Lithium-ion batteries (LIBs) have been widely used in our daily life, especially in portable electronics like cell phones and personal computers. In recent years, LIBs have also been adopted as power sources in electrical vehicles (EVs), which greatly expands the portion of LIBs in the energy storage market. With EVs market being expected to further grow by 50% by 2030, demand for new generation of LIBs with higher energy/power density and superior safety features becomes urgent. However, safety concerns rise associating with increase of cell energy density, mainly because of organic liquid electrolytes (OLEs) possessing intrinsically high flammability, great volatility, and radical reactivity in contact with oxidative or reductive electrode materials. Compared to LIBs or lithium metal batteries (LMBs) using OLEs, adoption of inflammable inorganic solid-state electrolytes (SSEs) in all-solid-state batteries (ASSBs) could fundamentally eliminate safety concerns.
High performance solid-state electrolytes (SSEs), such as sulfides, oxides, and polymer- based electrolytes, are crucial to the success of ASSBs with high energy and power density. Among these SSEs, sulfides are believed to be more promising because of their soft nature and high ionic conductivities at room temperature, both of which ensure good SSE/electrode materials contact and fast Li-ion conduction. However, poor moisture stability of sulfide SSEs associated with generation of highly toxic H2S gas hinders their evaluation and application at practical scale. To address this critical issue, several strategies have been previously tried.
One is to combine inorganic H2S absorption additives (such as Fe2O3, ZnO, and Bi2O3) into SSEs to chemically consume the generated H2S gas. Even though the amount of H2S releasing from SSE can be lowered to some extent, overall Li-ion conductivity was hugely reduced due to the existence of H2S releasing reactions and non-conductive nature of these additives. Another strategy is focused on developing sulfide SSEs with intrinsically good moisture stability based on the hard/soft acidbase (HSAB) theory. Specifically, relatively soft acids such as CuI, GeIV, and AsV prefer to bond soft bases such as S2−, forming strong covalent bonds and a rigid framework. Guided by the HSAB theory, quaternary sulfides such as Li3.833Sn0.833AS0.166S4 and Li4Cu8Ge3S12 have been developed, which exhibited improved moisture stability. However, these sulfide-containing SSEs (including Li10GeP2S12 and Li10SnP2S12 as well) suffer from poor chemical/electrochemical stability against Li metal anode, where SSEs are reduced into electronically conductive Li-metal alloys (LiGex and LiSnx), shorting the cell ultimately. Moreover, those “heavy metal” contained SSEs usually involves high temperature synthesis and penalties of high materials density. In addition, existing solid state sulfide electrolytes suffer from poor air stability, which makes it hard to produce materials in an ambient air environment.
One embodiment disclosed herein is a method comprising:
contacting an amphipathic surface protective agent with a moisture sensitive Li-ion conductor material surface resulting in a protected Li-ion conductor material, and
assembling an electrochemical cell that includes the protected Li-ion conductor material.
Another embodiment disclosed herein is a method comprising:
coating an amphipathic surface protective agent onto a surface of a sulfide-containing solid-state electrolyte material.
Another embodiment disclosed herein is a material comprising a sulfide-containing solid-state electrolyte coated with an amphipathic surface protective agent, wherein the amphipathic surface protective agent includes a hydrophilic head selected from —OH; —C(O)O—; —C═O—; —NH—; —Aln(OH)m, wherein n≥1 and m≥1; —PO4—; —C(O)NH2; —NH2; —OSO3H; —SO3H; —SH; —Cl; —Br; —I; and —NR4+, wherein R is CxH2x+1, x≥1; and a hydrophobic tail selected from —CH3; —CH2—CH3; —R—C6H5, wherein R is CxH2x+1, x≥1; —CH═CH2; -C3-C50 alkyl or substituted alkyl; -C3-C50 alkenyl or substituted alkenyl; -C3-C50 alkynyl or substituted alkynyl; (CH2)n(n≥2); —CH2F; —CHF2; —CF3; (CF2)n(n≥2); and (Si(CH3)2—O—)n(n≥2).
