUND
[0004] The demand for batteries to meet high power and high-energy system applications has resulted in substantial research and development activities to improve their safety, as well as performance. As the world becomes increasingly dependent on
portable electronic devices, and looks toward increased use of electrochemical storage devices for vehicles, power distribution load leveling and the like, it is increasingly important that three key objectives are met: performance, safety, and cost.
[0005] In recent years, extensive world-wide efforts have been undertaken to develop systems that meet such criteria. At this moment, lithium-ion batteries are the most promising candidates that meet these criteria due to their higher gravimetric and volumetric energy densities compared to other rechargeable battery systems such as lead- acid, nickel-cadmium and nickel-metal hydride batteries. Conventional lithium-ion batteries are fabricated with a lithium-containing cathode and a metallic lithium or carbon-based anode. However, conventional lithium-ion batteries still show substantial limitations in energy and power density due to the design of their cathodes.
[0006] One alternative to using a lithium-containing cathode and a metallic lithium or carbon-based anode is to use a sodium-ion battery with a sodium-containing cathode and a sodium-accepting anode to take advantage of the lower cost and greater abundance of sodium relative to lithium, especially for large-scale energy storage applications. Although such systems are promising from a cost perspective, the rate, lifetime, and voltage performance of sodium-ion batteries have to date been generally found to be inferior to those of lithium-ion batteries. A second alternative which has also proven to be more practical is to start with a sodium-containing cathode and to utilize a good Li-ion electrolyte to cycle it against a lithium-containing anode (such as Li metal), resulting in the electrochemical removal of Na from the cathode followed by the electrochemically-driven intercalation of Li into the cathode. Hybrid-ion battery performance which is competitive with Li-ion battery performance has been demonstrated in systems that include Na2FeP04F, Na3V2(P04)2F3 and Li2NaV2(P04)3. (J. Barker et al.
J. Electrochem. Soc., 154 (9) A882-A887 (2007); B.L. Cushing & J.B. Goodenough, J. Solid State Chem., 162, 176-181 (2001); and B.L. Ellis, et al, Nature Materials 6, 749- 753 (2007); incorporated herein by reference in their entirety). There is a continuing need to develop new cathode materials for Li-ion, Na-ion, and hybrid-ion batteries that would allow large-scale and cost-effective energy storage that matches or exceeds current industry standards for safe and inexpensive storage application.
SUMMARY
[0007] In view of the above-described problems, needs, and goals, a class of cubic ionic conductor compounds is provided that can be employed as an electrode in electrochemical storage and ionic conduction applications. These cubic ionic conductor (or "CUBICON") compounds have the framework formula (1) and a general formula (2)
[MTsXjof- (1)
where M is a cation in octahedral coordination, T is a cation in tetrahedral coordination, and X denotes anions. The framework has a net negative charge of -n. A variable number of additional chemical species, A, can fit into the open space within this framework with the constraint that they provide charge balance and have a net charge of +n. Although it is preferable that the A species are cations, it is also expected that neutral species or even anions could be accommodated in this framework. The A species can be relatively loosely bound and can move through a lattice, demonstrating good ionic conduction that makes this family of compounds useful for electrochemical applications.
[0008] One exemplary embodiment of the cubic ionic conductors
("CUBICON") is a family of the nitridophosphate compounds having a general formula (3)
AxM(P03)3N (3)
[0009] For the family of the nitridophosphate compounds disclosed by general formula (3), the T3X10 portion of the cubic ionic conductor framework (1) {[MT3X10]' ' ) has the composition P3O9N (T = P, X = O, N), with a net charge (-n) of -6. These compounds are known to form the cubic ionic conductor framework with A and M independently selected from a set of monopositive (Na, K), dipositive (Mg, Mn, Fe, Co), or tripositive (Al, Ga, In, Ti, V, Cr, Mn, Fe) cations. As in formula (2), M is a framework cation in octahedral coordination, and A is a variable number of non-framework cations inserted into the open space within this framework. The total A and M cations is no more than four {i.e., x < 3), and the sum of the charges of these four cations is +6 giving a net neutral composition {e.g., Na3Ti(P03)3N or Na2Fe2(P03)3N). In some embodiments, however, the total A and M cations is more than four, whereby the oxidation state of M is reduced below its starting state, while the sum of the charges of these cations is still +6 giving a net neutral composition. Based on chemical and structural analogies, it is believed that additional cations having the above (1+, 2+, 3+) or different charges or chemical species, such as neutral or ionic small molecules, can be incorporated into this structure.
[0010] It is believed that the presence of the [MT X10 anion framework and the unique crystal structure of these compounds provide desirable electrochemical and ionic properties that allow cation mobility and reversible electrochemical cycling. In particular, it has been discovered that monopositive cations, such as sodium (Na), can be
removed from these compounds at room temperature when redox-active cations are present so that the sum x + y is less than 4, preferably substantially less than 4. Electrochemical methods can be used to remove these monopositive cations and insert other monopositive cations, such as lithium (Li), in their place. The insertion and removal of cations can be done in a reversible fashion. In one exemplary embodiment, the cubic ionic conductor material has a sodium cation, a transition metal nitridophosphate anion framework, and a lithium cation that can be reversibly intercalated and de-intercalated within the crystal structure, with a variable formula such as Li2-xNaV(P03)3N (0 < x < 2).
[0011] An electrode, preferably a cathode, is composed of a cubic ionic conductor compound having a framework of formula (1), a conductive additive, e.g., carbon black, and a binder, e.g., polyvinylidene difluoride. In one embodiment, the composition of the nitridophosphate compound, additive, and binder is about 50% to 100% of the nitridophosphate compound, 0%> to 30%> of additive, and 0%> to 20%> of binder. In a preferred embodiment the composition of the nitridophosphate, additive, and binder is about 80: 10: 10. Also disclosed herein is an electrochemical cell, i.e., a battery, having a cathode, an anode, and an electrolyte solution. In a preferred embodiment, the electrochemical cell is a lithium-ion battery, a hybrid-ion battery, or a sodium-ion battery having a cathode composed of the disclosed cubic ionic conductor compound, preferably a nitridophosphate compound. Although, the lithium-ion battery, the hybrid-ion battery, or the sodium-ion battery are preferred, it is also within the scope of this disclosure that the electrochemical cell can be of other types such as a semisolid flow cell (SSFC) batteries, in which a nitridophosphate electrode is produced by suspending particles in an electrolyte solution, rather than being cast as a solid film. (Duduta et al. Advanced Energy Materials 1(4), 2011, 511-516, incorporated herein by reference in its entirety).
[0012] The cubic ionic conductor compounds, such as nitridophosphates, exhibit substantial ionic conductivity. Thus, besides functioning as battery electrodes, these cubic ionic conductor compounds can also be utilized as solid state electrolytes in which they serve as a membrane or layer with high ionic conductivity but low electronic conductivity. The cubic ionic conductor compounds can also serve as the separator between electrodes in batteries, or as a coating for electrode active material in batteries. It is believed that the most suitable elemental components for ionic conductivity
2_|_ applications are those which have a closed shell of valence electrons, such as M = Mg , Zn2+, Ca2+, Sr2+, Sc3+, Al3+, Ga3+, In3+, Ti4+, Zr4+, Hf^, V5+, Nb5+, Ta5+, Cr6+, Mo6+, and W6+. In a preferred embodiment, the nitridophosphate, as the cubic ionic conductor compound, will be substantially composed of one or a mixture of these elements.
[0013] Also disclosed herein is a method for synthesizing substantially pure nitridophosphate compound(s) based on a solid state mechanism using urea (CO(NH2)2) as a solid nitrogen source, optionally with a polymeric precursor (Pechini-type). The use of urea as a solid nitrogen source over just solid phosphorous oxynitride (PON) or ammonia gas (NH3) of prior art provides the improved reaction rates and improved product purity. The method generally has the steps of (1) mixing stoichiometric amounts of metal oxide, a metaphosphate, and urea, (2) heating the mixture under flowing ammonia gas to about 350 °C at a rate of about 300 °C/hour, and (3) heating the mixture to about 700 to 800 °C under flowing ammonia. In a preferred embodiment, the mixing of stoichiometric amounts of metal oxide, a metaphosphate, and urea can be accomplished by grinding or by using a vibratory ball mill. Depending on the selection of the metal oxide and metaphosphate, the time and temperature of the reaction may be adjusted accordingly without departing from the scope and spirit of the invention. In one
exemplary embodiment, the mixture is heated at about 350 °C under flowing ammonia gas for several hours and at about 700 to 800 °C for about 10 to 30 hours under flowing ammonia. After heating the mixture at about 350 °C under flowing ammonia gas for several hours, the reaction product is preferably subjected to grinding.
[0014] Although, substantially pure nitridophosphate compound(s) can be synthesized based on a solid state mechanism using urea (CO(NH2)2) as a solid nitrogen source, optionally with a polymeric precursor (Pechini-type), a substantially pure nitridophosphate compound(s) can also be synthesized based on a solid state mechanism utilizing a phosphorus source other than PON or NaP03.
[0015] These and other characteristics of the nitridophosphate compound and methods of synthesis of such compounds will become more apparent from the following description and illustrative embodiments, which are described in detail with reference to the accompanying drawings. Similar elements in each figure are designated by like reference numbers and, hence, subsequent detailed descriptions of such elements have been omitted for brevity.
BRIEF DESCRIPTION OF THE DRAWINGS
[0016] FIG. 1A and IB are schematic illustrations of a cubic ionic conductor building block of a I^io trimer containing three tetrahedra and the trimer's three neighboring octahedra (viewed in two different orientations) for a representative nitridophosphate, Na3VP30 N, an example of an AsMI^Xw cubic ion conductor.
[0017] FIG. 1C is a schematic illustration of the octahedral M cation coordination in the cubic ionic conductor structure of Na3VP30 N. Each ¾ octahedron is connected to three different Γ^ιο trimers by two bridging anions connected to two different 7¾ tetrahedra within the trimer.
[0018] FIG. 2 A is a schematic illustration of the framework structure (MT3X10) of the cubic ionic conductor phase with the composition of Na3V(P03)3N with Na atoms omitted for clarity.
[0019] FIG. 2B is a schematic illustration of the full structure (A3MT3X10) of the cubic ionic conductor phase with the composition of Na3V(P03)3N shown in FIG. 2A with the A species (Na atoms) shown inside the Γ^ιο framework.
[0020] FIG. 3A is a schematic illustration of the framework structure of the cubic ionic conductor phase of Na2Fe2(P03)3N with Na atoms omitted, and the Fe2 octahedron opened to reveal the Fe2 atom that sits on the position corresponding to the Na2 site of the Na3V(P03)3N structure.
[0021] FIG. 3B is a schematic illustration of the framework structure of the cubic ionic conductor phase of Na2Fe2(P03)3N shown in FIG. 3A including the Na atoms, which sit on the positions corresponding to the Nal and Na3 sites in Na3V(P03)3N.
[0022] FIG. 4A is a plot of X-ray diffraction patterns of Na3V(P03)3N obtained by a conventional solid state synthesis from different synthesis temperatures for 20 hours. From top to bottom: (1) 700 °C with urea; (2) 850 °C; (3) 800 °C; (4) 750 °C; (5) 700 °C; and (6) 675 °C.
[0023] FIG. 4B is a plot of X-ray diffraction (XRD) patterns of Na3V(P03)3N obtained from different sintering times at 700 °C. From top to bottom: (1) 25 hours, (2) 20 hours, and (3) 12 hours.
[0024] FIG. 4C is a plot of an XRD pattern of Na3V(P03)3N obtained from urea- added (100% molar ratio) starting material which was heated to 600 °C for 20 hours, with the reaction product washed by distilled water prior to X-ray analysis.
[0025] FIG. 5A is a plot of X-ray diffraction patterns of Na3Ti(P03)3N obtained by a conventional solid state synthesis at different sintering temperatures. From bottom to top: (1) 700 °C; (2) 750 °C; (3) 800 °C; and (4) 750 °C with a distilled water wash.
