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Publication DateJournal of the Electrochemical Society, ISSN 0013-4651, 2019, Volume 166, Issue 3, pp. A5184 - A5186
Electrode/electrolyte interphase in Li-ion batteries is a critical component that ensures reversible cell reactions far from thermodynamic equilibria. The...
ELECTROCHEMISTRY | SOLID-ELECTROLYTE INTERPHASE | STABILITY | PERFORMANCE | GRAPHITE | ANODES | SAFE | INTERCALATION | MATERIALS SCIENCE, COATINGS & FILMS | LITHIUM-ION
ELECTROCHEMISTRY | SOLID-ELECTROLYTE INTERPHASE | STABILITY | PERFORMANCE | GRAPHITE | ANODES | SAFE | INTERCALATION | MATERIALS SCIENCE, COATINGS & FILMS | LITHIUM-ION
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Loading RightsSolid State Ionics, ISSN 0167-2738, 10/2015, Volume 278, pp. 98 - 105
Interfacial reactions of solid electrolytes play an important role in all-solid-state batteries. The interface resistances—describing charge transfer between...
All-solid-state battery | Buried interfaces | In situ XPS | Interphase formation | Lithium metal anode | Interfacial reactions | PHYSICS, CONDENSED MATTER | INSERTION | MECHANISM | CHEMISTRY, PHYSICAL | IONIC-CONDUCTIVITY | BATTERIES | METALS | OXIDES | ANODE | Electrolytes | Spectrum analysis | Batteries | Interphase | Electronics | Lithium | Formations | Solid electrolytes | Interface reactions | Electric batteries | Deposition
All-solid-state battery | Buried interfaces | In situ XPS | Interphase formation | Lithium metal anode | Interfacial reactions | PHYSICS, CONDENSED MATTER | INSERTION | MECHANISM | CHEMISTRY, PHYSICAL | IONIC-CONDUCTIVITY | BATTERIES | METALS | OXIDES | ANODE | Electrolytes | Spectrum analysis | Batteries | Interphase | Electronics | Lithium | Formations | Solid electrolytes | Interface reactions | Electric batteries | Deposition
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Loading RightsJournal of Power Sources, ISSN 0378-7753, 01/2014, Volume 246, pp. 840 - 845
To understand the mechanism for preventing the shuttle in lithium–sulfur batteries, the SEI films formed in different electrolyte solutions are studied using...
Solid electrolyte interphase | Polysulfides | Lithium–sulfur batteries | Shuttle | Lithium nitrate | Lithium-sulfur batteries | ELECTROCHEMISTRY | ENERGY | PARTICLES | ENERGY & FUELS | PERFORMANCE | LIQUID | IMPEDANCE SPECTROSCOPY | MODEL | CATHODE MATERIAL | DISCHARGE | LI ELECTRODES | CAPACITY FADING MECHANISMS | Electrolytes | X-ray spectroscopy | Chemical properties | Batteries | Sulfates | Lithium compounds | Sulfides | Sulfur
Solid electrolyte interphase | Polysulfides | Lithium–sulfur batteries | Shuttle | Lithium nitrate | Lithium-sulfur batteries | ELECTROCHEMISTRY | ENERGY | PARTICLES | ENERGY & FUELS | PERFORMANCE | LIQUID | IMPEDANCE SPECTROSCOPY | MODEL | CATHODE MATERIAL | DISCHARGE | LI ELECTRODES | CAPACITY FADING MECHANISMS | Electrolytes | X-ray spectroscopy | Chemical properties | Batteries | Sulfates | Lithium compounds | Sulfides | Sulfur
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Loading RightsAdvanced Materials, ISSN 0935-9648, 03/2017, Volume 29, Issue 10, pp. 1605531 - n/a
An artificial solid electrolyte interphase (SEI) is demonstrated for the efficient and safe operation of a lithium metal anode. Composed of...