An additional embodiment disclosed herein is a construct comprising:
a sulfide-containing solid-state electrolyte coated with an amphipathic surface protective agent, wherein the amphipathic surface protective agent includes a hydrophilic head selected from —OH; —C(O)O—; —C═O—; —NH—; —Aln(OH)m, wherein n≥1 and m≥1; —PO4—; —C(O)NH2; —NH2; —OSO3H; —SO3H; —SH; —Cl; —Br; —I; and —NR4+, wherein R is CxH2x+1, x≥1; and a hydrophobic tail selected from —CH3; —CH2—CH3; —R—C6H5, wherein R is CxH2x+1, x≥1; —CH═CH2; -C3-C50 alkyl or substituted alkyl; -C3-C50 alkenyl or substituted alkenyl; -C3-C50 alkynyl or substituted alkynyl; (CH2)n(n≥2); —CH2F; —CHF2; —CF3; (CF2)n(n≥2); and (Si(CH3)2—O—)n(n≥2);
a cathode material; and
an anode material.
The foregoing will become more apparent from the following detailed description, which proceeds with reference to the accompanying figures.
Anode: An electrode through which electric charge flows into a polarized electrical device. From an electrochemical point of view, negatively-charged anions move toward the anode and/or positively-charged cations move away from it to balance the electrons leaving via external circuitry.
Cathode: An electrode through which electric charge flows out of a polarized electrical device. From an electrochemical point of view, positively charged cations invariably move toward the cathode and/or negatively charged anions move away from it to balance the electrons arriving from external circuitry.
Electrochemical cell: As used herein, a cell refers to an electrochemical device used for generating a voltage or current from a chemical reaction, or the reverse in which a chemical reaction is induced by a current. Examples include voltaic cells, electrolytic cells, and fuel cells, among others. A battery includes one or more cells. The terms “cell” and “battery” are used interchangeably when referring to a battery containing only one cell.
Electrolyte: A substance containing free ions that behaves as an electrically conductive medium.
Microparticle: As used herein, the term “microparticle” refers to a particle with a size measured in microns, such as a particle with a diameter of 1-100 μm.
Nanoparticle: As used herein, the term “nanoparticle” particle that has a size measured in nanometers, such as a particle with a diameter of 1-100 nm.
Separator: A battery separator is a porous sheet or film placed between the anode and cathode. It prevents physical contact between the anode and cathode while facilitating ionic transport.
The methods and materials disclosed herein improve the processability as well as lower the cost associated with electrolyte production and cell fabrication. Disclosed herein is a novel surface protection strategy for moisture sensitive sulfide SSEs. By employing amphipathic compound(s) as a surface protection agent, an ultra-thin and effective layer can be constructed on the surface of an SSE via Van der Waals force interaction. A singe amphipathic compound or a mixture or amphipathic compounds can be used. The SSE can be in the form of particles, films, or other shapes.
The amphipathic compound includes at least one hydrophilic head and at least one hydrophobic tail. The hydrophilic head is anchored on the surface of the SSE via Van der Waals force, forming an ultra-thin layer of protecting interphase; the hydrophobic tail shields sulfide SSE surface from water molecules attacking the SSE surface. There are several advantages of such an amphipathic interphase. First, molecules with hydrophilic heads are physically attached on sulfides' surface, forming very thin protection layers, which has very limited impact on the bulk properties of the SSEs. Second, chemical composition and structure of this protection layer can be tuned through the design or selection of appropriate functional groups depending on the structures/surface properties of the target SSE. Third, the protection layer can be released by heat treatment due to weak interaction force between the protection layer and SSE, bringing ionic conductivity back to the original value, which is desirable in practical application and processing.
In certain embodiments, the surface protective agent has a boiling point lower than the synthesis temperature of the SSE.
The protected air-stable sulfide-containing SSEs facilitate synthesis, storage, transfer, and processing of solid electrolytes and fabrication of solid-state lithium batteries in an ambient environment. The protected SSEs are stable with O2, CO2 and N2 in the air and also stable against water with very limited generation of H2S (<10 ppm within 2 hours) in the air (relative humidity <15%). The outstanding air stability of the protected SSEs significantly improves processability of the materials for the cell manufacturer and this hugely reduces the cost of the processing. In addition, the developed air-stable solid-state electrolytes provide superior lithium-ion conductivity.
