CA2728141C - Mixed oxide containing a lithium manganese spinel and process for its preparation - Google Patents
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Abstract
Furthermore, the present invention relates to a process for its preparation and the use of the mixed oxide as electrode material for lithium ion batteries.
Description
FOR ITS PREPARATION
The invention relates to a mixed oxide containing a mixed-doped lithium manganese spinel and a boron-oxygen compound as well as a process for the preparation thereof and its use, in particular as cathode material in lithium-ion secondary batteries.
Rechargeable lithium-ion batteries are characterized by high specific energy and power. They are therefore preferably used in applications which require the smallest possible weight and little space. Thus, it is lithium-ion secondary batteries that are predominantly used today as energy stores for portable electronic devices, such as e.g. video cameras, laptop computers or mobile phones. If the production costs of rechargeable lithium batteries are further reduced, further potential applications are conceivable, such as e.g. cordless power tools, onboard power supply, traction or hybrid batteries in vehicles, or also in stationary applications, e.g. for emergency power supply equipment.
The operating principle of current lithium-ion batteries is based on the use of electrode materials which can intercalate lithium reversibly. At present, carbon compounds are customarily used as anode and a lithium-containing oxide as cathode.
In order to be able to obtain the highest possible energy densities, cathode materials which can intercalate lithium at potentials between 3 and 4 V vs. Li/Li+ are preferably used. The
Of the lithium manganese oxides, compounds with spinel structure, such as e.g. LiMn204 (stoichiometric spinel), Li2Mn409 (oxygen-rich spinel) and Li4Mn5012 (lithium-rich spinel), show the most promising properties as cathode materials. Normally, these spinels are prepared by means of solid-state reactions. This normally results in stoichiometric spinels which, however, in most cases have only an inadequate cycle life. This is attributed to changes and defects in the lattice structure which occur during the insertion and removal of lithium ions.
In US 4,507,371 an electrochemical cell is described in which the anode, electrolyte and cathode each have a material which has a cubic-close-packed framework structure, which has, as its basic structural unit, a unit of the formula (B2)X4' - and is the structural unit of an A(B2)X4 spinel. The structure accommodates active cations M+ capable of diffusion within this structure.
This document also describes the forms of crystal defects and stoichiometric deviations known in structural chemistry for spinel structures of the AB2X4 type, such as for example the partial replacement of B-cations by A-cations or the lack or excess of X-anions, and teaches that these can exert an influence, not quantified in more detail, on the electrochemical properties.
In EP 0 783 459 B1 doped lithium complex oxides of the general formula LiyMeõMn2,04 are described which have a spinel-type crystalline structure and are suitable as cathode material in lithium secondary batteries. The batteries produced with these cathodes are said to have a long cycle life. The lithium manganese spinel is prepared by reacting quantities, corresponding to the stoichiometry of the spinel to be prepared, of the reaction components in the form of hydroxides and/or water-soluble metal salts in dissolved form in a basic aqueous medium accompanied by formation of a homogeneous suspension. The dried reaction products are then heated to temperatures of between 500 and 900 C at a heating rate of 1 - 20 K/min, wherein the respective mixed oxides form in radiographically phase-pure form. Particularly suitable metal cations Me are iron, titanium and aluminium, as well as cobalt and nickel. Complex oxides of the formulae LiFe0.1Mn1.904, LiTi0,1Mn1.904 and LiNi01Mn1.504 are disclosed in the examples. The patent teaches that a uniform fine distribution of the starting components is important for the preparation of phase-pure doped lithium manganese spinels and that this fine distribution is achieved particularly
In EP 1 035 075 Al, a two-stage precipitation and suspension process for the preparation of a complex lithium manganese spinel doped inter alia with boron is described. The compound has the following general formula:
LixMn (2-y)MylBy204 r wherein M is selected from the group of Al, Cr, Fe, Ni, Co, Ga and Mg, and furthermore: 0.9 5 x 5 1.1; Y = Yl + y2, wherein 0.002 y 0.5 and 0 5 yi < 0.5 and 0.002 y2
Robertson et al. (J. Electrochem. Soc. 144, 10, (1997), 3500-3512) report enlarged crystallites (about 1 pm) and a reduced specific surface area according to BET (<1 m2/g) for a boron-doped spinel of the composition LiMn1.9030.0204. The associated scanning electron microscopy image shows large octahedral crystallites with rounded corners and edges with indicated crystal surfaces. However, very poor electrochemical properties are also reported for this material. Thus, a specific capacity of less than 50 mAh/g was measured, which also decreases markedly from cycle to cycle.
In EP 1 204 601 Bl, lithium manganese spinels for thin-film electrodes are described. In the process of EP 1 204 601 Bl, the obtained lithium manganese spinel is sintered in the form of agglomerates in oxidizing atmosphere at 450 C to 900 C, wherein 0.1 to 3% boron oxide or boric acid, relative to the weight of the solids used, can be added as sintering auxiliary, in order to achieve a higher strength of the agglomerates. No effect of the boron compounds on the crystallinity of the spinel is described.
In EP 0 993 058 Al, a lithium secondary battery is described, the positive electrode active material of which is composed mainly of lithium and manganese and has a cubic spinel structure. In a comparison example, LiMn204 doped with boron is used as electrode material. This electrode material is prepared by mixing powdery Li2CO3, Mn02 and B203 in the molar ratio Li : Mn B = 1 : 2 : 0.03 and calcining the obtained mixture in an oxidizing atmosphere for twenty-four hours at 800 C. Particles are obtained which have a deformed octahedral shape with flat crystal faces, wherein the edges and corners of the crystals are rounded.
In JP 2001-48545, a process for the preparation of a complex boron-doped lithium manganese oxide with spinel structure is described, wherein a lithium compound and a manganese compound are reacted in liquid phase in the presence of a boron compound.
The doping element aluminium is introduced in the form of a solid compound. Roughly spherical granulated particles with an average particle diameter of 15 pm are obtained.
