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Publication DateAdvanced Energy Materials, ISSN 1614-6832, 12/2017, Volume 7, Issue 23, pp. 1700536 - n/a
The ever‐growing market of portable electronic devices and electric vehicles has significantly stimulated research interests on new‐generation rechargeable...
magnesium‐ion batteries | sodium‐ion batteries | dual‐ion batteries | aluminum‐ion batteries | metal anodes | zinc‐ion batteries | lithium‐ion batteries | Lithium-ion batteries | Metal anodes | Zinc-ion batteries | Sodium-ion batteries | Dual-ion batteries | Aluminum-ion batteries | Magnesium-ion batteries | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | ENERGY & FUELS | MATERIALS SCIENCE, MULTIDISCIPLINARY | aluminum-ion batteries | STRETCHABLE ELECTRONICS | CHEMISTRY, PHYSICAL | sodium-ion batteries | LIGHT-EMITTING-DIODES | INORGANIC ELECTRONIC MATERIALS | zinc-ion batteries | HIGH ELECTROCHEMICAL PERFORMANCE | SENSITIZED SOLAR-CELLS | lithium-ion batteries | dual-ion batteries | STATE FLEXIBLE SUPERCAPACITORS | ENERGY-STORAGE DEVICES | THIN-FILM TRANSISTORS | magnesium-ion batteries | ZINC-AIR BATTERY | Battery chargers | Electric vehicles | Magnesium | Electronic devices | Antimony | Lithium | Product design | Batteries | Intercalation | Zinc | Rechargeable batteries | Electrode materials | Flux density | Low cost | Design modifications | Market research | Portable equipment | Product safety | Anodes | Commercialization
magnesium‐ion batteries | sodium‐ion batteries | dual‐ion batteries | aluminum‐ion batteries | metal anodes | zinc‐ion batteries | lithium‐ion batteries | Lithium-ion batteries | Metal anodes | Zinc-ion batteries | Sodium-ion batteries | Dual-ion batteries | Aluminum-ion batteries | Magnesium-ion batteries | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | ENERGY & FUELS | MATERIALS SCIENCE, MULTIDISCIPLINARY | aluminum-ion batteries | STRETCHABLE ELECTRONICS | CHEMISTRY, PHYSICAL | sodium-ion batteries | LIGHT-EMITTING-DIODES | INORGANIC ELECTRONIC MATERIALS | zinc-ion batteries | HIGH ELECTROCHEMICAL PERFORMANCE | SENSITIZED SOLAR-CELLS | lithium-ion batteries | dual-ion batteries | STATE FLEXIBLE SUPERCAPACITORS | ENERGY-STORAGE DEVICES | THIN-FILM TRANSISTORS | magnesium-ion batteries | ZINC-AIR BATTERY | Battery chargers | Electric vehicles | Magnesium | Electronic devices | Antimony | Lithium | Product design | Batteries | Intercalation | Zinc | Rechargeable batteries | Electrode materials | Flux density | Low cost | Design modifications | Market research | Portable equipment | Product safety | Anodes | Commercialization
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Loading RightsAdvanced Materials, ISSN 0935-9648, 01/2018, Volume 30, Issue 4, p. n/a
Under development for next‐generation wearable electronics are flexible, knittable, and wearable energy‐storage devices with high energy density that can be...