Illustrative moieties that can serve as hydrophilic heads include —OH; —C(O)O—; —C═O—; —NH—; —Aln(OH)m, wherein n≥1 and m≥1; —PO4—; —C(O)NH2; —NH2; —OSO3H; —SO3H; —SH; —Cl; —Br; —I; and —NR4+, wherein R is CxH2x+1, x≥1.
Illustrative moieties that can serve as hydrophobic tails include —CH3; —CH2—CH3; —R—C6H5, wherein R is CxH2x+1, x≥1; —CH═CH2; -C3-C50 alkyl or substituted alkyl; -C3-C50 alkenyl or substituted alkenyl; -C3-C50 alkynyl or substituted alkynyl; (CH2)n(n≥2); —CH2F; —CHF2; —CF3; (CF2)n(n≥2); and (Si(CH3)2—O—)n(n≥2).
Illustrative amphipathic compounds that could function as surface protection agents include:
CxH2x+1Br (x≥1): For example, 2-Bromopentane, 3-Bromopentane, 1-Bromo-3-methylbutane, 1-Bromo-2-methylbutane, 1-Bromo-2,2-dimethylpropane, 2-Bromo-2-methylbutane, 1-Bromobutane, 1-Bromohexane, and 1-Bromooctane
CxH2x+1Cl (x≥1): For example, 1-Chloropentane, 2-Chloropentane, 3-Chloropentane, 1-Chloro-3-methylbutane, 1-Chloro-2-methylbutane, 1-Chloro-2,2-dimethylpropane, 2-Chloro-2-methylbutane, 1-Chlorobutane, 1-Chlorohexane, and 1-Chlorooctane
CxH2x+1I (x≥1): For example, 1-Iodopentane, 2-Iodopentane, 3-Iodopentane, 1-Iodo-3-methylbutane, 1-Iodo-2-methylbutane, 1-Iodo-2,2-dimethylpropane, 2-Iodo-2-methylbutane, 1-Iodobutane, 1-Iodohexane, and 1-Iodooctane
CxH2x+1SH (x≥1): For example, 1-Butanethiol, 2-Methyl-1-butanethiol, 3-Methyl-1-butanethiol, 4-Methoxy-2-methyl-2-butanethiol, 1-Propanethiol, 2-Propanethiol, 2-Methyl-1-propanethiol, 1-Hexanethiol, 1-Octanethiol, 1-Dodecanethiol
Ether R1OR2, wherein, R1 and R2 are each independently CxH2x+1(x≥1): For example, Diethyl Ether, Isoamyl ether, Dibutyl ether, Dipentyl ether, Diisopropyl ether, Dipropyl ether, Dihexyl ether, and Dioctyl ether
Ester R1COOR2, wherein R1 and R2 are each independently CxH2x+1(x≥1): For example, Butyl valerate, Butyl hexanoate, Butyl octanoate, Pentyl valerate, Propyl butyrate, Propyl hexanoate, Hexyl hexanoate, and Hexyl octanoate.
In certain embodiments, the surface protection layer forms a continuous layer of uniform thickness on the SSE surface. In certain embodiments, the layer has a thickness of ≥0.1 nm.
The surface protection layer can be removed by subjecting the coated SSE to a temperature of 20 to 600, more particularly 20 to 150° C., for 1 minute to 120 minutes, more particularly 10 minutes to 60 minutes.
The surface protection can be applied to any SSE. Preferably, the SSE is an air-stable SSE, particularly SSEs having high ionic conductivity (>1 mS/cm) at room temperature, high chemical stability with O2, N2, and CO2 in the air, and high chemical stability against water in the air with a limited generation of H2S (<10 ppm within 2 hours, under relative humidity <15%).
In certain embodiments, the SSE is Li7P2S8X, wherein X is Cl, Br, I, and/or F. The halide doping enables tuning of the crystalline structure and bonding strength to enhance the Li+ conductivity and chemical stability against Li metal and moisture.
In certain embodiments, the SSE is Li3PS4 (LPS) or Li10GeP2S12 (LGPS).
In other embodiments, the protective coating can be applied to moisture sensitive Li-ion conductors (sulfides and oxides) and active electrode materials (e.g. LiNi0.8Co0.1Mn0.1O2).
In certain embodiments, the sulfide—containing SSEs have a room-temperature Li+ conductivity >5 mS/cm or >1 mS/cm, and a Li/SSE interfacial resistance <5 Ωcm2. In certain embodiments, the SSE is an ultra—thin solid film (10-30 μm).