[0026] FIG. 5B is a plot of X-ray diffraction patterns of Na3Ti(P03)3N obtained by a conventional solid state synthesis at 750 °C. From top to bottom: (1) 25 hours, (2) 20 hours, and (3) 12 hours.
[0027] FIG. 5C is a plot of an X-ray diffraction pattern of Na3Ti(P03)3N obtained from urea-added starting materials and washed by diluted HC1 (1 : 10) solution.
[0028] FIG. 6A is a plot of XRD patterns of Na3V(P03)3N synthesized by different methods, including from bottom to top (a) a conventional solid state synthesis at 700 °C for 20 hours, (b) a solid state synthesis with urea added in an equimolar amount relative to vanadium and heating at 600 °C for 20 hours (c) a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours (d) a sol-gel method and heating at 650 °C for 15 hours.
[0029] FIG. 6B is a plot of X-ray diffraction patterns of Na3Ti(P03)3N synthesized by methods including from bottom to top (a) a conventional solid state synthesis at 750 °C for 20 hours, (b) a solid state synthesis with urea added in an equimolar amount relative to titanium and heating at 700 °C for 20 hours (c) a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours. Pattern (d) is the partially desodiated sample, Na3_xTi(P03)3N with x ~ 0.6, that resulted from washing the product of the conventional solid state reaction with diluted HC1 (1 : 10), which exhibits a prominent 002 peak at around 18 degrees two-theta.
[0030] FIG. 7 is a plot of X-ray diffraction patterns of Na2Fe2(P03)3N synthesized by different methods, including from bottom to top (a) a conventional solid state synthesis and heating at 650 °C for 20 hours and (b) using a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours.
[0031] FIG. 8 A is a plot of cycling performance of a hybrid-ion battery made with a Na3Ti(P03)3N cathode and a Li metal anode which was measured between 2.5V and 4.5V at C/10 rate during the first charge-discharge cycle.
[0032] FIG. 8B is a plot of cycling performance of a hybrid-ion battery made with a Na3Ti(P03)3N cathode and a Li metal anode which was measured between 2.5V and 4.5V at C/10 rate over the first three charge-discharge cycles.
[0033] FIG. 8C is a plot of cycle life performance over 20 cycles of a hybrid-ion battery made with a Na3Ti(P03)3N cathode and a Li metal anode which was measured between 2.5V and 4.5V at a C/5 rate.
[0034] FIG. 9 is a plot of cycling performance of a hybrid-ion battery made from
Na3V(P03)3N. The first ten charge-discharge curves were measured at room temperature at a C/8 ratio.
[0035] FIG. 10A is a plot of cycling performance of a sodium-ion battery made with a Na3Ti(P03)3N cathode (acetate method) and a Na metal anode which was measured between 2.0V and 3.5V at a C/10 rate. The low voltage plateau around 2.1 V is due to the response of a Na3Ti2(P04)3 impurity phase.
[0036] FIG. 10B is a plot of cycling performance lifetime of a sodium-ion battery made with a Na3V(P03)3N cathode (urea added solid state reaction) and a Na metal anode which was measured between 2.5V and 4.2V at a C/20 rate.
[0037] FIG. 11 is a spectrum of X-ray diffraction patterns of the in-situ heating of the HCl-washed Na3_xTi(P03)3N sample with an X-ray wavelength of 0.3196 A. (Data were collected with a 2D area detector and a temperature increasing rate of 2 °C/min up to 850 °C, and with a final scan at room temperature at the end of the run).
[0038] FIG. 12A is an SEM image of the as-prepared Na3Ti(P03)3N sample obtained from the reaction (750 °C, 20 hours, flowing Ν¾) of NaPC"3 and Ti02 (rutile, micrometer particles) starting materials.
[0039] FIG. 12B is an SEM image of the as-prepared Na3Ti(P03)3N sample obtained by reacting (650 °C, 15 hours, flowing NH3) the starting materials of Na(CH3COO), (NH4)2HP04, and Ti02 (rutile, <32nm particle).
[0040] FIG. 13A is an SEM image of the as-prepared Na3V(P03)3N sample obtained from a solid state synthetic route (700 °C, 20 hours, flowing NH3) using NaPC"3 and V2C"5 as starting materials.
[0041] FIG. 13B is an SEM image of the as-prepared Na3V(P03)3N sample obtained using the Pechini method (final reaction at 650 °C for 20 hours, flowing NH3) with NaPC"3, NH4VC"3 and citric acid used as starting materials.
[0042] FIG. 14 is an SEM image of the as-prepared Na2Fe2(PC"3)3N sample obtained from a solid state synthetic route (600 °C, 20 hours, flowing NH3) using NaPC"3, Fe2C"3 and (NH4)2HP04 as starting materials.
[0043] FIG. 15A is a plot of the XANES spectra obtained for Na3Ti(P03)3N before and after sodium removal. The oxidation state of Ti approached 4+ after desodiation, indicating that the removal of Na is nearly complete or complete.
[0044] FIG. 15B is a plot showing EXAFS analysis of the Ti X-ray absorption edge for Na3Ti(P03)3N. The local environment of Ti is not substantially changed by desodiation, suggesting that the cubic ionic conductor structure is preserved during the process of Na removal.
[0045] FIG. 16A is a plot of the in situ XANES spectrum obtained for
Na3VP3C"9N (vs. Li+/Li) during the first charge of the in situ coin cell to 4.9 V (scan 29).
[0046] FIG. 16B is a plot of the in situ XANES spectrum obtained for
Na3VP3C"9N (vs. Li+/Li) during the discharge of the in situ coin cell to 1.1 V (scan 55).
[0047] FIG. 17A is a plot of electrochemical performance of Na3VP30 N cathode cycled against Li metal. Voltage charge/discharge curve with capacity retention of Na3VP3C"9N versus Li+/Li cycled between 1 V and 4.9 V at C/36. The first cycle is shown in black and the second cycle is shown in red.
[0048] FIG. 17B is a plot of the gravimetric capacity of the Na3V(P03)3N system shown in FIG. 17A, which increases beyond the theoretical capacity for cycling V → V5+ after the first charge cycle.
[0049] FIG. 18A is a plot of the electrochemical performance (charge/discharge) of Li3V(P03)3N cathode cycled against Li+/Li between 2 V and 4.2 V at C/15, corresponding to current density of 0.02mA/cm .
[0050] FIG. 18B is a plot of the gravimetric capacity (up to 10 cycles) of the
Li3V(P03)3N system shown in FIG. 18A cycled against Li+/Li between 2 V and 4.2 V at C/15.
[0051] FIG. 19A is a plot of the electrochemical performance (charge/discharge) of Li2+xTi(P03)3N cathode cycled against Li+/Li between 1.5 V and 3.2 V at C/15, corresponding to current density of 0.015 mA/cm .
[0052] FIG. 19B is a plot of the gravimetric capacity (up to 10 cycles) the
Li2+xTi(P03)3N system shown in FIG. 19A cycled against Li+/Li between 1.5 V and 3.2 V at C/15.
[0053] FIG. 20A is a plot of the electrochemical performance (charge/discharge) of LixFe2(P03)3N cathode cycled against Li+/Li between 1.5 V and 3.2 V at C/15, corresponding to current density of 0.012mA/cm .
[0054] FIG. 20B is a plot of the gravimetric capacity (up to 20 cycles) of the
LixFe2(P03)3N system shown in FIG. 20A cycled against Li+/Li 1.5 V and 3.2 V at C/15.
DETAILED DESCRIPTION
[0055] A cubic ionic conductor compound is disclosed that can be employed as an electrode or electrolyte in electrochemical storage and ionic conduction applications. These CUBic Ionic CONductor (or "CUBICON") compounds have the framework formula (1)
[MTsXjof- (1), having a space group which is either P2i3 or slightly distorted form of this space group and a general formula (2),
where M is one or more charged cations in octahedral coordination, T is one or more cations that adopt tetrahedral coordination, and X denotes anions. The framework has a net negative charge of -n. The framework belongs to the same structural family as Na3Ti(P03)3N as evidenced by a T3X10 trimer of TX4 tetrahedra sharing one common anion, organized around an octahedral M¾ site such that each M¾ octahedron is connected to three different T3X10 trimers by two bridging anions that connect to two different 7¾ tetrahedra within the trimer. A variable number of additional chemical species, A, can fit into the open space within this framework with the constraint that they provide charge balance and have a net charge of +n. Although it is preferable that the A species are cations, and even more preferable that the A species are one or more monopositive cations, it is also expected that neutral species or even anions could be accommodated in this framework. The A species can be relatively loosely bound and can move through a lattice such as an electrode lattice, demonstrating good ionic conduction that makes this family of compounds useful for electrochemical applications. Examples of the cubic ionic conductor compounds include nitridophosphates such as Na3Al(P03)3N, Na3Ti(P03)3N, Ν&3ν(Ρ03)3Ν, K3Ti(P03)3N, K3V(P03)3N, Na2Mg2(P03)3N and Na2Fe2(P03)3N, desodiated nitridophosphate compounds such as Na2Ti(P03)3N and NaiV(P03)3N, and Li-intercalated nitridophosphates such as LiNa2Ti(P03)3N and Li2NaiV(P03)3N. Other possible examples of the cubic ionic conductor compounds include Na2(NH4)Ti(P03)3N, Na2AgTi(P03)3N, Li3V(P03)3N, Li2Fe2(P03)3N, Na2.5FeVo.5(P03)3N, Na3Mo(P03)3N, Na2V2(Si03)3N, NaFe(S03)3N, and Na3V(S02N)3N. Compounds will be recognized as still belonging to the cubic ionic conductor family if the nitridophosphate compound undergoes tetrahedral changes such as from P03N to P04, P02N2, PON3, PN4, Si04, V04, Mo04, V03N, S03N, S1O3N, etc. Of these cubic ionic conductor compounds, nitridophosphates are preferred.
[0056] The present cubic ionic conductor compound(s), and preferably the crystalline or semi-crystalline form of these compounds, are also encompassed in an electrode, which can be used in the production of one or more electrochemical systems. In addition, methods of synthesizing the cubic ionic conductor compounds are disclosed. It is to be understood, however, that those skilled in the art may develop other structural and functional modifications without significantly departing from the scope of the disclosed invention.
I. NITRIDOPHOSPHATE MATERIAL(S
[0057] The nitridophosphate is a preferred embodiment of the CUBICON compound having a framework disclosed in formula (1) with a general formula (2) that can be employed as an electrode or electrolyte in electrochemical storage and ionic conduction applications. The nitridophosphate material can form crystalline particles described by a general formula (3),
Λ (Ρ03)3Ν (3) where x < 3. In a preferred embodiment x is between 0 and 3. In a more preferred embodiment, x is between 1 and 3. In yet even more preferred embodiment, x is between 2 and 3, and in even more preferred embodiment x is about 3. In yet another embodiment, x can be greater than 3 for the nitridophosphate material of formula (3) that can accept excess ions. As in formula (2), M is a framework cation in octahedral coordination, and A are non-framework cations inserted into the open space within this framework. These non- framework A cations include a variable number of mobile or a combination of mobile and immobile cations (i.e. , Μ χ (Ρ03)3Ν or (Λ7Λ (Ρ03)3Ν, where AM are mobile cations and A1 are immobile cations). The mobile A cations are preferably wholly or partially monopositive cations and can be mobile under ambient conditions or can
become mobile at elevated temperature or at non-equilibrium electrochemical potentials. In contrast, the more highly charged M cation(s) help preserve the framework and do not freely diffuse through the solid. The mobile A cations can potentially be intercalated or de-intercalated when the cubic ionic conductor compound contains redox-active cations. The mobile cation A is preferably selected from one or more monopositive cations or cationic functional groups: hydrogen (H), lithium (Li), sodium (Na), potassium (K), silver (Ag), copper (Cu), ammonium (NH4) and hydronium (H3O). However, it is also envisioned that the mobile A cations can be divalent. The immobile cation A and the framework cation M are independently selected from one or more cations that can be accommodated in the structure, such as Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Zn, Cu, Al, Ga, In, Mg, and Ca. It is believed that the presence of [(P03)3N]6~ anion and the unique crystal structure of these compounds provide desirable electrochemical properties that allow cation mobility and reversible electrochemical cycling. For example, the nitridophosphate compound(s) form crystalline structure showing excellent capacity {e.g., 140 mAh/g for Na3_xLixV(P0 ) N (0 < x < 2)) at a high working potential (e.g., 4.1 V for Na3_xLixV(P03)3N vs. 3.4 V for LiFeP04). For the nitridophosphate compounds of formula (3), the ability to reduce M to oxidation states lower than its starting state enables the structure to accept excess mobile cations, which can further increase the theoretical capacity of the nitridophosphate compound(s). (e.g., 233 mAh/g for Li3NaVP309N (V2+ <→ V5+) vs. 158 mAh/g for Li2NaVP309N (V3+ <→ V5+)).