cobalt oxides | atomically thin hybrid nanosheets | knittable | wearable electronics | zinc–air batteries | HYDROGEN EVOLUTION REACTIONS | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | CARBON | MATERIALS SCIENCE, MULTIDISCIPLINARY | zinc-air batteries | CHEMISTRY, PHYSICAL | WATER OXIDATION | NANOSCIENCE & NANOTECHNOLOGY | OXYGEN REDUCTION REACTION | CHEMISTRY, MULTIDISCIPLINARY | ELECTROCATALYSTS | HIGH ELECTROCHEMICAL PERFORMANCE | 2-DIMENSIONAL CRYSTALS | COBALT OXIDE | DOPED GRAPHENE | IN-SITU | Zinc products | Catalysts | Graphene | Electrochemistry | Oxides | Batteries | Cobalt | Computer storage devices | Electrochemical analysis | Electronic devices | Deformation | Short circuits | Ruthenium oxide | Cobalt oxides | Nanostructure | Nitrogen | Textiles | Thin films | Flux density | Zinc-oxygen batteries | Metal air batteries | Catalysis | Energy storage | Wearable technology | MATERIALS SCIENCE
cobalt oxides | atomically thin hybrid nanosheets | knittable | wearable electronics | zinc–air batteries | HYDROGEN EVOLUTION REACTIONS | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | CARBON | MATERIALS SCIENCE, MULTIDISCIPLINARY | zinc-air batteries | CHEMISTRY, PHYSICAL | WATER OXIDATION | NANOSCIENCE & NANOTECHNOLOGY | OXYGEN REDUCTION REACTION | CHEMISTRY, MULTIDISCIPLINARY | ELECTROCATALYSTS | HIGH ELECTROCHEMICAL PERFORMANCE | 2-DIMENSIONAL CRYSTALS | COBALT OXIDE | DOPED GRAPHENE | IN-SITU | Zinc products | Catalysts | Graphene | Electrochemistry | Oxides | Batteries | Cobalt | Computer storage devices | Electrochemical analysis | Electronic devices | Deformation | Short circuits | Ruthenium oxide | Cobalt oxides | Nanostructure | Nitrogen | Textiles | Thin films | Flux density | Zinc-oxygen batteries | Metal air batteries | Catalysis | Energy storage | Wearable technology | MATERIALS SCIENCE
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Loading RightsAdvanced Materials, ISSN 0935-9648, 02/2019, Volume 31, Issue 6, pp. 1970043 - n/a
A semiconductor rich in oxygen vacancies is introduced by Zhengyu Bai, Zhongwei Chen, and co‐workers in article number 1806761 to design an efficient and...
bifunctional catalysts | oxygen evolution reaction | metal–support interactions | oxygen vacancies | zinc–air batteries | Zinc products | Batteries
bifunctional catalysts | oxygen evolution reaction | metal–support interactions | oxygen vacancies | zinc–air batteries | Zinc products | Batteries
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Loading RightsAdvanced Materials, ISSN 0935-9648, 10/2017, Volume 29, Issue 37, pp. 1703185 - n/a
Rechargeable flexible solid Zn‐air battery, with a high theoretical energy density of 1086 Wh kg−1, is among the most attractive energy technologies for future...
bifunctional electrocatalysts | oxygen reduction reaction | defect engineering | zinc‐air batteries | zinc-air batteries | Zinc compounds | Energy efficiency | Batteries | Graphene | Energy technology | Flux density | Zinc-oxygen batteries | Metal air batteries | Reaction kinetics | Chemical evolution | Scaffolds | Open circuit voltage | Defects | Rechargeable batteries | Wearable technology
bifunctional electrocatalysts | oxygen reduction reaction | defect engineering | zinc‐air batteries | zinc-air batteries | Zinc compounds | Energy efficiency | Batteries | Graphene | Energy technology | Flux density | Zinc-oxygen batteries | Metal air batteries | Reaction kinetics | Chemical evolution | Scaffolds | Open circuit voltage | Defects | Rechargeable batteries | Wearable technology
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Loading RightsAdvanced Materials, ISSN 0935-9648, 09/2017, Volume 29, Issue 35, pp. 1702327 - n/a
Bifunctional electrocatalysis for oxygen evolution reaction (OER) and oxygen reduction reaction (ORR) constitutes the bottleneck of various sustainable energy...
oxygen evolution reaction | layered double hydroxides | Zn–air batteries | CoFe hydroxysulfides | bifunctional air cathodes | oxygen reduction reaction | ASSISTED SYNTHESIS | GRAPHENE OXIDE | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | CHEMISTRY, MULTIDISCIPLINARY | EFFICIENT ELECTROCATALYST | ENERGY-CONVERSION | REDUCTION | NANOCARBON | NITROGEN | NANOWIRES | Zn-air batteries | CATALYSTS | Zinc compounds | Hydroxides | Electrical conductivity | Batteries | Hydrogen | Hydrogen storage | Electrocatalysts | Sulfurization | Rechargeable batteries | Electrodes | Electrocatalysis | Electronic structure | Zinc-oxygen batteries | Electrical resistivity | Platinum | Metal air batteries | Iridium | Room temperature
oxygen evolution reaction | layered double hydroxides | Zn–air batteries | CoFe hydroxysulfides | bifunctional air cathodes | oxygen reduction reaction | ASSISTED SYNTHESIS | GRAPHENE OXIDE | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | CHEMISTRY, MULTIDISCIPLINARY | EFFICIENT ELECTROCATALYST | ENERGY-CONVERSION | REDUCTION | NANOCARBON | NITROGEN | NANOWIRES | Zn-air batteries | CATALYSTS | Zinc compounds | Hydroxides | Electrical conductivity | Batteries | Hydrogen | Hydrogen storage | Electrocatalysts | Sulfurization | Rechargeable batteries | Electrodes | Electrocatalysis | Electronic structure | Zinc-oxygen batteries | Electrical resistivity | Platinum | Metal air batteries | Iridium | Room temperature
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Loading RightsAdvanced Materials, ISSN 0935-9648, 02/2017, Volume 29, Issue 7, pp. 1604685 - n/a
Zinc–air batteries have attracted much attention and received revived research efforts recently due to their high energy density, which makes them a promising...