The surface protection agent may be applied to the SSE surface by any method. For example, the surface protection agent may be applied to the SSE surface via physical stir-mixing, spraying, chemical vapor deposition, molecular layer deposition, and/or atomic layer deposition. In certain embodiments, the surface protection agent is a liquid that is mixed with SSE particles. The SSE particles may have, for instance, an average particle diameter of 10 nm-100 μm. The surface protection agent/SSE particle mixture is heated under conditions sufficient for depositing the surface protection agent onto the SSE particle surface. For example, the surface protection layer can be deposited onto SSE particle surfaces by stir-mixing the surface protection agent and SSEs at a temperature of 0 to 200, more particularly 20 to 80° C., for 1 min to 120 min, more particularly 10 min to 60 min.
The SSE may be included in an electrochemical cell includes the cathode, an anode, an electrolyte, and a separator positioned between the anode and the cathode. The cell may be assembled into a lithium-ion battery system.
Illustrative cathode materials include intercalated lithium, a metal oxide (for example, a lithium-containing oxide such as a lithium cobalt oxide, a lithium iron phosphate, a lithium magnesium oxide, a lithium nickel manganese cobalt oxide, or a lithium nickel cobalt aluminum oxide), or graphene.
In any of the foregoing or following embodiments, the cathode may further comprise one or more inactive materials, such as binders and/or additives (e.g., carbon). In some embodiments, the cathode may comprise from 0-10 wt %, such as 2-5 wt % inactive materials. Suitable binders include, but are not limited to, polyvinyl alcohol, polyvinyl fluoride, ethylene oxide polymers, polyvinylpyrrolidone, polyurethane, polytetrafluoroethylene, polyvinylidene fluoride, polyethylene, polypropylene, styrene-butadiene rubber, epoxy resin, nylon, polyimide and the like. Suitable conductive additives include, but are not limited to, carbon black, acetylene black, Ketjen black, carbon fibers (e.g., vapor-grown carbon fiber), metal powders or fibers (e.g., Cu, Ni, Al), and conductive polymers (e.g., polyphenylene derivatives).
In any of the foregoing or following embodiments, the anode may be any anode suitable for a lithium ion battery. In some embodiments, the anode is lithium metal, lithium-metal alloy (for example, a lithium-metal alloy with Li atomic percentage of 0.1-99.9%, such as Li—Mg, Li—Al, Li—In, Li—Zn, Li—Sn, Li—Au, Li—Ag), graphite, an intercalation material, or a conversion compound. The intercalation material or conversion compound may be deposited onto a substrate (e.g., a current collector) or provided as a free-standing film, typically, including one or more binders and/or conductive additives. Suitable binders include, but are not limited to, polyvinyl alcohol, polyvinyl chloride, polyvinyl fluoride, ethylene oxide polymers, polyvinylpyrrolidone, polyurethane, polytetrafluoroethylene, polyvinylidene fluoride, polyethylene, polypropylene, styrene-butadiene rubber, epoxy resin, nylon, polyimide and the like. Suitable conductive additives include, but are not limited to, carbon black, acetylene black, Ketjen black, carbon fibers (e.g., vapor-grown carbon fiber), metal powders or fibers (e.g., Cu, Ni, Al), and conductive polymers (e.g., polyphenylene derivatives). Exemplary anodes for lithium batteries include, but are not limited to, lithium metal, carbon-based anodes (e.g., graphite, silicon-based anodes (e.g., porous silicon, carbon-coated porous silicon, carbon/silicon carbide-coated porous silicon), Mo6S8, TiO2, V2O5, Li4Mn5O12, Li4Ti5O12, C/S composites, and polyacrylonitrile (PAN)—sulfur composites. In some embodiments, the anode is lithium metal.
In any of the foregoing or following embodiments, the separator may be glass fiber, a porous polymer film (e.g., polyethylene- or polypropylene-based material) with or without a ceramic coating, or a composite (e.g., a porous film of inorganic particles and a binder). One exemplary polymeric separator is a Celgard® K1640 polyethylene (PE) membrane. Another exemplary polymeric separator is a Celgard® 2500 polypropylene membrane. Another exemplary polymeric separator is a Celgard® 3501 surfactant-coated polypropylene membrane.
