CA2869499C - Surface-modified low surface area graphite, processes for making it, and applications of the same - Google Patents
Surface-modified low surface area graphite, processes for making it, and applications of the same Download PDFInfo
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- C23C16/22—Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the deposition of inorganic material, other than metallic material
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- C23C16/00—Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes
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Abstract
Description
IT, AND APPLICATIONS OF THE SAME
FIELD OF THE DISCLOSURE
[0001] The present disclosure relates to surface-modified, low surface area, synthetic, graphite, to processes for preparing said graphite and to applications for said graphite material, particular as a negative electrode material in lithium-ion batteries.
BACKGROUND
In any event, the SEI formation is connected with an irreversible consumption of lithium and electrolyte material, which in turn leads to an irreversible charge loss commonly referred to as "irreversible capacity" (Cirr).
include, amongst others, the type of binder and the porosity of the electrode. For negative electrodes wherein the active material is graphite, the type of graphite (e.g., particle size distribution, particle shape or morphology, surface area, functional groups on the surface, etc.) also appears to influence the SEI layer formation.
Contescu et al. (Journal of Nuclear Materials 381 (2008), pp. 15-24) examined the effect of air flow rate on the properties of various surface-oxidized 3-dimensional graphite specimens (i.e. graphite bars) including a binder material, reporting inter alia that the intensity of the D
band decreased compared to the G band after oxidation treatment, indicating an increase in the surface order of the treated graphite particles.
Park et al., Journal of Power Sources 190 (2009), pp. 553-557, examined the thermal stability of CVD coated natural graphite when used as an anode material in lithium-ion batteries. The authors found that carbon coating of natural graphite by CVD
led to a lower irreversible capacity and increased coulombic efficiency compared to unmodified natural graphite. Natarajan et al., Carbon 39 (2001), pp. 1409-1413, describe the CVD
coating of synthetic graphite at temperatures between 700 and 1000 C. The authors report that a CVD
coating at around 800 C yielded the best results in terms of coulombic efficiency while showing a decreased disorder of the treated graphite particles (i.e. the intensity of the D
band as determined by Raman spectroscopy decreases compared to the untreated material).
Interestingly, the authors report that at 1000 C the intensity of the D band increased, hinting at an increased disorder on the surface of the graphite particles at the higher temperature.
Finally, Ding et al., Surface & Coatings Technology 200 (2006), pp. 3041-3048, likewise report on CVD coated graphite particles by contacting synthetic graphite with methane at 1000 C. Ding et al. conclude that the graphite particles coated by CVD for 30 minutes at 1000 C exhibited improved electrochemical properties compared to untreated graphite material.
SUMMARY
The process parameters are further carefully selected so as to produce a surface-modified synthetic graphite maintaining a BET surface area of below about 4 m2/g, and preferably below 3.5 or even 3.0 m2/g (e.g. ranging from 2.0 to 3.0 m2/g).
coating treatment with hydrocarbon-containing process gas at elevated temperatures for a sufficient time to achieve an increase of the ratio Lc/La, preferably to a ratio of >1, or even greater, such as >1.5, 2.0, 2.5 or even 3Ø
BRIEF DESCRIPTION OF THE DRAWINGS
bands (ID / IG) at around 1330 cm-1 and 1580 cm-1, respectively.
DETAILED DESCRIPTION OF THE INVENTION
Surface-Modified Low-Surface Area Synthetic Graphite
ratio (R(ID/IG)) of below 0.8, or below 0.6, 0.4, 0.3, 0.2 or even below 0.15 (determined by Raman spectroscopy when measured with a laser having an excitation wavelength of 632.8 nm). Given that the surface-modification processes increase the intensity of the 0-band (i.e.
an increase of the ratio of ID/IG) compared to the untreated material, it will be understood that in most embodiments, the ID/IG ratio will be above 0.05, preferably above 0,07.
Regarding the latter, it has been found that surface oxidation leads to an increase of the xylene density over the starting material, indicating etching of the less graphitized carbon (followed by production of CO and 002) while the observed decrease of the xylene density in CVD treatments suggest deposition of pyrolytic carbon with lower xylene density.
Surface-Treated Synthetic Graphite Obtainable by Oxidation Treatment
value ranging from about 5.0 to about 6.5. In certain embodiments, the pH of the synthetic graphites modified by mild oxidation ranges from 5.2 to 6, or from 5.3 to 5.5. Untreated synthetic graphite typically has a neutral pH (i.e. around pH 7), and the lower pH observed for surface-modified graphites by oxidation is believed to be due to the chemical modification of the graphite surface (which introduces carbonyl, carboxyl and hydroxyl groups primarily on the prismatic surfaces of the particles).
i) a BET surface area ranging from 2.3 to 3 m2/g ii) a crystallite size Lc ranging from 100 to 180 nm iii) a crystallite size La ranging from 10 to 40 nm iv) a pH value ranging from 5.2 to 6.0 v) an oxygen content of greater than 90 ppm vi) a tapped density of greater than 0.98 g/cm3 vii) a particle size distribution (D90) ranging from 25 to 35 pm.
Surface-Treated Synthetic Graphite Obtainable by CVD Coating
surface ranging from 1.0 to 1.5 m2/g. Alternatively or in addition, such CVD coated surface-modified synthetic graphite can be characterized by a xylene density ranging from 2.1 to 2.26 g/cm3.
