CA3152463C - Anode material and method for producing same - Google Patents
Anode material and method for producing same Download PDFInfo
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- CA3152463C CA3152463C CA3152463A CA3152463A CA3152463C CA 3152463 C CA3152463 C CA 3152463C CA 3152463 A CA3152463 A CA 3152463A CA 3152463 A CA3152463 A CA 3152463A CA 3152463 C CA3152463 C CA 3152463C
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Abstract
Description
Field of the Invention [0001] The present invention relates to an anode material. More particularly, the anode material of the present invention is intended for use as an anode material in lithium-ion batteries.
That is, cold temperatures can cause deposits of lithium metal to form in the battery, causing internal short circuits that may lead to fires in cells.
A Review, Progress in Natural Science: Materials International, Shuai Ma et al., December 2018).
Consequently, the battery's capacity and cycle efficiency drops and this translates to poorer performance (Final Technical Report: Internal Short Circuits in Lithium-Ion Cells for PHEVs" Sriramulu & Stringfellow, 2014).
Investigation found that cold winter overnight temperatures fostered lithium plating within the battery cells and caused the short circuits (Aircraft Serious Incident Investigation Report, All Nippon Airways Ltd, JA804A., Sep 2014).
PCT/18 2020/058 910 - 23.07.2021
Disclosure of the Invention
AMENDED SHEET
PCT/IB 2020/058 910 - 23.07.2021 (i) about 2 to 9 m2/g; or (ii) about 2 to 6 m2/g.
at 2C rate discharge.
wt/wt CMC.
(i) less than about 15 microns;
(ii) less than about 10 microns; or (iii) in the range of about 4 to 6 microns.
AMENDED SHEET
PCT/IB 2020/058 910 - 23.07.2021
characteristics of one or more of a d002 of > 3.35 A, an Le of >1000 A and an La of >1000 A.
In a preferred form, the ground primary graphite particles have XRD
characteristics of each of a d002 of > 3.35 A, an Lc of >1000 A and an La of >1000 A, and a purity of > 99.9%.
AMENDED SHEET
PCT/I B 2020/058 910 - 23.07.2021
(i) less than about 15 microns;
(ii) less than about 10 microns; or (iii) in the range of about 4 to 6 microns.
(i) about 2 to 9 m2/g; or (ii) about 2 to 6 m2/g.
characteristics of one or more of a d002 of > 3.35 A, an Le of >1000 A and an La of >1000 A.
In a preferred form, the ground primary graphite particles have XRD
characteristics of each of a d002 of > 3.35 A, an Lc of >1000 A and an La of >1000 A. and a purity of > 99.9%.
Brief Description of the Drawings
PCT/IB 2020/058 910 - 23.07.2021 Figures la and lb are scanning electron microscope (SEM) images of an anode material of the present invention comprises secondary graphite particles predominantly having a form that approximates an oblate spheroid;
Figure 2 is a schematic representation of the steps employed in the production of an electrode in accordance with an embodiment of the present invention, showing the secondary graphite particle (referenced as Talnode-C') being processed through a series of process steps to provide a slurry and in turn producing the electrode;
Figure 3 is a graph of electrode density against mechanical strength, for an electrode prepared in accordance with the present invention, utilising the secondary graphite particles thereof;
Figure 4 is a cross-sectional view through a single layer laminate cell constructed in known manner, utilising the anode material of the present invention to provide an anode in accordance therewith;
Figure 5 is a Nyquist plot of resistance in a cell prepared utilising the anode material of the present invention to provide an anode in accordance therewith, at 25 C;
Figure 6 is a Bode plot of resistance (Z' vs frequency) in a cell prepared utilising the anode material of the present invention to provide an anode in accordance therewith, at 25 C;
Figure 7 is a Bode plot of resistance (Z" vs frequency) in a cell prepared utilising the anode material of the present invention to provide an anode in accordance therewith, at 25 C;
Figure 8 is a Nyquist plot of resistance in a cell prepared utilising the anode material of the present invention to provide an anode in accordance therewith, at 0 C;
AMENDED SHEET
PCT/IB 2020/058 910 - 23.07.2021 Figure 9 is a Bode plot of resistance (Z' vs frequency) in a cell prepared utilising the anode material of the present invention to provide an anode in accordance therewith, at 0 C;
Figure 10 is a Bode plot of resistance (Z vs frequency) in a cell prepared utilising the anode material of the present invention to provide an anode in accordance therewith, at 00C;