EP 1 136 446 A2 discloses coated lithium complex oxide particles and a method for their preparation. The coating, which can be formed as a single or as several identical or different layers, is said to improve the properties of electrochemical cells in
P. Strobel et al. describe, in "Cation Ordering in Substituted LiMn204 Spinels", Mat. Res. Soc. Symp. Vol. Proc. 756, the effect of different trivalent and divalent metal cations as doping agents which occupy the 16d manganese lattice sites on the electronic properties of such doped lithium manganese spinels. In particular, the replacement of precisely a quarter of the octahedral cations (16 e) was attempted here and it was shown that, for magnesium and zinc, this resulted in a superstructure with a primitive cubic symmetry. In the case of zinc, a further lattice distortion was detected at the tetrahedral 8a site by FTIR spectroscopy.
DE 199 13 925 Al discloses hyperstoichiometric lithium manganese spinels. The lithium manganese spinels in this patent application conform to the general formula Li(Mn2,Lix)04, wherein x is 0 < x 0.8, which can be obtained by a spray pyrolysis process.
Lithium is inserted instead of manganese in its 16d lattice sites, but the lithium doping is limited to the range 0 < x 0.05, since outside of this range the cycle characteristic of cathodes containing this material deteriorates, because of the Jahn-Teller effect, compared to the unsubstituted lithium manganese spinels.
Buhrmester's doctoral thesis (Darmstadt 2001) deals with the defect structure in the Li1+xMn2_y04_6 system and describes the structural and electronic behaviour of lithium manganese spinels hyperstoichiometrically doped with lithium.
Lithium secondary batteries are also increasingly used for applications in which a long cycle life, a high current carrying capacity and a high safety in the event of misuse or malfunction are required. Such requirements must be satisfied for example for storage batteries in hybrid vehicles which have an electric motor in addition to a normal combustion engine. In addition, such batteries must also be cheap to produce. The production costs are influenced by all components of the batteries.
The object of the invention was therefore to provide material, in particular a material containing a lithium manganese spinel, which can be used as electrode material in particular in secondary lithium-ion batteries and which has good charging characteristics.
This object is achieved by a mixed oxide containing a) a mixed-substituted lithium manganese spinel in which some of the manganese lattice sites are occupied by lithium ions and
Surprisingly, it was found that the mixed oxide according to the invention has improved electrochemical properties compared with a non-doped lithium manganese spinel or one doped with foreign atoms such as Zn, Mg, Cu, Al (mixed-substituted), but also compared with a lithium manganese spinel only hyperstoichiometrically doped with lithium or such a spinel which is doped with further foreign atoms.
The term "some" is explained in more detail in the following Formula I by the numerical value for the index c.
The term "mixed oxide" describes according to the invention a single-phase homeotype mixed crystal comprising the two constituents (e.g. Hollemann-Wiberg, Lehrbuch der Anorganischen Chemie, 102nd edition, de Gruyter 2007, pp. 130-131) and serves to illustrate that the boron of the boron-oxygen compound is not a doping element for the 16 d manganese lattice sites in the lithium manganese spinel and does not occupy these sites. In this case, the compound would be a so-called "complex" oxide.
The term "mixed-substituted" means that, in addition to (hyperstoichiometric) lithium, at least one further metal, other than manganese, is located on the 16 d lattice sites of the manganese.
In particular, the single-phase mixed oxide according to the invention has a smaller BET surface area than comparable lithium manganese spinels doped with lithium and/or with metals or transition metals or pure lithium manganese spinels, namely a BET
surface area of < 4 m2/g, preferably < 2 m2/g and more preferably of < 1 m2/g and most preferably < 0.5 m2/g, whereby the manganese dissolution in the electrolyte of a corresponding cell is clearly reduced, since the BET surface area is correlated with the manganese dissolution in the electrolyte.
The resistance to a dissolution in the electrolyte is thus increased by the mixed oxide according to the invention, i.e. in particular thus by the presence of the boron-oxygen bond (see below).
In addition, for the mixed oxide according to the invention, very narrow reflex widths in X-ray diffraction spectra are obtained, since according to the invention very large crystallites of the mixed oxide are surprisingly obtained. The large crystallites lead to a reduced surface area of the mixed oxide, whereby the dissolution in the electrolyte is further reduced and the tap density (or, in other words, compression) is also increased. In comparison with a pure lithium manganese spinel (LiMn204), an improvement in the tap density from 1.23 g/cm3 to 2.03 g/cm3 is observed for the mixed oxide according to the invention. By the term "tap density" is meant in the present case the compression
The external pressing force acts on a container filled with a predetermined quantity of the sample, which then repeatedly strikes a flat surface (see e.g.
www.particletesting/com/density.aspx).
Moreover, the presence of the boron-oxygen compound in the mixed oxide according to the invention surprisingly ensures a clearly increased homogeneity of the insertion of the transition metal in the lithium manganese spinel compared with a doping without the presence of a boron-oxygen compound, with the result that in particular a homogeneous uniform insertion of for example aluminium, zinc, etc. in the 16 d manganese lattice sites takes place. This likewise leads to clearly improved electrochemical properties.
Within the framework of the present invention, an improvement of up to approx. 20% in the cycle stability was recorded in an electrode containing the mixed oxide according to the invention compared with an electrode containing only pure doped or undoped lithium manganese spinel.
As already briefly stated above, in the lithium manganese spinel of the mixed oxide, further manganese lattice sites (16 d position) are preferably occupied or substituted by at least one metal ion, selected from the group consisting of Al, Mg, Zn, Co, Ni, Cu and Cr or mixtures thereof, with the result that a wide variety of mixed-substituted hyperstoichiometric lithium
Some of the lithium ions on the 8a tetrahedral sites are further substituted by a metal ion selected from the group consisting of Zn, Mg and Cu, whereby the electrochemical properties of the mixed oxide according to the invention can be adjusted still more precisely.
Preferably, the boron-oxygen compound in the mixed oxide according to the invention is a boron oxide or a boric acid, quite particularly preferably B203 or H3B03. Further representatives of these classes of compound that can be used according to the invention are (B0)x, BO, B20, as well as H2E02 and HBO. In likewise preferred developments of the present invention, borates, i.e. the salts of orthoboric acid (H3B03) and metaboric acid (H2B02), preferably monoborates, can also be used.