In certain of these embodiments, the xylene density ranges from 2.2 to 2.255 g/cm3, and sometimes even from 2.24 to 2.25 g/cm3.
non-ground) synthetic graphite by chemical vapor deposition at temperatures ranging from about 500 to about 1000 C with a hydrocarbon-containing gas for treatment times ranging from 3 to 120 minutes in a suitable furnace.
i) a BET surface area ranging from 1.3 to 1.8 g/cm3 ii) a crystallite size 1_, ranging from 100 to 160 nm iii) a crystallite size L. ranging from 20 and 60 nm, and, optionally, iv) an oxygen content of greater than 80 ppm.
Processes for Preparing Surface-Treated Synthetic Graphite
compared to the untreated starting material, as explained above.
In general, those of skill in the art will appreciate that the modification of the surface of the graphite particles is ¨ at least for similar treatment times - more pronounced at higher temperatures.
In other words, for comparable results the treatment time will have to be shorter if the process is carried out at higher temperatures. However, it may in some instances not be possible to reproduce the results at different temperatures even if the treatment time is appropriately adapted.
surface area defined herein for the final surface-modified graphite material of certain embodiments of the present invention, i.e. lower than about 4 m2/g, and preferably lower than 3.5 or 3.0 m2/g, particularly for surface oxidation processes. In contrast, the BET surface for the synthetic graphite starting material subjected to a CVD coating process may be higher than the upper end of the allowed BET surface are for the finished product since the CVD
coating will normally decrease the surface area of the treated material.
2010/049428).
Processes for the Modification of Synthetic Graphite by Surface Oxidation
Indeed, employing different starting materials, temperatures and oxygen partial pressure may demand an adaptation of the treatment time in order to arrive at a surface modified synthetic graphite having the desired structural parameters as defined herein.
Regardless of the above variability of the treatment time, it can be observed that the present surface modification process is relatively short compared to otherwise similar oxidation treatments described in the art (which are mostly in the (multiple) hour range).
Processes for the Modification of Synthetic Graphite by Chemical Vapor Deposition
coating in the context of this embodiment of the invention involves thus contacting the synthetic graphite starting material with a process gas containing hydrocarbons or a lower alcohol for a certain time period at elevated temperatures (e.g. 500 to 1000 C).
Suitable gas flow rates can be determined by those of skill in the art. In some embodiments, .. good results were obtained with a process gas containing 2 to 10% of acetylene or propane in a nitrogen carrier gas, and a flow rate of around 1 m3/h.
coating process generally leads to a decrease of the surface area, which means that the starting material must not necessarily exhibit a BET surface area of below about 4 m2/g, although in many cases it will nevertheless be advantageous to employ non-ground graphite particles which frequently have a BET surface of below 4 m2/g.
Graphite Compositions comprising the Surface-Modified Low-Surface-Area Synthetic Graphite and Highly Crystalline Synthetic Graphite
In other embodiments of this aspect, the highly crystalline synthetic graphite is characterized by a Dgo of about 4 to about 10 pm, or preferably about 5 to about 7 pm and a 050 of about 2 to about 6 pm, or preferably of about 3 to about 5 pm and a specific BET
surface area of about 10 to about 25 m2 g-1 or more preferably of about 14 to about 20 m2 g-1, such as the product C-NERGY SFG 6L supplied by TIMCAL Ltd..
Use of the Surface-Modified Low-Surface-Area Synthetic Graphite and Downstream Products comprising said Material
Measurement Methods
Specific BET Surface Area
Crystallite Size Lc
lwashita, C. Rae Park, H. Fujimoto, M. Shiraishi and M. Inagaki, Carbon 42, 701-714 (2004)) is used. The algorithm proposed by lwashita has been specifically developed for carbon materials. The widths of the line profiles at the half maximum of sample and reference are measured. By means of a correction function, the width of pure diffraction profile can be determined. The crystallite size is subsequently calculated by applying Scherrer's equation (P. Scherrer, Gottinger-Nachrichten 2 (1918) p. 98).
Crystallite Size La
La[Angstrom (A)]= C x (IG/ID) where constant C has values 44[A] and 58[A] for lasers with wavelength of 514.5 nm and 632.8 nm, respectively.
Particle Size Distribution by Laser Diffraction
parallel beam from a low-power laser lights up a cell which contains the sample suspended in water. The beam leaving the cell is focused by an optical system. The distribution of the light energy in the focal plane of the system is then analyzed. The electrical signals provided by the optical detectors are transformed into particle size distribution by means of a calculator. A small sample of graphite is mixed with a few drops of wetting agent and a small amount of water.
The sample prepared in the described manner is introduced in the storage vessel of the apparatus and measured.
References: ISO 13320-1 / ISO 14887 Xylene Density
Approx. 2.5 g (accuracy 0.1 mg) of powder is weighed in a 25 ml pycnometer.
Xylene is added under vacuum (15 Torr). After a few hours dwell time under normal pressure, the pycnometer is conditioned and weighed.
The density represents the ratio of mass and volume. The mass is given by the weight of the sample and the volume is calculated from the difference in weight of the xylene filled pycnometer with and without sample powder.
Reference: DIN 51 901 Scott Density (Apparent Density)
Tap Density
Subsequently, the cylinder is fixed on the off-centre shaft-based tapping machine and 1500 strokes are run. The reading of the volume is taken and the tap density is calculated.