Figure 11 is a diagrammatic representation of the limit load characteristics of a cell prepared utilising the anode material of the present invention to provide an anode in accordance therewith, showing the performance at 25 C and 0 C, and utilising different C-rates;
Figure 12 is a graphical representation of the efficiency of an anode in accordance with the present invention at 25 C and 0 C;
Figure 13 is a graphical representation of voltage drop over time during endurance testing of a cell in accordance with the present invention at low temperature, comparing the performance against indicative 'market leaders';
Figure 14 is a graphical representation of capacity of a cell, at a different discharge rate, in accordance with the present invention at low temperature, comparing the performance against an indicative 'market leader';
Figure 15 is a is a schematic representation of the steps employed in the production of an electrode in accordance with another embodiment of the present invention, showing the secondary graphite particle (referenced here as '1-13') being processed through a series of process steps to provide a slurry and in turn producing a coated electrode;
Figure 16 is a graphical representation of cycle performance of a pouch cell in accordance with the present invention showing the capacity retention thereof; and AMENDED SHEET
PCT/IB 2020/058 910 - 23.07.2021 Figure 17 is a graphical representation of discharge rate characteristics of a pouch cell in accordance with the present invention.
Best Mode(s) for Carrying Out the invention
wt/wt CMC.
AMENDED SHEET
=
PCT/IB 2020/058 910 - 23.07.2021
(i) less than about 15 microns;
(ii) less than about 10 microns; or (iii) in the range of about 4 to 6 microns.
= =
PCT/IB 2020/058 910 - 23.07.2021 predominantly having a form that approximates an oblate spheroid and that have a D50 of less than about 5 microns.
relative to graphite.
(i) less than about 15 microns;
(ii) less than about 10 microns; or (iii) in the range of about 4 to 6 microns.
[00e4] The ground primary graphite particles have XRD characteristics of one or more of a d002 of > 3.35 A, an Lc of >1000 A and an La of >1000 A. For AMENDED SHEET
PCT/IB 2020/058 910 - 23.07.2021 example, the ground primary graphite particles have XRD characteristics of each of a d002 of > 3.35 A, an Lc of >1000 A and an La of >1000 A, and a purity >99-9%-[0065] In a further form of the present invention the ground primary graphite particles are processed by way of an agglomeration and/or surface modification step so as to produce the secondary graphite particles predominantly having a form that approximates an oblate spheroid. The agglomeration and/or surface modification step may comprise a spray drying process. In one embodiment the spray drying process is achieved utilising a fluidised bed.
[0066] In a typical arrangement of graphite flake relative to a collector in an anode of the prior art, the anisotropic graphite flake or particle orientation relative to the collector contributes to consequent high resistance to diffusion of lithium ions therethrough. The anisotropic graphite particle orientation simply doesn't provide any physical opportunity for lithium ion diffusion. Consequently, the prior art has sought to orient graphite in random directions, creating spheronised graphite in an effort to overcome the anisotropic limitations apparent. This is why most current anode materials are nearly spherical in shape. The near spherical shape of prior art graphite anode material is also intended to provide a packing density needed on the collector so as to increase the volumetric capacity to store lithium.
[0067] Without limitation to the scope of the present invention, the secondary graphite particles of the present invention are envisaged to ideally be orientated in a largely irregular manner relative to a collector and thereby provide consequently lower resistance to diffusion of lithium ions therethrough. The oblate spheroid nature of the secondary particles of the present invention are such that they do not orient in the same manner as the graphite flake of the prior art. Rather, the secondary particles of the present invention clump in an irregular manner, creating clumps of secondary particles that provide a level of porosity, and a relatively greater packing density, in the anode material and the anode of the present invention. It is understood by the Applicants that swelling and lithium ion resistance in the anode of the present invention are reduced relative to that of the prior art.