In less preferred embodiments, oligo- and polyborates can also be used. Alkali metal metaborates M2B02, in particular Li2B02, are quite particularly preferred. Reference is made in individual cases to Hollemann-Wiberg, Lehrbuch der Anorganischen Chemie, de Gruyter, Berlin 1021 edition, 2007, pp. 1104-1110 with regard to the structure and chemistry of the boron-oxygen compounds.
Surprisingly, it was found that the mixed oxide according to the invention has the advantages summarized as follows
= The mixed oxide according to the invention has a greatly reduced BET surface area of < 0.5 m2/g, wherein the BET
surface area correlates with the manganese dissolution in the electrolyte.
= The mixed oxide according to the invention has an increased tap density (increase from 1.23 g/cm3 to 2.03 g/cm3).
= The mixed oxide according to the invention has narrow reflex widths in the XRD spectrum and large crystallites.
= The homogeneity of the insertion of the doping metal in the spinel of the mixed oxide is clearly improved compared with doped lithium manganese spinel of the state of the art.
= Electrochemically, an improvement in the cycle stability of the mixed oxide according to the invention was recorded compared with doped lithium manganese spinel of the state of the art.
The lithium manganese spinel of the mixed oxide contains, as already stated above, the lithium on some of the manganese lattice sites (hyperstoichiometry). The doping metal ions are distributed uniformly in the crystal. This is shown for example by the oxidation state of the manganese and by the X-ray diffraction spectrum (see examples below).
The general formula of the mixed oxide according to the invention can be expressed as follows:
[ (Li -aMa) (Mn2-c-dLicGd) Ox] ' b (Bz0y1-10<v) ( I) wherein:
0 a < 0.1;
d 1.2;
3.5 < x < 4.5;
0.01 < c < 0.06;
z = 1, 2 or 4;
y = 1, 2, 3 or 7;
u 0, 1, 2 or 3;
v - 0, 1, 2 or 3;
0.01 < b < 0.5;
M is at least one element from the group of Zn, Mg and Cu;
X is at least one element from the group Li, Na, K.
In quite particularly preferred developments, the above-named formula can be expressed as follows:
[ (Lii-aMa) (Mn2-c-dLicGd)Ox] ' (b B203 = f*b Li2O) (II) wherein:
0 a < 0.1;
d < 1.2;
3.5 < x < 4.5;
0.01 < c < 0.06;
0.01 < b < 0.05;
1 < f < 4;
M is at least one element from the group of Zn, Mg and Cu;
G is at least one element from the group of Al, Mg, Co, Ni, Cu and Cr.
The quantity of boron-oxygen compound in the mixed oxide is chosen such that the above-defined formula coefficient b is between 0.01 and 0.05, preferably between 0.01 and 0.025. A coefficient of b = 0.001
As already explained above, the lithium manganese spinel of the mixed oxide according to the invention has a very uniform distribution of the doping elements G in the crystal lattice.
Furthermore, the mixed oxide according to the invention has a very high phase purity, which is also reflected in the X-ray diffraction spectrum. Preferably, the mixed oxide according to the invention has, in an X-ray diffractogram at a diffraction angle of 2 e in the range from 63.5 to 65 , a signal in which the ratio of the line widths Bn measured at 10% of the signal height to the line width 350 measured at 50% of the signal height is less than 2.0, preferably less than 1.8. In particular, the diffraction signal has no shoulder, which indicates a high phase purity (see also Figures 1 and 5).
The hyperstoichiometric lithium is, as already stated, inserted in the lithium manganese spinel according to the invention on lattice sites of the manganese. This is shown by the degree of oxidation of the manganese. Preferably, the manganese of the spinel in the mixed oxide according to the invention has a degree of oxidation, defined by cerimetry, in the range from 3.60 to 3.69.
The mixed oxide according to the invention has comparatively large particles, wherein the lithium manganese spinel contained in the mixed oxide has few defects. This advantageously results in a small BET surface area. Preferably, the mixed oxide
The mixed oxide according to the invention has a relatively high particle size. Preferably, the size of the primary crystallites is at least 0.5 pm, preferably < 1 pm, most preferably in the range between 1 and 3 pm. The size of the primary crystallites can be determined under the electron microscope. (see also Figure 4) A level of doping elements G in which the value for d lies in the range from 0.05 to 0.2 is preferred. A value for d in the range between 0.08 and 0.15 is particularly preferred. Preferably, aluminium is used as doping element G of the mixed oxide according to the invention. Alternatively, magnesium is a further preferred doping element G, or mixtures of aluminium and magnesium.
So-called high-voltage spinels very strongly doped with Co and Ni for which d in the case of Co is preferably 1 0.2 and in the case of nickel 0.5 0.1 occupy a special position.
A level of doping elements M which corresponds to a value of a of 0.005 to 0.02 is preferred. A particularly preferred doping element M is zinc.
The mixed oxide according to the invention is very suitable as electrode material for the production of secondary lithium batteries. A subject of the invention is therefore also an
A further object of the invention was to provide a process for the preparation of mixed oxides containing a doped or non-doped lithium manganese spinel which can be carried out economically and with which a mixed oxide containing lithium manganese spinel can be obtained which can be used as electrode material in high-performance lithium secondary batteries.
This object is achieved by a process for the preparation of a mixed oxide containing a mixed-doped hyperstoichiometric lithium manganese spinel, wherein at least a lithium component, a manganese component, a boron-oxygen component, a component containing G, wherein G is selected from the group of Al, Mg, Co, Ni, Cu and Cr, and/or a component containing M, wherein M is selected from Zn, Mg and Cu is provided;
a first portion of a solid mixture is prepared by mixing some of the components in dry, powdery form;
- a second portion of a liquid mixture is prepared which contains a portion of the components in dissolved form and/or as a suspension, - wherein the stoichiometric quantities of the components of the first and second portions are
[ (Lii-aMa) (Mn2-c-dLicGd) Ox] = b ( BzOyFluXv) wherein:
0 __. a < 0.1;
d < 1.2;
3.5 < x < 4.5;
0.01 < c < 0.06;
z = 1, 2 or 4;
y = 1, 2, 3 or 7;
u = 0, 1, 2 or 3;
v = 0, 1, 2 or 3;
0.01 < b < 0.5;
- M is at least one element from the group of Zn, Mg and Cu;
- G is at least one element from the group of Al, Mg, Co, Ni, Cu and Cr;
- X is at least one element from the group Li, Na, K;
(It is understood that a mixed oxide according to Formula II can of course also be obtained by a suitable choice of the quantities of starting materials)
- the solvent is drawn off from the mixture obtained, - the mixture is calcined at a temperature of more than 300 C.
