Phase-controllable synthesis of cobalt hydroxide for electrocatalytic oxygen evolution
Identification of active sites for oxygen evolution reaction (OER) plays a key role in the
design and fabrication of high-performance cobalt-based electrocatalysts. Herein, we report
the synthesis of two types of two-dimensional monometallic cobalt hydroxide nanoplates in
aqueous solution for OER: α-Co (OH) 2 with both Co2+ Td and Co2+ Oh sites and β-Co
(OH) 2 with Co2+ Oh sites. Electrochemical characterization reveals that α-Co (OH) 2 is
more active than β-Co (OH) 2 towards OER. The better activity can be attributed to the …
design and fabrication of high-performance cobalt-based electrocatalysts. Herein, we report
the synthesis of two types of two-dimensional monometallic cobalt hydroxide nanoplates in
aqueous solution for OER: α-Co (OH) 2 with both Co2+ Td and Co2+ Oh sites and β-Co
(OH) 2 with Co2+ Oh sites. Electrochemical characterization reveals that α-Co (OH) 2 is
more active than β-Co (OH) 2 towards OER. The better activity can be attributed to the …
Identification of active sites for oxygen evolution reaction (OER) plays a key role in the design and fabrication of high-performance cobalt-based electrocatalysts. Herein, we report the synthesis of two types of two-dimensional monometallic cobalt hydroxide nanoplates in aqueous solution for OER: α-Co(OH)2 with both Co2+Td and Co2+Oh sites and β-Co(OH)2 with Co2+Oh sites. Electrochemical characterization reveals that α-Co(OH)2 is more active than β-Co(OH)2 towards OER. The better activity can be attributed to the presence of Co2+Td sites in α-Co(OH)2, which are more active than Co2+Oh sites. Our finding clarifies the contribution of the two catalytic sites and helps future rational design of high-performance OER electrocatalysts.
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