CA3166124A1 - Fast charging pre-lithiated silicon anode - Google Patents
Fast charging pre-lithiated silicon anode Download PDFInfo
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- CA3166124A1 CA3166124A1 CA3166124A CA3166124A CA3166124A1 CA 3166124 A1 CA3166124 A1 CA 3166124A1 CA 3166124 A CA3166124 A CA 3166124A CA 3166124 A CA3166124 A CA 3166124A CA 3166124 A1 CA3166124 A1 CA 3166124A1
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Abstract
Description
RELATED APPLICATION
[0001] The following application claims priority to U.S. Application No.
17/178,439, filed February 18, 2021, and U.S. Provisional No. 62/978,475, filed February 19, 2020, the disclosures of which are incorporated by reference in their entireties.
FIELD OF THE INVENTION
BACKGROUND OF THE INVENTION
During the first charge of lithium-ion cell, lithium moves from the cathode material to the anode active material.
The lithium moving from the cathode to the anode reacts with an electrolyte material at the surface of the graphite anode, causing the formation of a passivation film on the anode. The passivation film formed on the graphite anode is also called solid electrolyte interface (SEI).
Upon subsequent discharge, the lithium consumed by the formation of the SEI is not returned to the cathode. This results in a lithium-ion cell having a smaller capacity compared to the initial charge capacity because some of the lithium has been consumed by the formation of the SEI.
The partial consumption of the available lithium on the first cycle reduces the capacity of the lithium-ion cell. This phenomenon is called irreversible capacity and is known to consume about 10% to more than 20% of the capacity of a lithium ion cell. Thus, after the initial charge of a lithium-ion cell, the lithium-ion cell loses about 10% to more than 20% of its capacity.
For example, lithium powder can be stabilized by passivating the metal powder surface with carbon dioxide such as described in U.S. Pat. Nos. 5,567,474, 5,776,369, and 5,976,403, the disclosures of which are incorporated herein in their entireties by reference.
The CO2 passivated lithium metal powder can be used only in air with low moisture levels for a limited period of time before the lithium metal content decays because of the reaction of the lithium metal and air. Another solution is to apply a coating such as fluorine, wax, phosphorus or a polymer to the lithium metal powder such as described in U.S. Patent Nos.
[0007] When lithium foil is used for pre-lithiation and directly laminated to the surface of the electrode, as a result of "short circuit" lithiation due to the lamination pressure applied, potentially, significant heat might be generated. When this pre-lithiation technique is performed in a roll to roll process, heat might build up in the center of the roll and might be difficult to dissipate. This heat buildup can potentially lead to for example, mechanical damage of the electrode and more importantly, to potential thermal runaway.
[0008] Another known battery issue is lithium plating, which commonly occurs during fast charging when lithium deposits, called dendrites, accumulate on the electrode surface potentially leading to short circuiting and failure of the battery.
SUMMARY OF THE INVENTION
The silicon active material is alloyed with lithium particles to form a three-dimensional porous framework in the anode having an increased electrode porosity and reduced electrode deterioration from volume expansion due to the buffering effect of the pores.
A highly conductive porous layer may also be formed on a surface of the anode. The porous conductive surface layer and gradient porosity enables high rates of charging by effectively lowering the areal current density and by having increased conductivity and allowing for faster diffusion of lithium at the electrode surface and in the electrode bulk, thereby allowing thicker electrodes while decreasing the likelihood of lithium plating on the anode surface.
BRIEF DESCRIPTION OF THE DRAWINGS
initially deposited at its surface.
capacity loss).
DETAILED DESCRIPTION OF THE INVENTION
"include," "includes"
and "including" specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.
The polymer binder may be compatible with the lithium metal powder. The rheology modifier may be compatible with the lithium metal powder and the polymer binder. The solvent may be compatible with the lithium metal powder and with the polymer binder.
Porosity of Lithium Layer Before lithium Diffusion Actual Density of Printable Lithium Composition = 1 Theoretical Density of Printable Lithium Composition
Porosity of Lithium Layer After Diffusion = 1 Actual Density of Printable Composition without Lithium Theoretical Density of Printable Lithium Composition without Lithium Composition
Thus, surfaces treated with a printable lithium composition after lithium diffusion have a higher porosity than the bulk electrode. Moreover, the porosity at an electrode surface may be dependent on the amount of lithium deposited and diffused.