With the process according to the invention for the preparation of a mixed oxide containing a doped hyperstoichiometric lithium manganese spinel and a boron-oxygen compound, initially at least one compound each of the elements Li, Mn and boron (here, of course, a boron-oxygen compound) and a compound of a metal G, wherein G is selected from the group of Al, Mg, Co, Ni, Cu and Cr and/or a compound of a metal M, wherein M is selected from Zn, Mg and Cu, are prepared. The starting components, preferably the lithium or the boron-oxygen component, can be prepared in solid form. The boron-oxygen component is one of the boron-oxygen compounds described above.
The solid components are preferably used in pre-ground form. In the experiments it was shown that the particle morphology of the mixed oxide can be controlled in a targeted manner through the particle morphology of a solid and undissolved manganese compound used. In a particularly preferred embodiment, therefore, a solid and insoluble manganese compound is used which has previously been brought to the desired particle size, which is defined by laser granulometry, of the end-product. The essential aim is to limit the so-called oversize particle which causes problems during the processing into thin-film electrodes. The D95 value of
The compounds are preferably each provided in the form of a metal compound (thus as a so-called binary compound in which, however, several anions can also be present, but only one (metal) cation), since this allows problem-free doping. However, it is also possible to use compounds which contain several of the metals, thus so-called polynary compounds with several different (metal) cations.
At least one starting component, namely preferably that of a chemically inert doping element such as aluminium, magnesium, zinc, cobalt or nickel, is provided in dissolved form in order to guarantee the fine distribution in the later process steps. The solvent is preferably water.
The quantity of solvent is chosen such that the components to be dissolved can be completely dissolved. Since the solvent must be removed again in a later process step, the chosen quantity of solvent is, however, as small as possible. The chosen quantity of solvent should, however, be large enough for it to be able to take up the solid components in the form of a suspension or paste. All of the starting components can also be used in dissolved form in order to create ideal conditions for their fine distribution in the later process steps. However, because of the greater solvent requirement and because of the limitations on the selection of raw materials, this is a less preferred embodiment.
The soluble manganese component is preferably selected from manganese nitrate and manganese acetate.
The solid manganese component is preferably selected from manganese carbonate, manganese oxide and manganese dioxide.
The boron component is preferably selected from a boric acid, an alkali borate and a boron oxide. Typical representatives of boric acid are H3B03, H3B02, and of oxides B203, (B0)x, B02. Boric acid H3B03 and boron oxide B203 and also lithium or sodium borates are quite particularly preferred.
The named manganese and boron components can be used on their own or in a mixture.
The stoichiometric quantities of the components are selected such that they are present in a molar ratio which corresponds to a mixed oxide comprising a doped lithium-manganese spinel and a boron-oxygen compound of the following formula:
[ (Lii-aMa) (Ivin2-c-dLicGd) Ox] = b (3,00-1Xv) (I) wherein:
d < 1.2;
3.5 < x < 4.5;
0.01 < c < 0.06;
z = 1, 2 or 4;
y = 1, 2, 3 or 7;
u = 0, 1, 2 or 3;
v = 0, 1, 2 or 3;
0.01 < b < 0.5;
- M is at least one element from the group of Zn, Mg and Cu;
- G is at least one element from the group of Al, Mg, Co, Ni, Cu and Cr;
- X is at least one element from the group Li, Na, K.
In quite particularly preferred developments, the above-named formula can be expressed as follows:
[ (Lii-aMa) (Mn2-e_dLicGd)Ox] = (b B203 = f*b Li2O) (II) wherein:
0 a < 0.1;
d < 1.2;
3.5 < x < 4.5;
0.01 < c < 0.06;
0.01 < b < 0.05;
M is at least one element from the group of Zn, Mg and Cu;
G is at least one element from the group of Al, Mg, Co, Ni, Cu and Cr.
The components are then mixed, wherein the mixing can be carried out in any order. In a procedure preferred on process engineering grounds, the liquid partial mixture is introduced first and the solid powdery partial mixture added under stirring, wherein a suspension or paste is obtained. It is possible that a particular element is represented either only in the solid portion or only in the liquid portion. However, a particular element can also be distributed over both portions. Thus, it can be advantageous that the manganese portion is added both as a solid compound and as a dissolved compound, in order to both control the particle morphology of the end-product and promote the homogeneous distribution of the chemically inert doping elements. The mixture can be prepared in a normal mixer.
The mixing conditions are such that essentially no further reduction of the insoluble solid components occurs. The components can be mixed at temperatures of 00 to 100 C, but preferably between room temperature and 50 C. Depending on the mixing intensity of the mixing unit used, the mixing is carried out over a period of a few minutes to several hours. The mixing process preferably proceeds under chemical conditions in which compounds of the dissolved chemically inert elements are
value through one of the added components or by reacting two dissolved components or one dissolved and one solid component with each other. However, it is also possible not to precipitate the dissolved chemically inert components until the subsequent drying, which is, however, less advantageous for their uniform, fine distribution.
When the mixing is concluded, the solvent is drawn off from the mixture. Any process can be used per se. For example, the solvent can be removed by freeze-drying or spray-drying. The solvent can also be removed by heating the mixing container after the mixing and distilling off the solvent under stirring. The mixture assumes a doughy consistency, with the result that, as far as possible, measures are taken to prevent the mixture sticking to the mixer or on the walls of the mixing container. At the end of the drying process, the mixture can for example also be placed in a furnace and remaining solvent expelled at increased temperature there. The temperatures are chosen such that the evaporation of the solvent is as uniform as possible. Preferably, the drying occurs at temperatures of less than 300 C.
When the solvent has been removed, the mixture is calcined in air at temperatures of 300 C to 900 C. The calcining is preferably carried out in two stages. The first stage is carried out at a holding temperature between 300 C and 600 C and for a period of 10 min. to 2 hours and serves to expel gaseous decomposition products and form a still little-crystallized and immature spinel compound.