The surface protective-coated SSE can be assembled with a cathode, an anode, and optionally a separator into an electrochemical cell.
A SSE structure (e.g., a thin film) can be fabricated from the protective agent-coated particles by any suitable method.
In one method the protective agent-coated SSE particles are pelletized directly with a pressing die at 100-650 MPa to form an SSE pellet.
In another method for SSE thin film fabrication, 1%-99 wt % of polymeric binder is mixed with the protective agent-coated SSE particles to form a slurry and then is casted to form SSE thin film with the thickness in the range of 2-300 um.
In a further method 1%-99 wt % of polymeric binder is dry mixed with the protective agent-coated SSE particles and then dry processed into SSE thin film with the thickness in the range of 2-300 um. The whole process is protected under the Ar gas.
A cell can be assembled from the protective agent-coated SSEs by any suitable method.
In one method the protective agent-coated SSE particles are pelletized with a pressing die at 100-650 MPa to form an SSE pellet. A mixture of cathode powders, agent-coated SSE particles, and carbon conductors is spread on the top of the SSE pellet and pressed together with SSE pellet under 100-650 MPa. Then Li metal, Li-alloy, or other anode materials is pressed on the other side of SSE pellet under 100—650 MPa to form a cell.
In a method for SSE thin film fabrication, 1%-99 wt % of polymeric binder is mixed with the protective agent-coated SSE particles to form a slurry and then is casted to form SSE thin film with the thickness in the range of 2-300 um. For cathode film fabrication, 1%-99 wt % of binder is mixed with the cathode active materials, agent-coated SSE particles, and carbon additives, and then is casted to form cathode film with the thickness in the range of 2-300 um. Cathode film, SSE film, and Li metal, Li-alloy or other anodes are sandwitched and pressed together under 100-650 MPa to form a cell.
In another method for SSE thin film fabricatoin, 1%-99 wt % of polymeric binder is dry mixed with the protective agent-coated SSE particles and then dry processed into SSE thin film with the thickness in the range of 2-300 um. For the cathode film fabrication, 1%-99 wt % of binder is dry mixed with the cathode active materials , agent-coated SSE particles, and carbon additives, and then is processed into cathode film with the thickness in the range of 2-300 um. Cathode film, SSE film, and Li metal, Li-alloy or another anode material are sandwitched and pressed together under 100-650 MPa to form a cell. The whole process is protected under the Ar gas.
At the last step of pressing cathode, SSE, and Li/Li-alloy/other anode together, heat the whole cell to remove the protective coating layer before the cell is vacuum-sealed in package materials.
A typical process of amphipathic molecule coating and releasing onto/from the SSEs is illustrated in
To study changes of SSE surface properties before and after 1-Bromopentane coating, X-ray photoelectronic spectra (XPS) analysis was carried out on the pristine LPSBI, LPSBI-Bromo, and LPSBI-Bromo-160 powders.
The thickness of 1-Bromopentane interphase was calculated based on the molecular size and density of 1-Bromopentane, mass change of LPSBI before and after treated with 1-Bromopentane, and Brunauer-Emmett-Teller (BET) surface area. The molecular length of 1-Bromopentane is about 0.75 nm. Density of 1-Bromopentane is 1.2 g cm−3. BET surface area of LPSBI is ˜10 m2 g−1. After treated with 1-Bromopentane, 1 g of LSPBI gained ˜9.7 mg in mass, which is convert to nearly a single layer of 1-Bromopentane molecules on the surface of LSPBI particles. A more detailed picture of the interaction between 1-Bromopentane and LPSBI can be obtained from XPS. After absorption, we find a decrease in the intensity of the LPSBI substrate signals Li 1 s, P 2 p, and S 2 p, from which we can estimate the adsorption layer thickness d according to:
where Ix, corr is the core level intensity of the element x in the LPSBI, Ix, meas is the intensity of the element x signal attenuated by the adsorbed layer, λx is the inelastic mean free path (IMFP) of x photoelectron in the adsorption overlayer, and θ is the emission angle relative to the sample normal. Using Equation 1, we calculated d=0.59 nm (±0.05 nm) for 1-bromopentane on LPSBI. Binding energies and peak shapes of the Li 1 s, P 2 p, and S 2 p signals remain the unchanged after monolayer adsorption. XPS results agree well with our thermalgravimetric analysis, confirming that it is monolayer adsorption of 1-bromopentane on the LPSBI.
