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US20160141601A1 - High energy materials for a battery and methods for making and use - Google Patents

High energy materials for a battery and methods for making and use Download PDF

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US20160141601A1
US20160141601A1 US15/008,252 US201615008252A US2016141601A1 US 20160141601 A1 US20160141601 A1 US 20160141601A1 US 201615008252 A US201615008252 A US 201615008252A US 2016141601 A1 US2016141601 A1 US 2016141601A1
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metal
precursor material
coating
coating precursor
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Cory O'Neill
Steven Kaye
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Wildcat Discovery Technologies Inc
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Publication of US20160141601A1 publication Critical patent/US20160141601A1/en
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/04Processes of manufacture in general
    • H01M4/0471Processes of manufacture in general involving thermal treatment, e.g. firing, sintering, backing particulate active material, thermal decomposition, pyrolysis
    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C14/00Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material
    • C23C14/06Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material characterised by the coating material
    • C23C14/0641Nitrides
    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C14/00Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material
    • C23C14/06Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material characterised by the coating material
    • C23C14/0694Halides
    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C14/00Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material
    • C23C14/06Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material characterised by the coating material
    • C23C14/08Oxides
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/05Accumulators with non-aqueous electrolyte
    • H01M10/052Li-accumulators
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/04Processes of manufacture in general
    • H01M4/0402Methods of deposition of the material
    • H01M4/0421Methods of deposition of the material involving vapour deposition
    • H01M4/0423Physical vapour deposition
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/13Electrodes for accumulators with non-aqueous electrolyte, e.g. for lithium-accumulators; Processes of manufacture thereof
    • H01M4/136Electrodes based on inorganic compounds other than oxides or hydroxides, e.g. sulfides, selenides, tellurides, halogenides or LiCoFy
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/36Selection of substances as active materials, active masses, active liquids
    • H01M4/362Composites
    • H01M4/366Composites as layered products
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/36Selection of substances as active materials, active masses, active liquids
    • H01M4/48Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides
    • H01M4/485Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of mixed oxides or hydroxides for inserting or intercalating light metals, e.g. LiTi2O4 or LiTi2OxFy
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/36Selection of substances as active materials, active masses, active liquids
    • H01M4/48Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides
    • H01M4/52Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of nickel, cobalt or iron
    • H01M4/525Selection of substances as active materials, active masses, active liquids of inorganic oxides or hydroxides of nickel, cobalt or iron of mixed oxides or hydroxides containing iron, cobalt or nickel for inserting or intercalating light metals, e.g. LiNiO2, LiCoO2 or LiCoOxFy
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/36Selection of substances as active materials, active masses, active liquids
    • H01M4/58Selection of substances as active materials, active masses, active liquids of inorganic compounds other than oxides or hydroxides, e.g. sulfides, selenides, tellurides, halogenides or LiCoFy; of polyanionic structures, e.g. phosphates, silicates or borates
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M4/00Electrodes
    • H01M4/02Electrodes composed of, or comprising, active material
    • H01M4/36Selection of substances as active materials, active masses, active liquids
    • H01M4/58Selection of substances as active materials, active masses, active liquids of inorganic compounds other than oxides or hydroxides, e.g. sulfides, selenides, tellurides, halogenides or LiCoFy; of polyanionic structures, e.g. phosphates, silicates or borates
    • H01M4/5825Oxygenated metallic salts or polyanionic structures, e.g. borates, phosphates, silicates, olivines
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/10Energy storage using batteries

Definitions

  • the present invention is in the field of battery technology, and more particularly in the area of materials for making high-energy electrodes for batteries, including metal-fluoride materials.
  • One type of battery consists of a negative electrode made primarily from lithium and a positive electrode made primarily from a compound containing a metal and fluorine.
  • a negative electrode made primarily from lithium
  • a positive electrode made primarily from a compound containing a metal and fluorine.
  • lithium ions and electrons are generated from oxidation of the negative electrode while fluoride ions are produced from reduction of the positive electrode.
  • the generated fluoride ions react with lithium ions near the positive electrode to produce a compound containing lithium and fluorine, which may deposit at the positive electrode surface.
  • Metal fluoride based batteries are an attractive energy storage technology because of their extremely high theoretical energy densities.
  • certain metal fluoride active materials can have theoretical energy densities greater than about 1600 Wh/kg or greater than about 7500 Wh/L.
  • metal fluorides have a relatively low raw material cost, for example less than about $10/kg.
  • a number of technical challenges currently limit their widespread use and realization of their performance potential.
  • metal fluoride active materials have electrochemical potentials greater than about 2.5 V because of their relatively large bandgap produced by the highly ionic bonding between the metal and fluorine, and in particular between a transition metal and fluorine.
  • one of the drawbacks to wide bandgap materials is the intrinsically low electronic conductivity that results from the wide bandgap. As a result of this low conductivity, discharge rates of less than 0.1 C are required in order to obtain full theoretical capacity. More typically, discharge rates of 0.05 C to 0.02 C are reported in the literature. Such low discharge rates limit the widespread use of metal fluoride active materials.
  • the second limitation to extended cycle life is the mechanical stress imparted to the binder materials by the metal fluoride particles as a result of the volume expansion that occurs during the conversion reaction. Over time, the binder is pulverized, compromising the integrity of the cathode. Notably, for the metal fluoride CuF 2 , no demonstrations of rechargeability have been reported.
  • CuF 2 For CuF 2 , an additional challenge prevents rechargeability.
  • the potential required to recharge a CuF 2 electrode is 3.55V.
  • Cu metal oxidizes to Cu 2+ at approximately 3.4 V vs. Li/Li + .
  • the oxidized copper can migrate to the anode, where it is irreversibly reduced back to Cu metal.
  • Cu dissolution competes with the recharge of Cu+2LiF to CuF 2 , preventing cycling of the cell.
  • the Cu metal accumulating on the anode surface can increase the impedance and/or destroy the solid-electrolyte interphase (SEI) on the anode.
  • SEI solid-electrolyte interphase
  • Certain embodiments of the present invention can be used to form electrochemical cells having metal fluoride active material that exhibit improved rate performance, improved energy efficiency, and improved cycle life when compared to prior batteries.
  • Certain embodiments of the invention include a method of making a composition for use in forming a cathode for a battery.
  • the method includes coating a metal fluoride material with a coating precursor material including a metal or a metal complex and annealing coated metal fluoride material, wherein at least a portion of the metal fluoride material and at least a portion of the coating undergo a phase change.
  • the metal fluoride material is preferably CuF 2 .
  • the metal can be, for example, Ni, Ba, or Ta.
  • the metal complex can be, for example a metal oxide, such as Al 2 O 3 , SiO 2 , Ta 2 O 5 , TiO 2 ; a metal nitride, such as AlN, TaN; a metal silicate, such as ZrSiO 4 ; or other materials that are volatile enough to be evaporated and re-condensed onto a substrate.
  • the annealing temperature is less than 450 degrees C., less than 400 degrees C., less than 325 degrees C., or less than 200 degrees C. Preferably, the annealing temperature is about 325 degrees C.
  • the temperature is chosen such that it is sufficiently high for the metal complex to react with the metal fluoride, but not high enough to decompose the metal fluoride. Without such heat treatment and the resulting reaction, the material is not rechargeable, as is demonstrated by experiments described herein.
  • Certain embodiments of the invention include a composition formed by the methods disclosed herein.
  • the composition is characterized by having reversible capacity.
  • the composition can include particles with a grain size greater than 100 nm, 110 nm, 120 nm, or 130 nm.
  • the composition can include a particle having a first phase and a coating on the particle having a second phase.
  • the first phase includes the metal fluoride and the second phase includes the metal oxide.
  • the coating can be covalently bonded to the particle.
  • Certain embodiments of the invention include batteries having electrodes formed from the compositions disclosed herein, the method of making such batteries, and the method of use of such batteries.
  • FIG. 1 illustrates electrochemical characterization of different hybrid cathode formulations according to embodiments of the invention in which the content of a conductive precursor material is varied in the cathode.
  • FIG. 2 illustrates electrochemical characterization of a cathode formulation from FIG. 1 in which the voltage of a hybrid cathode according to embodiments of the invention is plotted against the capacity for the first and second cycles.
  • FIG. 3 illustrates electrochemical characterization of different hybrid cathode formulations according to embodiments of the invention in which the discharge is plotted as a function of cycle for 10 cycles.
  • FIG. 4 illustrates electrochemical characterization of a hybrid cathode formed from a metal fluoride and a reactant material according to certain embodiments.
  • the cathode demonstrates rechargeability.
  • FIG. 5 illustrates a powder X-ray diffraction pattern of a material used to form a rechargeable metal fluoride cathode.
  • FIG. 6 illustrates second cycle discharge capacity for a variety of hybrid cathode materials used according to embodiments of the invention.
  • FIG. 7 illustrates second cycle discharge capacity for a hybrid cathode material used according to embodiments of the invention versus annealing temperature.
  • FIG. 8 illustrates second cycle the capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt % CuF 2 with 15 wt % of certain metal oxides (in this case NiO or TiO 2 ) at certain annealing temperatures.
  • certain metal oxides in this case NiO or TiO 2
  • FIG. 9 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt % CuF 2 with 15 wt % of certain metal oxides (in this case NiO or TiO 2 ) for certain annealing times.