AMENDED SHEET
PCT/1B 2020/058 910 - 23.07.2021 [0068] In Figures la and 1b there are shown a number of generally oblate spheroid secondary graphite particles of the present invention, showing their Dso in the range of about 3 to 5 microns.
[0069] The process of the present invention may be better understood with reference to the following non-limiting examples.
EXAMPLE
[0070] As noted above, the present invention still further provides a method for the production of an anode material, the method comprising the grinding of a graphite material to produce ground primary graphite particles, wherein those ground primary graphite particles are processed in a manner so as to produce secondary graphite particles predominantly having a form that approximates an oblate spheroid.
[0071] Table A below provides an example of an appropriate ground primary graphite particle for use in/as used in the method of the present invention, whilst Table B provides the elemental analysis thereof.
Table A
Property Value Method Carbon Content >99.9%
LECO (C%, S%). Loss of Ignition (101) Surface Area 2-9 mfg Bernauer-Emmett-Teller (BET) Particle size 3-151.tm Particle size analyzer Di 1~3um D50 s1~6um D90 7-101.1in Bulk Density 0.2-1g/cc Bulk density apparatus d1002 >3.35 A XRfl Lc >1000 A
La >limo A
Table B
C Al Ca Cu Fe K Mg Mn Si S
ELEMENTS
>99.9% 3.3 7.4 7.3 26.7 5.7 19 0.2 <0.1 37 PPm AMENDED SHEET
PCT/1B 2020/058 910 - 23.07.2021 [0072] The ground primary graphite particles are spheronised and coated with a carbon based material, after which they are pyrolysed, thereby producing the secondary particle that approximates an oblate spheroid. The carbon based material is one or more of pitch, polyethylene oxide and polyvinyl alcohol.
The amount of carbon based material used in coating the ground primary graphite particles is in the range of 2 to 10 wt% relative to graphite. The temperature of pyrolysis is between about 880 C to 1100 C. The time for pyrolysis is in the range of about 12 to 40 hours, including both heating and cooling periods.
[0073] In Figure 2 there is shown a representation of the method for slurrying an anode material in accordance with the present invention for application, in known manner, to a collector, to produce an anode in accordance with one embodiment of the present invention. As noted, the secondary graphite particles of the present invention, here designated Talnode-C, is mixed at an amount of 29.25 g, with 0.21 g of CMC, providing a 1.0% H20 solution; 21 g. This is mixed at 2000rpm for 2 minutes, three times. Two subsequent additions of 0.45 g of CMC (1.0% H20 solution; 4.5g) are made and mixed at 2000rpm for two minutes, two times, as shown. Further, a 0.45 g addition of SBR is provided (48% H20 solution;
0.928g), and mixed at 2000 rpm for two minutes, a single time. This process provides a slurry of anode material in accordance with the present invention at a solids content of 49.9% and a viscosity of 41nnPas. Subsequent application of the slurry so produced to a collector, and drying, is achieved in known manner. This process provides an anode composition of 97.5% wt/wt secondary graphite particles, about 1.5% wt/wt SBR and about 1% wt/wt CMC.
[0074] Table 1 below describes the characteristics of the anode produced in accordance with the present invention and Figure 3 shows a graph of electrode density against mechanical strength. The density and mechanical strength of the anode of the present invention are good relative to those of equivalent prior art anodes, and the reversible capacity, of 350-365 mAh/g, depending upon the cell configuration, is understood by the Applicant to be 'industry-standard'.