bifunctional air electrodes | reversible zinc electrodes | electrically rechargeable | zinc–air batteries | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | SIZE-DEPENDENT ACTIVITY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | OXYGEN REDUCTION REACTION | SULFUR-DOPED GRAPHENE | CHEMISTRY, MULTIDISCIPLINARY | NICKEL-OXIDE CELLS | ZN SECONDARY BATTERIES | NEGATIVE ELECTRODE MATERIALS | METAL-FREE ELECTROCATALYST | ALKALINE FUEL-CELLS | ELECTROCHEMICAL WATER OXIDATION | SUPERIOR BIFUNCTIONAL ELECTROCATALYSTS | Zinc products | Raw materials | Batteries | Life span | Flux density | Zinc-oxygen batteries | Low cost | Metal air batteries | Rechargeable batteries | Recommendations | Electronics | Energy density | Devices
bifunctional air electrodes | reversible zinc electrodes | electrically rechargeable | zinc–air batteries | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | MATERIALS SCIENCE, MULTIDISCIPLINARY | SIZE-DEPENDENT ACTIVITY | CHEMISTRY, PHYSICAL | NANOSCIENCE & NANOTECHNOLOGY | OXYGEN REDUCTION REACTION | SULFUR-DOPED GRAPHENE | CHEMISTRY, MULTIDISCIPLINARY | NICKEL-OXIDE CELLS | ZN SECONDARY BATTERIES | NEGATIVE ELECTRODE MATERIALS | METAL-FREE ELECTROCATALYST | ALKALINE FUEL-CELLS | ELECTROCHEMICAL WATER OXIDATION | SUPERIOR BIFUNCTIONAL ELECTROCATALYSTS | Zinc products | Raw materials | Batteries | Life span | Flux density | Zinc-oxygen batteries | Low cost | Metal air batteries | Rechargeable batteries | Recommendations | Electronics | Energy density | Devices
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Loading RightsAdvanced Functional Materials, ISSN 1616-301X, 01/2018, Volume 28, Issue 5, pp. 1705048 - n/a
Here first a 2D dual‐metal (Co/Zn) and leaf‐like zeolitic imidazolate framework (ZIF‐L)‐pyrolysis approach is reported for the low‐cost and facile preparation...
cobalt–nitrogen–carbon nanotubes | 2D and leaf‐like zeolitic imidazolate frameworks | rechargeable zinc–air batteries | bifunctional air electrodes | 2D and leaf-like zeolitic imidazolate frameworks | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | SUPERCAPACITORS | PERFORMANCE | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | ELECTROCATALYST | NANOSCIENCE & NANOTECHNOLOGY | OXYGEN REDUCTION REACTION | CHEMISTRY, MULTIDISCIPLINARY | cobalt-nitrogen-carbon nanotubes | NANOPARTICLES | rechargeable zinc-air batteries | POROUS CARBON NANOSHEETS | NITROGEN | FRAMEWORK | NANOTUBES | CATALYSTS | Electrodes | Pyrolysis | Chemical properties | Batteries | Cobalt | Zinc | Encapsulation | Electrochemical analysis | Nanotubes | Carbon nanotubes | Nanomaterials | Nitrogen | Rechargeable batteries | Nanoparticles | Zinc-oxygen batteries | Platinum | Metal air batteries | Metal-organic frameworks | Tips
cobalt–nitrogen–carbon nanotubes | 2D and leaf‐like zeolitic imidazolate frameworks | rechargeable zinc–air batteries | bifunctional air electrodes | 2D and leaf-like zeolitic imidazolate frameworks | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | SUPERCAPACITORS | PERFORMANCE | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | ELECTROCATALYST | NANOSCIENCE & NANOTECHNOLOGY | OXYGEN REDUCTION REACTION | CHEMISTRY, MULTIDISCIPLINARY | cobalt-nitrogen-carbon nanotubes | NANOPARTICLES | rechargeable zinc-air batteries | POROUS CARBON NANOSHEETS | NITROGEN | FRAMEWORK | NANOTUBES | CATALYSTS | Electrodes | Pyrolysis | Chemical properties | Batteries | Cobalt | Zinc | Encapsulation | Electrochemical analysis | Nanotubes | Carbon nanotubes | Nanomaterials | Nitrogen | Rechargeable batteries | Nanoparticles | Zinc-oxygen batteries | Platinum | Metal air batteries | Metal-organic frameworks | Tips
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Loading RightsAdvanced Materials, ISSN 0935-9648, 01/2018, Volume 30, Issue 4, p. n/a
Knittable fiber‐shaped zinc–air batteries based on atomically thin mesoporous Co3O4 layers strongly coupled with nitrogen‐doped reduced graphene oxide...