  • certain metal oxides in this case NiO or TiO 2
  • FIG. 10 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, 90 wt %, or 95 wt % CuF 2 with 5 wt %, 10 wt %, 15 wt % of NiO.
  • FIG. 11 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO as a function of milling energy.
  • FIG. 12 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO as a function of milling time.
  • FIG. 13 illustrates the second cycle reversible capacity measured for various starting materials used to react with CuF 2 .
  • FIG. 14 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting CuF 2 with nickel (II) acetylacetonate using various processing conditions.
  • FIG. 15 illustrates the capacity as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO and for a control material.
  • FIG. 16 illustrates a galvanostatic intermittent titration technique measurement for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO.
  • FIG. 17 illustrates the capacity of full cells and half cells as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO.
  • FIG. 18 illustrates voltage traces of the full cell and half cells prepared as described in relation to FIG. 17 .
  • FIG. 19 illustrates the capacity retention of full cells and half cells as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO.
  • FIG. 20 illustrates the second cycle reversible capacity measured for various coating precursor materials used to react with CuF 2 .
  • conductive refers to the intrinsic ability of a material to facilitate electron or ion transport and the process of doing the same.
  • the terms include materials whose ability to conduct electricity may be less than typically suitable for conventional electronics applications but still greater than an electrically-insulating material.
  • active material refers to the material in an electrode, particularly in a cathode, that donates, liberates, or otherwise supplies the conductive species during an electrochemical reaction in an electrochemical cell.
  • transition metal refers to a chemical element in groups 3 through 12 of the periodic table, including scandium (Sc), titanium (Ti), vanadium (V), chromium (Cr), manganese (Mn), iron (Fe), cobalt (Co), nickel (Ni), copper (Cu), zinc (Zn), yttrium (Y), zirconium (Zr), niobium (Nb), molybdenum (Mo), technetium (Tc), ruthenium (Ru), rhodium (Rh), palladium (Pd), silver (Ag), cadmium (Cd), hafnium (Hf), tantalum (Ta), tungsten (W), rhenium (Re), osmium (Os), iridium (Ir), platinum (Pt), gold (Au), mercury (Hg), rutherfordium (Rf), dubnium (Db), seaborgium (Sg), bohrium (Bh), hassium (H
  • halogen refers to any of the chemical elements in group 17 of the periodic table, including fluorine (F), chlorine (Cl), bromine (Br), iodine (I), and astatine (At).
  • chalcogen refers to any of chemical elements in group 16 of the periodic table, including oxygen (O), sulfur (S), selenium (Se), tellurium (Te), and polonium (Po).
  • alkali metal refers to any of the chemical elements in group 1 of the periodic table, including lithium (Li), sodium (Na), potassium (K), rubidium (Rb), cesium (Cs), and francium (Fr).
  • alkaline earth metals refers to any of the chemical elements in group 2 of the periodic table, including beryllium (Be), magnesium (Mg), calcium (Ca), strontium (Sr), barium (Ba), and radium (Ra).
  • rare earth element refers to scandium (Sc), yttrium (Y), lanthanum (La), cerium (Ce), praseodymium (Pr), neodymium (Nd), promethium (Pm), samarium (Sm), europium (Eu), gadolinium (Gd), terbium (Tb), dysprosium (Dy), holmium (Ho), erbium (Er), thulium (Tm), ytterbium (Yb), and lutetium (Lu).
  • a rate “C” refers to either (depending on context) the discharge current as a fraction or multiple relative to a “1 C” current value under which a battery (in a substantially fully charged state) would substantially fully discharge in one hour, or the charge current as a fraction or multiple relative to a “1 C” current value under which the battery (in a substantially fully discharged state) would substantially fully charge in one hour.
  • a novel active material is prepared for use in a cathode with metal fluoride (MeF x ) active materials.
  • the novel active material sometimes referred to herein as a hybrid material, is prepared by combining a metal fluoride and a metal complex, followed by heat treatment of the mixture under an inert atmosphere according to the Formula (I)
  • the heat treatment of the metal fluoride and metal complex causes a reaction to form a new phase according to the formula (II)
  • the heat treatment causes the formation of covalent bonds between the metal fluoride and the metal complex, improving conductivity and passivating the surface.
  • Suitable metal complexes which can act as precursors for the reaction described herein, for use in synthesizing the active material include, but are not limited to, MoO 3 , MoO 2 , NiO, CuO, VO 2 , V 2 O 5 , TiO 2 , Al 2 O 3 , SiO 2 , LiFePO 4 , LiMe T PO 4 (where Me T is one or more transition metal(s)), metal phosphates, and combinations thereof. According to embodiments of the invention, these oxides can be used in Formula (I).
  • the synthetic route for achieving the active material may vary, and other such synthetic routes are within the scope of the disclosure.
  • the material can be represented by Me a Me′ b X c F and in the examples herein is embodied by a Cu 3 Mo 2 O 9 active material.
  • Other active materials are within the scope of this disclosure, for example, NiCuO 2 , Ni 2 CuO 3 , and Cu 3 TiO 4 .
  • the coating materials disclosed herein provide rechargeability to otherwise non-rechargeable metal fluoride materials.
  • the rechargeability may be due to the electrochemical properties of the novel hybrid material, the coating of the metal fluoride to prevent copper dissolution, or a more intimate interface between the metal fluoride and the coating material as a result of the heat treatment and reaction.
  • the novel hybrid material may provide a kinetic barrier to the Cu dissolution reaction, or to similar dissolution reactions for other metal fluoride materials to the extent such dissolution reactions occur in the cycling of electrochemical cells.
  • Suitable coating precursors include materials that decompose to form metal oxides (and in particular, transition metal oxides) as opposed to using a metal oxide to directly react with the metal fluoride.
  • Suitable coating precursors include, but are not limited to, metal acetates, metal acetylacetonates, metal hydroxides, metal ethoxides, and other similar organo-metal complexes.
  • the final rechargeable material is not necessarily a pure oxide or a purely crystalline material.
  • the reaction of Formula II predicts that there would not be a pure oxide or a purely crystalline material.
  • the metal oxide precursor or metal oxide material can form a coating, or at least a partial coating, on the metal fluoride active material.
  • the reaction of the metal oxide precursor or metal oxide material with the surface of the metal fluoride (and in particular copper fluoride) active material is important for generating a rechargeable electrode active material.
  • the coating material (nickel metal) was vaporized and then physically condensed onto the substrate at 20 weight percent. X-ray diffraction measurements were performed on the coated material to confirm the bulk CuF 2 was not altered. The coated material was then annealed similarly to materials prepared by other methods.
  • Electrode Formulation Cathodes were prepared using a formulation composition of 80:15:5 (active material:binder:conductive additive) according to the following formulation method: 133 mg PVDF (Sigma Aldrich) and about 44 mg Super P Li (Timcal) was dissolved in 10 mL NMP (Sigma Aldrich) overnight. 70 mg of coated composite powder was added to 1 mL of this solution and stirred overnight. Films were cast by dropping about 70 ⁇ L of slurry onto stainless steel current collectors and drying at 150 degrees C. for about 1 hour. Dried films were allowed to cool, and were then pressed at 1 ton/cm 2 . Electrodes were further dried at 150 degrees C. under vacuum for 12 hours before being brought into a glove box for battery assembly.
  • Electrodes and cells were electrochemically characterized at 30 degrees C. with a constant current C/50 charge and discharge rate between 4.0 V and 2.0 V. A 3 hour constant voltage step was used at the end of each charge.
  • cathodes were lithiated pressing lithium foil to the electrode in the presence of electrolyte (1M LiPF 6 in 1:2 EC:EMC) for about 15 minutes. The electrode was then rinsed with EMC and built into cells as described above, except graphite was used as the anode rather than lithium.
  • FIG. 1 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the second cycle discharge capacity of three different cathode formulations containing a LiFePO 4 material is plotted as a function of LiFePO 4 content (labeled LFP) in the cathode in FIG. 1 . The dotted line depicts the theoretical capacity of LiFePO 4 .
  • One cathode formulation is 100% LiFePO 4 .
  • Another cathode formulation is a combination of CuF 2 and LiFePO 4 in which the content of LiFePO 4 was varied from 10% to 50% of the total weight of conductive material.
  • the third cathode formulation is a combination of CuF 2 and the conventional conductive oxide MoO 3 and LiFePO 4 in which the content of LiFePO 4 was varied from 10% to 50% of the total weight of conductive material.
  • FIG. 1 demonstrates that all of the CuF 2 /LiFePO 4 matrices are rechargeable.
  • the (CuF 2 /MoO 3 )/LiFePO 4 hybrid cathode containing 50% LiFePO 4 is also able to recharge.
  • FIG. 1 further demonstrates a direct relationship between the capacity and the percent content of LiFePO 4 .
  • FIG. 2 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the voltage of a hybrid cathode is plotted against the capacity for the first and second cycles. The dashed line indicates the expected theoretical capacity from the LiFePO 4 content in cathode.
  • the cathode formulation is the CuF 2 (70%)/LiFePO 4 (30%) hybrid cathode from FIG. 1 .