Reference: -DIN-ISO 787-11 pH Value:
Fe Content
Graphite powder, ground to a maximum particle size of 80 pm by means of a vibrated mill is compacted to a tablet. The sample is placed onto the excitation stand under argon atmosphere of the spectrometer. Subsequently the fully automatic analysis can be initiated.
Ash Content
References: DIN 51903 and DIN 51701 (dividing process), ASTM C 561-91 Oxygen Content
Carbonyl, Carboxyl, Hydroxyl group content:
Lithium-Ion Negative Electrode Half Cell Test ¨ TIMCAL PVDF Standard Procedure
General half cell parameters:
2 Electrode coin cell design with Li metal foil as counter/reference electrode, cell assembly in an argon filled glove box (oxygen and water content < 1 ppm).
Diameter of electrodes: 13 mm A calibrated spring (100 kN) was used in order to have a defined force on the electrode.
Tests were carried out at 25 C.
Dispersion formulation: 94% graphite (active material, 18.8 g), 6% PVDF
(polyvinylidene fluoride) binder (9.23 g), 11 g N-methylpyrrolidine.
Dispersion preparation: The PVDF binder (13% solution in N-methylpyrrolidin), graphite and N-methylpyrrolidin were added to a Schott bottle, and stirred using a glass rod. A rotor-stator mixer was used to homogenize the solution for 5 minutes or longer at 11000 rpm.
Blading height on Cu foil: 200 pm (doctor blade).
Drying procedure: coated Cu foils were dried for 1 h at 80 C, followed by 12 h at 120 C
under vacuum (<50 mbar). After cutting, the electrodes were dried for 10 h at 120 C under vacuum (<50 mbar) before insertion into the glove box.
Pressing: A 5 x 5 cm square of the electrode foils was pressed with 50-75 kN
for 1 second in order to obtain electrode densities of 1.2-1.4 g/cm3.
Electrolyte: Ethylenecarbonate(EC) :Ethylmethylcarbonate(EMC) 1:3, 1 M LiPF6 Separator: glass fiber sheet, ca. 1 mm Cycling program using a potentiostat:
1st charge: constant current step 10 mA/g to a potential of 5 mV vs. Li/Li', followed by a constant voltage step at 5 mV vs. Li/Li until a cutoff current of 5 mA/g was reached. 1s1 discharge: constant current step 10 mA/g to a potential of 1.5 V vs. Li/Li", followed by a constant voltage step at 1.5 V vs. Li/Li' until a cutoff current of 5 mA/g was reached.
Further charge cycles: constant current step at 50 mA/g to a potential of 5 mV
vs. Li/Lit, followed by a constant voltage step at 5 mV vs. Li/Li' until a cutoff current of 5 mA/g was reached.
Further discharge cycles: constant current step at 3 C to a potential of 1.5 V
vs. Li/Li", followed by constant voltage step at 1.5 V vs. Li/Li' until a cutoff current of 5 mA/g was reached.
Lithium-Ion Negative Electrode Half Cell Test ¨ CMC/SBR Standard Procedure
General half cell parameters:
2 Electrode coin cell design with Li metal foil as counter/reference electrode, cell assembly in an argon filled glove box (oxygen and water content < 1 ppm).
Diameter of electrodes: 13 mm.
A calibrated spring (100 kN) was used in order to have a defined force on the electrode.
Tests were carried out at 25 C.
Dispersion formulation: 97% graphite (active material, 48.5 g), 2% SBR
(styrene butadiene rubber) binder (48 weight% in water, 2.08 g), 11% CMC (sodium carboxymethyl cellulose) binder (1.5 weight% in water, 33.3 g), 17 g water.
Dispersion preparation: A dispersion of the CMC binder solution and the graphite is prepared in a flask that can be put under vacuum, mixed with a glass rod until the graphite is fully wetted, then water is added. The mixture was stirred with a mechanical mixer (600 rpm) for 30 minutes under vacuum (<50 mbar). Vacuum was temporarily removed and SBR
binder solution was added. The mixture was then stirred with a mechanical mixer (600 rpm) for another 30 min under vacuum (<50 mbar).
Blading height on Cu foil: 150 pm (doctor blade).
Drying procedure: coated Cu foils were dried for 1 h at 80 C, followed by 12 h at 120 C
under vacuum (<50 mbar). After cutting, the electrodes were dried for 10 h at 120 C under vacuum (<50 mbar) before insertion into the glove box.
Pressing: 5 x 5 cm squares of the electrode foils were pressed with 75-400 kN
for 1 second in order to obtain electrode densities of 1.45-1.55 g/cm3.
Electrolyte A: Ethylenecarbonate (EC) : Ethylmethylcarbonate (EMC) 1:3 (v/v), Electrolyte B: Ethylenecarbonate (EC) : Ethylmethylcarbonate (EMC) 1:3 (v/v), 0.5 volume% vinylene carbonate, 1 M LiPF6 Separator: glass fiber sheet, ca. 1 mm Cycling program A using a potentiostat: 1st charge: constant current step 20 mA/g to a potential of 5 mV vs. Li/Lit, followed by a constant voltage step at 5 mV vs.