To form a phase-pure and homogeneously doped mixed oxide comprising a lithium manganese spinel and a boron-oxygen compound with improved electrochemical properties, a fine homogeneous distribution of the chemically inert doping components in the precursor mixture is needed. With the process according to the invention, this is guaranteed by joint precipitation of these components from the dissolved state.
An expensive and energy-consuming high-energy grinding, e.g. in a ball mill, can thereby be dispensed with for example unlike with doped, in particular boron-doped, aluminium manganese spinels of the state of the art. Moreover, such a process brings with it the risk of contamination by the rubbings from the grinding tools.
Furthermore, the dissolved and precipitated components are uniformly distributed in the mixture and are thus also uniformly inserted in the spinel, without excessively high temperatures also having to be used over an extended period for the thermal treatment of the mixture, as is the case for example with pure solid-state processes. This increases the profitability of the process through lower energy costs and a larger throughput and
In order to counter this unfavourable effect, the invention therefore provides for an extra addition of a boron-oxygen compound, with the result that a phase-pure mixed oxide forms.
Surprisingly, however, it was shown that the addition of the boron-oxygen compound in the process according to the invention not only promotes the growth of the crystallites but also, as already stated above, the homogeneous distribution of the remaining doping elements. The distribution, qualifiable by evaluation of the powder X-ray diffraction profiles of the end-product in the spinel structure, of the doping elements is completely homogeneous in the process according to the invention both when using exclusively dissolved starting components and when predominantly using solid starting components, as long as a boron-oxygen compound is also added.
Surprisingly, the process according to the invention leads to a phase-pure mixed oxide in which boron - as already stated above -does not occupy lattice sites of the manganese ("doping" or "substitution"), but is present as a boron-oxygen compound in the same phase as the doped lithium manganese spinel. This effect was previously unknown.
Moreover, it was surprisingly shown that an increase in boron addition necessitates a matching increase in the lithium excess (hyperstoichiometry) in order to compensate for negative concomitant effects.
With the process according to the invention, the mixed oxides according to the invention containing doped lithium manganese spinels and a boron-oxygen compound can thus be prepared which have a comparatively large crystallite size and a small BET
surface area. The doping agents, the metals of the groups formed by N and M, are uniformly distributed in the spinels on the manganese lattice sites in the spinel. Very uniform crystallites are obtained which have few lattice defects.
A further subject of the invention is a secondary battery, in particular a rechargeable secondary battery, which comprises an electrode containing the mixed oxide according to the invention as electrode material ("active material"), in particular cathode material.
The figures show in detail:
Figure 1: dQ/dE plotted against E for various Co/Al/Li levels of lithium manganese spinels Figure 2: comparison of XRD spectra of mixed oxides according to the invention and pure lithium manganese spinels Figure 3: the flowchart of the method according to the invention Figure 4: SEM micrographs of mixed oxides according to the invention Figure 5: position, reflex width and phase-purity of mixed oxides according to the invention Figure 6: the effect of the addition of borate on the electrochemical behaviour Figure 7: the manganese dissolution of mixed oxides according to the invention compared with pure lithium manganese spinels in mg Mn/kg
General Analysis methods:
In the following examples, the following analysis methods were used and implemented in accordance with the following instructions:
Initially, the Mn02, obtained from a sample of the mixed oxide by e.g. acid decomposition, with a defined excess of Mohr's salt was reacted in acidic solution and the Fe2+ that was not consumed was back titrated with Cer(Iv) sulphate, whereupon the quantity of Mn02 and therefore the analytical content of the sample, consequently the average degree of oxidation, can be determined via difference calculation.
d) XRD measurement Apertures (lmm/lmm/0.2mm); radiation: CuK a..range: 10 800; increment: 0.02 ; measurement period: 5.5 sec/step Experimental:
The starting products used are commercially available from the following suppliers and, unless otherwise indicated, were used as received.
Manganese carbonate (MnCO3) S grade: Comilog/Erachem Lithium hydroxide monohydrate (LiOH*H20): Acu Pharma Boric acid (H3B03): Jakle Chemie Aluminium nitrate nonahydrate (A1(NO3)3*9H20): Tropitzsch
and then arranged in a Swagelok PVDF T-cell for electrochemical measurements. The counter and reference electrodes consisted of a lithium metal film and were separated by a glass wool separator film from Whatman. Merck LP30 was used as electrolyte. The charge/discharge/test cycles were recorded at a current of C/20 and a nominal specific capacity of 120 mA/h in a voltage window between 4.2 volts and 2.8 volts.
Comparison example 1 Preparation of a lithium manganese spinel of the formula composition Lil-Mn1.87A10.1oLio.03.1204 with no added boron-oxygen compound.
The following components were provided as starting materials:
MnCO3 93% 231.13g Al(NO3)3*9H20 98.50% 38.08g HNO3 65% 70.77g
51.1 g of the drying product was calcined in air in the ceramic crucible at 500 C for 1 h in the chamber furnace and 32.5 g of a black powder obtained. 9.0 g of the calcination product was sintered in air in the ceramic crucible in the chamber furnace at 750 C for 12 h, with a heating time of 6 h and a cooling time likewise of 6 h. 8.85 g of sintered product was obtained.
Comparison example 2 Preparation of an aluminium- or cobalt-doped lithium manganese spinel with lithium hyperstoichiometry.
A more pronounced markedness of the additional stages and lower cycle stability in the examined cycle range were shown in the case of the electrochemical behaviour of the spinels containing Co/Li. Higher cycle stability was found in the case of the Al/Li-doped sample.
Spinels with different Li/Mn/Co/A1 contents were synthesized.
Table 1 shows the prepared spinels:
Table 1 Effect of the dopants (doping elements) Al, Co and Li; the quoted values correspond to the portions of replaced Mn ions in %
Sample Al Co Li G1007 0 5 1.5 G1008 0 5 1.5
Important information about inter alia the cycle stability can be found in the course of the potential of the charge/discharge curves. Typically, after approximately half charge/discharge, the charge and discharge curves show a potential step which is attributable to structural order effects in the spinel lattice. The more pronounced and sharper this jump is, the poorer as a rule the cycle stability of the tested material. This effect already gives an advance indication of the cycle stability of the material.