  • the first cycle very little discharge capacity is observed, indicating that the LiFePO 4 material is not capable of accepting charge on this cycle. Without being bound to a particular theory or mechanism of action, the LiFePO 4 material may not accept charge as a result of defects introduced during milling. This data suggests that all of the capacity observed during the first and second cycles can be attributed solely to the CuF 2 .
  • FIG. 3 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the discharge capacity for cells with a range of LiFePO 4 content is plotted as a function of cycle for 10 cycles.
  • the cathode formulation is CuF 2 with LiFePO 4 content ranging from 10% to 50% of the total weight of conductive material.
  • FIG. 4 demonstrates that the hybrid cathode is able to consistently recharge across a number of cycles. Based on data from FIG. 2 , it is expected that the discharge capacity is contributed solely by CuF 2 and not LiFePO 4 . This is a significant finding because CuF 2 has not been previously shown to have such significant reversible capacity.
  • the combination of certain conductive materials with CuF 2 renders the CuF 2 cathode material rechargeable.
  • FIG. 4 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the first and second cycle voltage traces for a cell containing a cathode formed from a metal fluoride and the new hybrid material.
  • the metal fluoride active material is CuF 2 and the hybrid material is Cu 3 Mo 2 O 9 .
  • FIG. 4 demonstrates that the cell has about 140 mAh/g of reversible capacity. Previously known cathodes containing CuF 2 have not demonstrated such significant reversible capacity.
  • FIG. 5 illustrates the results of structural characterization of certain embodiments disclosed herein. Specifically, the powder X-ray diffraction pattern of the material forming the cathode tested in FIG. 4 is shown along with the powder X-ray diffraction patterns of CuF 2 and Cu 3 Mo 2 O 9 .
  • FIG. 5 demonstrates that the material contains phases rich in CuF 2 and phases rich in Cu 3 Mo 2 O 9 . Thus, FIG. 5 demonstrates a new hybrid material in combination with a metal fluoride active material.
  • grain size analysis of this powder X-ray diffraction data shows that the CuF 2 has a grain size greater than 130 nm. This is a significant finding since such comparatively large particles were thought to be too large to provide good electrochemical performance.
  • the reactions described herein yield a new material at least at the surface of the particles of the metal fluoride active material.
  • the novel material present at least at the surface of the particles of the metal fluoride active material is believed to provide many of the benefits disclosed herein.
  • FIG. 6 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the second cycle discharge capacity of CuF 2 with various materials and annealing temperatures. FIG. 6 shows many oxide materials that provide recharge capability, demonstrated by capacities greater than 100 mAh/g.
  • Table 1 presents the results of further electrochemical characterization of certain embodiments disclosed herein.
  • Table 1 shows that many metal oxide and metal oxide precursor starting materials can be used in the reactions described herein to yield rechargeable metal fluoride electrode materials.
  • the materials in Table 1 include metal oxides, metal phosphates, metal fluorides, and precursors expected to decompose to oxides. In particular, nickel oxide showed excellent performance.
  • FIG. 7 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the second cycle discharge capacity for cells containing a cathode formed from a metal fluoride and the precursor material treated at different temperatures.
  • the metal fluoride active material is CuF 2 and the precursor material is NiO.
  • FIG. 7 shows a peak for cycle 2 capacity at about 325 degrees C. for NiO precursors, with nearly 250 mAh/g discharge capacity.
  • FIG. 8 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt % CuF 2 with 15 wt % of certain metal oxides (in this case NiO or TiO 2 ) at certain annealing temperatures.
  • the mixtures were milled at high energy for about 20 hours.
  • the anneal temperatures ranged from about 225 degrees C. to about 450 degrees C. and the anneal time was 6 hours.
  • the 325 degree C. anneal temperature for the NiO starting material generated the best performance.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC. The testing was performed at a rate of 0.02 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 9 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt % CuF 2 with 15 wt % of certain metal oxides (in this case NiO or TiO 2 ) for certain annealing times.
  • the mixtures were milled at high energy for about 20 hours.
  • the anneal temperature was 325 degrees C. and the anneal time was 1 hour, 6 hours, or 12 hours.
  • the 6 hour anneal time yielded the best results for both the NiO and TiO 2 starting materials, and the NiO starting material generated better performance.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC. The testing was performed at a rate of 0.02 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 10 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, 90 wt %, or 95 wt % CuF 2 with 5 wt %, 10 wt %, 15 wt % of NiO.
  • the mixtures were milled at high energy for about 20 hours.
  • the anneal temperature was 325 degrees C. and the anneal time was 6 hours.
  • Using 10 wt % or 15 wt % of the NiO starting material generated better performance.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC. The testing was performed at a rate of 0.02 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 11 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO.
  • the mixtures were milled at various energies comparable to milling on a Fritch Pulverisette 7 Planatery Mill at 305, 445, 595, and 705 RPM for about 20 hours.
  • the anneal temperature was 325 degrees C. and the anneal time was 6 hours. Performance improves with increasing milling energy, suggesting that intimate physical interaction of the materials is required.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC. The testing was performed at a rate of 0.05 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 12 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO.
  • the mixtures were milled for various times (3 hours, 20 hours, or 40 hours) at a high energy (comparable to 705 RPM on Fritch Pulverisette 7).
  • the anneal temperature was 325 degrees C. and the anneal time was 6 hours. Performance does not improve after 20 hours of milling.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC. The testing was performed at a rate of 0.05 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 13 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, FIG. 13 shows the second cycle reversible capacity measured for various starting materials used to react with CuF 2 .
  • the starting materials include NiO, nickel (II) acetylacetonate (Ni acac in Table 1), nickel acetate, nickel hydroxide, NiCO 3 *Ni(OH) 2 , Ni(C 2 O 2 ), Ni(CP) 2 , and Ni.
  • the starting materials react to form a new phase.
  • the materials react with the surface of the CuF 2 particles. Additionally, the anneal atmosphere was either N 2 or dry air.
  • the precursor starting materials decompose to NiO (although this depends on the atmosphere for some precursors) at or below the annealing temperatures used for the reaction.
  • the precursors that are soluble or have low boiling points can enable solution or vapor deposition processing methods.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC. The testing was performed at a rate of 0.05 C and over a voltage range of 2.0 V to 4.0 V. Several materials show similar performance to the NiO baseline.
  • FIG. 14 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting CuF 2 with nickel (II) acetylacetonate using various processing conditions.
  • the CuF 2 was dispersed using methods described herein.
  • the coatings were applied using mill coating techniques (that is, agitating the mixture in a milling apparatus) or by solution coating techniques (including solution coating driven by physisorption). All samples were annealed under dry air.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC.
  • the testing was performed at a rate of 0.05 C and over a voltage range of 2.0 V to 4.0 V. Testing demonstrates that solution coating methods can provide similar performance to the mill coating techniques.
  • FIG. 20 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting CuF 2 with coatings formed from various coating methods and from various precursors.
  • the precursors included NiO, Ni, TiO 2 , nickel (II) acetylacetonate, and nickel acetate. All five precursor types were applied according to the mill coating techniques (that is, agitating the mixture in a milling apparatus). Solution coating techniques were used for nickel (II) acetylacetonate, and nickel acetate.
  • PVD Physical vapor deposition
  • ALD atomic layer deposition
  • the solution, vapor, and atomic layer deposition methods can provide comparatively more uniform coatings on metal fluoride particles than the coatings obtained by milling methods.
  • a comparatively thinner, more uniform coatings can provide the benefits of the coating material, such as more complete protection of the metal fluoride particle, with less precursor material.
  • thin, conformal coatings can provide an advantage in terms of weight-normalized reversible capacity.
  • FIG. 20 shows that although absolute reversible capacity was inferior for solution and vapor coatings as compared to milled coatings, the reversible capacity per weight percentage of coating was significantly improved.
  • the atomic layer deposition coating method yielded greater than about 60% more reversible capacity per coating weight than the milled coating method.
  • the ALD coated material had a coating that was about 8 nm thick and less than about 3 weight percent of the coated particle.
  • the non-milling coating methods shown in FIG. 20 are compatible with a subset of the metal complexes disclosed herein.
  • a variety of coating materials is possible with atomic layer deposition methods including metals (e.g., Ni), metal oxides (e.g., Al 2 O 3 , SiO 2 , Ta 2 O 5 , TiO 2 ), metal nitrides (e.g., AlN, TaN), and others.
  • Physical vapor deposition techniques can also deposit coatings of a wide number of materials including metals (e.g., Ni, Ba, Ta), metal oxides (e.g., SiO 2 , Ta 2 O 5 , TiO 2 , NiO), metal nitrides (e.g., TiN, AlN), metal silicates (e.g., ZrSiO 4 ) or other materials that are volatile enough to be evaporated and re-condensed onto a substrate.
  • metals e.g., Ni, Ba, Ta
  • metal oxides e.g., SiO 2 , Ta 2 O 5 , TiO 2 , NiO
  • metal nitrides e.g., TiN, AlN
  • metal silicates e.g., ZrSiO 4
  • FIG. 15 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the capacity as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO and for a control material.
  • the NiO/CuF 2 mixture was milled at high energy for about 20 hours.
  • the anneal temperature was 325 degrees C. and the anneal time was 6 hours.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC.
  • the testing was performed at a cycle 1 rate of 0.02 C, a cycle 2 rate of 0.05 C, and a cycle 3 through cycle 25 rate of 0.5 C and over a voltage range of 2.0 V to 4.0 V.