("Fast formation cycling for lithium ion batteries", J Power Sources, 2017, 342, 846), incorporated herein by reference in its entirety. However, formation cycle time can be significantly decreased by prelithiating electrodes with a printable lithium composition.
Typically, gas is generated during a standard SEI formation cycle due to solvent reduction during the formation of the SEI layer. Electrolyte solvents, such as ethylene carbonate, may be reduced on the graphite surface at 2.7 V (-0.9 V vs Li/Li), which is well below the open circuit voltage of the cells prelithiated with a printable lithium composition, typically at 2.9-3V. As a result, cells with electrodes prelithiated with a printable lithium composition may produce almost no gas during a typical SEI formation charging-discharging cycle. This is because the SEI layer is formed on electrodes prelithiated with a printable lithium composition during a rest period prior to a formation cycle. Therefore, a simplified and shorter formation cycle can be used. For example, the simplified formation process may only consist of a resting period of a few hours to up to 24 hours at room or elevated temperatures followed by a degassing process. FIG. 2A
shows pouch cells with electrodes prelithiated with a printable lithium composition produce gas during the 24hs rest. This gas can be removed by a degassing step prior to formation cycle. In comparison, baseline cells, which are not prelithiated, do not produce gas during the 24hs rest.
FIG. 2B shows baseline cells produced gas during the formation charging-discharging cycle while pouch cells with prelithiated electrodes produced no gas. FIG. 20 shows both baseline cells and cells containing printable lithium treated electrodes produce similar gas during long-term cycling. FIG. 3 shows cells with electrodes prelithiated with a printable lithium composition have no solvent reduction peaks at all during the formation cycle before 2.9 V. This is because pre-lithiation treatment results in partial charging of the cell beyond 2.9 V, which is beyond the voltage of solvent reduction. This is a further indication that pre-lithiation process initiate SEI
formation.
Pe) available from FMC USA Lithium Corp. The lithium metal powder may also include a substantially continuous layer or coating of fluorine, wax, phosphorus or a polymer or the combination thereof (as disclosed in U.S. Pat. Nos. 5,567,474, 5,776,369, and 5,976,403 and incorporated herein by reference in their entireties). Lithium metal powder has a significantly reduced reaction with moisture and air.
may include, for example, silver or gold. Suitable elements from Group II B
may include, for example, zinc, cadmium, or mercury. Suitable elements from Group IIA of the Periodic Table may include beryllium, magnesium, calcium, strontium, barium, and radium.
Elements from Group IIIA that may be used in the present invention may include, for example, boron, aluminum, gallium, indium, or thallium. Elements from Group IVA that may be used in the present invention may include, for example, carbon, silicon, germanium, tin, or lead. Elements from Group VA that may be used in the present invention may include, for example, nitrogen, phosphorus, or bismuth. Suitable elements from Group VIII B may include, for example, palladium, or platinum.
"Compatible with" or "compatibility" is intended to convey that the polymer binder does not violently react with the lithium metal powder resulting in a safety hazard.
The lithium metal powder and the polymer binder may react to form a lithium¨polymer complex, however, such complex should be stable at various temperatures. It is recognized that the amount (concentration) of lithium and polymer binder contribute to the stability and reactivity. The polymer binder may have a molecular weight of about 1,000 to about 8,000,000, and often has a molecular weight of 2,000,000 to 5,000,000. Suitable polymer binders may include one or more of poly(ethylene oxide), polystyrene, polyisobutylene, natural rubbers, butadiene rubbers, styrene-butadiene rubber, polyisoprene rubbers, butyl rubbers, hydrogenated nitrile butadiene rubbers, epichlorohydrin rubbers, acrylate rubbers, silicon rubbers, nitrile rubbers, polyacrylic acid, polyvinylidene chloride, polyvinyl acetate, ethylene propylene diene ternnononner, ethylene vinyl acetate copolymer, ethylene-propylene copolymers, ethylene-propylene terpolymers, polybutenes. The binder may also be a wax.