The same applies for an additional potential step which can occur at 3.1 V vs. Li.
The differentials of the potential curves (dQ/dE vs. E) were plotted (Figure 1) in order to be able to better compare the markedness of the potential steps. The maxima/minima correspond to the plateaus in the charge curves. The sharper
Figure 1 shows that the peaks merge more markedly as the aluminium content in the structure increases, which corresponds to a "blurring" of the potential curves. This effect is a criterion for the structural insertion of the aluminium in the spinel structure. Electrochemically, a higher cycle stability thus results.
Alongside this, an increase in potential was also established by exchanging cobalt with aluminium.
The consequence of the additional insertion of hyperstoichiometric lithium (in manganese lattice sites) in the aluminium-doped sample is an even more pronounced overlapping of the peaks. No shift of the peak position is to be seen.
Example 1 Preparation of a mixed oxide according to the invention The mixed oxide according to the invention was prepared starting from a stoichiometric doped lithium manganese spinel (precursor value) obtained analogously to comparison example 1. To create the hyperstoichiometry, LiOH and, as boron-oxygen compound, boron oxide in the form of a mixture of LiOH and B203 were used. The molar ratio of Li to B was 2 to 1 or f = 2.5).
The addition of the boron-oxygen compound, here the borate, affects the morphology, the half-widths of the X-ray reflexes and the BET surface area of the Al/Li-doped lithium manganese spinels of the mixed oxide according to the invention.
Even a small addition of borate is already enough to achieve a pronounced jump in important properties.
As can be seen in Figure 4, the crystallite size increases markedly when borate is added and when the tempering temperature increases. The largest crystallites are accordingly achieved at a temperature of 770 C and when adding 1% by weight (preferably based on the total mixture of the mixed oxide). However, the BET surface area and, as can be seen in Figure 5, the half-width of the XRD reflexes clearly decrease.
The examined mixed oxides according to the invention were single-phase (homophase or homeotype) according to the profile of the XRD reflexes, i.e. a complete regular insertion of aluminium into the crystallite structure had taken place.
Example 2 XRD spectrum of the mixed oxide according to the invention
spectra of Al-doped hyperstoichiometric lithium manganese spinels obtainable according to comparison example 1 (M29 and M30) (Figure 2).
All samples were doped with Li/A1 in the ratio 1:5. The aim was to test the homogeneous insertion of the dopants into the crystal lattice.
In the XRD spectrum, a homogeneously doped single-phase lithium manganese spinel of the mixed oxide according to the invention shows individual "symmetrical" reflexes (M01 and M02) (after Ka2 correction).
The curves of M 29 and M 30 show clearly pronounced shoulders (arrows) (after Ka2 correction). This indicates a multiphase structure or an inhomogeneous distribution of the dopants.
Example 3 Electrochemistry The presence of a boron-oxygen compound, here the borate, in the mixed oxide according to the invention obtained according to Example I also has a positive electrochemical effect. The cycle stability increases, as can be seen in Figure 6, as the
Example 4 Manganese solution A reason for the previous lack of cycle stability of pure doped or non-doped lithium manganese spinels was their decomposition in electrolytes. In order to examine the relative stability of the mixed oxide according to the invention compared with a decomposition of the spinel component in an electrolyte, in each case 4 g of mixed oxide powder from Example 1 was stored for four weeks at 40 C with different quantities of borate and an Al-doped lithium manganese spinel from Example 1 in 40 g of LP30 (Merck electrolyte). The electrolyte was then analysed for dissolved manganese by means of ICP. The powders tempered at 770 C were tested.
As can be seen in Figure 7, the examined samples showed, in the relative comparison, a decrease in the manganese dissolution as the BET surface area increased. It can be seen that a pure lithium manganese spinel without the added boron-oxygen compound shows the highest dissolution. The addition of the boron-oxygen compound thus stabilizes the lithium manganese spinel in the mixed oxide according to the invention.
Example 5
Chosen dopings were Al 5% Li 1% (d = 0.1; c - 0.02), Al 5% Li 2% (d = 0.1; c = 0.04) and Al 5% Li 2.5% (d = 0.1; c = 0.05).
Each of the samples was first calcined at 500 C with and without 1% by weight of an Li0H/B203 mixture (b = 0.002; f =
2.5) as described and then tempered at 690 C, 730 C and 770 C.
For the mixed oxides according to the invention, a clear relationship between reflex half-widths and lithium hyperstoichiometry was able to be recorded. As the lithium hyperstoichiometry increased, the reflexes narrowed.
The BET surface area was then correlated with the lithium hyperstoichiometry:
Due to the influence of the borate, there was a "levelling" of the scatterings of the reflex half-widths depending on the lithium hyperstoichiometry which occurred in samples from different syntheses (see Figure 2). The same phenomenon was observed when measuring the BET surface area of the samples.
Here too, a levelling was to be recorded in the presence of borate (Figure 8).
Table 2: BET surface area: Li-hyperstoichiometry variation Sample BET m2/g T C Li (mol % on Mn) G1051B1 0.62 770 1.0 G1051B1 1.07 730 1.0 G1051B1 2.5 690 1.0 G1031B2 0.6 770 1.5 G1031B2 2.2 690 1.5 G1052 4.91 770 2.0 G1052B1 0.31 770 2.0 G1052B1 0.92 730 2.0 G1052B1 1.66 690 2.0 G1053 4.85 770 2.5 G1053B1 0.4 770 2.5 G1053B1 1.04 730 2.5 G1053B1 1.7 690 2.5 Overall, as well as the addition of borate and the temperature, the lithium hyperstoichiometry also affects the BET surface area. BET values < 1 m2/g were found.
Example 6 Cerime try
Were the lithium present only as fluxing agent (in the form of Li20), the average degree of manganese ion oxidation would be +3.56, in the case of a structural insertion, +3.62.
The two structural borderline cases can be represented as follows:
Pure fluxing agent Lii [Li+10.029A1+3o.o98Mn+x1.874] 04 0.071 Li20*wB203 Mrn+3-56 Structural lithium insertion Lii [Li+lo. 067A1+30 094Mn+x1. 839] 04 W B203 mn+3. 62 The obtained values which are listed in Table 3 lay in the range from +3.59 to +3.69, which proves the structural insertion.