AMENDED SHEET
PCT/IB 2020/058 910 - 23.07.2021 Table 1 mwmowngkgammamm BMer ftzaM0**,ilt-wgt.W.
mwszm-sw:µ,.;;Q=4-w:;1=.0,-,..:=. = :=mwm..õwww.mm:,,owai-m=-m....mom=i EiNmOtt n8011W-E-:-:==-40:NEMMEswitnittl#4011-pmni-Min This 66 =
Detbty I 63 j/& ......
E-k-Agi,togigawgwg*M
...............................................................................
......................................................
0,11***41, OCroi!c,..WWW=glaratiattakt¨iiiiiii-AOS
1:?.y:irmtottt.r7-tho.l.rs.vmnmsmt.mmmws.,..m.ntrtm.mmtg ..
..
WatNIISAKM: 4..
[0075] Table 2 below and Figure 4 show a full cell 10 incorporating the anode material and anode in accordance with the present invention. The full cell 10 comprises an aluminium laminate film or outer package 12, a negative electrode =
or anode 14 in accordance with the present invention, a positive electrode or cathode 16, and a separator 18, each arranged in substantially known manner.
The anode 14 further comprises a copper current collector 20 and the cathode further comprises an aluminium current collector 22. Importantly, there is no gas discharge during initial charge/discharge of the full cell 10, and minimal discharge at 3.6V charge (0.04cc).
Table 2 Coikatisitio0 MIttaltiffdP.0314.'3 pc.41,T. MO:um Deanity 30 X $0nran Caniextt graphitelOICASER*91.S/Liiil rpm Thickness 71 u.
Oft1111,1* Demtity S2 r Intn Sastriur M401dard PE Dikr0001Twrfi Elvetrabte, IM-UPFV3ECIMEC4VCIPS
Fstfing dreM. !SI'S?
AMENDED SHEET
. , PCT/IB 2020/058 910 - 23.07.2021 [0076] In Figures 5 to 7 there are shown plots of resistance in the cell 10 at 25 C, and which can be compared with Figures 8 to 10, in which there are shown plots al resistance in the cell 10 at 0 C. Importantly, the cell 10 demonstrates a 15%
lower cell resistance relative to typical or known cells utilising current graphite anodes at 25 C. For example, the resistance value largely related to the reaction resistance of the negative electrode is 0.29, which is, as noted, about 15%
lower than the cell resistance of typical or known cells utilising current graphite anodes at 25 C. At 0 C the cell 10 is at the lowest level of typical or known cells utilising current graphite anodes.
[0077] A test protocol to test the limit load characteristics of the cell 10 (initial load and post-deterioration simulated load) at both 25 C and at 0 C, 10 cycles per setting, and at variable charge depth, is represented in Figure 11. Charge depth is varied by changing the charging voltage, and the cells are only partially charged/discharged to allow for different voltages. Resistance and charge depth detail is set out in Table 3 below. Performance evaluation of the cell 10 was conducted in this manner, considering different C-rates at the respective different temperatures. Details of the tests included the use of 10 cycles per setting, with the cell 10 being only partially charged/discharged so as to allow for different voltages.
Table 3 IR revel/ (1)4.05V (2410V {MAW
Anode &ogle depth IR. revel 251I--0,2CA
IR re v4 2VG-0.SCA INPAINN gide006101ilialiatala IR met 2VC- .00A
Ernlatal ta revel 01:-LIVA
...........................................................
IJ revel LocA
[00781 Further testing of the limit load characteristics of the cell 10 is represented in Figure 12, in terms of efficiency. In Tables 4 and 5 below the related capacity data is provided.
AMENDED SHEET
PCT/IB 2020/058 910 - 23.07.2021 Table 4 -T. .1 .. _.....
66e1atra1nst tIaleiVi;atiWki _ ft3 244 . I
6.
disthOr1tst.t60116.10,KaiR) 149 . . . _ Caot rtiotttionou 94$9.5 IS, 1 cks.4 MIA
Table 5 -1r47-11.04r¨iiiiiiir-1942i_ nallit9N1104.S40.1V11}Millt N.