  • the cell cycles reversibly for extended cycling with capacity greater than 100 mAh/g for 25 cycles. Further, the reacted NiO/CuF 2 active material demonstrates retention of 80% of cycle 3 capacity as far out as cycle 15.
  • the control material which was prepared according to the process described in Badway, F. et al., Chem. Mater., 2007, 19, 4129, does not demonstrate any rechargeable capacity. Thus, the material prepared according to embodiments described herein is significantly superior to known materials processed according to known methods.
  • FIG. 16 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, a galvanostatic intermittent titration technique (GITT) measurement for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO and for a control material.
  • the NiO/CuF 2 mixture was milled at high energy for about 20 hours.
  • the anneal temperature was 325 degrees C. and the anneal time was 6 hours.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC. The testing was performed over a voltage range of 2.0 V to 4.0 V at a rate of 0.1 C and with a 10 hour relaxation time.
  • GITT galvanostatic intermittent titration technique
  • the GITT measurement relaxation points show low voltage hysteresis (about 100 mV), which indicate that the overpotential and/or underpotential are likely caused by kinetic and not thermodynamic limitations. This is consistent with other properties and characteristics observed for the reacted NiO/CuF 2 active material.
  • FIG. 17 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the capacity of full cells and half cells as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO.
  • the NiO/CuF 2 mixture was milled at high energy for about 20 hours.
  • the anneal temperature was 325 degrees C. and the anneal time was 6 hours.
  • the label “Cu+2LiF” indicated that the NiO/CuF 2 electrode was lithiated by pressing Li foil to CuF 2 electrode in the presence of electrolyte as described above.
  • the other half cell was lithiated electrochemically in the initial cycles.
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC.
  • the testing was performed over a voltage range of 2.0 V to 4.0 V.
  • Half cell performance is essentially identical between the two lithiation methods after cycle 2, while full cell shows additional irreversible capacity loss as compared to the half cells but similar capacity retention.
  • FIG. 18 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the voltage traces of the full cell and half cells prepared as described in relation to FIG. 17 .
  • the full cell has similar charge capacity to the half cells, but larger irreversible capacity loss and lower discharge voltage (which can indicate increased cell impedance).
  • FIG. 18 demonstrates that the full cell has about 250 mAh/g of reversible capacity and about 500 mV hysteresis between charge and discharge plateau voltages.
  • FIG. 19 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the capacity retention of full cells and half cells as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF 2 with 15 wt % of NiO.
  • the results from a control material are also depicted.
  • the full cell and half cells were prepared as described in relation to FIG. 17 .
  • the cells used a Li anode and an electrolyte containing 1M LiPF 6 in EC:EMC.
  • the testing was performed at a cycle 1 rate of 0.1 C and over a voltage range of 2.0 V to 4.0 V.
  • the capacity retention is essentially identical for the full and half cells of the NiO/CuF 2 active material.
  • the control material shows essentially no rechargeable capacity.

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Abstract

A method of forming an electrode active material by reacting a metal fluoride and a reactant. The method includes a coating step and a comparatively low temperature annealing step. Also included is the electrode formed following the method.

Description

    CROSS-REFERENCE TO RELATED APPLICATIONS
  • This application is a continuation of U.S. patent application Ser. No. 14/604,013, having a filing date of Jan. 23, 2015 entitled “High Energy Materials for a Battery and Methods for Making and Use” which is a continuation-in-part of International Application No. PCT/US2014/028506, having an international filing date of Mar. 14, 2014 entitled “High Energy Materials For A Battery And Methods For Making And Use,” which claims priority to U.S. Provisional Application No. 61/786,602 filed Mar. 15, 2013 entitled “High Energy Materials For A Battery And Methods For Making And Use.” This application claims priority to and the benefit of each of these applications, and each application is incorporated herein by reference in its entirety.
    • BACKGROUND OF THE INVENTION
  • The present invention is in the field of battery technology, and more particularly in the area of materials for making high-energy electrodes for batteries, including metal-fluoride materials.
  • One type of battery consists of a negative electrode made primarily from lithium and a positive electrode made primarily from a compound containing a metal and fluorine. During discharge, lithium ions and electrons are generated from oxidation of the negative electrode while fluoride ions are produced from reduction of the positive electrode. The generated fluoride ions react with lithium ions near the positive electrode to produce a compound containing lithium and fluorine, which may deposit at the positive electrode surface.
  • Metal fluoride based batteries are an attractive energy storage technology because of their extremely high theoretical energy densities. For example, certain metal fluoride active materials can have theoretical energy densities greater than about 1600 Wh/kg or greater than about 7500 Wh/L. Further, metal fluorides have a relatively low raw material cost, for example less than about $10/kg. However, a number of technical challenges currently limit their widespread use and realization of their performance potential.
  • One challenge for certain metal fluoride materials is comparatively poor rate performance. Many metal fluoride active materials have electrochemical potentials greater than about 2.5 V because of their relatively large bandgap produced by the highly ionic bonding between the metal and fluorine, and in particular between a transition metal and fluorine. Unfortunately, one of the drawbacks to wide bandgap materials is the intrinsically low electronic conductivity that results from the wide bandgap. As a result of this low conductivity, discharge rates of less than 0.1 C are required in order to obtain full theoretical capacity. More typically, discharge rates of 0.05 C to 0.02 C are reported in the literature. Such low discharge rates limit the widespread use of metal fluoride active materials.
  • Another challenge for certain metal fluoride active materials is a significant hysteresis observed between the charge and discharge voltages during cycling. This hysteresis is typically on the order of about 1.0V to about 1.5V. While the origin of this hysteresis is uncertain, current evidence suggests that kinetic limitations imposed by low conductivity play an important role. Further, asymmetry in the reaction paths upon charge and discharge may also play a role. Since the electrochemical potential for many of the metal fluorides is on the order of 3.0V, this hysteresis of about 1.0V to about 1.5V limits the overall energy efficiency to approximately 50%.
  • Limited cycle life is another challenge for certain metal fluoride active materials. Although rechargeability has been demonstrated for many metal fluoride active materials, their cycle life is typically limited to tens of cycles and is also subject to rapid capacity fade. Two mechanisms are currently believed to limit the cycle life for the metal fluoride active materials: agglomeration of metallic nanoparticles and mechanical stress due to volume expansion. It is believed that metal fluoride active materials can cycle by virtue of the formation during lithiation of a continuous metallic network within a matrix of insulating LiF. As the number of cycles increases, the metal particles tend to accumulate together into larger, discrete particles. The larger agglomerated particles in turn create islands that are electrically disconnected from one another, thus reducing the capacity and ability to cycle the metal fluoride active materials. The second limitation to extended cycle life is the mechanical stress imparted to the binder materials by the metal fluoride particles as a result of the volume expansion that occurs during the conversion reaction. Over time, the binder is pulverized, compromising the integrity of the cathode. Notably, for the metal fluoride CuF2, no demonstrations of rechargeability have been reported.
  • For CuF2, an additional challenge prevents rechargeability. The potential required to recharge a CuF2 electrode is 3.55V. However, in typical electrolytes for lithium ion batteries, Cu metal oxidizes to Cu2+ at approximately 3.4 V vs. Li/Li+. The oxidized copper can migrate to the anode, where it is irreversibly reduced back to Cu metal. As a result, Cu dissolution competes with the recharge of Cu+2LiF to CuF2, preventing cycling of the cell. The Cu metal accumulating on the anode surface can increase the impedance and/or destroy the solid-electrolyte interphase (SEI) on the anode.
  • The following papers and patents are among the published literature on metal fluorides that employ mixed conductors that are not electrochemically active within the voltage window of the metal fluoride: Badway, F. et al., Chem. Mater., 2007, 19, 4129; Badway, F. et al., J. Electrochem. Soc,. 2007, 150, A1318; “Bismuth fluoride based nanocomposites as electrode materials” U.S. Pat. No. 7,947,392; “Metal Fluoride And Phosphate Nanocomposites As Electrode Materials” US 2008/0199772; “Copper fluoride based nanocomposites as electrode materials” US 2006/0019163; and “Bismuth oxyfluoride based nanocomposites as electrode materials” U.S. Pat. No. 8,039,149.
  • Certain embodiments of the present invention can be used to form electrochemical cells having metal fluoride active material that exhibit improved rate performance, improved energy efficiency, and improved cycle life when compared to prior batteries. Thus, these and other challenges can be addressed by embodiments of the present invention described below.
    • BRIEF SUMMARY OF THE INVENTION
  • Certain embodiments of the invention include a method of making a composition for use in forming a cathode for a battery. The method includes coating a metal fluoride material with a coating precursor material including a metal or a metal complex and annealing coated metal fluoride material, wherein at least a portion of the metal fluoride material and at least a portion of the coating undergo a phase change. The metal fluoride material is preferably CuF2. The metal can be, for example, Ni, Ba, or Ta. The metal complex can be, for example a metal oxide, such as Al2O3, SiO2, Ta2O5, TiO2; a metal nitride, such as AlN, TaN; a metal silicate, such as ZrSiO4; or other materials that are volatile enough to be evaporated and re-condensed onto a substrate. The annealing temperature is less than 450 degrees C., less than 400 degrees C., less than 325 degrees C., or less than 200 degrees C. Preferably, the annealing temperature is about 325 degrees C. The temperature is chosen such that it is sufficiently high for the metal complex to react with the metal fluoride, but not high enough to decompose the metal fluoride. Without such heat treatment and the resulting reaction, the material is not rechargeable, as is demonstrated by experiments described herein.
