A microbial-mineralization-inspired approach for synthesis of manganese oxide nanostructures with controlled oxidation states and morphologies

Advanced Functional Materials

Volumn 20, Issue 24, 2010, Pages 4279-4286

  Oba, Manabu ^a   Oaki, Yuya ^a   Imai, Hiroaki ^a  

^a KEIO UNIVERSITY   (Japan)

Author keywords

batteries; biomimetic processes; biomineralization; manganese oxides; nanostructures

Indexed keywords

AQUEOUS SOLUTIONS; ASCORBIC ACIDS; BATTERIES; BIOMIMETIC PROCESSES; BIRNESSITE; CATHODE MATERIALS; CHELATING AGENT; CONTROLLED OXIDATIONS; DRIED POWDER; LITHIUM-ION BATTERY; MANGANESE HYDROXIDE; MANGANESE IONS; MANGANESE OXYHYDROXIDE; MICROBIAL MINERALIZATION; ORGANIC MOLECULES; OVEROXIDATIONS; OXIDATION STATE; OXIDE NANOSTRUCTURES; PARALLEL CONTROL; POTENTIAL APPLICATIONS; ROOM TEMPERATURE; SELECTIVE FORMATION; SYNTHETIC ROUTES; TRANSITION-METAL OXIDES;

BIOMIMETICS; BIOMINERALIZATION; CATHODES; CHELATION; KETONES; LEAD OXIDE; LITHIUM; LITHIUM COMPOUNDS; MANGANESE; MINERALOGY; MOLECULES; MORPHOLOGY; NANOSTRUCTURES; OCEAN HABITATS; ORGANIC ACIDS; OXIDATION; REACTION INTERMEDIATES; SOLUTIONS; TRANSITION METAL COMPOUNDS;

MANGANESE OXIDE;

EID: 78650360696     PISSN: 1616301X     EISSN: 16163028     Source Type: Journal    
DOI: 10.1002/adfm.201000361     Document Type: Article

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