[0058] The crystalline particles of nitridophosphate compounds have a cubic non- centrosymmetric structure with the space group of P2i3. The [(P03)3N]6~ anion in these compounds is formed by three P03N tetrahedra sharing one N vertex as illustrated in FIG. 1A and IB of a representative nitridophosphate Na3VP3C>9N. The building block of
the nitridophosphate is a (P03)3N (or Ρ3(¾Ν), trimer of three tetrahedra that are connected to three neighboring octahedra via corner-shared oxygens, where each pair of tetrahedra share two corners of a V06 octahedron. In contrast, the M cation has octahedral coordination in the cubic ionic conductor structure as shown in FIG. 1C. Each corner of the MX octahedron is shared with a Z¾ tetrahedron, allowing connections with two neighboring tetrahedra in each of three different T3X10 trimers of tetrahedra. As illustrated in FIGs. 2A and 2B the framework structure of the cubic ionic conductor allows free movement of Na atoms from A sites and replacement of these atoms with, for example, Li. In this exemplary embodiment, the structure has three different A sites for non-framework (or intercalated) cation occupancy (e.g., Nal, Na2, Na3) when x is 3. However, without being bound by theory, it is believed that other mobile cations may or may not occupy the same A sites of the crystalline nitridophosphate compounds, particularly, since other monopositive cations, such as Li or K, have different sizes and/or bonding preferences as compared to Na. The non-framework Na sites can potentially also be occupied by cations with different charges. For example, in a crystalline nitridophosphate compound of formula (3) where x = 3 illustrated in FIG. 3A and 3B, it is believed that the second divalent immobile cation A (e.g. , Fe) atom occupies the site designated as Na2 (shown in FIG. 2B) for the different nitridophosphate compound Na3VP309N.
[0059] The cations occupying the A sites can be removed from the nitridophosphate compounds of formula (3) by electrochemical and/or chemical techniques known in the art to produce typically substoichiometric compounds that provide reversible storage capacity. While the crystal structure remains cubic, it is also possible without departing from the scope of this invention that the symmetry of the
substoichiometric compounds can be different from that of the stoichiometric material. Such a change in symmetry may also occur for chemically substituted or doped nitridophosphate compounds. Since there is known variation in the type and position of the A and M cations, the structure of the nitridophosphate compound is best defined by the connectivity of its tetrahedral units. Thus, compounds can be recognized as belonging to this nitridophosphate structural family if they share the same network topology of tetrahedral units as the structure prototype of Na3Al(P03)3N illustrated in FIG. 1. Compounds recognized as still belonging to this nitridophosphate family include replacement of P03N with P04, P02N2, PON3, PN4, Si04, V04, Mo04, V03N, S03N, Si03N, etc., so long as the network topology remains intact. While it is preferred that the nitridophosphate compound(s) of formula (3) are partially or fully crystalline, it is possible that this compound can also be amorphous. For example, synthesis reactions designed to give products of formula Na3Mn(P03)3N do not give X-ray diffraction peaks characteristic of a crystalline phase even after heating at temperatures as high as 800 °C. This suggests that the components of the nitridophosphate structural family may also exist without a well-defined network topology.
[0060] In one preferred embodiment the nitridophosphate compound of formula
(3) has three sodium (Na) cations per formula unit as the non-framework species A and one or more metals on the single framework site M with a net oxidation state that results in a charge-balanced compound. This nitridophosphate compound is described by a formula (4),
Na3 (P03)3N (4)
Preferably, M is selected from Al, Sc, Ti, V, Cr, Mn, Fe, Ga, In, or a mixture of these cations, such as A1(III)/V(III), or as a mixture of cations whose average valence is three,
such as Mg(II)/V(IV). In one exemplary embodiment a stoichiometric sodium nitridophosphate compound can have a formula Na3Ti(P03)3N (5) or Na3V(P03)3N (6). The sodium, however, can be removed from these nitridophosphate compounds by electrochemical and/or chemical techniques known in the art to produce Na3_x (P03)3N
(7) , where x indicates the degree of substoichiometry with a maximum theoretical value dependent on the transition metal employed in M. For example the maximum theoretical value for M=T\ is x=l, while the maximum theoretical value for M=V is x=2. This removal (and/or re-insertion) of Na allows these compounds to perform as intercalation- type sodium-ion batteries.
[0061] In another preferred embodiment, lithium (Li) can be introduced into the nitridophosphate compounds of formula (7) to produce lithium-containing materials having formula: Na3_xLiy (P03)3N (8) that show reversible storage capacity. In particular, these lithium-containing materials can be reversibly intercalated and de- intercalated with Li in a manner that is useful for batteries. The compounds of formula
(8) that are employed to produce electrodes for the batteries would typically be named Li- ion battery materials if the Li was directly inserted during the synthesis, or hybrid ion battery materials if Na was electro chemically de-intercalation prior to Li insertion. The number of Li cations that can be intercalated into these compounds can range between 0 and x. The process can occur at a potential voltage prescribed by the selected redox-active metal (M). For example, the potential voltage to intercalate Li if the M atom is Ti is about 2.8 V (vs. Li metal), whereas the potential voltage to intercalate Li if the M atom is V is about 4.1 V (vs. Li metal). These are suitable voltages for these materials to serve as cathodes in electrochemical devices. The higher potential (e.g., M=V) is particularly desirable, as it optimizes the energy storage density without compromising the stability of
the device. The potentials are approximate, as the each potential will vary depending on the exact state of charge/discharge (i.e. precise value of x), as well as the chosen charge rate, the battery fabrication process, and a number of other variables.
[0062] In another preferred embodiment the nitridophosphate compound of formula (3) has two mobile sodium (Na) cations per formula unit as the non-framework species A, one redox-active immobile cation (A1) per formula unit also as the non- framework species A and one redox-active framework cation (M) per formula unit. The immobile redox-active cations A1 and M have an average oxidation state of 2+, resulting in a charge-balanced compound. This nitridophosphate compound is described by a formula (9),
Na2^7 (P03)3N (9),
[0063] Preferably, A1 and M are selected from Mg, V, Cr, Mn, Fe, Co, Ni, Zn, Ca, or a mixture of these cations. Preferably, A1 and M are selected from the same chemical species (e.g., Na2Fe2(P03)3N), although A1 and M can be different as well. Similarly to the nitridophosphate compounds shown in formula (7), the sodium can be removed to produce a nitridophosphate compound with a formula
(10), where x indicates the degree of substoichiometry with a maximum theoretical value dependent on the transition metals employed as A1 and M. Lithium (Li) can be introduced into the nitridophosphate compounds of formula (10) to produce lithium based materials having formula: Na2_xLi 4 (P03)3N (11) that show reversible storage capacity.
[0064] In one embodiment, the nitridophosphate compound of formula (3) can accept excess mobile ions by reducing the oxidation state of M below its starting state. The nitridophosphate compound that can accept excess mobile ions has formula:
A3+xMz-w(P03)3N (12), where a combination of A3+XMZ~W yields a net charge of +6, z is the starting oxidation state of M, and w is a reduction in the oxidation state defined as 0<w<2, preferably 0<w<l . In a preferred embodiment x is between 0 and 3. In a more preferred embodiment, x is between 0 and 2. In even more preferred embodiment, x is between 0 and 1. In the most preferred embodiment, x is about 1. M is a framework cation that can reduce its oxidation state below the starting state in order to accommodate the excess mobile ions (A), such as V, Cr, Mn, Ti, Co, Ni, and Fe. The mobile cation A is preferably selected from one or more monopositive cations or cationic functional groups: H, Li, Na, K, Ag, Cu, NH4 and H3O. However, it is also envisioned that the mobile A cations can be divalent.
[0065] In one exemplary embodiment, M is vanadium (V) and the nitridophosphate compound that can accept excess mobile ions has formula,
A3+xV3-w(P03)3N (13), where A is Na, Li or a mixture of Na and Li cations, and x and w is between 0 and 1. Preferably x and w is about 1. The theoretical capacity of such nitridophosphate compound {e.g., Li NaVP3(¾N, -233 niAh/g; V2+ <→ V5+) is substantially greater than that of a compound at its initial oxidation state {e.g., Li2NaVP30 N, -158 niAh/g; V <→■ V5 ). It is believed that the ability to reduce V to oxidation states lower than its starting state of 3+ is enabled by the ability of the structure to accept excess mobile cations. In yet another preferred embodiment, instead of sodium in the nitridophosphate compound(s) of formula (7), (8), (10), and (11), these compounds can be produced with potassium (K) {i.e., K3_xLiyNaz (P03)3N and
(14 and 15). Since the potassium will expand the crystal lattice of these compounds, it is believed that these
compounds will have improved Na and/or Li mobility and improved battery charge/discharge rate performance.
[0066] In one embodiment the nitridophosphate compound of formula (3) has three lithium (Li) cations per formula unit as the non-framework species A and one or more metals on the single framework site M with a net oxidation state that results in a charge -balanced compound. This nitridophosphate compound is described by a formula (16),
Li3 (P03)3N (16)
[0067] In certain embodiments, M is selected from Al, Sc, Ti, V, Cr, Mn, Fe, Ga,
In, or a mixture of these cations, such as A1(III)/V(III), or as a mixture of cations whose average valence is three, such as Mg(II)/V(IV). In exemplary embodiments a stoichiometric lithium nitridophosphate compound can have a formula Li3Ti(P03)3N, Li3V(P03)3N, Li3Al(P03)3N, Li2Mg2(P03)3N, LixFe2(P03)3, or Li2+xTi(P03)3N where x indicates the degree of substoichiometry with a maximum theoretical value dependent on the transition metal employed in M. Compared to their sodium-ion analogues, these lithium version materials may increase the theoretical capacity of the materials by about 15%, which is advantageous for energy storage.
[0068] In another embodiment, the nitridophosphate compound can further be doped with other elemental (cations, anions, or neutral) and molecular species (with a radius of less than 2 A) in a manner that preserves the framework of the cubic ionic conductor compound. The elements which can substitute on the octahedral M sites of the framework include Li, Na, Mg, Al, Si, P, S, Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Ga, Ge, Zr, Nb, Mo, Tc, Ru, Rh, Pd, Ag, Cd, In, Sn, Sb, Hf, Ta, W, Re, Os, Ir, Pt, Au, and Hg. Some species which may populate the A sites and others which will reside within the
voids of the framework. These species include, but are not limited to, H, H20, H3O, OH, NH3, NH4, N2, 02, Li, Na, K, Rb, Cs, Be, Mg, Ca, Sr, Ba, Al, Si, P, S, Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Ga, Ge, Zr, Nb, Mo, Tc, Ru, Rh, Pd, Ag, Cd, In, Sn, Sb, Hf, Ta, W, Re, Os, Ir, Pt, Au, and Hg. It is also equally possible that the A sites can be substituted with Y, La, Zr, Hf, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Th, Pa, U, Np, and Pu. Substitutions can be incorporated into the tetrahedral TX4 group in a number of different ways. For instance, tetrahedral 7Ό4 groups can have a p-block element as T (T = B, N, Al, Si, P, S, CI, Ga, Ge, As, Se, In, Sn, Sb, Te, TI, Pb, Bi, Po), or one of a number of metals which are also known to adopt tetrahedral coordination ( 7Ό4 with T = Ag, Co, Cr, Cu, Fe, Mn, Mo, Ni, Re, Ru, Ti, V, W, Zn, Zr). In addition to the P03N tetrahedra which are constituents of the nitridophosphate compounds, other mixed or substituted 7¾ groups in which oxygen is substituted by another /?-block anion (e.g., B, C, N, F, etc.) are known that can form groups, such as P02N2, PON3, PN4, P03S, P03F, PO2F2, PO2CI2, S03N, S03F, S03C1, Si03N, Si02N2, SiON3, and SiN4.
