Metal-Organic-Framework-Based Materials as Platforms for Renewable Energy and Environmental Applications

Joule

Volumn 1, Issue 1, 2017, Pages 77-107

  Zhang, Huabin ^a   Nai, Jianwei ^a   Yu, Le ^a  

^a David)   (Singapore)

Author keywords

battery; electrocatalysis; gas adsorption; metal organic frameworks; photocatalysis; solar cell; supercapacitor

Indexed keywords

ADSORPTION; CATALYSIS; CRYSTALLINE MATERIALS; ELECTROCATALYSIS; ENERGY CONVERSION; ENVIRONMENTAL ENGINEERING; FUNCTIONAL MATERIALS; GAS ADSORPTION; GASES; HYBRID MATERIALS; HYDROGEN STORAGE; METALS; ORGANIC POLYMERS; ORGANOMETALLICS; PHOTOCATALYSIS; POROSITY; SOLAR CELLS; SOLAR POWER GENERATION; STORAGE (MATERIALS); STRUCTURAL OPTIMIZATION; SUPERCAPACITOR;

BATTERY; DEVELOPMENT OF SCIENCE AND TECHNOLOGIES; ENVIRONMENTAL APPLICATIONS; ENVIRONMENTAL REMEDIATION; METAL ORGANIC FRAMEWORK; METALORGANIC FRAMEWORKS (MOFS); NOVEL FUNCTIONAL MATERIALS; POROUS COORDINATION POLYMER;

RENEWABLE ENERGY RESOURCES;

ADSORPTION; ALTERNATIVE ENERGY; COMPOSITE; ELECTROKINESIS; ELECTRONIC EQUIPMENT; GAS; PHOTOLYSIS; SCIENCE AND TECHNOLOGY;

EID: 85030163437     PISSN: None     EISSN: 25424351     Source Type: Journal    
DOI: 10.1016/j.joule.2017.08.008     Document Type: Review

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