  • Certain embodiments of the invention include a composition formed by the methods disclosed herein. The composition is characterized by having reversible capacity. The composition can include particles with a grain size greater than 100 nm, 110 nm, 120 nm, or 130 nm. The composition can include a particle having a first phase and a coating on the particle having a second phase. Preferably, the first phase includes the metal fluoride and the second phase includes the metal oxide. The coating can be covalently bonded to the particle.
  • Certain embodiments of the invention include batteries having electrodes formed from the compositions disclosed herein, the method of making such batteries, and the method of use of such batteries.
    • BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWINGS
  • FIG. 1 illustrates electrochemical characterization of different hybrid cathode formulations according to embodiments of the invention in which the content of a conductive precursor material is varied in the cathode.
  • FIG. 2 illustrates electrochemical characterization of a cathode formulation from FIG. 1 in which the voltage of a hybrid cathode according to embodiments of the invention is plotted against the capacity for the first and second cycles.
  • FIG. 3 illustrates electrochemical characterization of different hybrid cathode formulations according to embodiments of the invention in which the discharge is plotted as a function of cycle for 10 cycles.
  • FIG. 4 illustrates electrochemical characterization of a hybrid cathode formed from a metal fluoride and a reactant material according to certain embodiments. The cathode demonstrates rechargeability.
  • FIG. 5 illustrates a powder X-ray diffraction pattern of a material used to form a rechargeable metal fluoride cathode.
  • FIG. 6 illustrates second cycle discharge capacity for a variety of hybrid cathode materials used according to embodiments of the invention.
  • FIG. 7 illustrates second cycle discharge capacity for a hybrid cathode material used according to embodiments of the invention versus annealing temperature.
  • FIG. 8 illustrates second cycle the capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt % CuF2 with 15 wt % of certain metal oxides (in this case NiO or TiO2) at certain annealing temperatures.
  • FIG. 9 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt % CuF2 with 15 wt % of certain metal oxides (in this case NiO or TiO2) for certain annealing times.
  • FIG. 10 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, 90 wt %, or 95 wt % CuF2 with 5 wt %, 10 wt %, 15 wt % of NiO.
  • FIG. 11 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO as a function of milling energy.
  • FIG. 12 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO as a function of milling time.
  • FIG. 13 illustrates the second cycle reversible capacity measured for various starting materials used to react with CuF2.
  • FIG. 14 illustrates the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting CuF2 with nickel (II) acetylacetonate using various processing conditions.
  • FIG. 15 illustrates the capacity as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO and for a control material.
  • FIG. 16 illustrates a galvanostatic intermittent titration technique measurement for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO.
  • FIG. 17 illustrates the capacity of full cells and half cells as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO.
  • FIG. 18 illustrates voltage traces of the full cell and half cells prepared as described in relation to FIG. 17.
  • FIG. 19 illustrates the capacity retention of full cells and half cells as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO.
  • FIG. 20 illustrates the second cycle reversible capacity measured for various coating precursor materials used to react with CuF2.
    •  DETAILED DESCRIPTION OF THE INVENTION
  • The following definitions apply to some of the aspects described with respect to some embodiments of the invention. These definitions may likewise be expanded upon herein. Each term is further explained and exemplified throughout the description, figures, and examples. Any interpretation of the terms in this description should take into account the full description, figures, and examples presented herein.
  • The singular terms “a,” “an,” and “the” include the plural unless the context clearly dictates otherwise. Thus, for example, reference to an object can include multiple objects unless the context clearly dictates otherwise.
  • The terms “substantially” and “substantial” refer to a considerable degree or extent. When used in conjunction with an event or circumstance, the terms can refer to instances in which the event or circumstance occurs precisely as well as instances in which the event or circumstance occurs to a close approximation, such as accounting for typical tolerance levels or variability of the embodiments described herein.
  • The term “about” refers to the range of values approximately near the given value in order to account for typical tolerance levels, measurement precision, or other variability of the embodiments described herein.
  • The terms “conductive,” “conductor,” “conductivity,” and the like refer to the intrinsic ability of a material to facilitate electron or ion transport and the process of doing the same. The terms include materials whose ability to conduct electricity may be less than typically suitable for conventional electronics applications but still greater than an electrically-insulating material.
  • The term “active material” and the like refers to the material in an electrode, particularly in a cathode, that donates, liberates, or otherwise supplies the conductive species during an electrochemical reaction in an electrochemical cell.
  • The term “transition metal” refers to a chemical element in groups 3 through 12 of the periodic table, including scandium (Sc), titanium (Ti), vanadium (V), chromium (Cr), manganese (Mn), iron (Fe), cobalt (Co), nickel (Ni), copper (Cu), zinc (Zn), yttrium (Y), zirconium (Zr), niobium (Nb), molybdenum (Mo), technetium (Tc), ruthenium (Ru), rhodium (Rh), palladium (Pd), silver (Ag), cadmium (Cd), hafnium (Hf), tantalum (Ta), tungsten (W), rhenium (Re), osmium (Os), iridium (Ir), platinum (Pt), gold (Au), mercury (Hg), rutherfordium (Rf), dubnium (Db), seaborgium (Sg), bohrium (Bh), hassium (Hs), and meitnerium (Mt).
  • The term “halogen” refers to any of the chemical elements in group 17 of the periodic table, including fluorine (F), chlorine (Cl), bromine (Br), iodine (I), and astatine (At).
  • The term “chalcogen” refers to any of chemical elements in group 16 of the periodic table, including oxygen (O), sulfur (S), selenium (Se), tellurium (Te), and polonium (Po).
  • The term “alkali metal” refers to any of the chemical elements in group 1 of the periodic table, including lithium (Li), sodium (Na), potassium (K), rubidium (Rb), cesium (Cs), and francium (Fr).
  • The term “alkaline earth metals” refers to any of the chemical elements in group 2 of the periodic table, including beryllium (Be), magnesium (Mg), calcium (Ca), strontium (Sr), barium (Ba), and radium (Ra).
  • The term “rare earth element” refers to scandium (Sc), yttrium (Y), lanthanum (La), cerium (Ce), praseodymium (Pr), neodymium (Nd), promethium (Pm), samarium (Sm), europium (Eu), gadolinium (Gd), terbium (Tb), dysprosium (Dy), holmium (Ho), erbium (Er), thulium (Tm), ytterbium (Yb), and lutetium (Lu).
  • A rate “C” refers to either (depending on context) the discharge current as a fraction or multiple relative to a “1 C” current value under which a battery (in a substantially fully charged state) would substantially fully discharge in one hour, or the charge current as a fraction or multiple relative to a “1 C” current value under which the battery (in a substantially fully discharged state) would substantially fully charge in one hour.
  • In certain embodiments, a novel active material is prepared for use in a cathode with metal fluoride (MeFx) active materials. In some embodiments, the novel active material, sometimes referred to herein as a hybrid material, is prepared by combining a metal fluoride and a metal complex, followed by heat treatment of the mixture under an inert atmosphere according to the Formula (I)

  • MeFx+Me′yXz+heat   (I)
  • According to certain embodiments, the heat treatment of the metal fluoride and metal complex causes a reaction to form a new phase according to the formula (II)

  • MeFx+Me′yXz→MeaMe′bXcFd   (II)
  • where x, y, z, a, b, and c depend on the identity and valence of the Me, Me′, and X. In some instances, 0<a≦1, 0<b≦1, 0≦c≦1, and 0≦d≦1. In other embodiments, the heat treatment causes the formation of covalent bonds between the metal fluoride and the metal complex, improving conductivity and passivating the surface.
  • Suitable metal complexes, which can act as precursors for the reaction described herein, for use in synthesizing the active material include, but are not limited to, MoO3, MoO2, NiO, CuO, VO2, V2O5, TiO2, Al2O3, SiO2, LiFePO4, LiMeTPO4 (where MeT is one or more transition metal(s)), metal phosphates, and combinations thereof. According to embodiments of the invention, these oxides can be used in Formula (I).
  • It is understood that the synthetic route for achieving the active material may vary, and other such synthetic routes are within the scope of the disclosure. The material can be represented by MeaMe′bXcF and in the examples herein is embodied by a Cu3Mo2O9 active material. Other active materials are within the scope of this disclosure, for example, NiCuO2, Ni2CuO3, and Cu3TiO4.
  • The coating materials disclosed herein provide rechargeability to otherwise non-rechargeable metal fluoride materials. Without being bound by a particular theory or mechanism of action, the rechargeability may be due to the electrochemical properties of the novel hybrid material, the coating of the metal fluoride to prevent copper dissolution, or a more intimate interface between the metal fluoride and the coating material as a result of the heat treatment and reaction. Further, the novel hybrid material may provide a kinetic barrier to the Cu dissolution reaction, or to similar dissolution reactions for other metal fluoride materials to the extent such dissolution reactions occur in the cycling of electrochemical cells.