One example of a lithium control layer is described in US Publication No. 2019/0229380 herein incorporated by reference in its entirety. Having a controlled rate of lithium diffusion increases the safety of pre-lithiation process due to a controlled heat dissipation.
10.1126/sciadv.aat5168], incorporated herein by reference in its entirety, which uses a hollow carbon sphere as a stable host that prevents parasitic reactions, resulting in improved cycling behavior. Yet another support structure may be a nanowire as described in US
Patent No.
10,090,512 incorporated herein by reference in its entirety. Other compatible carbon-based rheology modifiers include carbon black, graphene, graphite, hard carbon and mixtures or blends thereof.
Exemplary rheology modifiers may include one or more of silicon nanotubes, fumed silica, titanium dioxide, zirconium dioxide and other Group IIA, IIIA, IVB, VB and VIA
elements/compounds and mixtures or blends thereof. Other additives intended to increase lithium ion conductivity can be used; for example, electrochemical device electrolyte salts such as lithium perchlorate (LiCI04), lithium hexafluorophosphate (LiPF6), lithium difluoro(oxalate)borate (LiDFOB), lithium tetrafluoroborate (LiBF4), lithium nitrate (LiNO3), lithium bis(oxalate) borate (LiBOB), lithium trifluoromethanesulfonimide (LiTFSI), lithium bis(fluorosulfonyl) imide (LiFSI). The additives included in the printable lithium formulation may also be selected to modify the porosity and overall three-dimensional support structure as desired. Examples may include carbon nanotubes (CNTs), graphene or polyacrylate as described in Electrochemical and Solid-State Letters, 12, 5, A107-A110, 2009.
9,649,688 the disclosure of which is incorporated by reference in its entirety. However, embodiments of the printable lithium composition in accordance with the present invention can accommodate higher binder ratios, including up to 20 percent on a dry basis. Various properties of the printable lithium composition, such as viscosity and flow, may be modified by increasing the binder and modifier content up to 50% dry basis without loss of electrochemical activity of lithium.
Increasing the binder content facilitates the loading of the printable lithium composition and the flow during printing. The printable lithium composition may comprise between about 50% to about 98% by weight of lithium metal powder and about 2% to about 50% by weight of polymer binder and rheology modifiers on a dry weight basis. In one embodiment, the printable lithium composition comprises between about 60% to about 90% by weight lithium metal powder and between about 10% to about 40% by weight of polymer binder and rheology modifiers. In another embodiment the printable lithium composition comprises between about 75% to about 85% by weight of lithium metal powder and between about 15% to about 30% by weight of polymer binder and rheology modifiers.
When shear is applied, the suspension viscosity decreases to levels suitable for use in printing or coating applications.
Examples of suitable electrolytes include lithium perchlorate (LiCI04), lithium hexafluorophosphate (LiPF6), lithium difluoro(oxalate)borate (LiDFOB), lithium tetrafluoroborate (LiBF4), lithium nitrate (LiNO3), lithium bis(oxalate) borate (LiBOB), lithium bis(fluorosulfonyl) imide (LiFSI) and lithium trifluoromethanesulfonimide (LiTFSI) and mixtures or blends thereof. One exemplary example is a battery having a cathode and a porous anode lithiated with a printable lithium composition and a high concentration electrolyte, wherein LiFSI is the major salt of the high concentration electrolyte. Another example is a battery having a cathode and a porous anode lithiated with a printable lithium composition and a dual-salt liquid electrolyte as described by Weber et al [Nature Energy, Vol. 4, pgs. 683-689 (2019), DOI: 10.1038/s41560-019-0428-9]
and US
Publication No. 2019/0036171, both of which are incorporated herein by reference. The dual-salt liquid electrolyte may be comprised of lithium difluoro(oxalate)borate (LiDFOB) and LiBF4, and may have a concentration of about 1 M. Dual-salt electrolytes may provide increased initial capacity retentions and improved cycle performance.