¨ 02 _ Ca ad - r eltentioitt%) Moi 9#.6 1014 [0079] At 25 C the efficiency of the cell 10 is understood to be similar to that of leading known anode products. However, it is important to note that at 0 C the leading known anode products have a capacity retention of less than 98%, which then rapidly decreases to a limit level. The anode material of the present invention rather has a cycling efficiency of 98% at low loading (4.1V) and achieves a cycling efficiency 01100% even as a result of high loading (4.15V) and after cycles.
[00801At 25 C the cycle efficiency of the cell 10 is understood to be similar to that of leading known anode products. However, it is important to note that at 0 C
the leading known anode products have a capacity retention of less than 98%, which then rapidly decreases to a limit level. The anode material of the present invention rather has a cycle efficiency of 99% at low loading (4.1V) and achieves a capacity retention of 100% even as a result of high loading (4.15V) and after 60 cycles.
[0081] Testing has also been conducted to investigate the endurance of the cell (here broadly referenced as either Talnode or Talnode-C) under conditions of high power and fast charge, relative to those of indicative 'market leader' products. The results of this testing are shown in Figures 13 and 14. A cyclic test was conducted and was designed to simulate driving a car up a mountain at high speed. This cyclic test measures the ability of the cell 10 to collect fast charge regenerative current (from braking) efficiently, after a high-power discharge (or acceleration) in low temperature conditions.
AMENDED SHEET
PCT/IB 2020/058 910 - 23.07.2021 [0082] Figure 13 describes the time for cell voltage to fall below 3.2 V at 14 C.
The test cycle was discharge 3 seconds at 3G, charge 1 second at 1C, rest for seconds, and repeat until voltage drop or thermal/cell temperature limits are reached. Figure 14 demonstrates that the cell 10 provides higher capacity than the indicative 'market leader', or 'commercial synthetic', at all C rates_ [0083] In Figure 15 there is shown a representation of the method for slurrying an anode material in accordance with the present invention for application, in known manner, to a collector, to produce an anode in accordance with a further embodiment of the present invention. As noted, the secondary graphite particles of the present invention, here designated T-13, are mixed at an amount of 4.3 g, with 2 g of CMC, providing a 1.0% H20 solution. This is mixed at 2000 rpm for minutes, once. Five subsequent additions of between 0.2 g to 0.8 g of GMC
(1.0% H20 solution) are made and mixed at 2000rpm for 2 minutes, either two or three times, as shown. A further single mixing in 0.5 g of H20 is conducted at 2000rpm for 2 minutes is conducted. Further, a 0.14 g addition of SBR is provided (48.5% H20 dispersion), and mixed at 2000rpm for two minutes, a single time. This process provides a slurry of anode material in accordance with the present invention at a solids content of 47.2% and a viscosity of 200mPa.s.
Subsequent application of the slurry so produced to a collector, and drying, is achieved in known manner. This process provides an anode composition of 97.5% wt/wt secondary graphite particles, about 1.5% wt/wt SBR and about 1%
wt/wt C MC.
[0084] Table 6 below describes the characteristics of the anode produced in accordance with the present invention.
AMENDED SHEET
PCT/IB 2020/058 910 - 23.07.2021 Table 6 Wive maktial 1 Cain0 Comma* Mks Liwd ....
SINA
t;4, ft CNC
LOA
DMA COlkdai IAktO
WiDS night .1.41ggftie Thidatm 61 WC* _______________________________________________ 1.47g1tve Nettriml ax"TOM-Tri slaw* leo Willing Wrist. I 0 Ispregnatiotatoon6 [0085] Figure 16 describes the cycle performance or capacity retention of 30x50mm pouch cells (with NMC cathode) incorporating an anode composition in accordance with that of Table 6 across 100 cycles at 50 C, showing that capacity retention drops only to 90.1% over those 100 cycles. Cycles 1, 15, 50, 75 and 100 charge at 0.2C, 4.2V-CC; discharge at 0.2C, 2.7V-CC. Cycles 2-24, 26-49, 51-74, 76-99 charge at 0.5C, 4.2V-CC; discharge at 0.5C, 2.7V-CC.