II. ELECTRODES AND ELECTROCHEMICAL CELLS
[0069] As with most batteries, the electrochemical cell has an outer case made of metal or other material(s) or composite(s). The electrochemical cell is preferably a nonaqueous battery for the high power applications, though aqueous batteries may be preferred for stationary power applications where material cost is the primary concern. The case holds a positive electrode (cathode); a negative electrode (anode); a separator and an electrolyte solution, where the present cubic ionic conductor material(s) can be used in production of the cathode or anode. In a preferred embodiment, the electrochemical cell is a lithium-ion battery having a cathode composed of a nitridophosphate compound of the present invention. In another preferred embodiment, the electrochemical cell is a hybrid-ion battery having a cathode composed of a
nitridophosphate compound of the present invention. In another preferred embodiment, the electrochemical cell is a sodium-ion battery having a cathode composed of a nitridophosphate compound of the present invention. In yet another preferred embodiment, the nitridophosphate compound of the present invention is used for ionic conduction.
[0070] In one embodiment, both the anode and cathode are formed from materials that allow lithium migration. For example, when the battery discharges, lithium ions move through the electrolyte from the negative electrode to the positive electrode and insert into the cubic ionic conductor crystalline particles. During recharge/charge, the lithium ions move back to the anode from the cathode. Inside the case both the anode and the cathode are in contact with an organic solvent that acts as the electrolyte. The electrolyte is composed of one or more salts, one or more solvents, and, optionally, one or more additives, or may alternatively be a solid state electrolyte consisting of an ionic conductor which could be lithium phosphorus oxynitride (LiPON), a sodium super-ionic conductor (NASICON), a lithium super-ionic conductor (LISICON), sulfonated tetrafluoroethylene polymer (NAFION), β "-alumina or another similar material. In some embodiments, the cubic ionic conductor (or "CUBICON"), such as a nitridophosphate, can be used as a solid state electrolyte.
[0071] As a cathode in the Li-ion or hybrid ion battery, cubic ionic conductor compound of formula (2), and preferably nitridophosphate of formula (3), can provide a high capacity, reversible cycling, and performance high specific energy density. It is contemplated that the gravimetric capacity of the cathode containing the nitridophosphate material(s) of formula (3) are between 50 and 250 mAh g"1, the Coulombic efficiency is between 50% and 100% and the cycling life is more than 10 cycles. Preferably, the
cathode is composed of a nitridophosphate compound, a conductive additive, and a binder. The composition of the nitridophosphate compound, additive, and binder is about 50% to 100% of the nitridophosphate compound, 0% to 30% of additive, and 0% to 20% of binder. In a preferred embodiment the composition of the nitridophosphate compound, additive, and binder is 80: 10: 10. Another preferred embodiment is as the cathode in a flow battery cell (Bartolozzi et al, J. Power Sources, 27, 219, 1989; U.S. Pat. Publ. No. 2010/0047671 to Chiang et al.; both incorporated herein by reference in their entirety), where particles of the nitridophosphate can be suspended in an ion-conducting electrolyte and would require much less of a conductive additive (0 to 5%>) and no binder.
[0072] The electrode may include the cubic ionic conductor materials of formulae
1-13. With specific reference to the cathode in Li-ion (including hybrid-ion) applications, in addition to the cubic ionic conductor material the cathode may also have at least one other lithium mixed metal oxide (Li-MMO) made out of a material capable of serving as a cathode in a Li-ion battery or a Li-ion conductor. Preferably, materials such as NASICON (such as Na3M2(P04)3 with M typically being a 3d transition metal) and LISICON (such as Li3M2(P04)3 with M typically being a 3d transition metal) can be used as these compounds have been observed to occur as impurities or degradation products when producing or utilizing nitridophosphate compounds. Other examples of Li-MMOs may be used in the cathode include: LiM02 (M=Co, Ni, Mn, another 3d transition metal, or a combination thereof), L1M2O4 (M=Co, Ni, Mn, another 3d transition metal, or a combination of these metals), L1MPO4 (M=Fe, Co, Ni, Mn, another 3d transition metal, or a combination of these metals), Li2Cr207, Li2Cr04. Furthermore, transition metal oxides such as Mn02 and V205; transition metal sulfides such as FeS2, MoS2, and TiS2; and conducting or non-conducting polymer binders such as polyaniline, polypyrrole,
polyvinylidene fluoride, styrene-butadiene rubber, polyamide or melamine resin, and combinations thereof may also be present as performance-enhancing additives. Preferably, the full-cell capacity is between 50 and 300 mAh g"1.
[0073] With specific reference to the anode, it may contain lithium metal, carbon, silicon, or a carbon-, lithium, or silicon-based alloy. The carbon may be in the form of graphite such as, for example, mesophase carbon microbeads (MCMB). Lithium metal anodes may be lithium mixed metal oxide (MMOs) such as LiMn02 and Li4Ti50i2. Alloys of lithium with transition or other metals (including metalloids) may be used, including LiAl, LiZn, Li3Bi, Li3Cd, Li3Sd, Li4Si, Li4.4Pb, Li4.4Sn, LiC6, Li3FeN2, Li2.6Coo.4N, Li2.6Cuo.4N, and combinations of these metals. The anode may further comprise another metal oxide including SnO, Sn02, GeO, Ge02, ln20, ln203, PbO, Pb02, Pb203, Pb304, Ag20, AgO, Ag203, Sb203, Sb204, Sb205, SiO, ZnO, CoO, NiO, FeO, and combinations of these metal oxides. The anode may further comprise a polymeric binder. In a preferred embodiment, the binder may be polyvinylidene fluoride, styrene-butadiene rubber, polyamide or melamine resin, and combinations of these binders.
[0074] Although, a preferred embodiment has been described with reference to the lithium ion based electrochemical cells, it is also envisioned that the cubic ionic conductor materials can also be successfully applied to other electrochemical cells, such as hybrid electrochemical cells (HEC), supercapacitors, fuel cells, redox-flow batteries, and other ionic conductors.
III. SYNTHESIS OF THE NITRIDOPHOSPHATE MATERIALS
[0075] Also disclosed herein are the methods for synthesizing nitridophosphate compound(s) having a formula (3) by employing a solid state or a polymeric complex method. One aspect of these methods is how the nitrogen and phosphorus are provided
(i.e. nitrogen via a solid precursor such as phosphorus oxynitride (PON) or a gaseous precursor such as ammonia (NH3), which can be provided directly as a gas or indirectly through the decomposition of a solid species). In the prior art, all known syntheses used either phosphorus oxynitride (PON) or ammonia (NH3) gas as a nitrogen source, and included either ^4P03 (A = Na, K) and/or phosphorus oxynitride (PON) as a phosphorus source. A traditional solid state method includes mixing (by grinding or using a vibratory ball mill) stoichiometric amounts of a metal oxide and either a metaphosphate (e.g., sodium metaphosphate, NaP03) or phosphorus oxynitride (PON) as well as optionally adding ammonium phosphate (NH4H2PO4) or metal phosphate PO4 (e.g. Na3P04, FeP04) precursors to balance the stoichiometry, and heating the mixture to about 600 °C to 800 °C for about a day under flowing ammonia (NH3) gas in a tube furnace.
[0076] The disclosed more effective method for synthesizing substantially pure nitridophosphate compound(s) of formula (3) based on solid state methodology, including a Pechini-type method, relies on adding urea (CH4N20) in a preferred embodiment or any another precursor (e.g., melamine) which decomposes to release NH3 locally to the mixture of reactants. The method generally includes (1) mixing stoichiometric amounts of metal oxide, a metaphosphate, and urea, (2) heating the mixture under flowing ammonia gas to about 350 °C at a rate of about 300 °C/hour, and (3) heating the mixture to about 700 to 800 °C under flowing ammonia. In a preferred embodiment, the mixing of stoichiometric amounts of metal oxide, a metaphosphate, and urea can be accomplished by grinding or by using a vibratory ball mill. The urea typically has a mole fraction of 10 - 90% of the starting mixture, with a most preferred embodiment of 33 mole %. Depending on the selection of the metal starting material, phosphorus source, and nitrogen source, the time and temperature of the reaction may be adjusted accordingly
without departing from the scope and spirit of the invention. Preferably, the reaction temperatures range from 500 - 900 °C.
[0077] Another embodiment is directed to a method for synthesizing substantially pure nitridophosphate compound(s) of formula (3) based on a solid state synthesis utilizing a phosphorus source other than PON or NaP03. The method generally has the steps of (1) mixing stoichiometric amounts of metal oxide, e.g., Fe203, sodium acetate (NaOCH2CH3), and diammonium hydrogen phosphate [(ΝΗ4)2ΗΡθ4] together, preferably at Na:M:P molar ratio of 2:2:3; (2) heating the mixture to about 350 °C, and (3) heating the mixture to about 600 °C under flowing ammonia. The mixture is preferably ball milled prior to each step of heating. Depending on the selection of the metal starting material, phosphorus source, and nitrogen source, the time and temperature of the reaction may be adjusted accordingly without departing from the scope and spirit of the invention. For example, in synthesizing Na2Fe2(P03)3N, iron oxide (Fe203), sodium acetate (NaOCH2CH3), and diammonium hydrogen phosphate [(NH4)2HP04] are mixed together in a Na:Fe:P molar ratio of 2:2:3 by either grinding or vibratory ball milling and heated at about 350 °C for about 8 hours. The mixture is preferably ground again and heated at 600 °C for 20 hours under flowing ammonia (NH3) gas. It is believed that this method offers advantages in terms of the reaction time, reaction temperature, and product particle size.
[0078] Yet another embodiment is directed to a method for synthesizing substantially pure nitridophosphate compound(s) of formula (3) based a polymer complex method (or Pechini-type method). The method generally involves (1) dissolving stoichiometric amounts of sodium metaphosphate, metal ammonia, e.g., ammonium vanadate, citric acid and urea in water, preferably at a molar ratio of 3: 1 :2: 1; (2) heating
the solution at about 60-90 °C for 1 to 10 hours, (3) drying the resulting solution to obtain a dried gel; (4) grinding or ball-milling the dried gel; (5) heating the dried gel to about 400 °C in air for about 10-20 hours; (6) heating the resulting material at about 600-800 °C for about 10-20 hours under flowing ammonia gas. Based on the selection of the transition metals, the method can be modified to accommodate appropriate duration and temperature in order to produce the desired nitridophosphate.
[0079] Another embodiment is directed to a method of forming the nitridophosphate compounds of formula (16). The method generally involves converting (at least partially) sodium in the compounds of formulas (5) - (11) into lithium through ion-exchange. To propagate the conversion various ion-exchange agents can be used, such as (i) LiBr in acetonitrile, (ii) a eutectic mixture of LiNOs/LiCl, or (iii) a large excess of LiBr or LiCl. The use of LiBr in acetonitrile as an ion-exchange agent is especially suitable for nitridophosphate compound of formula (16) where M is Ti due to the higher sodium-ion mobility at moderate temperature. To accelerate the ion-exchange process, the ion-exchange agent alone, the nitridophosphate compound with sodium ion therein, or a combination of the ion-exchange agent and the nitridophosphate compound can be heated up. In one exemplary embodiment, if the ion-exchange agent is the eutectic mixture of LiNOs/LiCl, the mixture can be heated up to the melting point of the salt mixture. In another exemplary embodiment, if the ion-exchange agent is the large excess of LiBr or LiCl, the mixture of nitridophosphate and LiBr/LiCl can be heated up to around 200-400 °C {e.g., about 300 °C) for 10 to 20 hours. In some embodiments, it may be necessary to repeat the ion exchange process for several cycles, preferably 2 to 4, in order to obtain complete exchange of sodium with lithium.