nanotechnology | porous lithium | lithium metal anodes | electrochemistry | artificial solid electrolyte interphase | MATRIX | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | DEPOSITION | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | COMPOSITE PROTECTIVE LAYER | NANOSCIENCE & NANOTECHNOLOGY | LIQUID ELECTROLYTE | BATTERIES | CHEMISTRY, MULTIDISCIPLINARY | ELECTROCHEMICAL-BEHAVIOR | CRYSTALS | Electrochemistry | Electrochemical reactions | Electrolytes | Nanotechnology | Electric properties | Conducting polymers | Ion flux | Interphase | Lithium | Anodes | Dendritic structure | Nanoparticles | Efficiency | Flux | Solid electrolytes | Flexibility
nanotechnology | porous lithium | lithium metal anodes | electrochemistry | artificial solid electrolyte interphase | MATRIX | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | DEPOSITION | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | COMPOSITE PROTECTIVE LAYER | NANOSCIENCE & NANOTECHNOLOGY | LIQUID ELECTROLYTE | BATTERIES | CHEMISTRY, MULTIDISCIPLINARY | ELECTROCHEMICAL-BEHAVIOR | CRYSTALS | Electrochemistry | Electrochemical reactions | Electrolytes | Nanotechnology | Electric properties | Conducting polymers | Ion flux | Interphase | Lithium | Anodes | Dendritic structure | Nanoparticles | Efficiency | Flux | Solid electrolytes | Flexibility
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Loading RightsJournal of the American Chemical Society, ISSN 0002-7863, 12/2017, Volume 139, Issue 51, pp. 18670 - 18680
Solid-electrolyte interphase (SEI) is the key component that enables all advanced electrochemical devices, the best representative of which is Li-ion battery...
CELLS | TRANSPORT | SOLVENTS | STABILITY | IMPEDANCE | CONCENTRATED ELECTROLYTES | ANODES | LITHIUM | HIGH-PRECISION | CHEMISTRY, MULTIDISCIPLINARY | LI-ION BATTERIES | Anions | Electrolyte solutions | Aqueous solution reactions | Analysis | bio-inspired, energy storage (including batteries and capacitors), defects, charge transport, synthesis (novel materials), synthesis (self-assembly), synthesis (scalable processing)
CELLS | TRANSPORT | SOLVENTS | STABILITY | IMPEDANCE | CONCENTRATED ELECTROLYTES | ANODES | LITHIUM | HIGH-PRECISION | CHEMISTRY, MULTIDISCIPLINARY | LI-ION BATTERIES | Anions | Electrolyte solutions | Aqueous solution reactions | Analysis | bio-inspired, energy storage (including batteries and capacitors), defects, charge transport, synthesis (novel materials), synthesis (self-assembly), synthesis (scalable processing)
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Loading RightsAngewandte Chemie International Edition, ISSN 1433-7851, 02/2018, Volume 57, Issue 6, pp. 1505 - 1509
Lithium (Li) metal is a promising anode material for high‐energy density batteries. However, the unstable and static solid electrolyte interphase (SEI) can be...
lithium dendrites | lithium ion batteries | solid electrolyte interphase | in situ AFM | lithium metal anodes | ELECTROCHEMISTRY | ION BATTERIES | RECHARGEABLE BATTERIES | SULFUR BATTERIES | PERFORMANCE | LIQUID | AIR | CHEMISTRY, MULTIDISCIPLINARY | CHALLENGES | POLYMER ELECTROLYTE | PROSPECTS | Electrolytes | Batteries | Stripping | Side reactions | Interphase | Metals | Elasticity | Lithium | Electrode materials | Flux density | Safety engineering | Dendrites | Solid electrolytes | Product safety | Anodes | Polyacrylic acid
lithium dendrites | lithium ion batteries | solid electrolyte interphase | in situ AFM | lithium metal anodes | ELECTROCHEMISTRY | ION BATTERIES | RECHARGEABLE BATTERIES | SULFUR BATTERIES | PERFORMANCE | LIQUID | AIR | CHEMISTRY, MULTIDISCIPLINARY | CHALLENGES | POLYMER ELECTROLYTE | PROSPECTS | Electrolytes | Batteries | Stripping | Side reactions | Interphase | Metals | Elasticity | Lithium | Electrode materials | Flux density | Safety engineering | Dendrites | Solid electrolytes | Product safety | Anodes | Polyacrylic acid
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Loading RightsNature Nanotechnology, ISSN 1748-3387, 2012, Volume 7, Issue 5, pp. 310 - 315
Although the performance of lithium ion-batteries continues to improve, their energy density and cycle life remain insufficient for applications in consumer...