[0086] Figure 17 demonstrates the discharge rates for the cells of Figure 15 at 25 C in terms of the relationship between capacity and voltage. A 91.2%
capacity retention is achieved at 2C using an electrode loading capacity of 3.8 mAhicm2, assuming 100% capacity retention at 0.2C. Charge of 0.2C, 4.2V-CCCV with a current lower limit of 0.05C.
[0087] The anodes produced from the anode material of the present invention and the cells incorporating same demonstrate low electrode swelling relative to the expansion between lithiation and delithiation demonstrated by prior art natural and synthetic electrodes. This is despite the higher capacity of the anodes produced from the anode material of the present invention. For example, the anodes of the present invention have a capacity ol greater than about 360 mAh/g, whilst synthetic anodes of the prior art typically have a capacity in the order of 340 to 350 mAh/g. Despite this, the anodes of the present invention demonstrate about AMENDED SHEET
PCT/113 2020/058 910 - 23.07.2021 5% less anode swelling than those same synthetic anodes of the prior art, being in the order of 16% relative to the about 21% of the prior art.
[0088j Table 7 below provides a summary of the electrochemical properties and performance of the 30x50mm single layer pouch cells (with NMC cathode) described above:
Table 7 F4,4 on mx7F.artter:
.................. .............. ..
.. .....
.. ... . , . = =
..................... ............
= =-= = =
= .
...... ................... : . .. .
= : =======:=,---. ..................... .. , ...
::::::::::
.. ...
:
.... .
. . .
.. .. ......... ..... ....... .. ..... ..... ... ... ... ....
.. ......................
. .. ....... . . '=
Pa"' ..
=
1. The Applicant observed some variation on 10 Cycle Efficiency which depends on the NMC
manufacturer and cell building (i.e. electrolytes, additive used, type of binder used, cell manufacturer). 2. Capacity retention at 0 C is based on limit-load characteristic test after 50 cycles.
[0089] As can be seen with reference to the above description, the electrochemical characterisation by impedance spectroscopy and galvanostatic charge-discharge cycling testing demonstrates that the anode material of the present invention, the anodes produced therefrom and the cells incorporating same, demonstrate fast charge and high power having intrinsically good charge transfer propriety, low electrical resistance and high diffusion of lithium into the secondary graphite particles. In turn, and amongst other things, this provides the promise of application in high power/fast charge batteries, with particular application at low temperatures.
AMENDED SHEET
= =
PCT/IB 2020/058 910 - 23.07.2021 [0090] It is reasonably envisaged that the anode material of the present invention substantially overcomes problems of lithium plating formation at low temperatures and by this improves the safety of lithium-ion batteries. Further, the anode material of the present invention is understood to substantially overcome the problems of Cold Cranking Ampere (CCA) for lithium-ion battery systems, which should enable starter batteries utilising lithium-ion technology. Still further, the lower impedance of the anode material of the present invention produces cells having lower impedance, which in turn requires less 'thermal management of lithium-ion cells at the 'battery pack' level. Yet still further, the improved low temperature performance of the anode material and cells of the present invention in turn improves the lifetime of such a cell on a single charge.
[0091] In addition, the anode material of the present invention, the anodes produced therefrom and the cells incorporating same, demonstrate relatively low electrode swelling, particularly in relative terms to anodes and cells of the prior art.
[0092] The above description further demonstrates that whilst improvements are realised in respect of the low temperature performance of the anode material of the present invention, this is achieved without significant impact on the performance at higher temperatures (for example 50 C).
[0093] It is envisaged that the anode material of the present invention may comprise secondary graphite particles that predominantly have a form typified by being larger in two dimensions than/relative to their third dimension. It is to be understood that the oblate spheroid form satisfies such a criterion. It is further to be understood that the secondary graphite particles of the present invention may be, as described, comprised of an aggregate of primary graphite particles of indeterminate and/or variable form, whilst still presenting a generally oblate spheroid form.