[0080] While the cubic ionic conductor materials, primarily nitridophosphate materials, the electrodes and the electrochemical cells based on such materials have been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.
EXAMPLES
Example 1
[0081] This example illustrates the synthesis of Na3V(P03)3N using the conventional solid state synthesis method of prior art. Sodium metaphosphate, NaP03, (Fisher Scientific, 99.0%) was milled with vanadium oxide, V2O5, (Alfa Aesar, 99.9%) in a vibratory ball mill for 90 minutes in a Na: V molar ratio of 3 : 1. The mixture was heated at 350 °C/hour up to 850 °C, and reacted at that temperature for 20 hours in a tube furnace (Thermo Scientific Lindberg/Blue M Mini-Mite) under flowing NH3 gas (see FIG. 4A (2-6)). The final product was identified by X-ray diffraction to primarily contain the cubic phase Na3V(P0 ) N.
Example 2
[0082] This example illustrates the synthesis of Na3V(P03)3N. Sodium metaphosphate, NaP03, was ball-milled with vanadium oxide, V2O5, and urea, CO(NH2)2, for 90 minutes in a Na:V:urea molar ratio of 3: 1 :2. The temperature of the mixture was raised at a rate of about 350 °C/hour up to about 700 °C and heated at 700 °C for 25 hours, 20 hours, or 12 hours in a tube furnace under flowing NH3 gas (see FIG. 4B). The final product was identified by X-ray diffraction to primarily contain the cubic phase Na3V(P03)3N.
Example 3
[0083] This example illustrates the synthesis of Na3V(P03)3N. Sodium metaphosphate, NaPC"3, was ball-milled with vanadium oxide, V2O5, and urea, CO(NH2)2, for 90 minutes in a Na:V:urea molar ratio of 3: 1 :2. The mixture was heated at 300 °C/hour up to about 350 °C and held at that temperature for 5 hours in a tube furnace under flowing NH3 gas. The reaction product was then reground and heated at 350 °C/h up to about 700 °C for 20 hours in a tube furnace under flowing NH3 gas, resulting in a product of higher purity than the products of Example 1 and Example 2. The final product was identified by X-ray diffraction.
Example 4
[0084] This example illustrates the synthesis of Na3V(PC"3)3N using a solid state synthesis utilizing a phosphorus source other than PON or NaPC^. The diammonium hydrogen phosphate [(NH4)2HP04] was mixed with vanadium oxide (V205) and sodium acetate at a molar ratio of 2:2:3 by vibratory ball milling with an ascorbic acid as an additive. The mixture was calcined at a temperature of 350 °C for 8 hours under flowing nitrogen (N2) gas. The reaction product was further heated at 650 °C for 15 hours under flowing ammonia (NH3) gas. The final product was identified by X-ray diffraction.
Example 5
[0085] This example illustrates the synthesis of Na3V(PC"3)3N using a sol-gel method (Pechini-type). Sodium metaphosphate, (NaPC^), ammonium vanadate (NH4VO3), citric acid, and urea were dissolved in 150 ml of water in the molar ratio of 3: 1 :2: 1. This solution was stirred at 80 °C for about 5 hours. The obtained orange solution was further dried in a box furnace at 120 °C for 20 hours. The dried gel was then
reground and heated to 400 °C in air for about 15 hours. The resulting material was heated at 650 °C for 15 hours in a tube furnace under flowing NH3 gas to produce Na3V(P03)3N.
Example 6
[0086] The X-ray diffraction patterns of the final products were collected in a theta-theta configuration using a Bruker D8 Advance diffractometer utilizing Cu Ka radiation and a 192 channel LynxEye position sensitive detector. The primary and secondary radii were set at 300 mm, and a variable divergence slit width of 12 mm was used.
[0087] FIG. 6A is a plot of XRD patterns of Na3V(P03)3N synthesized by different methods, including (a) a conventional solid state synthesis at 700 °C for 20 hours (Example 1), (b) a solid state synthesis with urea added in an equimolar amount relative to vanadium and heating at 600 °C for 20 hours (Example 3); (c) a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours (Example 4); and (d) a sol-gel method and heating at 650 °C for 15 hours (Example 5). The methods disclosed in Examples 3-5 appear to be superior to the convention method of Example 1.
[0088] Na3V2(P04)3 was found to be the major impurity for products obtained from all synthesis conditions, although a small amount of unreacted V2O5 can also be found in the lowest temperature (600 °C and 700 °C) syntheses (see FIG. 4A). A rock salt phase (vanadium nitride or vanadium oxynitride) can be found above 800 °C and it becomes the only crystalline phase for the 850 °C sample. Sintering at 700 C for 20
hours has been found to be an appropriate synthesis condition for this method according to the X-ray diffraction patterns shown in FIG. 4B.
[0089] The formation of Na3 V2(P04)3 during the thermal ammono lysis of NaP03 and V2O5 is likely due to the amount of oxygen in the starting materials exceeding the stoichiometric amount needed for the reaction, and the relatively slow solid state reaction rate than occurs due to the limited contact area between solid starting materials and the nitrogen source. Urea is a good nitrogen source which decomposes into NH3 and HNCO at around 350 °C. If urea is ball-milled with the starting materials (NaP03 and V2O5) and the mixture is gently heated to the synthesis temperature (600 °C to 700 °C), the decomposition products from urea can not only reduce the oxygen concentration around the starting materials, but can also increase its contact area with the nitrogen source. Including urea together with the NaP03 and V2O5 starting materials helped to reduce the fraction of Na3V2(P04)3 in the final product, a result attributed to these effects. Another interesting result was that adding large amounts (typically a molar excess relative to the M transition metal) of urea to the starting materials can actually reduce the minimum required synthesis temperature to 600 °C. However, in order to obtain phase pure Na3V(P03)3N, water washing is still useful to remove the tiny amorphous impurity (whose solubility suggests a Na-P-0 phase) in the product obtained from this condition as is shown in FIG. 4C.
[0090] FIGs. 13A and 13B are the SEM images of the Na3V(P03)3N samples obtained from a conventional solid state synthetic route and obtained using Pechini method. The conventional synthesis produces large particles that are generally 1 - 10 microns (μ) in width. The ability of these particles to be electro chemically cycled to intercalate and de-intercalate both sodium and lithium ions indicates that this phase has a
substantial ionic conductivity for Na and for Li even at room temperature. The reaction product of the Pechini method results in smaller particles (typically less than 3 microns in width, and less than one micron thick), which is expected to lead to improved performance in electrochemical devices due to the smaller diffusion distances required for both ions and electrons.
Example 7
[0091] This example illustrates the synthesis of Na3Ti(P03)3N using a conventional solid state method. Sodium metaphosphate (Fisher Scientific, 99.0%) was ball-milled with titanium dioxide (either rutile or anatase form, Alfa Aesar, 99.5%)) for 90 minutes (min) in a Na:Ti molar ratio of 3 : 1. The mixture was heated at 350 °C/h up to 800 °C, and held at that temperature for 20 hours in a tube furnace under flowing NH3 gas (see FIG. 5A). The final product was identified by X-ray diffraction to primarily contain the cubic phase Na3Ti(P03)3N.
Example 8
[0092] This example illustrates the synthesis of Na3Ti(P03)3N. Sodium metaphosphate, NaP03, was ball-milled with Ti02, and urea, CO(NH2)2, for 90 min in a Na:Ti:urea molar ratio of 3: 1 :2. The temperature of the mixture was raised at a rate of about 350 °C/hour and heated at 750 °C for 25 hours, 20 hours, or 12 hours in a tube furnace under flowing NH3 gas (see FIG. 5B). The final product was identified by X-ray diffraction to primarily contain the cubic phase Na3Ti(P03)3N.
Example 9
[0093] This example illustrates the synthesis of Na3Ti(P03)3N. Sodium metaphosphate, titanium dioxide (either rutile or anatase), and urea were ball-milled
together for 90 minutes in a Na:Ti:urea molar ratio of 3: 1 :2. The mixture was heated at 350 °C/h up to 750 °C for 20 hours in a tube furnace under flowing NH3 gas. The resulting product had higher purity than the products of Examples 5 and 6. The final product was identified by X-ray diffraction to primarily contain the cubic phase Na3Ti(P03)3N.
Example 10
[0094] This example illustrates the synthesis of Na3Ti(P03)3N using a solid state synthesis utilizing a phosphorus source other than PON or NaP03. The diammonium hydrogen phosphate [(TNiH4)2HP04] was mixed with titanium oxide (Ti02) and sodium acetate at a molar ratio of 2:2:3 by vibratory ball milling with an ascorbic acid as an additive. The mixture was calcined at a temperature of 350 °C for 8 hours under flowing of nitrogen (N2) gas. The reaction product was further heated at 650 °C for 15 hours under flowing ammonia (NH3) gas. The final product was identified by X-ray diffraction.
Example 11
[0095] The structural characterization of the products from Examples 7-10 were investigated by X-ray diffraction and SEM imaging. The X-ray diffraction data was collected in a theta-theta configuration using a Bruker D8 Advance diffractometer using Cu Ka radiation. The X-ray diffraction patterns of final products are shown in FIG. 6B. Specifically, the plot shows the X-ray diffraction patterns of Na3Ti(P03)3N synthesized by different methods, including (a) a conventional solid state synthesis at 750 °C for 20 hours (see Example 7), (b) a solid state synthesis with urea added in an equimolar amount relative to titanium and heating at 700 °C for 20 hours (see Example 9), (c) a solid state synthesis that utilized sodium acetate and diammonium hydrogen phosphate starting materials and ascorbic acid as an additive, and heating at 650 °C for 15 hours (see
Example 10). Pattern (d) is the partially desodiated sample, Na3_xTi(P03)3N with x ~ 0.6, that resulted from washing the product of the conventional solid state reaction with diluted HC1 (1 : 10), and which exhibits a prominent 002 peak at around 18 degrees two- theta.
[0096] The major impurity is found to be NASICON-type Na3Ti2(P04)3. It was possible to eliminate Na3Ti2(P04)3 as an impurity in the final product by washing with dilute hydrochloride acid (1 : 10 by volume) solution. FIG. 5C shows the X-ray diffraction pattern of the diluted HCl-washed Na3Ti(PC"3)3N sample, which can be indexed in a simple cubic phase with the cell parameter around 9.514 A.
[0097] FIG. 12A illustrates an SEM image of the Na3Ti(P03)3N sample obtained from the conventional solid state reaction (750 °C, 20 hours, flowing NH3) of NaPC"3 and Ti02 (rutile, micrometer particles) starting materials. In contrast, FIG. 12B illustrates the SEM image of the Na3Ti(PC"3)3N sample obtained by reacting (650 °C, 15 hours, flowing NH3) the starting materials of Na(CH3COO), (NH4)2HP04, and Ti02 (rutile, <32nm particle). Relatively large (1 - 5 micron width), faceted particles are obtained by the conventional solid state reaction route. With the acetate precursor, smaller spherical particles about 1 micron in diameter are the primary reaction product. The smaller size of these particles is expected to enhance the rate performance of samples prepared in this manner.
Example 12
[0098] This example illustrates the synthesis of Na2Fe2(P03)3N using a conventional solid state method. Sodium metaphosphate (Fisher Scientific, 99.0%) was ball-milled with ferric iron oxide (Fe203) (Alfa Aesar) for 90 min in a Na:Fe molar ratio of 1 : 1. The mixture was heated at 350 °C/h up to 600 °C, and held at that temperature for
20 hours in a tube furnace under flowing NH3 gas. The final product was identified by X- ray diffraction to primarily contain the cubic phase Na2Fe2(P03)3N (see FIG. 7(a)).