Table 3 Average degree of oxidation, measured by means of cerimetry, of the manganese ions in the mixed oxide Li[Li Al Mn]04=B203.
Sample Temp. Stoichiometry be+
C Li Li Al Mn cerimetric STDDEV
In Figure 9, dQ/dE vs. E of materials of different mixed oxides according to the invention with different lithium hyperstoichiometries are plotted.
Example 7 Electrochemical examination Figure 10 compares the discharge capacities of samples of mixed oxides according to the invention in the first cycle.
The theoretical value was calculated from the analytically determined spinel stoichiometry. The measured values lie
The theoretical maximum capacity decreases from 129 mAh/g for EXM 1663 to 109 mAh/g for EXM1666. The measured values show the same tendency at a lower level.
The reference samples showed comparatively small capacities, which can be attributed to the increased lithium insertion.
Figure 11 shows in the overview the courses of the potential of the reference samples in the first complete cycle. In Figure 12, the emphasis is on potential ranges which gave initial indications of the cycle behaviour of the samples.
Both the occurrence of an additional potential step at 3.2 V
and a well-pronounced step at half charge/discharge are considered a feature of poor cycle stability:
= The potential plateau at 3.2 V (Figure 12a, left-hand side) is clearly pronounced for the Al-free sample, still difficult to spot for the sample doped with 3% Al and no longer present in the models doped with 5% Al.
= The markedness of the stage of potential at half charge/discharge decreases in the order EXM1663 after EXM1666.
2*0.9 Li2O) In each of several stirring mixtures, the following quantities of raw materials were used:
MnCO3 4.360 kg 93.50%
Mn(NO3)2 sol. 2.843 kg 50%
Al(NO3)3 * 9 H20 0.867 kg 101%
Zn (NO3) 2 * 6 H20 70.2 g 99%
H20 (dist.) 3.530 kg LiOH * H20 1.063 kg 55%
Boric acid 12.80 g 100.3%
The water, the manganese nitrate solution, the aluminium nitrate nonahydrate and the zinc nitrate hexahydrate were each placed in a 121 plastic bucket and mixed with a Pendraulik stirrer with stirring disk and dissolved completely. The finely-powdered boric
The stirring mixtures were combined in a stirred receiver container and the still pumpable suspension was dried in a Storck Bowen spray drier with two-fluid nozzle and spraying from above in the cocurrent process at an air-entry temperature of 550 C and an air-exit temperature between 140 C and 145 C. A brown powder with a bulk density of 1011 g/1 was obtained.
The drying product obtained in this way still contains nitrates and was calcined on stainless steel tray sheets in a continuous belt furnace with an attached exhaust-gas cleaning unit for nitrous vitriol gases at 450 C and an average residence time of 1 h in the heating zone. Surprisingly, small quantities of nitrous vitriol gases formed and a fine black powder with a bulk density of 823 g/1 was obtained. The calcination product was then tempered in air in an Alsint-ceramic crucible in the chamber furnace at 770 C for 12 h with a heating time of 6 h and a cooling time of 12 h.
The bluish black tempering product was ground on an Alpine AFG100 air separator mill with ceramic separator wheel and ceramic milling air nozzles 3.0 mm in diameter at a separator speed of 5500 rpm.
Li 3.9%
Mn 59.7%
Al 1.6%
Zn 3800 mg/kg B 600 mg/kg 0.23%
Na 920 mg/kg The particle-size distribution was monomodal and characterized by the following parameters:
D10 = 2.5pm D50 = 10.8pm D90 = 20.7pm Dno = 35.6pm Further product properties were:
pH value: 9.5 residual moisture content: 0.26% by weight (Karl-Fischer method) BET surface area: <1m2/g micropore volume: <0.001cm3/g (ASAP
2010, Micromeritics)
// Li type.
Claims (27)
[(Li1-a M a) (Mn2-e-d Li c G d)O x] .cndot. b (B z O y H u X v) wherein:
0 <= a < 0.1 d <= 1.2 3.5 < x < 4.5 0.01 < c < 0.06 z = 1, 2 or 4 y = 1, 2, 3 or 7 u = 0, 1, 2 or 3 v = 0, 1, 2 or 3 0.001 < b < 0.5 M is at least one element selected from the group of Zn, Mg and Cu;
G is at least one element selected from the group of Al, Mg, Zn, Co, Ni, Cu and Cr; and X is at least one element selected from the group Li, Na, and K, and wherein in the mixed-substituted lithium manganese spinel an element of G occupying a second portion of the manganese lattice sites is Ni or Co, wherein when Ni is present, the contribution of Ni to "d" is 0.5 +/- 0.1 or when Co is present, the contribution of Co to "d" is 1 +/- 0.2, and the size of the primary crystallites of the mixed oxide, measured as D50, is at least 0.5 um.
[ (Li1-a M a) (Mn2-c-d Li c O d) O x] .cndot. (b B203 = f*b Li2O) wherein:
0 <= a < 0.1;
d < 1.2;
3.5 < x < 4.5;
0.01 < c < 0.06;
0.001 < b < 0.05;
1 < f < 4;
M is at least one element selected from the group of Zn, Mg and Cu;
G is at least one element selected from the group of Al, Mg, Zn, Co, Ni, Cu and Cr; and wherein in the mixed-substituted lithium manganese spinel an element of G occupying a second portion of the manganese lattice sites is Ni or Co, wherein when Ni is present, the contribution of Ni to "d" is 0.5 +/- 0.1 or when Co is present, the contribution of Co to "d" is 1 +/- 0.2, and the size of the primary crystallites of the mixed oxide, measured as D50, is at least 0.5 µm.
selected from the group consisting of Al, Mg, Zn, Cu and Cr.