[0094] Modifications and variations such as would be apparent to the skilled addressee are considered to fall within the scope of the present invention.
AMENDED SHEET
Claims (27)
(i) between about 3 to about 5 microns; or (ii) about 3.5 microns.
(i) about 2 to about 9 m2/g; or (ii) about 2 to about 6 m2/g.
Date Recue/Date Received 2023-10-13 (i) about 25 to about 37 S/cm; or (ii) about 31 S/cm.
wt/wt CMC.
(i) less than about 15 microns;
(ii) less than about 10 microns; or (iii) in the range of about 4 to about 6 microns.
(i) about 2 to about 9 m2/g; or (ii) 7 to 9 m2/g.
Date Recue/Date Received 2023-10-13
(i) about 60 to about 75 microns; or (ii) 71 microns.
(i) less than about 15 microns;
(ii) less than about 10 microns; or (iii) in the range of about 4 to about 6 microns.
(i) about 2 to about 9 m2/g; or (ii) 7 to 9 m2/g.
(i) between about 3 to about 5 microns; or (ii) about 3.5 microns.
(i) about 2 to about 9 m2/g; or (ii) about 2 to about 6 m2/g.
Date Recue/Date Received 2023-10-13
(i) one or more of a d002 of > 3.35 A, an Lc of >1000 A and an La of >1000 A; or (ii) each of a d002 of > 3.35 A, an Lc of >1000 A and an La of >1000 A.
Date Recue/Date Received 2023-10-13
Applications Claiming Priority (5)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| AU2019903561A AU2019903561A0 (en) | 2019-09-24 | Anode Material and Method for Producing Same | |
| AU2019903561 | 2019-09-24 | ||
| AU2020902246A AU2020902246A0 (en) | 2020-07-01 | Anode Material and Method for Producing Same | |
| AU2020902246 | 2020-07-01 | ||
| PCT/IB2020/058910 WO2021059171A1 (en) | 2019-09-24 | 2020-09-24 | Anode material and method for producing same |
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| CA3152463C true CA3152463C (en) | 2024-05-21 |
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| EP (1) | EP4035219B1 (en) |
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| CN (1) | CN114651344B (en) |
| AU (1) | AU2020355399B2 (en) |
| CA (1) | CA3152463C (en) |
| FI (1) | FI4035219T3 (en) |
| HU (1) | HUE067742T2 (en) |
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| KR20220126541A (en) * | 2021-03-09 | 2022-09-16 | 삼성에스디아이 주식회사 | Anode for lithium secondary battery and lithium secondary battery comprising same |
| US20240204197A1 (en) * | 2021-06-30 | 2024-06-20 | Talga Technologies Limited | Cathode composition |
| US20250070171A1 (en) | 2021-12-20 | 2025-02-27 | Talga Technologies Limited | Anode material |
| WO2025134006A1 (en) | 2023-12-22 | 2025-06-26 | Talga Technologies Limited | Recycled graphite material purification process |
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| US6482547B1 (en) * | 1998-05-21 | 2002-11-19 | Samsung Display Devices Co., Ltd. | Negative active material for lithium secondary battery and lithium secondary battery using the same |
| CN1326267C (en) * | 2005-05-27 | 2007-07-11 | 深圳市贝特瑞电子材料有限公司 | Cathode material of composite carbon in use for lithium ion battery and preparation method |
| JP4974597B2 (en) * | 2006-07-19 | 2012-07-11 | 日本カーボン株式会社 | Negative electrode and negative electrode active material for lithium ion secondary battery |
| CN101087021B (en) * | 2007-07-18 | 2014-04-30 | 深圳市贝特瑞新能源材料股份有限公司 | Man-made graphite cathode material for lithium ion battery and its making method |
| US8142933B2 (en) * | 2009-09-30 | 2012-03-27 | Conocophillips Company | Anode material for high power lithium ion batteries |