Example 13
[0099] This example illustrates the synthesis of Na2Fe2(P03)3N. Sodium metaphosphate, ferric iron oxide, Fe203, and diammonium phosphate, (ΝΗ4)2ΗΡ04, were ball-milled together for 90 min in a Na:Fe:diammonium phosphate molar ratio of 2:2: 1. The mixture was heated at 300 °C/hour up to 350 °C and held there for 5 hours in a tube furnace under flowing NH3 gas. The product was then heated at 300 °C/h up to 600 °C and reacted at that temperature for 20 hours in a tube furnace under flowing NH3 gas. The final product was identified by X-ray diffraction to primarily contain the cubic phase Na2Fe2(P03)3N (see FIG. 7(b)). FIG. 14 shows the SEM image of the obtained Na2Fe2(P03)3N.
Example 14
[00100] This example illustrates a production of a battery with Na3V(P03)3N as a cathode. The reaction product from Example 3 was ball-milled with carbon black in an 8: 1 weight ratio. This mixture was then combined with PVDF (polyvinylidene fluoride) in a 9: 1 weight ratio. An appropriate amount of NMP (N-Methyl-2-Pyrrolidone) was added to the mixture as the solvent to form a thick slurry. The slurry was then painted on an aluminum (Al) foil, with a thickness of about 5 μιη and a loading of about 2 - 3 mg/cm , and the whole foil was dried in a vacuum oven at 80° C for about 12 hours. After that, the dried foil was cut into several round electrodes with the area of about 0.806 cm2 /each. The cycling performance was evaluated inside 2032-type coin cells, using lithium metal as the anode and a commercial Samsung electrolyte (1M LiPF6 in ethylene carbonate/dimethyl carbonate solution). The cycling was carried out between 2.0 V and
_i_ 2
5.0 V (versus Li /Li) at a current density of 0.045mA/cm (a rate of about C/8) as shown in FIG. 9. The cycling performance of a sodium-ion battery made with a Na3V(P03)3N cathode and a Na metal anode which was measured between 2.5 V and 4.2V at a current density of 0.020 mA/cm (a rate of about C/20) as shown in FIG. 10B.
Example 15
[00101] This example illustrates a production of a battery with Na3Ti(P03)3N as a cathode. The reaction product from Example 9 was ball-milled with carbon black and graphite in a 16: 1 : 1 weight ratio. This mixture was then mixed with PVDF (polyvinylidene fluoride) in a 9: 1 weight ratio. A minimal amount of NMP (N-Methyl-2- Pyrrolidone) was added to the mixture as the solvent to form a slurry. The slurry was then painted on an Al foil, with a thickness of about 10 μιη, and the whole foil was dried in a vacuum drying oven at 80° C for 10 hours. After that, the dried foil was cut into several round electrodes with the area of about 0.806 cm /each. The cycling performance was evaluated inside 2032-type coin cells, using lithium metal as the anode and a commercial Samsung electrolyte (1M LiPF6 in ethylene carbonate/dimethyl carbonate solution). The cycling was carried out between 2.0 V and 4.5 V at room temperature at a C/10 rate as shown in FIG. 8. The cycling performance of a sodium-ion battery made with a Na3Ti(P03)3N cathode and a Na metal anode which was measured between 2.0 V and 3.5V at a C/10 rate as shown in FIG. 10A.
Example 16
[00102] Cycling performance of a vanadium nitridophosphate battery made according to Example 14 is shown in FIG. 9. The cycling was carried out at a C/8 rate (charging or discharging of the theoretical capacity in 8 hours) between 2.5 V and 5 V. FIG 9 shows that the battery has a large initial storage capacity which persists over a
number of cycles. In the first charge cycle, Na is removed from the compound leaving a material with an approximate composition of NaiV(P03)3N. In the first discharge cycle, Li is intercalated into this compound giving an approximate final composition of NaiLi2V(P03)3N, and a composition during cycling which can be generically described as Na3_xLixV(P03)3N (0 < x < 2). The observed charge storage capacity of this material is as large as 120-140 mAh/g [essentially achieving its theoretical capacity of 145 mAh/g, calculated with respect to the starting composition of Na3V(P03)3N)], while the working potential of the battery is about 4.1 V. The actual gravimetric energy density of this compound is about the same as LiFeP04 when cycled against a Li or C anode. It is believed, however, that this nitridophosphate should exceed the gravimetric energy density of LiFeP04 when cycled against a higher potential anode such as Li4TisOi2.
Example 17
[00103] Cycling performance of a titanium nitridophosphate battery made according to Example 15 is shown in FIG. 8, having a substantial initial storage capacity which persists over a number of cycles. In the first charge cycle illustrated in FIG. 8A, Na is removed from the compound leaving a material with an approximate composition of Na2Ti(P03)3N. In the first discharge cycle, Li is intercalated into this compound giving an approximate final composition of Na2LiiTi(P03)3N. As shown in FIG. 8B the capacity is slowly decreasing over the first three charge-discharge cycles. However, the cycle life performance over 20 cycles shows good capacity retention as illustrated in FIG. 8C. Electrochemical features below -2.5V are primarily due to a NASICON-type minority phase of Na3V2(P04)3.
[00104] The composition during cycling can be generically described as
Na3_xLixTi(P03)3N (0 < x < 1). The observed Li charge storage capacity of this material is
typically 50-70 mAh/g, which is close to its ideal theoretical capacity of 73 mAh/g [calculated with reference to the initial formula of Na3Ti(P03)3N)], while the working potential of the battery is about 2.8 V.
Example 18
[00105] X-ray powder diffraction data of the Na3Ti(P03)3N sample from Example
9 was collected at the X7B beam line (λ=0.3184 A) at the NSLS (National Synchrotron Light Source, Brookhaven National Laboratory, Upton, NY), and the crystal structure was refined based on this data. A powder sample was loaded into a 0.5 mm capillary, diffraction data was collected on the 2D area detector at this beam line. Rietveld refinement was carried out on the collected X-ray diffraction data using the previously published single crystal structure of Na3Ti(P03)3N as the starting point of the refinement (Vitalij K. et al. "Fundamentals of Powder Diffraction and Structural Characterization of Materials". Springer Press, 2005; incorporated herein by reference). The refined crystal structure confirms the expected cubic non-centrosymmetric structure with the space group of P2i3, and that the N(P03)3 6" anion in these compounds is formed by three P03N tetrahedral sharing one N vertex. These anions are connected to Ti06 octahedral through an O vertex. There are three different sodium sites in the structure which are fully occupied.
[00106] A sample from Example 11 was also studied using synchrotron diffraction techniques. This material was found to have the same crystal structure but a composition which was sodium deficient as the refined formula was Na3_xTi(P03)3N with x = 0.4. X- ray absorption data also provide evidences for the sodium deficiency in the sample based on the shift of the titanium edge, confirming that this sodium can be extracted from this nitridophosphate structure type, as shown in FIG. 15A and FIG. 15B. It is believed that
the wash with dilute HCl resulted in the extraction of Na from Na3Ti(P03)3N that was originally stoichiometric, as the CI anion is a mild oxidant.
Example 19
[00107] An in-situ X-ray diffraction study of Na3Ti(P03)3N can provide useful information on the thermal stability, phase transformation processes, sodium deficiency, and sodium mobility over a wide range of temperatures. The in-situ X-ray diffraction patterns were collected at X-7B beam line at NSLS with the wavelength of 0.3196 A. The experiment was carried out between 25 °C and 850 °C with temperature increasing at a rate of 2 °C/min. After heating at 850 °C for half an hour, the sample was then cooled down to room temperature. FIG. 11 shows the in-situ XRD patterns of the heating process of Na3_xTi(P03)3N in the air. The formation of an oxidized phase above 600 °C is evident from the phase transition by which the nitridophosphate with P2[3 symmetry was converted to NASICON-type Na3Ti2(P04)3 with R-3 symmetry as temperature changes from 600 °C to 750 °C. This is a relatively high phase transition temperature for a battery cathode material, and indicates a good potential for stable and safe long term operation.
Example 20
[00108] The crystal structure of Na3V(P03)3N was determined using synchrotron
X-ray diffraction data. X-ray diffraction data was collected at X-14A beam line (λ=0.7717Α) with a ID PSD detector at the NSLS. A powder sample was loaded into a 0.5 mm capillary and was spun at about 5000 rpm to reduce preferred orientation effects. The Rietveld refinement on this data was carried out using the TOP AS program with a pseudo-Voigt type peak shape. The single crystal structure of Na3Ti(P03)3N was chosen as the starting model in this refinement. Similar to the structure of Na3Ti(P03)3N, three different sodium sites can be found in the structure of Na3V(P03)3N. All of them sit at
separate 4a symmetry sites and have significantly different B-factors, which perhaps indicates a different sodium binding energy and mobility for the different sites.
[00109] The vanadium valence in Na3V(P03)3N were probed using XANES data collected at the X-19A beam line at the NSLS. The edge position of Na3V(P03)3N is found at a much lower energy area than V204 (ΔΕ >2eV), confidently demonstrating that the oxidation state of vanadium in the as-prepared sample is substantially lower than +4. Since the absorption edge curves of Na3V(P03)3N and V203 cross, it is difficult to know whether the oxidation state of vanadium in Na3V(P03)3N is higher or lower than +3, but it is certainly near +3.
Example 21
[00110] This example illustrates the preparation of the vanadium based nitridophosphate that can accommodate excess mobile cations. The starting materials NaP03 (Fisher Scientific, n ~ 6), V205 (Alfa Aesar, 99.6%) and urea were ball milled for 120 min in the molar ratio of 3.05:0.5:2. Alternatively, the starting materials were ball milled for 120 minutes at the molar ratio of 3: 1 :2. The compound Na3VP30 N could be produced by heating this mixture to temperatures in the range of 600 °C to 800 °C and holding until the reaction was complete (typically 10 - 20 hrs). The final product was identified by X-ray diffraction to primarily contain the cubic phase Na3V(P03)3N.
Example 22
[00111] This example illustrates a production of a 2032-type coin cell battery with
Na3V(P03)3N as a cathode. The powdered reaction product from Example 21 was ball milled with carbon black (acetylene black) in a mass ratio of 8: 1 for 3 hours. PVDF (polyvinylidene difluoride) was then added into the mixture in a 1 :9 weight ratio. An
appropriate amount of NMP (l-Methyl-2-pyrrolidinone) was added as a solvent to the well mixed powder to form a thick slurry. The slurry was then casted on an Al foil with the thickness of about 5 μιη. The foil was then dried in a vacuum oven at 80 °C for 12 hours. After that, the dried foil was cut into several disc shape electrodes with the area of about 0.8 cm2 /each, and a typical active material loading of 5-6 mg/cm . A 2032-type coin cell battery was assembled in an Ar (Argon) filled glove box. In addition to the cathode film, 1M LiPF6 dissolved in EC/DMC with a 1 :2 mass ratio (ethylene carbonate / dimethyl carbonate) was used as electrolyte and a lithium metal foil was used as the anode. The galvanostatic cycling of Na3VP3(¾N/Li battery was carried out on an Arbin BTU-2000 cycler between 1.0 V and 4.9 V (versus Li+/Li) at a C/36 rate, corresponding to 0.045 mA/cm2.
Example 23
[00112] The reduction of vanadium in the Na3VP3 (¾N compound produced in
Example 21 has been confirmed by in situ XANES (X-ray absorption near edge spectroscopy) data which can probe the valence state of vanadium (V). As shown in FIG. 16A, vanadium starts in a 3+ oxidation state in pristine NasVPsOgN, and then is oxidized during charging to a valence near 5+ at the end of charging (Scan 29) compared to reference compounds for V3+ (V2O3), V4+ (V02), and V5+ (V205). On the subsequent discharge shown in FIG. 16B, V is reduced and by the end of discharge (Scan 55) the V oxidation state has been reduced below the 3+ state when compared to both the pristine compound and the V2O3 reference.
[00113] The ability of the structural framework to accept excess mobile cations can also been seen in the electrochemical cycling data of batteries constructed with a Na3VP3C"9N cathode, a Li metal anode, and a Li ion electrolyte. As illustrated in FIG.