  • In the case of oxide-based hybrid materials, intimate mixing of the metal fluoride and the metal complex (or other suitable precursor material) and moderate heat treatment can be used to generate rechargeable electrode materials. Suitable coating precursors include materials that decompose to form metal oxides (and in particular, transition metal oxides) as opposed to using a metal oxide to directly react with the metal fluoride. Examples of such precursors include, but are not limited to, metal acetates, metal acetylacetonates, metal hydroxides, metal ethoxides, and other similar organo-metal complexes. In either event, the final rechargeable material is not necessarily a pure oxide or a purely crystalline material. The reaction of Formula II predicts that there would not be a pure oxide or a purely crystalline material. In some instances, the metal oxide precursor or metal oxide material can form a coating, or at least a partial coating, on the metal fluoride active material. Without being bound by a particular theory or mechanism of action, the reaction of the metal oxide precursor or metal oxide material with the surface of the metal fluoride (and in particular copper fluoride) active material is important for generating a rechargeable electrode active material.
    • EXAMPLES
  • The following examples describe specific aspects of some embodiments of the invention to illustrate and provide a description for those of ordinary skill in the art. The examples should not be construed as limiting the invention, as the examples merely provide specific methodology useful in understanding and practicing some embodiments of the invention.
    • Example 1 Fabrication of Hybrid and/or Coated Electrodes for Rechargeable Cells
  • Materials and Synthetic Methods. All reactions were prepared in a high purity argon filled glove box (M-Braun, O2 and humidity contents <0.1 ppm). Unless otherwise specified, materials were obtained from commercial sources (e.g., Sigma-Aldrich, Advanced Research Chemicals Inc., Alfa Aesar, Strem) without further purification.
  • Preparation of CuF2 Hybrid. Milling vessels were loaded with CuF2 at from about 85 wt % to about 95 wt % and reactant (metal oxide or metal oxide precursor) at from about 5 wt % to about 15 wt %, and the vessels were sealed. The mixture was milled. After milling, samples were annealed at from about 200 degrees C. to about 575 degrees C. for 1 to 12 hours under flowing N2. Specific hybrid-forming reactants were processed as described below.
  • Preparation of CuF2/Cu3Mo2O9. Milling vessels were loaded with CuF2 (85 wt %) and MoO3 (15 wt %), sealed, and then milled. After milling, samples were annealed at 450 degrees C. for 6 hours under flowing N2.
  • Preparation of CuF2/NiO. Milling vessels were loaded with CuF2 (85 wt %) and NiO (15 wt %), sealed, and then milled. After milling, samples were annealed at 325 degrees C. for 6 hours under flowing N2.
  • Preparation of CuF2/Nickel (II) acetylacetonate. A fine dispersion of CuF2 was prepared by milling in the presence of THF (40-120 mg CuF2/mL THF). The dispersed sample was then added to a solution of Ni(AcAc)2 in THF such that Nickel (II) acetylacetonate accounted for 15 wt % of the solids in the solution. The solution was then agitated by either shaking, sonication, or low energy milling for from about 1 to about 12 hours. The solution was then dried at room temperature under vacuum and the resulting solid was annealed at 450 degrees C. for 6 hours under dry air.
  • Preparation of Vapor Deposited Coatings The coating material (nickel metal) was vaporized and then physically condensed onto the substrate at 20 weight percent. X-ray diffraction measurements were performed on the coated material to confirm the bulk CuF2 was not altered. The coated material was then annealed similarly to materials prepared by other methods.
  • Preparation of Atomic Layer Deposited Coatings CuF2 was coated with TiO2 by atomic layer deposition methods. The expected coating thickness was about 8.5 nm based on ellipsometry measurements on a silicon witness sample, which represented a nominal 3 weight percent coating on the CuF2. The coated material was then annealed similarly to materials prepared by other methods.
  • Electrode Formulation. Cathodes were prepared using a formulation composition of 80:15:5 (active material:binder:conductive additive) according to the following formulation method: 133 mg PVDF (Sigma Aldrich) and about 44 mg Super P Li (Timcal) was dissolved in 10 mL NMP (Sigma Aldrich) overnight. 70 mg of coated composite powder was added to 1 mL of this solution and stirred overnight. Films were cast by dropping about 70 μL of slurry onto stainless steel current collectors and drying at 150 degrees C. for about 1 hour. Dried films were allowed to cool, and were then pressed at 1 ton/cm2. Electrodes were further dried at 150 degrees C. under vacuum for 12 hours before being brought into a glove box for battery assembly.
    • Example 2 Electrochemical Characterization of Electrochemical Cells Containing Rechargeable Electrodes
  • All batteries were assembled in a high purity argon filled glove box (M-Braun, O2 and humidity contents <0.1 ppm), unless otherwise specified. Cells were made using lithium as an anode, Celgard 2400 separator, and 90 μL of 1M LiPF6 in 1:2 EC:EMC electrolyte. Electrodes and cells were electrochemically characterized at 30 degrees C. with a constant current C/50 charge and discharge rate between 4.0 V and 2.0 V. A 3 hour constant voltage step was used at the end of each charge. In some instances, cathodes were lithiated pressing lithium foil to the electrode in the presence of electrolyte (1M LiPF6 in 1:2 EC:EMC) for about 15 minutes. The electrode was then rinsed with EMC and built into cells as described above, except graphite was used as the anode rather than lithium.
  • FIG. 1 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the second cycle discharge capacity of three different cathode formulations containing a LiFePO4 material is plotted as a function of LiFePO4 content (labeled LFP) in the cathode in FIG. 1. The dotted line depicts the theoretical capacity of LiFePO4. One cathode formulation is 100% LiFePO4. Another cathode formulation is a combination of CuF2 and LiFePO4 in which the content of LiFePO4 was varied from 10% to 50% of the total weight of conductive material. The third cathode formulation is a combination of CuF2 and the conventional conductive oxide MoO3 and LiFePO4 in which the content of LiFePO4 was varied from 10% to 50% of the total weight of conductive material. As this is second cycle data, FIG. 1 demonstrates that all of the CuF2/LiFePO4 matrices are rechargeable. In addition, the (CuF2/MoO3)/LiFePO4 hybrid cathode containing 50% LiFePO4 is also able to recharge. FIG. 1 further demonstrates a direct relationship between the capacity and the percent content of LiFePO4.
  • FIG. 2 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the voltage of a hybrid cathode is plotted against the capacity for the first and second cycles. The dashed line indicates the expected theoretical capacity from the LiFePO4 content in cathode. The cathode formulation is the CuF2 (70%)/LiFePO4 (30%) hybrid cathode from FIG. 1. During the first cycle, very little discharge capacity is observed, indicating that the LiFePO4 material is not capable of accepting charge on this cycle. Without being bound to a particular theory or mechanism of action, the LiFePO4 material may not accept charge as a result of defects introduced during milling. This data suggests that all of the capacity observed during the first and second cycles can be attributed solely to the CuF2.
  • FIG. 3 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the discharge capacity for cells with a range of LiFePO4 content is plotted as a function of cycle for 10 cycles. The cathode formulation is CuF2 with LiFePO4 content ranging from 10% to 50% of the total weight of conductive material. FIG. 4 demonstrates that the hybrid cathode is able to consistently recharge across a number of cycles. Based on data from FIG. 2, it is expected that the discharge capacity is contributed solely by CuF2 and not LiFePO4. This is a significant finding because CuF2 has not been previously shown to have such significant reversible capacity. The combination of certain conductive materials with CuF2 renders the CuF2 cathode material rechargeable.
  • FIG. 4 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the first and second cycle voltage traces for a cell containing a cathode formed from a metal fluoride and the new hybrid material. In this case, the metal fluoride active material is CuF2 and the hybrid material is Cu3Mo2O9. FIG. 4 demonstrates that the cell has about 140 mAh/g of reversible capacity. Previously known cathodes containing CuF2 have not demonstrated such significant reversible capacity.
  • FIG. 5 illustrates the results of structural characterization of certain embodiments disclosed herein. Specifically, the powder X-ray diffraction pattern of the material forming the cathode tested in FIG. 4 is shown along with the powder X-ray diffraction patterns of CuF2 and Cu3Mo2O9. FIG. 5 demonstrates that the material contains phases rich in CuF2 and phases rich in Cu3Mo2O9. Thus, FIG. 5 demonstrates a new hybrid material in combination with a metal fluoride active material. Further, grain size analysis of this powder X-ray diffraction data shows that the CuF2 has a grain size greater than 130 nm. This is a significant finding since such comparatively large particles were thought to be too large to provide good electrochemical performance.
  • For many of the rechargeable matrices described herein (and in particular for matrices including Mo, Ni, or Ti), the reactions described herein yield a new material at least at the surface of the particles of the metal fluoride active material. The novel material present at least at the surface of the particles of the metal fluoride active material is believed to provide many of the benefits disclosed herein.
  • FIG. 6 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the second cycle discharge capacity of CuF2 with various materials and annealing temperatures. FIG. 6 shows many oxide materials that provide recharge capability, demonstrated by capacities greater than 100 mAh/g.
  • Table 1 presents the results of further electrochemical characterization of certain embodiments disclosed herein. Table 1 shows that many metal oxide and metal oxide precursor starting materials can be used in the reactions described herein to yield rechargeable metal fluoride electrode materials. The materials in Table 1 include metal oxides, metal phosphates, metal fluorides, and precursors expected to decompose to oxides. In particular, nickel oxide showed excellent performance.