Li/Lit until a cutoff current of 5 mA/g was reached. 1s1 discharge: constant current step 20 mA/g to a potential of 1.5 V vs. Li/Li, followed by a constant voltage step at 1.5 V vs. Li/Li +
until a cutoff current of 5 mA/g was reached. Further charge cycles: constant current step at 50 mA/g to a potential of 5 mV vs. Li/Li', followed by a constant voltage step at 5 mV vs. Li/Li until a cutoff current of 5 mA/g was reached. Further discharge cycles: constant current step at 3 C
to a potential of 1.5 V vs. Li/Li', followed by constant voltage step at 1.5 V vs. Li/Li +
until a cutoff current of 5 mA/g was reached.
Cycling program B using a potentiostat:
1st charge: constant current step 10 mA/g to a potential of 5 mV vs. Li/Li', followed by a constant voltage step at 5 mV vs. Li/Li' until a cutoff current of 5 mA/g was reached. 1st discharge: constant current step 10 mA/g to a potential of 1.5 V vs. Li/Li', followed by a constant voltage step at 1.5 V vs. Li/Li + until a cutoff current of 5 mA/g was reached. Further charge cycles: constant current step at 50 mA/g to a potential of 5 mV vs.
Li/Li, followed by a constant voltage step at 5 mV vs. Li/Lit until a cutoff current of 5 mA/g was reached.
Further discharge cycles: constant current step at 1 C to a potential of 1.5 V
vs. Li/Lit, followed by constant voltage step at 1.5 V vs. Li/Li + until a cutoff current of 5 mA/g was reached.
Calculation of 'per cycle capacity loss': the slope of a linear fit of the discharge capacities of cycles 5-15 is divided by the discharge capacity at cycle 5, resulting in a per cycle capacity loss value [%].
T-peel test
Test specimen: 35.0 x 71.4 mm rectangles were cut from electrode foils and pressed with 14-16 kN/cm2 for 1 second. Two specimens per electrode foil were tested. One electrode foil was made for each material.
Apparatus and procedure: tape was used to peel the active layer from the Cu current collector using a tension testing machine. The load was applied at a constant head speed of
Peel strength results are expressed in N/cm.
[00100] Having described the various aspects of the present invention in general terms, it will be apparent to those of skill in the art that many modifications and slight variations are possible without departing from the spirit and scope of the present invention.
1. Surface-modified synthetic graphite having a BET surface area from about 1.0 to about 4 m2/g, and exhibiting a ratio of the perpendicular axis crystallite size Lc to the parallel axis crystallite size La (Lc/La) of greater than 1.
2. The surface-modified synthetic graphite of embodiment 1, exhibiting an ID/IG ratio (R(ID/IG)) of below 0.8 when measured with a laser having excitation wavelength of 632.8 nm.
3. The surface-modified synthetic graphite of embodiment 1 or embodiment 2, wherein the BET surface area ranges from 1 to 3.5 m2/g, or from 1 to 3 m2/g, and/or wherein said ratio of Lc/La is greater than 1.5, 2.0, 2.5, or 3Ø
4. The surface-modified synthetic graphite of any one of embodiments 1 to 3, wherein the particle size distribution (D90) ranges from 10 to 50 pm, or from 20 to 35 pm, or from 27 to 30 pm; and/or wherein the particle size distribution (D50) ranges from 5 to 40 pm, or from 7 to 30 pm, or from 10 to 20 pm.
5. The surface-modified synthetic graphite of any one of embodiments 1 to 4, wherein the crystallite size LC ranges from 50 to 200 nm, or from 80 to 180 nm, or from 100 to 130 nm.
6. The surface-modified synthetic graphite of any one of embodiments 1 to 5, wherein the crystallite size La ranges from 5t0 100 nm, from 5 to 60 nm, or from 10 to 40 nm.
7. The surface-modified synthetic graphite of any one of embodiments 1 to 6, wherein the oxygen content is greater than 50 ppm, or greater than 90 ppm, or greater than 110 ppm.
8. The surface-modified synthetic graphite of any one of embodiments 1 to 7, wherein the tapped density is greater than 0.8 g/cm3, or greater than 0.9 g/cm3, or greater than 0.95 g/cm3, or greater than 1 g/cm3.
9. The surface-modified synthetic graphite of any one of embodiments 1 to 8, wherein the Fe content value is below 20 ppm, or below 10 ppm, or below 5 ppm.
10. The surface-modified synthetic graphite of any one of embodiments 1 to 9, wherein the ash content is below 0.04, or below 0.01 %, or preferably below 0.005 %.
11. The surface-modified synthetic graphite of any one of embodiments 1 to 10, wherein the pH value ranges from 5.0 to 6.5, or from 5.2 to 6, or from 5.3 to 5.5.
12. The surface-modified synthetic graphite of embodiment 11, wherein the xylene density ranges from 2.24 to 2.26 g/cm3, or from 2.245 to 2.255 g/cm3, or from 2.25 and 2.255 g/cm3.
13. The surface-modified synthetic graphite of embodiment 11 or embodiment 12, exhibiting an ID/IG ratio (R(ID/IG)) of below about 0.3, or below about 0.25, or below about 0.2, or below about 0.15 when measured with a laser having excitation wavelength of 632.8 nm.