17A, the gravimetric capacity of the cathode during the initial charge, where Na ions are removed, is measured to be 140 mAh/g. This value is close to the theoretical capacity of 144 mA/g of the pristine material expected when only vanadium oxidation (V3+ V5 ) occurs. The measured capacity during the first discharge is 165 mAh/g, exceeding the 144 mA/g theoretical capacity of Na3VP3C"9N for the V5+ V3+ reduction processes. This excess capacity is retained in subsequent cycles as shown in FIG. 17B. Without being bound by theory, it is believed that this excess capacity occurs due to the insertion of excess Li+ ions (which are small), rather than the insertion of Na+ ions (which are larger). In some embodiments, the conditions may exist for the insertion of excess Na+ ions, for instance, within the larger structural framework, such as K MIUP 09N compounds that are expanded due to the very large size of K+ ions. The ability to insert excess ions demonstrates that substantially larger gravimetric capacities can be accomplished with the present method than in a typical stoichiometric exchange. It is believed that this excess capacity will most likely occur at voltages suitable for battery anodes, enhancing the suitability of this system for applications such as symmetric batteries, or as epitaxial thin film batteries.
Example 24
[00114] This example illustrates the synthesis of Na3AlP309N. Sodium metaphosphate (Fisher scientific, 99.0%) was ball-milled with A1203 (Alfa Aesar, 99.0%) for 90 minutes at a molar ratio of 6: 1. The mixture was heated at the rate of 100 °C/h up to 775 °C and maintained at that temperature for 20 hours in a tube furnace under a flow of ammonium gas. The final product was identified by x-ray diffraction to primarily contain the cubic phase Na3Al(P03)3N.
Example 25
[00115] Similarly to Example 21, Na2Mg2P30 N was synthesized by ball-milling sodium metaphosphate with magnesium oxide (MgO) (Alfa Aesar, 99.5%) and ammonium phosphate (90%; dibasic) for 90 minutes at a molar ratio of 2:2: 1. The mixture was heated at the rate of 100 °C/h up to 800 °C and maintained at that temperature for 20 hours in a tube furnace under a flow of ammonium gas. The final product was identified by x-ray diffraction to contain the cubic phase Na2Mg2(P03)3N.
Example 26
[00116] This example illustrates the synthesis of Li3AlP309N. Na3AlP309N of
Example 23 and LiBr were mixed in a molar ratio of 1 : 10. The mixture was heated up to 320 °C for 20 hours in a tube furnace under a flow of N2 gas. The product was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio. This process was repeated 3 times. The final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter of about 8.9 A. This phase was identified to be Li3AlP309N.
Example 27
This example illustrates the synthesis of Li3_xNaxAlP309N. Na3AlP3(¾N of Example 24 and a eutectic mixture of LiN03/LiCl were mixed at a molar ratio of 1 : 10. The mixture was heated up to about 290 °C for about 10 h in a tube furnace under a flow of nitrogen gas. The product was washed with water and phosphoric acid and then mixed with another batch of fresh LiN03/LiCl in the same molar ratio as before. This process was repeated 2 times. The final product was identified by X-ray diffraction to contain a cubic
phase with lattice parameter about 9.0 A. This phase was identified to be Li3_ xNaxAlP309N.
Example 28
[00117] This example illustrates the synthesis of Li3V(P03)3N. Na3VP309N of
Example 1 and LiBr were mixed in a molar ratio of 1 : 10. The mixture was heated up to about 320 °C for about 20 hours in a tube furnace under a flow of nitrogen gas. The product was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio as before. This process was repeated 4 times. The final product was identified by X-ray diffraction and was found to contain a cubic phase with lattice parameter about 9.15 A. This phase was identified to be Li3VP3C"9N.
Example 29
[00118] This example illustrates a production of a battery with Li3VP3C"9N as a cathode. The reaction product from Example 28 was mixed with carbon black and PVDF (polyvinylidene fluoride) in a 6:3: 1 weight ratio. A minimal amount of NMP (N-Methyl- 2-Pyrrolidone) was added to the mixture as the solvent to form a thick slurry. The slurry was then painted on an aluminum (Al) foil, with a thickness of about 5 μιη, and the whole foil was dried in a vacuum oven at 80 °C for about 6 hours. After that, the dried foil was cut into several round electrodes with the area of about 0.806 cm /each. The cycling performance was evaluated inside of 2032-type coin cells, using lithium metal as the anode and commercial Samsung electrolyte (1M LiPF6 in ethylene carbonate/dimethyl carbonate solution) the electrolyte. The cycling was carried out between 2.0 V and 4.2 V
_i_ 2
(versus Li /Li) at room temperature at a C/15 rate, corresponding to 0.02 mA/cm . FIG. 18A shows the first and second charge-discharge profiles of Li3VP3C"9N cycled against Li+/Li between 2 V and 4.2 V at C/15. The electrochemical active potential was found to
be centered at about 3.8 V. A lithium ion can be reversibly cycled within the structure within this voltage window, corresponding to a specific capacity of about 73 mAh/g as illustrated in FIG. 18B.
Example 30
This example illustrates the synthesis of Li2+xTiP309N. Na3TiP309N of Example 7 and LiBr were mixed in a molar ratio of 1 : 10. The mixture was heated up to about 320 °C for about 20 hours in a tube furnace under a flow of N2 gas. The product was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio. This process was repeated 3 times. The final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter about 9.30 A. This phase was identified to be Li2+xTiP309N.
Example 31
[00119] This example illustrates the synthesis Of Li2+xTiP309N. Na3TiP3C"9N of
Example 7 (0.005 mol) was mixed with LiBr in acetonitrile solution (1 M, 20 ml), the mixture was sealed in a glass vial in a glove box and then heated up to about 75 °C for 5 days. The product was washed with acetonitrile and methanol several times. The final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter about 9.30 A. This phase was identified to be Li2+xTiP309N.
Example 32
[00120] This example illustrates a production of a battery with Li2+xTiP309N as a cathode. The reaction product from Example 30 was mixed with carbon black and PVDF (polyvinylidene fluoride) in a 6:3: 1 weight ratio. A minimal amount of NMP (N-Methyl- 2-Pyrrolidone) was added to the mixture as the solvent to form a slurry. The slurry was
then painted on an aluminum (Al) foil, with a thickness of about 5 μιη, and the whole foil was dried in a vacuum drying oven at about 80 °C for about 10 hours. After that, the dried foil was cut into several round electrodes with the area of about 0.806 cm /each. The cycling performance was evaluated inside of 2032-type coin cells, using lithium metal as the anode and commercial Samsung electrolyte (1M LiPF6 in ethylene carbonate/dimethyl carbonate solution) as the electrolyte. The cycling was carried out between 1.5 V and 3.2 V at room temperature at a CI 10 rate, corresponding to 0.015 mA/cm . FIG. 19A shows the first and second voltage charge-discharge profiles of Li2+xTiP3()9N cycled against Li+/Li between 1.5 V and 3.2 V at C/15. During lithium insertion/extraction, a solid solution type reaction has been found with the active redox potential centered at about 2.5 V. The cycling performance of Li2+xTiP30 N shown in FIG. 19B confirms that lithium ions can be reversibly inserted/extracted within the structure of this nitridophosphate.
Example 33
[00121] This example illustrates the synthesis of Li2Mg2P309N. Na2Mg2P309N of
Example 25 and LiBr were mixed in a molar ratio of 1 : 10. The mixture was heated up to about 320 °C for about 20 hours in a tube furnace under a flow of N2 gas. The product was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio as before. This process was repeated 4 times. The final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter about 9.12 A. This phase was identified to be Li2Mg2P309N.
Example 34
[00122] This example illustrates the synthesis of LixFe2P309N. Na2Fe2P309N of
Example 13 and LiBr were mixed in a molar ratio of 1 : 10. The mixture was heated up to about 300 °C for about 20 hours in a tube furnace under a flow of N2 gas. The product
was washed with methanol and then mixed with another batch of fresh LiBr in the same molar ratio as before. This process was repeated 3 times. The final product was identified by X-ray diffraction to contain a cubic phase with lattice parameter about 9.10 A. This phase was identified to be LixFe2P30 N.
Example 35
[00123] This example illustrates a production of a battery with LixFe2P30 N as a cathode. The reaction product from Example 34 was mixed with carbon black and PVDF (polyvinylidene fluoride) in a 6:3: 1 weight ratio. A minimal amount of NMP (N-Methyl- 2-Pyrrolidone) was added to the mixture as the solvent to form a thick slurry. The slurry was then painted on an aluminum (Al) foil, with a thickness of about 5 μιη, and the whole foil was dried in a vacuum oven at about 80 °C for about 6h. After that, the dried foil was cut into several round electrodes with the area of about 0.806 cm /each. The cycling performance was evaluated inside of 2032-type coin cells, using lithium metal as the anode and commercial Samsung electrolyte (1M LiPF6 in ethylene carbonate/dimethyl carbonate solution) as the electrolyte. The cycling was carried out between 2.0 V and 4.2
_i_ 2
V (versus Li /Li) at room temperature at a C/20 rate, corresponding to 0.012 mA/cm (see FIG. 20 A). An initial discharge capacity of 130 mAh/g was achieved with electrochemical active potential centered at about 2.2 V. However, serious capacity fading was observed after the first cycle as illustrated in FIG. 20B. After 10 cycles, the capacity stabilized at about half of the theoretical capacity (theoretical capacity is -135 mAh/g). A large voltage hysteresis between charge and discharge profile was also observed. The active potential during charge process was found to be centered at about 3.5V.
[00124] All publications and patents mentioned in the above specification are incorporated by reference in their entireties in this disclosure. Various modifications and variations of the described nanomaterials and methods will be apparent to those skilled in the art without departing from the scope and spirit of the invention. Although the disclosure has been described in connection with specific preferred embodiments, it should be understood that the invention as claimed should not be unduly limited to such specific embodiments. Indeed, those skilled in the art will recognize, or be able to ascertain using the teaching of this disclosure and no more than routine experimentation, many equivalents to the specific embodiments of the disclosed invention described. Such equivalents are intended to be encompassed by the following claims.
Claims
CLAIMS:
1 An electrode comprising:
a cubic ionic conductor compound having a framework of formula (1) with a general chemical formula (2)
where M is a cation in octahedral coordination, T is a cation in tetrahedral coordination, is an anion, n is a net charge of the framework between 0 and 16, A is a variable number of additional non-framework chemical species that can fit into an open space within the framework with a net charge of +n, and x is less than 10,
wherein a T3X10 trimer of a 7¾ tetrahedra share one common X anion, organized around an octahedral ¾ site such that each ¾ octahedron is connected to three different T3X10 trimers by two bridging X anions connected to two different TX4 tetrahedra within the T3X10 trimer.
2. The electrode of claim 1, wherein the framework can accept excess ions.
3. The electrode of claim 1 further comprising a conductive additive and a binder.
4. The electrode of claim 1, wherein A is a cation.
5. The electrode of claim 1, wherein A is loosely bound and can move through an electrode lattice.
6. The electrode of claim 1 , wherein A is selected from wholly or partially mobile cations (AM), or a combination of partially mobile and partially immobile cations
7. The electrode of claim 1, wherein TX4 tetrahedra comprises PO3N, P04, PO2N2, PON3, PN4, S1O4, V04, M0O4, VO3N, SO3N, or S1O3N.
8. The electrode of claim 1, wherein the cubic ionic conductor compound is
9. The electrode of claim 1, wherein the cubic ionic conductor compound belongs to a structural family of Na3Ti(PC"3)3N.
10. The electrode of claim 1, wherein the cubic ionic conductor compound further comprises dopants selected from the group of cations, anions, neutral atoms, and small molecules having a radius of less than 2 A in a manner that preserves the framework.
11. The electrode of claim 10, wherein the dopant is selected from the group
consisting of H, H20, H30, OH, NH3, NH4, N2, 02, Li, Na, K, Rb, Cs, Be, Mg, Ca, Sr, Ba, Y, La, Zr, Hf, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Th, Pa, U, Np, and Pu and populates one or more A sites within voids of the framework.
12. The electrode of claim 10, wherein the dopant is selected from the group
consisting of Li, Na, Mg, Al, Si, P, S, Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Ga, Ge, Zr, Nb, Mo, Tc, Ru, Rh, Pd, Ag, Cd, In, Sn, Sb, Hf, Ta, W, Re, Os, Ir, Pt, Au, and Hg and can substitute the M sites of the framework.