  • TABLE 1
    Electrochemical Characterization of Various Precursor Materials as a
    Function of Anneal Temperature
    Initial Capacity Reversible
    Precursor Annealing Temp (0.02 C, Cy1, Capacity (0.05 C,
    Material (C.) mAh/g) Cy2, mAh/g)
    None 200 181 30
    None 325 394 216
    None 450 247 61
    (NH4)H2PO4 200 307 5
    (NH4)H2PO4 325 406 178
    (NH4)H2PO4 450 397 0
    Al2O3 200 281 70
    Al2O3 325 348 107
    Al2O3 400 203 78
    AlF3 200 397 124
    AlF3 325 384 125
    AlF3 400 320 98
    AlPO4 200 410 115
    AlPO4 325 356 136
    AlPO4 450 284 74
    Bi2O3 200 128 32
    Bi2O3 325 89 34
    Bi2O3 400 103 36
    CaF2 200 301 86
    CaF2 325 310 107
    CaF2 400 282 125
    CaO 200 1 1
    CaO 325 138 27
    CaO 400 84 29
    Co3(PO4)2 200 323 93
    Co3(PO4)2 325 373 161
    Co3(PO4)2 450 382 126
    Co3O4 200 167 112
    Co3O4 325 216 132
    Co3O4 450 329 151
    Co3O4 575 310 134
    Cr2O3 200 223 88
    Cr2O3 325 234 132
    Cr2O3 450 227 102
    Cr2O3 575 184 70
    Fe Acetate 200 407 31
    Fe Acetate 325 431 11
    Fe Acetate 450 393 180
    Fe2O3 200 197 135
    Fe2O3 325 200 142
    Fe2O3 450 170 112
    Fe2O3 575 308 131
    FeF2 200 427 202
    FeF2 325 382 220
    FeF2 400 370 155
    FeF3 200 443 188
    FeF3 325 406 218
    FeF3 400 359 141
    FePO4 200 252 76
    FePO4 325 393 147
    FePO4 450 429 197
    In2O3 200 250 64
    In2O3 325 203 106
    In2O3 400 347 109
    La2O3 200 281 74
    La2O3 325 155 39
    La2O3 450 68 29
    La2O3 575 114 36
    Li2O 200 32 11
    Li2O 325 49 18
    Li2O 400 38 18
    Li3PO4 200 318 123
    Li3PO4 325 435 136
    Li3PO4 450 409 114
    LiCoPO4 200 372 97
    LiCoPO4 325 408 142
    LiCoPO4 450 338 136
    LiH2PO4 200 300 111
    LiH2PO4 325 423 149
    LiH2PO4 450 387 107
    LiMnPO4 200 351 77
    LiMnPO4 325 368 102
    LiMnPO4 450 397 178
    LiNiPO4 200 402 116
    LiNiPO4 325 396 191
    LiNiPO4 450 405 176
    MgF2 200 387 135
    MgF2 325 378 147
    MgF2 400 360 122
    MgO 200 313 181
    MgO 325 259 155
    MgO 400 198 126
    MnO 200 117 52
    MnO 325 130 65
    MnO 450 83 55
    MnO 575 59 38
    MnO2 200 120 76
    MnO2 325 123 57
    MnO2 450 242 150
    MnO2 575 104 69
    Mo Acetate 200 396 10
    Mo Acetate 325 433 17
    Mo Acetate 450 398 46
    Na2O 200 2 1
    Na2O 325 26 13
    Na2O 400 24 13
    Ni 200 345 197
    Ni 325 301 178
    Ni 400 302 158
    Ni 450 300 152
    Ni acac 200 425 56
    Ni acac 325 306 87
    Ni Acac 400 247 30
    Ni acac 450 362 172
    Ni acetate 200 397 148
    Ni acetate 325 376 46
    Ni acetate 350 370 191
    Ni acetate 400 383 180
    Ni acetate 450 371 186
    Ni acetate 500 373 171
    Ni3(PO4)2 200 410 124
    Ni3(PO4)2 325 430 52
    Ni3(PO4)2 450 126 44
    Ni(C2O2) 200 359 90
    Ni(C2O2) 325 395 195
    Ni(C2O2) 450 381 175
    Ni(CP)2 200 304 27
    Ni(CP)2 325 317 14
    Ni(CP)2 450 258 148
    Ni(OH)2 200 412 186
    Ni(OH)2 325 362 196
    Ni(OH)2 400 327 181
    Ni(OH)2 450 300 169
    NiBr2 200 125 0
    NiBr2 325 225 78
    NiBr2 400 244 113
    NiCO3*Ni(OH)2 200 380 17
    NiCO3*Ni(OH)2 325 359 215
    NiCO3*Ni(OH)2 450 317 184
    NiF2 200 367 121
    NiF2 325 395 207
    NiF2 400 411 170
    NiF2 450 396 177
    NiO 125 257 131
    NiO 200 403 222
    NiO 225 384 212
    NiO 250 385 221
    NiO 275 370 229
    NiO 300 335 175
    NiO 325 402 252
    NiO 350 365 209
    NiO 375 260 123
    NiO 400 371 200
    NiO 425 361 186
    NiO 450 386 183
    NiO 500 308 150
    NiO 575 319 112
    Sb2O3 200 111 34
    Sb2O3 325 147 37
    Sb2O3 400 223 104
    Sc2O3 200 359 159
    Sc2O3 325 293 159
    Sc2O3 400 84 33
    Sc2O3 450 150 68
    Sc2O3 575 55 17
    ScF3 200 400 178
    ScF3 325 387 174
    ScF3 400 243 100
    SiO2 200 1 1
    SiO2 325 114 28
    SiO2 400 230 92
    SnO2 200 210 48
    SnO2 325 182 68
    SnO2 400 133 65
    SrO 200 152 12
    SrO 325 66 16
    SrO 400 134 48
    Ta2O5 200 289 4
    Ta2O5 325 269 141
    Ta2O5 450 298 121
    Ta2O5 575 317 74
    Ti(OEt)4 200 438 21
    Ti(OEt)4 325 453 12
    Ti(OEt)4 450 353 5
    TiO2 225 322 150
    TiO2 250 309 169
    TiO2 275 262 162
    TiO2 300 199 127
    TiO2 325 322 173
    TiO2 350 327 187
    TiO2 375 120 77
    TiO2 400 359 199
    TiO2 425 345 194
    TiO2 450 353 169
    Y2O3 200 353 130
    Y2O3 325 279 104
    Y2O3 450 83 37
    Y2O3 575 80 30
    ZnF2 200 438 206
    ZnF2 325 372 191
    ZnF2 400 318 134
    ZnO 200 210 95
    ZnO 325 242 93
    ZnO 400 194 44
    ZnO 450 205 99
    ZnO 575 151 71
    ZrO2 200 302 122
    ZrO2 325 288 129
  • FIG. 7 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, the second cycle discharge capacity for cells containing a cathode formed from a metal fluoride and the precursor material treated at different temperatures. In this case, the metal fluoride active material is CuF2 and the precursor material is NiO. FIG. 7 shows a peak for cycle 2 capacity at about 325 degrees C. for NiO precursors, with nearly 250 mAh/g discharge capacity.
  • FIG. 8 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt % CuF2 with 15 wt % of certain metal oxides (in this case NiO or TiO2) at certain annealing temperatures. The mixtures were milled at high energy for about 20 hours. The anneal temperatures ranged from about 225 degrees C. to about 450 degrees C. and the anneal time was 6 hours. The 325 degree C. anneal temperature for the NiO starting material generated the best performance. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a rate of 0.02 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 9 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt % CuF2 with 15 wt % of certain metal oxides (in this case NiO or TiO2) for certain annealing times. The mixtures were milled at high energy for about 20 hours. The anneal temperature was 325 degrees C. and the anneal time was 1 hour, 6 hours, or 12 hours. The 6 hour anneal time yielded the best results for both the NiO and TiO2 starting materials, and the NiO starting material generated better performance. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a rate of 0.02 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 10 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, 90 wt %, or 95 wt % CuF2 with 5 wt %, 10 wt %, 15 wt % of NiO. The mixtures were milled at high energy for about 20 hours. The anneal temperature was 325 degrees C. and the anneal time was 6 hours. Using 10 wt % or 15 wt % of the NiO starting material generated better performance. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a rate of 0.02 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 11 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO. The mixtures were milled at various energies comparable to milling on a Fritch Pulverisette 7 Planatery Mill at 305, 445, 595, and 705 RPM for about 20 hours. The anneal temperature was 325 degrees C. and the anneal time was 6 hours. Performance improves with increasing milling energy, suggesting that intimate physical interaction of the materials is required. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a rate of 0.05 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 12 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO. The mixtures were milled for various times (3 hours, 20 hours, or 40 hours) at a high energy (comparable to 705 RPM on Fritch Pulverisette 7). The anneal temperature was 325 degrees C. and the anneal time was 6 hours. Performance does not improve after 20 hours of milling. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a rate of 0.05 C and over a voltage range of 2.0 V to 4.0 V.