14. The surface-modified synthetic graphite of any one of embodiments 1 to 13, wherein the graphite is characterized by the following parameters:
i) a BET surface ranging from 2.3 to 3 m2/g ii) a crystallite size Lc ranging from 100 to 180 nm iii) a crystallite size La ranging from 10 to 40 nm iv) a pH value ranging from 5.2 to 6.0 v) an oxygen content of greater than 90 ppm vi) a tapped density of greater than 0.98 g/cm3 vii) a particle size distribution (D90) ranging from 25 to 35 pm.
15. The surface-modified synthetic graphite of any one of embodiments 11 to 14, wherein the graphite is obtainable by oxidation of synthetic graphite with a BET
surface area ranging from 1 m2/g to about 3.5 m2/g at temperatures from 500 to 1100 C with treatment times .. ranging from 2 to 30 minutes, preferably wherein the synthetic graphite starting material is non-ground synthetic graphite.
16. The surface-modified synthetic graphite of any one of embodiments 1 to 10, wherein the BET surface area ranges from 1 and 2 m2/g, or from 1.0 to 1.5 m2/g.
17. The surface-modified synthetic graphite of embodiment 16, wherein the xylene density ranges from 2.1 to 2.26 g/cm3, or from 2.2 to 2.255 g/cm3, or from 2.24 to 2.25 g/cm3.
18. The surface-modified synthetic graphite of any one of embodiments 16 to 18, wherein the surface-modified synthetic graphite is characterized by the following parameters:
i) a BET surface area ranging from 1.3 to 1.8 g/cm3 ii) a crystallite size Lc ranging from 100 to 160 nm iii) a crystallite size La ranging from 20 to 60 nm; and, optionally iv) an oxygen content of greater than 80 ppm.
19. The surface-modified synthetic graphite of any one of embodiments 16 to 18, wherein said graphite is obtainable by chemical vapor deposition (CVD) on a synthetic graphite starting material at temperatures from 500 to 1000 C with hydrocarbon gas and treatment times ranging from 3 to 120 minutes.
20. A process for modifying the surface of synthetic graphite, wherein a synthetic graphite having a BET surface area from 1 to 4 m2/g, or from 1 to 3 m2/9 is subjected to a surface modification process selected from oxidation and chemical vapor deposition (CVD) under conditions that increase the ratio between the crystallite size L, and the crystallite size La.
21. The process of embodiment 20, wherein the surface of synthetic graphite is modified at a temperature ranging from 500 to 1100 C, or from 600 to 1000, or from 700 to 900 C.
22. The process of embodiment 20 or embodiment 21, wherein the surface of synthetic graphite is modified in a high temperature furnace, preferably wherein the furnace is a rotary furnace, a fluidized bed reactor or a fixed bed reactor.
23. The process of any one of embodiments 20 to 22, wherein the surface of said synthetic graphite is modified by contact with an oxygen-containing process gas, wherein the process parameters are adapted to keep the burn off rate ( /0 w/w) below 10%, or below 9 %, or below 8%.
24. The process of any one of embodiments 20 to 23, wherein the surface of said synthetic graphite is modified by contact with oxygen for a period ranging from 2 to 30 minutes, or from 2 to 15 minutes, or from 4 to 10 minutes, or from 5 to 8 minutes.
25. The process of embodiment 23 or embodiment 24, wherein the oxidation is achieved by contacting the synthetic graphite with air at a flow rate ranging from 1 to 200 l/min, or from 1 to 50 l/min, or from 2 to 5 l/min.
26. The process of any one of embodiments 20 to 22, wherein the surface of said synthetic graphite is modified by chemical vapor deposition achieved by contacting said graphite with a hydrocarbon gas or with alcohol vapor for a period ranging from 5 to 120 minutes, or from 10 to 60 minutes, or from 15 to 30 minutes.
27. The process of embodiment 26, wherein the hydrocarbon gas is an aliphatic or aromatic hydrocarbon selected from the group consisting of methane, ethane, ethylene, propane, propene, acetylene, butane, benzene, toluene, xylene and combinations thereof, or wherein the alcohol is selected from the group consisting of ethanol, propanol, isopropanol, and combinations thereof.
28. The process of embodiment 26 or embodiment 27, wherein the surface modification by chemical vapor deposition is carried out in a fluidized bed reactor at temperatures ranging from 500 to 1000 C with hydrogen carbon gas mixed with an inert carrier gas, preferably wherein the hydrocarbon gas is acetylene or propane, and the carrier gas is nitrogen.
29. The process of any one of embodiments 20 to 28, wherein the surface-modified synthetic graphite exhibits a ratio of the crystallite size Lc to the crystallite size La (Lc/La) of greater than 1, or wherein said ratio is greater than 1.5, 2.0, 2.5, or 3Ø
30. The process of embodiment any one of embodiments 20 to 29, wherein the crystallite size Lc of the surface-modified synthetic graphite ranges from 50 to 200 nm, or from 80 to 180 nm, or from 100 to 130 nm.
31. The process of any one of embodiments 20 to 30, wherein the crystallite size La of the surface-modified synthetic graphite ranges from 5 to 100 nm, or from 5 to 60 nm, or from 10 to 40 nm.
32. The process of any one of embodiments 20 to 31, wherein the oxygen content of the surface-modified synthetic graphite is greater than 50 ppm, or greater than 90 ppm, or greater than 110 ppm.