In another embodiment, the active anode material and the printable lithium composition are co-extruded to form a layer of the printable lithium composition on the current collector. The deposition of the printable lithium composition including the above extrusion technique may include depositing as wide variety patterns (e.g., dots, stripes), thicknesses, widths, etc. For example, the printable lithium composition and active anode material may be deposited as a series of stripes, such as described in US Publication No. 2014/0186519 incorporated herein by reference in its entirety. The stripes would form a 3D structure that would account for expansion of the active anode material during lithiation. For example, silicon may expand by 300 to 400 percent during lithiation. Such swelling potentially adversely affects the anode and its performance. By depositing the printable lithium as a thin stripe in the Y-plane as an alternating pattern between the silicon anode stripes, the silicon anode material can expand in the X-plane alleviating electrochemical grinding and loss of particle electrical contact.
Thus, the printing method can provide a buffer for expansion. In another example, where the printable lithium formulation is used to form the anode, it could be co-extruded in a layered fashion along with the cathode and separator, resulting in a solid-state battery.
2018/0013126 herein incorporated by reference in its entirety. For example, the printable lithium composition may be incorporated into a three-dimensional porous anode, porous current collector or porous polymer or ceramic film, wherein the printable lithium composition may be deposited therein. The printable lithium composition may be incorporated into a solid electrolyte, wherein the solid electrolyte may be combined with or applied to a lithium metal anode to form a composite anode. The solid electrolyte may be applied as one or more interface ion conductive electrolyte layers or interfaces to the lithium metal anode. One example is described in US Patent No.
8,182,943 herein incorporated by reference in its entirety.
2018/0013126 herein incorporated by reference in its entirety. The three-dimensional electrode may be a permeable composite material comprised of a support defining pores and an alkali metal deposit on the support, wherein the alkali metal is deposited using a printable lithium composition. The three-dimensional electrode may have a porosity between about 1% by volume to about 95% by volume, and may have a mean flow pore size in the range of from about 1 nm to about 300 pm.
A separator can be placed between the respective electrodes. Current can be allowed to flow between the electrodes. For example, an anode prelithiated with the printable lithium composition of the present invention may be formed into a second battery such as described in U.S. Patent No.
6,706,447 herein incorporated by reference in its entirety.
EXAMPLES
Example 1
0.85g of stabilized lithium metal powder (SLMPO, FMC USA Lithium Corp.) or PLF
with equivalent lithium metal content is added to the slurry and blended in the TH
INKY for 30 seconds at 1000rpm. The resulting slurry is coated on copper foil using a 6mi1 doctor blade.
The solvent is dried using a forced hot air dryer at 110 C until all solvent is removed. The dried electrode is pressed using at 30pm gap roll press. A 4cm x 4cm piece of the pressed electrode is placed into a sealed pouch with 1g of 1M LiPF6 in EC/DEC 1:1 electrolyte and observed under a digital microscope. After diffusion of lithium there is an increase in porosity of 33.6% to 35.2% (an increase of about 5%). This is estimated based upon the thickness and true density of the materials. Theoretical density is calculated by subtracting the contribution of lithium from the true density of each component, based on the assumption that all lithium is intercalated into the host anode material and that after diffusion pores would be left where lithium particles once resided.
Example 2
artificial graphite + 9.48% SiO, 3.8% binder (CMC + SBR) and 1.4% carbon black. The loading of the anode materials is 8.2mg/cm2 and the press density is about 1.5g/c1n3. The size of the electrode is 7cm x 7cm. This anode electrode has an FCE of 85% when tested in a half cell with a lithium metal counter electrode.
electrode. After drying and pressing, the electrode is assembled into a half cell in the pouch cell format with lithium metal counter electrode using 1M LiPF6 in EC:FEC:EMC:DMC 1:1:2:6 (volume ratio) electrolyte. The cell is tested with the following protocol on a Maccor series 4000 cycler: Rest 24hrs @ 45 C, then 1 Cycle conducted at the following condition: 1) discharge at 0.1C to 0.005V, 2) a constant voltage step until current drop to 0.05C, 3) charge at 0.1C to 1.5V. The first cycle efficiency is increased from 85.59% to 97.32% (Table 1). FIGS. 1A
and 1B show the as-printed, dried and pressed formulation on the surface of the 10% SiO
containing graphite electrode and the resulting increase in surface porosity after lithium diffusion.