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Loading RightsAdvanced Functional Materials, ISSN 1616-301X, 03/2018, Volume 28, Issue 13, pp. 1706513 - n/a
The “shuttle effect” that stems from the dissolution of polysulfides is the most fatal issue affecting the cycle life of lithium‐sulfur (Li–S) batteries. In...
shuttle effect | lithium sulfur batteries | separators | solid electrolyte interphases | HIGH-PERFORMANCE | ELECTROCHEMISTRY | GRAPHENE OXIDE | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | SEPARATOR | SULFUR BATTERIES | STABILITY | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | CHEMISTRY, MULTIDISCIPLINARY | CHALLENGES | INTERFACE | CARBONATE | FRAMEWORK | Sulfur compounds | Electrolytes | Batteries | Analysis | Spectrum analysis | Electric properties | Decay rate | Lithium fluoride | Conductivity | Ions | Lithium | Polysulfides | Ion diffusion | Diffusion layers | Solid electrolytes | Lithium ions | Diffusion coefficient | Dendritic structure | Electrochemical impedance spectroscopy
shuttle effect | lithium sulfur batteries | separators | solid electrolyte interphases | HIGH-PERFORMANCE | ELECTROCHEMISTRY | GRAPHENE OXIDE | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | SEPARATOR | SULFUR BATTERIES | STABILITY | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | CHEMISTRY, MULTIDISCIPLINARY | CHALLENGES | INTERFACE | CARBONATE | FRAMEWORK | Sulfur compounds | Electrolytes | Batteries | Analysis | Spectrum analysis | Electric properties | Decay rate | Lithium fluoride | Conductivity | Ions | Lithium | Polysulfides | Ion diffusion | Diffusion layers | Solid electrolytes | Lithium ions | Diffusion coefficient | Dendritic structure | Electrochemical impedance spectroscopy
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Loading RightsAdvanced Materials, ISSN 0935-9648, 11/2018, Volume 30, Issue 45, pp. e1804461 - n/a
Lithium‐metal electrodes have undergone a comprehensive renaissance to meet the requirements of high‐energy‐density batteries due to their lowest electrode...
mixed conductor interface | lithium‐metal anodes | lithium‐metal batteries | cupric fluoride | dendrite growth | lithium-metal batteries | lithium-metal anodes | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | SOLID-ELECTROLYTE INTERPHASE | HIGH-ENERGY | DEPOSITION | STABILITY | MATERIALS SCIENCE, MULTIDISCIPLINARY | LIQUID | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | IONIC-CONDUCTIVITY | CHEMISTRY, MULTIDISCIPLINARY | BATTERY SYSTEMS | DENSITY | LI-ION | CARBONATE | Electrolytes | Batteries | Ion currents | Lithium | Chemical reactions | Conductors | Modulus of elasticity | Nonaqueous electrolytes | Electrodes | Organic chemistry | Electrolytic cells | Anodic protection | Armor | Anode effect | Protective coatings | Dendritic structure
mixed conductor interface | lithium‐metal anodes | lithium‐metal batteries | cupric fluoride | dendrite growth | lithium-metal batteries | lithium-metal anodes | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | SOLID-ELECTROLYTE INTERPHASE | HIGH-ENERGY | DEPOSITION | STABILITY | MATERIALS SCIENCE, MULTIDISCIPLINARY | LIQUID | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | IONIC-CONDUCTIVITY | CHEMISTRY, MULTIDISCIPLINARY | BATTERY SYSTEMS | DENSITY | LI-ION | CARBONATE | Electrolytes | Batteries | Ion currents | Lithium | Chemical reactions | Conductors | Modulus of elasticity | Nonaqueous electrolytes | Electrodes | Organic chemistry | Electrolytic cells | Anodic protection | Armor | Anode effect | Protective coatings | Dendritic structure
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Loading RightsAdvanced Energy Materials, ISSN 1614-6832, 06/2018, Volume 8, Issue 16, pp. 1702724 - n/a
The intercalation of solvated sodium ions into graphite from ether electrolytes was recently discovered to be a surprisingly reversible process. The mechanisms...