33. The process of any one of embodiments 20 to 32, wherein the tapped density of the surface-modified synthetic graphite is greater than 0.8 g/cm3, or greater than 0.9 g/cm3, or greater than 0.95 g/cm3 , or greater than 1 g/cm3.
34. The process of any one of embodiments 20 to 33, wherein the Fe content value of the surface-modified synthetic graphite is below 20 ppm, or below 10 ppm, or below 5 ppm.
35. The process of any one of embodiments 20 to 34, wherein the ash content of the surface-modified synthetic graphite is below 0.04, or below 0.01 %, or below 0.005 %.
36. The process of any one of embodiments 20 to 35, wherein the surface-modified synthetic graphite provides for a higher discharge capacity and/or lower irreversible capacity compared to the untreated starting material when used as a negative electrode material in a lithium ion battery.
37. A surface-modified synthetic graphite having a BET surface area from about 1.0 to about 4 m2/g, and exhibiting a ratio of the perpendicular axis crystallite size Lc to the parallel axis crystallite size La (Lc/La) of greater than 1, obtainable by a process of any one of embodiments 20 to 36.
38. A graphite composition comprising the surface-modified synthetic graphite as defined in any one of embodiments 1 to 19 or 37 and further comprising 1 to 30% by weight of a highly crystalline synthetic or natural graphite.
39. The graphite composition of embodiment 38, wherein the highly crystalline graphite is a synthetic graphite characterized by i) a Dgo of about 15 to about 20 pm and a BET SSA of about 8 to about 12 m2 g-1; or ii) a Dgo of about 5 to about 7 pm and a BET SSA of about 14 to about 20 m2 g-1.
40. The graphite composition of embodiment 38 or 39, consisting of the surface-modified synthetic graphite as defined in any one of embodiments 1 to 19 or 37 and 5%
to 20% by weight of said highly crystalline synthetic graphite.
41. Use of the surface-modified synthetic graphite as defined in any one of embodiments 1 to 19 or 37, or the graphite composition as defined in any one of embodiments 38 to 40, for preparing a negative electrode material for a lithium ion battery.
42. A negative electrode of a lithium ion battery comprising the surface-modified synthetic graphite as defined in any one of embodiments 1 to 19 or 37, or the graphite composition as defined in any one of embodiments 38 to 40, as an active material.
43. A lithium ion battery comprising the surface-modified synthetic graphite as defined in any one of embodiments 1 to 19 or 37, or the graphite composition as defined in any one of embodiments 38 to 40, in the negative electrode of the battery.
44. A surface-modified synthetic graphite, wherein the surface-modified synthetic graphite:
- has a BET surface area from about 1.0 to about 4 m2/g;
- has a crystallite size Lc, as measured by XRD, from 50 to 200 nm;
- has a crystallite size La, as measured by Raman spectroscopy, from 5 to 100 nm;
and - exhibits a ratio (Lc / La) of the perpendicular axis crystallite size Lc to the parallel axis crystallite size La of greater than 1.5.
45. A surface-modified synthetic graphite, wherein the surface-modified synthetic graphite:
- has a BET surface area from about 1.0 to about 4 m2/g;
- has a crystallite size Lc, as measured by XRD, from 50 to 200 nm;
- has a crystallite size La, as measured by Raman spectroscopy, from 5 to 100 nm;
- exhibits a ratio Lc / La of the perpendicular axis crystallite size Lc to the parallel axis crystallite size La of greater than 1.5; and - has an oxygen content of greater than 50 ppm.
46. A surface-modified synthetic graphite, wherein the surface-modified synthetic graphite:
- has a BET surface area from about 1.0 to about 4 m2/g;
- has a crystallite size Lc, as measured by XRD, from 50 to 200 nm;
- has a crystallite size La, as measured by Raman spectroscopy, from 5 to 100 nm;
- exhibits a ratio Lc / La of the perpendicular axis crystallite size Lc to the parallel axis crystallite size La of greater than 1.5; and - has a particle size distribution (D50) ranging from 5 to 40 pm.
27a
EXAMPLES
Example 1 ¨ Surface modification of low surface area synthetic graphite by oxidation
Rotation of the stainless steel rotary kiln with 7.5 rpm ensured homogeneity of the treatment.
Using these conditions modified the product material comparing to starting material as shown in Table 1.
While the BET increase points to changes of the microporosity and morphology of the graphite particles, the decrease of the pH value shows occurrence of new functionalized groups. The introduction of oxygen-containing groups apparently leads to a less hydrophobic and less inert surface of the treated graphite, as indicated by a change in hydrophobicity values (data not shown).
Table 1: Properties of starting material and material after treatment according to Example 1 Starting material Surface oxidation BET [m2/g] 1.8 2.15 Lc [nm] 175 165 La [nm] 170 34 Xylene density [g/cm3] 2.252 2.257 Tapped density [g/cm3] 0.96 0.86 Scott density [g/cm3] 0.45 0.35 pH 6.7 5.3 D10 5.8 6.2 D50 13.4 13.8 D90 28.9 28.9
in the treated material at around 1330 cm-1, which arises from vibrational disorder-induced mode.