of the signal height to a line width B50 measured at 50% of the signal height is less tnan 2Ø
a first portion of a solid mixture is prepared by mixing the manganese component and the lithium component optionally with one or more of the components other than the manganese, lithium and boron components in dry, powdery form;
a second portion of a liquid mixture is prepared which contains the boron component in dissolved form and/or as a suspension, wherein the stoichiometric quantities of the components of the first and second portions are selected in such a way that the mixed oxide of the following formula results:
[ (Li1-a M a) (Mn2-c-d Li c G d) O x].cndot. b (B z O y H u X v) wherein:
0 <= a < 0.1;
d <= 1.2;
3.5 < x < 4.5;
0.01 < c < 0.06;
z = 1, 2 or 4;
y = 1, 2, 3 or 7;
u = 0, 1, 2 or 3;
v = 0, 1, 2 or 3;
0.001 < b < 0.5;
M is at least one element from the group of Zn, Mg and Cu;
G is at least one element from the group of Al, Mg, Co, Ni, Cu and Cr;
X is at least one element from the group Li, Na and K;
the first and second portions of the mixture are mixed;
a solvent is drawn off from the mixture obtained; and the mixture is calcined at a temperature of 300°C to 900°C.
a first portion of a solid mixture is prepared by mixing the manganese component and the lithium component optionally with one or more of the components other than the manganese, lithium and boron components in dry, powdery form;
a second portion of a liquid mixture is prepared which contains the boron component in dissolved form and/or as a suspension, wherein the stoichiometric quantities of the components of the first and second portions are selected in such a way that the mixed oxide of the following formula results:
[(Li]-a M a)(Mn2-c-d Li c Gd)O x]-(b B2O3 .cndot. f*b Li2O) wherein:
0 <= a < 0.1;
d < 1.2;
3.5 < x < 4.5;
0.01 < c < 0.06;
0.001 < b < 0.05;
1 < f < 4;
M is at least one element from the group of Zn, Mg and Cu;
G is at least one element from the group of Al, Mg, Co, Ni, Cu and Cr;
the first and second portions cf the mixture are mixed;
a solvent is drawn off from the mixture obtained; and the mixture is calcined at a temperature of 300°C to 900°C.
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| DE102008029804A DE102008029804A1 (en) | 2008-06-24 | 2008-06-24 | Mixed oxide containing a lithium manganese spinel and process for its preparation |
| DE102008029804.2 | 2008-06-24 | ||
| PCT/EP2009/004512 WO2009156119A1 (en) | 2008-06-24 | 2009-06-23 | Mixed oxide containing a lithium-manganese spinel and process for producing it |
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| EP (1) | EP2304828B1 (en) |
| JP (3) | JP2011525470A (en) |
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| CN (2) | CN102067364A (en) |
| CA (1) | CA2728141C (en) |
| DE (1) | DE102008029804A1 (en) |
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| EP2330079B1 (en) * | 2008-09-18 | 2018-12-12 | Toda Kogyo Corp. | Method for producing lithium manganate particle powder and nonaqueous electrolyte secondary battery |
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| JP2012116746A (en) * | 2010-11-10 | 2012-06-21 | Jgc Catalysts & Chemicals Ltd | Spinel type lithium manganese composite oxide |
| KR101264333B1 (en) | 2011-01-12 | 2013-05-14 | 삼성에스디아이 주식회사 | Cathode active material, cathode and lithium battery containing the same, and preparation method thereof |
| JP6292738B2 (en) * | 2012-01-26 | 2018-03-14 | Jx金属株式会社 | Positive electrode active material for lithium ion battery, positive electrode for lithium ion battery, and lithium ion battery |
| CN102903905A (en) * | 2012-10-09 | 2013-01-30 | 江苏科捷锂电池有限公司 | Preparation method of zinc-doped spinel cathode material |
| WO2015012650A1 (en) | 2013-07-26 | 2015-01-29 | 주식회사 엘지화학 | Anode active material and method for manufacturing same |
| JP6275593B2 (en) * | 2013-09-24 | 2018-02-07 | 株式会社東芝 | Negative electrode active material for lithium ion secondary battery and method for producing the same, lithium ion secondary battery, battery pack, and automobile |
| KR20160065837A (en) * | 2013-10-04 | 2016-06-09 | 가부시키가이샤 한도오따이 에네루기 켄큐쇼 | Lithium manganese composite oxide, secondary battery, electronic device, and method for forming layer |
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| CL2017002221A1 (en) * | 2017-09-01 | 2018-01-19 | Univ Antofagasta | Magnesium-doped manganese spinel, cathode material comprising it, preparation method, and lithium ion battery comprising it |
| CN110235291A (en) | 2017-10-11 | 2019-09-13 | 株式会社Lg化学 | Positive electrode active material, method of preparing the same, and lithium secondary battery comprising the same |
| KR102656223B1 (en) | 2017-11-22 | 2024-04-11 | 주식회사 엘지에너지솔루션 | Positive electrode active material for lithium secondary battery and method for preparing the same |
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| CN110790315A (en) * | 2019-02-22 | 2020-02-14 | 重庆大学 | Preparation method of lithium ion battery anode Li4Mn5O12 nanoparticles |
| CN110492097B (en) * | 2019-08-30 | 2021-04-27 | 中南大学 | A kind of NCM ternary composite cathode material and its preparation and application |
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| JP6054284B2 (en) | 2016-12-27 |
| US20170179485A1 (en) | 2017-06-22 |
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| WO2009156119A8 (en) | 2010-03-18 |
| DE102008029804A1 (en) | 2010-07-08 |
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| EP2304828A1 (en) | 2011-04-06 |
| KR20110036897A (en) | 2011-04-12 |
| JP2011525470A (en) | 2011-09-22 |
| US9562303B2 (en) | 2017-02-07 |
| CN107840343A (en) | 2018-03-27 |
| TW201008879A (en) | 2010-03-01 |
| US10483538B2 (en) | 2019-11-19 |
| US20110287319A1 (en) | 2011-11-24 |
| JP2014111533A (en) | 2014-06-19 |
| JP2017081819A (en) | 2017-05-18 |
| EP2304828B1 (en) | 2018-10-31 |
| KR101365578B1 (en) | 2014-02-20 |
| TWI466829B (en) | 2015-01-01 |
| CA2728141A1 (en) | 2009-12-30 |
| US20160068991A1 (en) | 2016-03-10 |
| CN102067364A (en) | 2011-05-18 |
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