cointercalation | sodium‐ion batteries | dilatometry | graphite | solid electrolyte interphases | sodium-ion batteries | AUXILIARY BASIS-SETS | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | CARBON | ANODE MATERIALS | ENERGY & FUELS | BEHAVIOR | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NONAQUEOUS ELECTROLYTES | INITIO MOLECULAR-DYNAMICS | LITHIUM-ION | ELECTROCHEMICAL INTERCALATION | Electrolytes | Batteries | Mass spectrometry | Analysis | Scanning electron microscopy | X-ray diffraction | Gas analysis | Intercalation | Electrodes | Dilatometry | Transmission electron microscopy | Sodium | Graphite | Solid electrolytes | Platelets
cointercalation | sodium‐ion batteries | dilatometry | graphite | solid electrolyte interphases | sodium-ion batteries | AUXILIARY BASIS-SETS | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | CARBON | ANODE MATERIALS | ENERGY & FUELS | BEHAVIOR | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NONAQUEOUS ELECTROLYTES | INITIO MOLECULAR-DYNAMICS | LITHIUM-ION | ELECTROCHEMICAL INTERCALATION | Electrolytes | Batteries | Mass spectrometry | Analysis | Scanning electron microscopy | X-ray diffraction | Gas analysis | Intercalation | Electrodes | Dilatometry | Transmission electron microscopy | Sodium | Graphite | Solid electrolytes | Platelets
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Loading RightsAngewandte Chemie International Edition, ISSN 1433-7851, 05/2017, Volume 56, Issue 20, pp. 5541 - 5545
The development of all‐solid‐state rechargeable batteries is plagued by a large interfacial resistance between a solid cathode and a solid electrolyte that...
interfacial resistances | solid-state batteries | plastic crystals | sodium batteries | solid electrolytes | LICOO2 ELECTRODE | PERFORMANCE | BEHAVIOR | CHEMISTRY, MULTIDISCIPLINARY | LITHIUM-ION BATTERY | CATHODE | TRANSPORT | INTERFACE | CONDUCTIVITY | POLYMER | ENERGY-STORAGE | Sodium | Interphase | Electrochemistry | Particulates | Electrolytes | Lithium | Batteries | Plastics | Rechargeable batteries
interfacial resistances | solid-state batteries | plastic crystals | sodium batteries | solid electrolytes | LICOO2 ELECTRODE | PERFORMANCE | BEHAVIOR | CHEMISTRY, MULTIDISCIPLINARY | LITHIUM-ION BATTERY | CATHODE | TRANSPORT | INTERFACE | CONDUCTIVITY | POLYMER | ENERGY-STORAGE | Sodium | Interphase | Electrochemistry | Particulates | Electrolytes | Lithium | Batteries | Plastics | Rechargeable batteries
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Loading RightsAdvanced Energy Materials, ISSN 1614-6832, 06/2018, Volume 8, Issue 17, pp. 1703082 - n/a
Sodium‐ion batteries (SIBs) as economical, high energy alternatives to lithium‐ion batteries (LIBs) have received significant attention for large‐scale energy...
anode solid electrolyte interphases | sodium‐ion batteries | interphase functionalities | cathode solid electrolyte interphases | sodium-ion batteries | HIGH-PERFORMANCE | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | SOLID-ELECTROLYTE INTERPHASE | ENERGY & FUELS | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | LITHIUM-ION | LI-ION | GRAPHITE ANODE | ETHER-BASED ELECTROLYTE | HARD-CARBON | ATOMIC-LAYER-DEPOSITION | HIGH-CAPACITY | NEGATIVE ELECTRODE | Electrochemistry | Electrochemical reactions | Electrolytes | Chemical properties | Batteries | Electrochemical analysis | Chemical reactions | Storage batteries | Electrodes | Lithium-ion batteries | Organic chemistry | Electrode materials | Solvation | Alternative energy sources | Sodium | Solid electrolytes | Energy storage
anode solid electrolyte interphases | sodium‐ion batteries | interphase functionalities | cathode solid electrolyte interphases | sodium-ion batteries | HIGH-PERFORMANCE | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | SOLID-ELECTROLYTE INTERPHASE | ENERGY & FUELS | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | LITHIUM-ION | LI-ION | GRAPHITE ANODE | ETHER-BASED ELECTROLYTE | HARD-CARBON | ATOMIC-LAYER-DEPOSITION | HIGH-CAPACITY | NEGATIVE ELECTRODE | Electrochemistry | Electrochemical reactions | Electrolytes | Chemical properties | Batteries | Electrochemical analysis | Chemical reactions | Storage batteries | Electrodes | Lithium-ion batteries | Organic chemistry | Electrode materials | Solvation | Alternative energy sources | Sodium | Solid electrolytes | Energy storage
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