This is believed to be due to the existence of defects in graphite hexagonal layers, sp3-hybridization as well as amorphous carbon occurrence. Similarly, the G-band peak at around 1580 cm-1 corresponds to the Raman mode of graphite, which has been shown to be related to the fraction of sp2- bonded sites. As apparent from the spectra, the intensity of the G-band clearly decreases after oxidation treatment. A change of the ID/IG ratio confirms the creation of defects and the shrinking of the crystalline domains (La) in graphite because of etching with oxygen atoms. The creation of functional groups, e.g. carboxylic acid, carbonyl, hydroxyl and/or ether groups, modifies the hybridization of the surface carbon atoms towards greater sp3 character, thereby increasing the number of defects (Dongil etal., Journal of Colloid and Interface Science, 2011, 355, 179-189).
1:3 (vol /0) of electrodes containing said graphite and 6 % PVDF (as a binder), which in turn leads to lower charge losses (shown in Figure 3). In addition, the oxidation significantly increased the performance of the electrode at high current drain.
Example 2 ¨ Surface modification of low surface area synthetic graphite by oxidation
Table 2 below). A
scanning electron microscope image of the treated material is shown in Figure 2.
Table 2: Properties of the starting and treated material according to Example Starting Material Surface Oxidation BET [m2/g] 1.6 2.8 Lc [nm] 110 110 La [nm] 40 15 Fe content [ppm] 3.2 4.8 Xylene density [g/cm3] 2.251 2.252 Tapped density [g/cm3] 1.11 1 Scott density [g/cm3] 0.45 0.4 Example 3 ¨ Surface modification of low surface area synthetic graphite by oxidation
Table 3: Properties of the starting and treated material according to Example Starting Material Surface Oxidation BET [m2/g] 1.95 2.45 Xylene density [g/cm3] 2.246 2.249 Tapped density [g/cm3] 1.02 1.04 Scott density [g/cm3] 0.44 0.43 pH 6.8 5.4
Table 4: Parameters of starting and treated materials:
Starting Material Surface Oxidation CVD Coating BET [m2/g] 1.6-2.0 2.0 ¨ 3.0 1.4 ¨ 1.7 Lc [nm] 100 - 180 100 - 180 80 - 160 Fe content [ppm] <20 <20 <20 Carbonyl type groups [%] 20 20-40 40 Carboxyl type groups [h.] 61 70-50 40 Hydroxyl type groups [%] 19 10 20 pH 7 5.3 Oxygen content [ppm] 50 ¨ 80 90 - 140 110 Example 4¨ Peel Strength and Per Cycle Capacity Loss of surface-modified low surface area synthetic graphite by oxidation and of untreated material
standard procedure described in the method section above (electrolyte A, cycling program A, 3 C
discharge rate). The surface-treated material again showed significantly improved properties over the untreated material as the per cycle capacity loss was significantly reduced compared to the untreated reference material (see again Table 5) for detailed results).
Table 5: Peel Strength and Per Cycle Capacity Loss of starting and treated materials:
Without surface oxidation With surface oxidation treatment treatment Peel strength 0.066 0.002 0.080 0.003 [N cm-1]
Per cycle capacity loss 0.317 0.017 0.192 0.002
0.3355 nm, Xylene density = 2.260 g cm-3 (TIMRDe SFG 15) and the physical and electrochemical properties of the mixtures compared to the pure treated material. The mixtures and pure treated material were tested for the retention of the specific charge per cycle, 1st discharge cycle specific charge, 51 h discharge cycle specific charge (CMC/SBR standard procedure, electrolyte B, cycling program B, 1 C discharge rate).
Table 6: Per Cycle Capacity Loss of Mixtures of Surface-Oxidized Low Surface-Area Synthetic Graphite with Highly Crystalline Synthetic Graphite Surface- Surface-oxidized Surface-oxidized Surface-oxidized oxidized low low surface-area low surface-area low surface-area surface-area synthetic graphite synthetic graphite synthetic graphite synthetic with 5% highly with 10% highly with 20%
highly graphite crystalline crystalline crystalline without synthetic graphite synthetic graphite synthetic graphite additives Per cycle capacity loss 0.102 0.002 0.034 0.004 0.036 0.004 0.020 0.003 [A]
1st cycle irreversible 8.7 3.6 11.7 2.8 11.5 3.1 16.6 2.9 capacity [`)/0]
-th cycle discharge 338.1 2.9 345.6 2.7 343.1 2.1 348.7 3.0 capacity [Ah/kg]
Tap density 0.96 g/cm3 not measured not measured 0.50 g/cm3 of graphite BET surface area of graphite 2.0-3.5 2.3-3.9 2.7-4.1 3.3-4.7 [1.112/g]
Claims (17)
- has a BET surface area from about 1.0 to about 4 m2/g;
- has a crystallite size L c, as measured by XRD, from 50 to 200 nm;
- has a crystallite size L a, as measured by Raman spectroscopy, from 5 to 100 nm;
and - exhibits a ratio (L c/L a) of the perpendicular axis crystallite size L c to the parallel axis crystallite size L a of greater than 1.5.
i) a BET surface area ranging from 1 to 3.5 m2/g;
ii) an ash content of below 0.04 %; a ratio of L c/L a of greater than 1.5;
iii) a particle size distribution (D90) ranging from 10 to 50 µm;
iv) a particle size distribution (D50) ranging from 5 to 40 µm;
v) an Fe content of below 20 ppm a crystallite size L a from 5 to 100 nm;
vi) an oxygen content of greater than 50 ppm;
vii) a tapped density of greater than 0.8 g/cm3;
viii) an Fe content of below 20 ppm; and ix) an ash content of below 0.04 %.