| US20110104576A1 (en) * | 2009-10-29 | 2011-05-05 | Uchicago Argonne, Llc | Lithium-oxygen electrochemical cells and batteries |
| KR101004443B1 (en) | 2010-02-11 | 2010-12-27 | 강원대학교산학협력단 | Anode active material for lithium secondary battery, preparation method thereof and lithium secondary battery comprising same |
| EP2445049B1 (en) * | 2010-10-22 | 2018-06-20 | Belenos Clean Power Holding AG | Electrode (anode and cathode) performance enhancement by composite formation with graphene oxide |
| EP2696409B1 (en) * | 2011-05-23 | 2017-08-09 | LG Chem, Ltd. | High energy density lithium secondary battery having enhanced energy density characteristic |
| KR101708360B1 (en) * | 2011-10-05 | 2017-02-21 | 삼성에스디아이 주식회사 | Negative active material and lithium battery containing the material |
| GB2498803B (en) | 2012-01-30 | 2015-04-08 | Nexeon Ltd | Composition |
| JP5953249B2 (en) * | 2012-03-16 | 2016-07-20 | Jfeケミカル株式会社 | Composite graphite particles and their use in lithium ion secondary batteries |
| JP6162482B2 (en) * | 2012-05-29 | 2017-07-12 | Jfeケミカル株式会社 | Negative electrode material for lithium ion secondary battery and production method thereof, negative electrode for lithium ion secondary battery and lithium ion secondary battery using the same |
| EP2889937B1 (en) * | 2012-08-23 | 2018-10-03 | Mitsubishi Chemical Corporation | Carbon material for non-aqueous electrolyte secondary battery, negative electrode for non-aqueous electrolyte secondary battery, non-aqueous electrolyte secondary battery, and manufacturing method for carbon material for non-aqueous electrolyte secondary battery |
| US10418629B2 (en) * | 2014-03-25 | 2019-09-17 | Tosoh Corporation | Composite active material for lithium ion secondary batteries and method for producing same |
| KR101685832B1 (en) * | 2014-07-29 | 2016-12-12 | 주식회사 엘지화학 | Graphite secondary particles and lithium secondary battery comprising thereof |
| JP6240586B2 (en) * | 2014-10-28 | 2017-11-29 | Jfeケミカル株式会社 | Graphite particles for negative electrode material of lithium ion secondary battery, negative electrode of lithium ion secondary battery and lithium ion secondary battery |
| CN105236393B (en) * | 2015-08-31 | 2016-08-31 | 三峡大学 | A kind of spherical porous artificial graphite negative electrode material and preparation method thereof |
| CA2990347A1 (en) * | 2015-10-21 | 2017-04-27 | Imerys Graphite & Carbon Switzerland Ltd. | Carbonaceous composite materials with snowball-like morphology |
| KR102606317B1 (en) * | 2016-06-02 | 2023-11-23 | 에스케이온 주식회사 | Negative electrode active material for lithium secondary battery, negative electrode, and lithium secondary battery comprising the same |
| WO2018068035A1 (en) | 2016-10-07 | 2018-04-12 | Kratos LLC | Graphite and group iva composite particles and methods of making |
| KR102601605B1 (en) * | 2017-12-27 | 2023-11-14 | 삼성전자주식회사 | Anode, Lithium battery comprising anode, and Preparation method of anode |
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| HUE067742T2 (en) | 2024-11-28 |
| FI4035219T3 (en) | 2024-05-10 |
| WO2021059171A1 (en) | 2021-04-01 |
| JP2023501046A (en) | 2023-01-18 |
| AU2020355399B2 (en) | 2026-04-02 |
| US12424627B2 (en) | 2025-09-23 |
| PL4035219T3 (en) | 2024-10-07 |
| KR20220072846A (en) | 2022-06-02 |
| JP7779483B2 (en) | 2025-12-03 |
| CA3152463A1 (en) | 2021-04-01 |
| CN114651344A (en) | 2022-06-21 |
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| US20230246191A1 (en) | 2023-08-03 |
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