Table 1: Performance comparison for Graphite-10%SiO/Li vs. Graphite-10%SiO-PLF/Li cells Baseline cell Cell incorporating PLF
Performance improvement First cycle efficiency, % 85.59 97.32 11.73%
Example 3
LiPF6 in 1:1:2:6 Vol EC:FEC:EMC:DMC electrolyte is used. Cells are cycled using the formation protocol of a 24-hour rest period at a temperature of 45 C, followed by charging at the constant current of 10 mA to 4.2V and then discharging at the constant current of 10 mA
to 2.8V with a current cutoff of 5 mA. The cells are charged to 3.8V after formation step for impedance measurements. Following initial impedance test, the cells are tested for rate capability.
Table 2: Impedance Measurements for PLF-incorporated and Baseline Cells Impedance Measurement Impedance Measurement at Cell ID
after Formation step (ohm) 80% Capacity Retention (ohm) PLF Cell -1 0.502 0.447 PLF Cell -2 0.429 0.352 PLF Cell -3 0.437 0.343 PLF Cell -4 0.436 f 0.389 PLF Cell -5 0.510 0.555 Baseline Cell -1 0.572 0.525 Baseline Cell -2 0.534 0.476 Baseline Cell -3 0.527 0.528 Baseline Cell -4 0.526 0.489 Baseline Cell -5 0.527 0.504 PLT Avg. 0.463 0.040 0.417 0.087 BL Avg. 0.537 0.020 0.504 0.023 Surface porosity for the PLF cells is about 50% prior to lithium diffusion.
Lithium represents about 84% of the volume of the PLF treatment solution. After lithium diffusion, the surface porosity is about 88.5% and the porosity of the bulk is 34%. Increased porosity at the surface provides increased surface area for electrolyte absorption and therefore faster lithium ion diffusion kinetics. Faster diffusion kinetics results in lower charge transfer impedance and provides better charge rate capabilities. When comparing total impedance of Graphite-10% SiO
full cells, there is a 14% reduction in cells treated with PLF versus baseline cells. Furthermore, at the end of cycle life there is about a 16% reduction in total impedance for cells with electrodes treated with PLF vs baseline cells. There is about a 9% improvement in rate capability at a 10 charge rate and about a 36% improvement at a 2C charge rate.
b) first two formation cycles and c) cycling at room temperature. Gas generation is indicative of SEI formation. As seen in FIGS. 2A-C, PLF-incorporated cells produced the most gas during 24 hours rest at 60 C. In contrast, baseline cells produced no gas during the same period of rest time. FIGS. 2A-C demonstrate the PLF-incorporated cells are capable of producing a SEI layer within a shorter period of time compared to baseline cells.
layer during the 24 hours rest period and therefore no formation cycle is needed to form SEI
layers with PLF-treated cells.
The diffusion rate is slowed by the polymer layer applied to the surface of the anode during PLF
application. This slower diffusion rate can result in controlled heat dissipation during the diffusion process and leads to a safer prelithiation process. Furthermore, during dry state diffusion stage before electrolyte addition, it has been observed that PLF
diffusion is minimal compared to use of dry SLMP. This property leads to less heat generation due to lithium diffusion after lamination of PLF to the electrode surface. Heat generation due to dry state lithium diffusion in electrode rolls during storage has been observed to generate heat sufficient to damage the electrode films or even cause thermal event while the electrode rolls are stored prior to being used in cell assembly processes.
at a loading equal to about 0.7mg/cm2 lithium, a quantity sufficient to compensate the irreversible capacity. The electrodes are then pressed with force selected to induce mechanical lithiation. The test results show that the diffusion rate of lithium deposited using PLF is significantly slower than that of SLMP.
10.1149/2.001404jes] and Xia et al. [Journal of Power Sources. 328 (2016) 124-135. DOI:
10.1016/j.jpowsour.2016.08.015] for further discussions regarding solvent reduction peaks, both of which are herein incorporated by reference in their entireties.