i) a pH value ranging from 5.0 to 6.5;
ii) a xylene density from 2.24 to 2.26 g/cm3; and iii) exhibits an ID/IG ratio (R(ID/IG)) of below 0.3 when measured with a laser having excitation wavelength of 632.8 nm.
i) a BET surface ranging from 2.3 to 3 m2/g;
ii) a crystallite size L c ranging from 100 to 180 nm;
iii) a crystallite size L a ranging from 10 to 40 nm;
iv) a pH value ranging from 5.2 to 6.0;
v) an oxygen content of greater than 90 ppm;
vi) a tapped density of greater than 0.98 g/cm3; and vii) a particle size distribution (D90) ranging from 25 to 35 µm.
- has a BET surface area from about 1.0 to about 4 m2/g;
- has a crystallite size L c, as measured by XRD, from 50 to 200 nm;
- has a crystallite size L a, as measured by Raman spectroscopy, from 5 to 100 nm;
- exhibits a ratio L c/L a of the perpendicular axis crystallite size L c to the parallel axis crystallite size L a of greater than 1.5; and - has an oxygen content of greater than 50 ppm.
i) a pH value ranging from 5.0 to 6.5;
ii) a xylene density from 2.24 to 2.26 g/cm3; and iii) exhibits an ID/IG ratio (R(ID/IG)) of below 0.3 when measured with a laser having excitation wavelength of 632.8 nm.
i) a BET surface ranging from 2.3 to 3 m2/g;
ii) a crystallite size L c ranging from 100 to 180 nm;
iii) a crystallite size L a ranging from 10 to 40 nm;
iv) a pH value ranging from 5.2 to 6.0;
v) an oxygen content of greater than 90 ppm;
vi) a tapped density of greater than 0.98 g/cm3; and vii) a particle size distribution (D90) ranging from 25 to 35 µm.
i) a BET surface area ranging from 1 and 2 m2/g; and ii) a xylene density ranging from 2.1 to 2.26 g/cm3.
i) a BET surface area ranging from 1.3 to 1.8 g/cm3;
ii) a crystallite size L c ranging from 100 to 160 nm; and iii) a crystallite size L a ranging from 20 to 60 nm.
- has a BET surface area from about 1.0 to about 4 m2/g;
- has a crystallite size L c, as measured by XRD, from 50 to 200 nm;
- has a crystallite size L a, as measured by Raman spectroscopy, from 5 to 100 nm;
- exhibits a ratio L c/L a of the perpendicular axis crystallite size L c to the parallel axis crystallite size L a of greater than 1.5; and - has a particle size distribution (D50) ranging from 5 to 40 µm.
i) a pH value ranging from 5.0 to 6.5;
ii) a xylene density from 2.24 to 2.26 g/cm3; and iii) exhibits an ID/IG ratio (R(ID/IG)) of below 0.3 when measured with a laser having excitation wavelength of 632.8 nm.
i) a BET surface ranging from 2.3 to 3 m2/g;
ii) a crystallite size L c ranging from 100 to 180 nm;
iii) a crystallite size L a ranging from 10 to 40 nm;
iv) a pH value ranging from 5.2 to 6.0;
v) an oxygen content of greater than 90 ppm;
vi) a tapped density of greater than 0.98 g/cm3; and vii) a particle size distribution (D90) ranging from 25 to 35 µm.
i) a BET surface area ranging from 1 to 2 m2/g; and ii) a xylene density ranging from 2.1 to 2.26 g/cm3.
i) a BET surface area ranging from 1.3 to 1.8 g/cm3;
ii) a crystallite size L c ranging from 100 to 160 nm; and iii) a crystallite size L a ranging from 20 to 60 nm.
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| MX2019013870A (en) | 2020-01-20 |
| CN104364193B (en) | 2017-08-01 |
| JP6360034B2 (en) | 2018-07-18 |
| ES2934232T3 (en) | 2023-02-20 |
| HUE036038T2 (en) | 2018-06-28 |
| EP3326968A1 (en) | 2018-05-30 |
| KR20150059135A (en) | 2015-05-29 |
| US20150079477A1 (en) | 2015-03-19 |
| US10305107B2 (en) | 2019-05-28 |
| HUE060820T2 (en) | 2023-04-28 |
| MX369771B (en) | 2019-11-21 |
| FI3326968T3 (en) | 2023-01-13 |
| CA2869499A1 (en) | 2013-10-10 |
| EP3326968B1 (en) | 2022-10-12 |
| JP2015517971A (en) | 2015-06-25 |
| WO2013149807A3 (en) | 2013-12-19 |
| PL2834192T3 (en) | 2018-06-29 |
| EP2834192A2 (en) | 2015-02-11 |
| DK2834192T3 (en) | 2018-02-19 |
| ES2659193T3 (en) | 2018-03-14 |
| NO2834192T3 (en) | 2018-06-02 |
| PL3326968T3 (en) | 2023-03-20 |
| CN104364193A (en) | 2015-02-18 |
| MX2014011983A (en) | 2015-03-09 |
| EP2834192B1 (en) | 2018-01-03 |
| WO2013149807A2 (en) | 2013-10-10 |
| KR102055822B1 (en) | 2019-12-13 |
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