13. The electrode of claim 1, wherein T is phosphorus (P), X is oxygen (O), nitrogen (N), or a combination thereof, and n is 6.
14. The electrode of claim 13, wherein T3X10 trimer of the formula (1) is P3O9N
forming a nitridophosphate compound having a general formula (3) Λ (Ρ03)3Ν (3) where x < 3 and a combination of AXM yields a net charge of +6.
15. The electrode of claim 14, wherein A is an ionic or neutral species.
16. The electrode of claim 15, wherein A is selected from wholly or partially mobile cations (AM), or a combination of partially mobile and partially immobile cations
17. The electrode of claim 15, wherein M is Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Zn, Cu, Al, Ga, In, Mg, Ca or a combination thereof.
18. The electrode of claim 16, wherein the cation AM is mobile under ambient
temperature and equilibrium electrochemical potential, under an elevated temperature, under a non-equilibrium electrochemical potential or under combinations of these conditions.
19. The electrode of claim 18, wherein the cation AM is a monopositive cation selected from H, Li, Na, K, Ag, Cu, NH4, H30 or a combination thereof.
20. The electrode of claim 16, wherein cation A1 is selected from H, Li, Na, K, Ag, Cu, NH4, H30, Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Al, Ga, In, Mg, Ca, Sr or a combination thereof.
21. The electrode of claim 14, wherein x is between 0 and 3.
22. The electrode of claim 14, wherein x is about 0.5 and 3.
23. The electrode of claim 14, wherein x is between about 1 and 3.
24. The electrode of claim 14, wherein x is between about 2 and 3.
25. The electrode of claim 14, wherein the nitridophosphate compound is partially or fully crystalline.
26. The electrode of claim 25, wherein the crystalline particles of nitridophosphate compounds have a cubic non-centrosymmetric structure with the space group of
27. The electrode of claim 14, wherein a N(P03)36" anion in the nitridophosphate compound of formula (3) is formed by a trimer of three PO3N tetrahedra sharing one N vertex and each pair of PO3N tetrahedra within the trimer share two corners with an M06 octahedron.
28. The electrode of claim 27, wherein each corner of the M06 octahedron is shared with a PO4 tetrahedron allowing connections with two neighboring tetrahedra in three different P3O10 trimers of the tetrahedra.
29. The electrode of claim 14, wherein the nitridophosphate compound has formula
(4) :
where M is Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Al, Ga, In, Mg, Ca, or a combination thereof.
30. The electrode of claim 29, wherein the nitridophosphate compound has a formula
(5) :
31. The electrode of claim 29, wherein the nitridophosphate compound has a formula
(6) :
32. The electrode of claim 14, wherein the nitridophosphate compound has up to three free occupancy sites available for intercalation, and the nitridophosphate compound has a formula (7): Na3_x (P03)3N (7), where 0 < x < 3.
33. The electrode of claim 32, wherein Mis Ti and x is between 0 and 1
34. The electrode of claim 32, wherein Mis V and x is between 0 and 2.
35. The electrode of claim 14, wherein the nitridophosphate compound has formula (9):
Na2^7 (P03)3N (9), where A1 and M are each independently selected from Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Al, Ga, In, Mg, Ca, or a combination thereof.
36. The electrode of claim 35, wherein A1 and M are selected from the same element.
37. The electrode of claim 35, wherein the nitridophosphate compound has up to two free occupancy sites available for intercalation, and the nitridophosphate compound has a formula (10):
Na2_x (P03)3N (10), where 0 < x < 2.
38. The electrode of claim 14, wherein the nitridophosphate compound is amorphous.
39. The electrode of claim 38, wherein the nitridophosphate compound has a formula Na3Mn(P03)3N.
40. The electrode of claim 13, wherein T3X10 trimer of the formula (1) is Ρ3(¾Ν
forming a nitridophosphate compound having a general formula (12)
,+^(Ρ03)3Ν (12) where a combination of A 3+xAf w yields a net charge of +6, z is a starting oxidation state, 0<w < 2, and 0< x < 2.
41. The electrode of claim 40, wherein M is selected from Ti, V, Cr, Mn, Fe, Co, Ni or a combination thereof.
42. The electrode of claim 40, wherein the cation A is a monopositive cation selected from H, Li, Na, K, Ag, Cu, NH4, H30 or a combination thereof.
43. The electrode of claim 40, wherein the oxidation state of M is below its starting oxidation state.
44. The electrode of claim 40, wherein M is V having a starting oxidation state of +3, and x is between 0 and 1.
45. The electrode of claim 40, wherein Mis Ti having a starting oxidation state of +4 and x is between 0 and 1.
46. The electrode of claim 40, wherein A is Li.
47. A solid electrolyte comprising a cubic ionic conductor compound having a
framework of formula (1) with a general chemical formula (2)
[MTSXJOJ (1)
ΑχΜΤιΧιο (2) where M is a cation in octahedral coordination, T is a cation in tetrahedral coordination, is an anion, n is a net charge of the framework between 0 and 16, A is a variable number of additional non-framework chemical species that can fit into an open space within the framework with a net charge of +n, and x is less than 10,
wherein a T3X10 trimer of TX4 tetrahedra share one common X anion, organized around an octahedral ¾ site such that each ¾ octahedron is connected to three different T3X10 trimers by two bridging X anions connected to two different TX4 tetrahedra within the trimer.
48. The solid electrolyte of claim 47, wherein the T Xw trimer of formula (1) is P3O9N forming a nitridophosphate compound having a general formula (3)
Λ (Ρ03)3Ν (3) where x < 3, and A is an ionic or neutral species and the combination of A and M species produce a +6 charge that results in a net charge neutrality.
49. The solid electrolyte of claim 48, wherein A and M are ions or neutral species with closed shell configurations and no unpaired electrons.
50. The solid electrolyte of claim 48, wherein A and M are selected from a
combination of one or more monopositive cations among H, Li, Na, K, Cu, Ag, H3O or NH4, and a combination of one or more fully oxidized cations selected from among Sc, Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, W, Mg, Zn, Ca, Sr, Al, Ga, or In.
51. The solid electrolyte of claim 48, wherein the nitridophosphate compound has a specific formula of Na3Al(P03)3N, Na3Ga(P03)3N, Na3In(P03)3N, Na2Ti(P03)3N, NaiV(P03)3N, K3A1(P03)3N, K3Ga(P03)3N, K3In(P03)3N, K2Ti(P03)3N, or K!V(P03)3N.
52. A composition comprising
a nitridophosphate compound having the formula:
A 3_xLiy (P03)3N
where x is between 0 and 2, y is between 0 and x, A is selected from H, Na, K, Ag, Cu, H30, or NH4, and Mis selected from Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Al, Ga, In, Mg, Ca, or a combination thereof.
53. The composition of claim 52, wherein A is Na.
54. The composition of claim 52, wherein A is K.
55. A composition comprising
a nitridophosphate compound having the formula:
where x and w are each independently between 0 and 2, y is between 0 and x+1, z is a starting oxidation state of M, A is selected from H, Na, K, Ag, Cu, H3O, or NH4, and Mis selected from Ti, V, Cr, Mn, Fe, or a combination thereof.
56. The composition of claim 55, wherein A is Na.
57. The composition of claim 55, wherein A is K.
58. An electrode comprising the composition of claim 55, wherein Mis Ti and a
potential voltage to intercalate Li is about 2.8 V (vs. Li metal).
59. An electrode comprising the composition of claim 55, wherein Mis V and a
potential voltage to intercalate Li is about 4.1 V (vs. Li metal).
60. An electrode comprising the composition of claim 59, wherein a theoretical
capacity of the compound is about 233 niAh/g.
61. A composition comprising
a nitridophosphate compound having the formula:
^M 2-xLiy (P03)3N,
where x is between 0 and 2, y is between 0 and x, AM is selected from H, Na, K, Ag, Cu, H3O, or NH4, and A1 and M are independently selected from Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Al, Ga, In, Mg, Ca, or a combination thereof.
62. The composition of claim 61 , wherein AM is Na.
63. The composition of claim 61 , wherein AM is K.
64. An electrochemical cell comprising:
a cathode,
an anode, and an electrolyte solution,
wherein the cathode comprises an electrode of claim 1.
65. The electrochemical cell of claim 64, wherein the anode is a carbon anode.
66. The electrochemical cell of claim 65, wherein the carbon anode is a hard carbon anode.
67. A method of synthesizing substantially pure crystalline nitridophosphate,
comprising
mixing stoichiometric amounts of a metal oxide, a metaphosphate, and urea; heating the mixture to about 300 to 400 °C under flowing ammonia gas for about 1 to 10 hours;
heating the mixture to about 700 to 800 °C for about 10 to 30 hours under flowing ammonia; and
collecting the substantially pure crystalline nitridophosphate.
68. The method of claim 67, further comprising grinding or milling the mixture before either or both times the mixture is heated.
69. The method of claim 67, wherein the urea has a mole fraction of 10 - 90% of the starting mixture.
70. The method of claim 67, wherein the urea has a mole fraction of 33 mole % of the starting mixture.
71. A method of synthesizing substantially pure crystalline nitridophosphate,
comprising
mixing stoichiometric amounts of metal oxide, sodium acetate, and diammonium hydrogen phosphate; heating the mixture to about 300-400 °C for about 1 to 10 hours, and
heating the mixture to about 600 °C for about 10 to 30 hours under flowing ammonia.
72. The method of claim 71, further comprising grinding or milling the mixture before either or both times the mixture is heated.
73. The method of claim 71, wherein the stoichiometric amounts are a Na:M:P molar ratio of 2:2:3.
74. A method of synthesizing substantially pure crystalline nitridophosphate,
comprising:
dissolving into solution stoichiometric amounts of sodium metaphosphate, ammonium metal, citric acid and urea in water,
heating the solution at about 60-90 °C for 1 to 10 hours,
drying the resulting solution to obtain a dried gel;
grinding or ball-milling the dried gel;
heating the dried gel to about 400 °C in air for about 10-20 hours to obtain a resulting material;
heating the resulting material at about 600-800 °C for about 10-20 hours under flowing ammonia gas.
75. The method of claim 74, wherein the stoichiometric amounts are a molar ratio of 3: 1 :2: 1.
76. The electrode of claim 14, wherein the nitridophosphate compound is
Li3V(P03)3N.
77. The electrode of claim 14, wherein the nitridophosphate compound has a general formula, Li3Ti(P03)3N.
78. The electrode of claim 14, wherein the nitridophosphate compound has a general formula, Li2-xFe2(P03)3N, where x< 2.
79. The solid electrolyte of claim 48, wherein the nitridophosphate compound is Li3V(P03)3N.
80. The solid electrolyte of claim 48, wherein the nitridophosphate compound is Li3Ti(P03)3N.
81. The solid electrolyte of claim 48, wherein the nitridophosphate compound has a general formula, Li2-xFe2(P03)3N, where x< 2.
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Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
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WO2014165773A1 (en) * | 2013-04-05 | 2014-10-09 | Brookhaven Science Associates, Llc | Cubic ionic conductor ceramics for alkali ion batteries |
US11532806B2 (en) | 2014-04-01 | 2022-12-20 | The Research Foundation For The State University Of New York | Electrode materials that include an active composition of the formula MgzMxOy for group II cation-based batteries |
WO2018062085A1 (en) * | 2016-09-29 | 2018-04-05 | Tdk株式会社 | All solid-state lithium ion secondary battery |
CN111995396A (en) * | 2020-07-20 | 2020-11-27 | 南昌航空大学 | Method for utilizing oxygen ion conductivity of magnesium modified sodium niobate ceramic |
CN112397779A (en) * | 2020-11-17 | 2021-02-23 | 郑州新世纪材料基因组工程研究院有限公司 | Halogen fast ion conductor |
CN112397779B (en) * | 2020-11-17 | 2022-09-27 | 郑州新世纪材料基因组工程研究院有限公司 | Halogen fast ion conductor |
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