AC impedance spectra are collected with ten points per decade from 100 kHz to 100 mHz with a signal amplitude of 10 mV using a Gamry Potentiostats (Reference 3000Tm).
FIGS. 5A and 5B
show PLF-incorporated cells have significantly lower impedance after formation and during cycling, indicating that treating cells with printable lithium compositions may improve the rate performance. As reported in Table 1, PLF-incorporated cells may have an improved cycle efficiency compared to baseline lithium ion cell.
Table 4: Test results for baseline and PLF incorporated cells Thickness Volumetric Thickness as Gravimetric after First CE energy Cell chemistry assembled energy density formation (%) density (mm) (VVh/kg) (mm) (VVh/L) Baseline 3.16 3.27 80.5 451 NMC811/5% PLF
3.31 3.29 87.7 494 Si0+95%Graphite incorporated % increase 4.70 0.60 7.2 10.80 10.10
Claims (27)
a cathode; and an anode comprised of an anode active material and lithiated with a lithium source;
wherein the anode active material is alloyed or intercalated with lithium particles diffused from the lithium source to form a three-dimensional porous framework within the anode that provides reduced electrode deterioration due to volume expansion.
oxides.
poly(ethylene oxide), polystyrene, polyisobutylene, natural rubbers, butadiene rubbers, styrene-butadiene rubber, polyisoprene rubbers, butyl rubbers, hydrogenated nitrile butadiene rubbers, epichlorohydrin rubbers, acrylate rubbers, silicon rubbers, nitrile rubbers, polyacrylic acid, polyvinylidene chloride, polyvinyl acetate, ethylene propylene diene termonomer, ethylene vinyl acetate copolymer, ethylene-propylene copolymers, ethylene-propylene terpolymers, polybutenes, and wax.
composite, Si-based alloys, graphite-SnO. Sn/C composite, and other lithium ion battery and lithium ion capacitor anode materials.
a cathode; and a silicon-containing anode lithiated with a printable lithiurn composition comprised of a lithium metal powder, a polymer binder compatible with the lithiurn metal powder, a rheology modifier compatible with the lithium metal powder, and a solvent compatible with the lithium metal powder and with the polymer binder;
wherein a surface of the silicon anode is alloyed with lithium particles diffused from the printable lithium composition to form a porous layer on the surface that provides increased lithium conductivity and prevents lithium plating to enable fast charging of the battery.
providing a slurry comprised of a silicon active material; and adding to anode slurry a printable lithium composition comprised of a lithium metal powder, a polymer binder compatible with the lithium metal powder, a rheology modifier compatible with the lithium metal powder, and a solvent compatible with the lithium metal powder and with the polymer binder to form an anode slurry.
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| US62/978,475 | 2020-02-19 | ||
| PCT/US2021/018495 WO2021168063A1 (en) | 2020-02-19 | 2021-02-18 | Fast charging pre-lithiated silicon anode |
| US17/178,439 US11923535B2 (en) | 2020-02-19 | 2021-02-18 | Fast charging pre-lithiated silicon anode |
| US17/178,439 | 2021-02-18 |
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Also Published As
| Publication number | Publication date |
|---|---|
| KR20220144387A (en) | 2022-10-26 |
| CN115769395A8 (en) | 2023-09-22 |
| MX2022010096A (en) | 2022-09-02 |
| US20210273220A1 (en) | 2021-09-02 |
| AU2021224637A1 (en) | 2022-09-15 |
| AU2021224637B2 (en) | 2026-03-05 |
| JP2025164791A (en) | 2025-10-30 |
| CN115769395A (en) | 2023-03-07 |
| IL295608A (en) | 2022-10-01 |
| US12469845B2 (en) | 2025-11-11 |
| PH12022552085A1 (en) | 2023-11-20 |
| WO2021168063A1 (en) | 2021-08-26 |
| JP2023529515A (en) | 2023-07-11 |
| US20240178374A1 (en) | 2024-05-30 |
| US11923535B2 (en) | 2024-03-05 |
| BR112022014928A2 (en) | 2022-10-18 |
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