  • FIG. 13 illustrates the results of electrochemical characterization of certain embodiments disclosed herein. Specifically, FIG. 13 shows the second cycle reversible capacity measured for various starting materials used to react with CuF2. The starting materials include NiO, nickel (II) acetylacetonate (Ni acac in Table 1), nickel acetate, nickel hydroxide, NiCO3*Ni(OH)2, Ni(C2O2), Ni(CP)2, and Ni. In some instances, the starting materials react to form a new phase. The materials react with the surface of the CuF2 particles. Additionally, the anneal atmosphere was either N2 or dry air. The precursor starting materials decompose to NiO (although this depends on the atmosphere for some precursors) at or below the annealing temperatures used for the reaction. The precursors that are soluble or have low boiling points can enable solution or vapor deposition processing methods. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a rate of 0.05 C and over a voltage range of 2.0 V to 4.0 V. Several materials show similar performance to the NiO baseline.
  • FIG. 14 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting CuF2 with nickel (II) acetylacetonate using various processing conditions. In some cases, the CuF2 was dispersed using methods described herein. The coatings were applied using mill coating techniques (that is, agitating the mixture in a milling apparatus) or by solution coating techniques (including solution coating driven by physisorption). All samples were annealed under dry air. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a rate of 0.05 C and over a voltage range of 2.0 V to 4.0 V. Testing demonstrates that solution coating methods can provide similar performance to the mill coating techniques.
  • FIG. 20 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the second-cycle capacity retention and reversible capacity for cathode active materials formed from reacting CuF2 with coatings formed from various coating methods and from various precursors. The precursors included NiO, Ni, TiO2, nickel (II) acetylacetonate, and nickel acetate. All five precursor types were applied according to the mill coating techniques (that is, agitating the mixture in a milling apparatus). Solution coating techniques were used for nickel (II) acetylacetonate, and nickel acetate. Physical vapor deposition (PVD) techniques were used to form a coating from Ni precursor, and atomic layer deposition (ALD) techniques were used to form a coating from TiO2. All samples were annealed under dry air. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a rate of 0.05 C and over a voltage range of 2.0 V to 4.0 V.
  • The solution, vapor, and atomic layer deposition methods can provide comparatively more uniform coatings on metal fluoride particles than the coatings obtained by milling methods. A comparatively thinner, more uniform coatings can provide the benefits of the coating material, such as more complete protection of the metal fluoride particle, with less precursor material. To the extent that excess precursor material is less active (and therefore less desirable) than the active material, thin, conformal coatings can provide an advantage in terms of weight-normalized reversible capacity.
  • FIG. 20 shows that although absolute reversible capacity was inferior for solution and vapor coatings as compared to milled coatings, the reversible capacity per weight percentage of coating was significantly improved. For example, for the TiO2 the atomic layer deposition coating method yielded greater than about 60% more reversible capacity per coating weight than the milled coating method. The ALD coated material had a coating that was about 8 nm thick and less than about 3 weight percent of the coated particle.
  • Notably, the non-milling coating methods shown in FIG. 20 (that is, the solution coating, vapor deposition, and atomic layer deposition methods) are compatible with a subset of the metal complexes disclosed herein. A variety of coating materials is possible with atomic layer deposition methods including metals (e.g., Ni), metal oxides (e.g., Al2O3, SiO2, Ta2O5, TiO2), metal nitrides (e.g., AlN, TaN), and others. Physical vapor deposition techniques can also deposit coatings of a wide number of materials including metals (e.g., Ni, Ba, Ta), metal oxides (e.g., SiO2, Ta2O5, TiO2, NiO), metal nitrides (e.g., TiN, AlN), metal silicates (e.g., ZrSiO4) or other materials that are volatile enough to be evaporated and re-condensed onto a substrate.
  • FIG. 15 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the capacity as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO and for a control material. The NiO/CuF2 mixture was milled at high energy for about 20 hours. The anneal temperature was 325 degrees C. and the anneal time was 6 hours. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a cycle 1 rate of 0.02 C, a cycle 2 rate of 0.05 C, and a cycle 3 through cycle 25 rate of 0.5 C and over a voltage range of 2.0 V to 4.0 V. With the reacted NiO/CuF2 as the active material, the cell cycles reversibly for extended cycling with capacity greater than 100 mAh/g for 25 cycles. Further, the reacted NiO/CuF2 active material demonstrates retention of 80% of cycle 3 capacity as far out as cycle 15. The control material, which was prepared according to the process described in Badway, F. et al., Chem. Mater., 2007, 19, 4129, does not demonstrate any rechargeable capacity. Thus, the material prepared according to embodiments described herein is significantly superior to known materials processed according to known methods.
  • FIG. 16 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, a galvanostatic intermittent titration technique (GITT) measurement for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO and for a control material. The NiO/CuF2 mixture was milled at high energy for about 20 hours. The anneal temperature was 325 degrees C. and the anneal time was 6 hours. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed over a voltage range of 2.0 V to 4.0 V at a rate of 0.1 C and with a 10 hour relaxation time. The GITT measurement relaxation points show low voltage hysteresis (about 100 mV), which indicate that the overpotential and/or underpotential are likely caused by kinetic and not thermodynamic limitations. This is consistent with other properties and characteristics observed for the reacted NiO/CuF2 active material.
  • FIG. 17 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the capacity of full cells and half cells as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO. The NiO/CuF2 mixture was milled at high energy for about 20 hours. The anneal temperature was 325 degrees C. and the anneal time was 6 hours. The label “Cu+2LiF” indicated that the NiO/CuF2 electrode was lithiated by pressing Li foil to CuF2 electrode in the presence of electrolyte as described above. The other half cell was lithiated electrochemically in the initial cycles. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed over a voltage range of 2.0 V to 4.0 V. Half cell performance is essentially identical between the two lithiation methods after cycle 2, while full cell shows additional irreversible capacity loss as compared to the half cells but similar capacity retention.
  • FIG. 18 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the voltage traces of the full cell and half cells prepared as described in relation to FIG. 17. The full cell has similar charge capacity to the half cells, but larger irreversible capacity loss and lower discharge voltage (which can indicate increased cell impedance). FIG. 18 demonstrates that the full cell has about 250 mAh/g of reversible capacity and about 500 mV hysteresis between charge and discharge plateau voltages.
  • FIG. 19 illustrates the results of electrochemical characterization of certain embodiments disclosed herein, specifically, the capacity retention of full cells and half cells as a function of cycle for cathode active materials formed from reacting 85 wt %, CuF2 with 15 wt % of NiO. The results from a control material are also depicted. The full cell and half cells were prepared as described in relation to FIG. 17. The cells used a Li anode and an electrolyte containing 1M LiPF6 in EC:EMC. The testing was performed at a cycle 1 rate of 0.1 C and over a voltage range of 2.0 V to 4.0 V. The capacity retention is essentially identical for the full and half cells of the NiO/CuF2 active material. The control material shows essentially no rechargeable capacity.
  • While the invention has been described with reference to the specific embodiments thereof, it should be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the true spirit and scope of the invention as defined by the appended claims. In addition, many modifications may be made to adapt a particular situation, material, composition of matter, method, or process to the objective, spirit and scope of the invention. All such modifications are intended to be within the scope of the claims appended hereto. In particular, while the methods disclosed herein have been described with reference to particular operations performed in a particular order, it will be understood that these operations may be combined, sub-divided, or re-ordered to form an equivalent method without departing from the teachings of the invention. Accordingly, unless specifically indicated herein, the order and grouping of the operations are not limitations of the invention.

Claims (20)

We claim:
1. A method of making an electrode, comprising:
coating particles, wherein each particle includes a metal fluoride material, with a coating precursor material, wherein the coating precursor material includes a transition metal;
annealing the particles such that at least a portion of the metal fluoride material and at least a portion of the transition metal react to undergo a phase change; and
forming the coated particles into an electrode.
2. The method of claim 1, wherein the electrode forming step comprises preparing a formulation composition of coated particles, binder, and conductive additive.
3. The method of claim 1, wherein the metal fluoride material comprises copper fluoride.
4. The method of claim 1, wherein the coating step comprising milling the particles with the coating precursor material.
5. The method of claim 4, wherein the coating precursor material comprises a organo-metal complex.
6. The method of claim 4, wherein the coating precursor material comprises a metal oxide.
7. The method of claim 4, wherein the coating precursor material comprises elemental metal.
8. The method of claim 4, wherein the coating precursor material comprises NiO.
9. The method of claim 4, wherein the coating precursor material comprises TiO2.
10. The method of claim 4, wherein the coating precursor material is Ni.
11. The method of claim 4, wherein the coating precursor material comprises nickel (II) acetylacetonate.
12. The method of claim 4, wherein the coating precursor material comprises nickel acetate.
13. The method of claim 1, wherein the coating step comprises a solution coating process.
14. The method of claim 13, wherein the coating precursor material comprises an organo-metal complex.
15. The method of claim 13, wherein the coating precursor material comprises nickel (II) acetylacetonate.
16. The method of claim 1, wherein the coating step comprises a physical vapor deposition process.
17. The method of claim 16, wherein the coating precursor material comprises a metal oxide.
18. The method of claim 16, wherein the coating precursor material comprises a metal nitride.
19. The method of claim 16, wherein the coating precursor material comprises a metal silicate.
20. The method of claim 16, wherein the coating precursor material is Ni or Ti.
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