cobalt oxides | atomically thin hybrid nanosheets | knittable | wearable electronics | zinc–air batteries | Cobalt | Zinc products | Batteries | Thin films | Electronic devices | Power supplies | Zinc-oxygen batteries | Catalysts | Metal air batteries | Cobalt oxides | Nanostructure | Catalysis | Nitrogen
cobalt oxides | atomically thin hybrid nanosheets | knittable | wearable electronics | zinc–air batteries | Cobalt | Zinc products | Batteries | Thin films | Electronic devices | Power supplies | Zinc-oxygen batteries | Catalysts | Metal air batteries | Cobalt oxides | Nanostructure | Catalysis | Nitrogen
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Loading RightsAdvanced Materials, ISSN 0935-9648, 08/2016, Volume 28, Issue 30, pp. 6420 - 6420
On page 6421, Z. Chen and co‐workers describe an electrically rechargeable, nanoarchitectured air electrode that morphologically emulates a human‐hair array...
bifunctional air electrodes | flexible zinc‐air batteries | solid‐state | cobalt oxide | solid-state | flexible zinc-air batteries | Electrodes | Electric Power Supplies | Biomimetics | Stainless Steel | Humans | Oxygen - chemistry | Water - chemistry | Hair - anatomy & histology | Air | Catalysis | Zinc - chemistry | Zinc products | Batteries
bifunctional air electrodes | flexible zinc‐air batteries | solid‐state | cobalt oxide | solid-state | flexible zinc-air batteries | Electrodes | Electric Power Supplies | Biomimetics | Stainless Steel | Humans | Oxygen - chemistry | Water - chemistry | Hair - anatomy & histology | Air | Catalysis | Zinc - chemistry | Zinc products | Batteries
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Loading RightsAdvanced Materials, ISSN 0935-9648, 12/2017, Volume 29, Issue 47, pp. 1704681 - n/a
The development of highly active and stable oxygen evolution reaction (OER) electrocatalysts is crucial for improving the efficiency of water splitting and...
interface catalysis | Zn–air batteries | water splitting | porous nanowires | oxygen vacancies | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | OXIDE | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSHEETS | NANOSCIENCE & NANOTECHNOLOGY | CHEMISTRY, MULTIDISCIPLINARY | HIGHLY EFFICIENT | ELECTROCATALYSTS | ARRAYS | ATOMIC-STRUCTURE | ENERGY-CONVERSION | BIFUNCTIONAL CATALYST | SURFACE | ELECTRODE | Zn-air batteries | Zinc compounds | Electrochemical reactions | Batteries | Catalysis | Zinc | Electric properties | Water splitting | Vacancies | Electrocatalysts | Chemical reactions | Devices | Open circuit voltage | Rechargeable batteries | Zinc-oxygen batteries | Nickel sulfide | Metal air batteries | Portable equipment | Nanowires | Chemical evolution | Cathodes
interface catalysis | Zn–air batteries | water splitting | porous nanowires | oxygen vacancies | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | OXIDE | MATERIALS SCIENCE, MULTIDISCIPLINARY | CHEMISTRY, PHYSICAL | NANOSHEETS | NANOSCIENCE & NANOTECHNOLOGY | CHEMISTRY, MULTIDISCIPLINARY | HIGHLY EFFICIENT | ELECTROCATALYSTS | ARRAYS | ATOMIC-STRUCTURE | ENERGY-CONVERSION | BIFUNCTIONAL CATALYST | SURFACE | ELECTRODE | Zn-air batteries | Zinc compounds | Electrochemical reactions | Batteries | Catalysis | Zinc | Electric properties | Water splitting | Vacancies | Electrocatalysts | Chemical reactions | Devices | Open circuit voltage | Rechargeable batteries | Zinc-oxygen batteries | Nickel sulfide | Metal air batteries | Portable equipment | Nanowires | Chemical evolution | Cathodes
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