To investigate the effects of 1-Bromopentane coating on moisture stability of LPSBI, we monitored H2S generation from the LPSBI and LPSBI-Bromo during exposure in dry room (R.H.=0.1%) and ambient (R.H.=20%) environments for 120 minutes (See set-up of the H2S measurement in supporting information). As shown in
To study surface details of these samples before and after exposure, XPS measurements have been conducted on LPSBI, LPSBI-20%, LPSBI-Bromo, and LPSBI-Bromo-20% powders.
To investigate the effects of 1-Bromopentane coating on moisture stability of Li6PS5Cl (LPSC), we monitored H2S generation from the LPSC and LPSC-Bromo-25C during the exposure in an ambient environment with R.H.=10% for 50 minutes. As shown in
To investigate the effects of 1-Bromopentane coating on moisture stability of Li3PS4 (LPS), we monitored H2S generation from the LPS and LPS-Bromo-25C during the exposure in an environment with R.H.=49% for 120 minutes. As shown in
Preparation of solid-state electrolytes. Glass-ceramic Li7P2S8Br0.5I0.5 was prepared by ball-mill technic followed but low-temperature heat treatment. The stoichiometric amounts of Li2S (Sigma-Aldrich, anhydrous, 99%), P2S5 (Sigma-Aldrich, 99%), LiBr (Sigma-Aldrich, 99.99%), and LiI (Sigma-Aldrich, 99.99%) were hand-ground before transferring to a zirconium oxide grinding jar. The mixture was ball-milled for 40 h at a speed of 600 rpm using a planetary ball mill (RETSCH PM 100 Planetary Ball Mill). The obtained powders were heated at 160° C. for 1 hour. The whole process was under Argon atmosphere protection. Glass ceramic Li3PS4 was prepared following the same ball mill method but heating at 243° C. for 2 h.
Surface modification. 1-bromopentane (Sigma-Aldrich, 98%) was dried with molecular sieve before use. 450 mg of each of Li3PS4, Li7P2S8Br0.5I0.5, and Li10GeP2S12 were mixed with 3 g 1-bromopentane for 8 h. The mixture was dried under vacuum at 80° C. overnight to obtain the final products. To release 1-bromopentane on the surface, solid-state electrolytes with surface treatment were heated at 160° C. for 1 h. All the processes were protected under Ar atmosphere. Moisture stability characterization. To monitor the amount of H2S gas releasing from pristine and surface treated powder samples, 150 mg of each powder was sealed in a desiccator with volume of 7112 cm3, in which a calibrated gas detector (FORENSICS DETECTORS) and a humidity detector (ThermoPro) were used to detect the concentration of H2S and relative humidity in detector, respectively. Dedicator was put in ambient environment with relative humidity of 20% and dry room with relative humidity of 0.5% one day prior to the test. XRD and Raman spectroscopies. Powder XRD measurements were performed on a Rigaku Miniflex II spectrometer with Cu Kα radiation, using XRD holder with beryllium window (Rigaku Corp.) for air sensitive samples.
SEM and TEM characterization. Morphologies of SSE powders were observed on a scanning electron microscope (JSM-IT-200, JOEL)
Electrochemical measurement. The Li-ion conductivity of the SSE was measured by electrochemical impedance spectroscopy using Biologic SP 200 over a 7 MHz to 0.1 Hz frequency range with an amplitude of 5 mV. SSE pellet was prepared by pressing powders under the pressure 400 MPa, where carbon-coated aluminum foils were attached on both faces of pellets, serving as blocking electrodes.
In view of the many possible embodiments to which the principles of the disclosed invention may be applied, it should be recognized that the illustrated embodiments are only preferred examples of the invention and should not be taken as limiting the scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 63/104,718 filed on Oct. 23, 2020, which is incorporated herewith in its entirety.
This invention was made with government support under Contract DE-AC0576RL01830 awarded by the U.S. Department of Energy. The government has certain rights in the invention.
Number | Date | Country | |
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63104718 | Oct 2020 | US |