School of Materials Science and Engineering, Nanyang Technological University, 50 Nanyang Avenue, Singapore, 639798, Singapore.
Institute of Chemical and Engineering Sciences A*STAR, 1 Pesek Road, Singapore, 627833, Singapore.
Adv Mater. 2018 Aug;30(32):e1802912. doi: 10.1002/adma.201802912. Epub 2018 Jun 25.
Cobalt-containing spinel oxides are promising electrocatalysts for the oxygen evolution reaction (OER) owing to their remarkable activity and durability. However, the activity still needs further improvement and related fundamentals remain untouched. The fact that spinel oxides tend to form cation deficiencies can differentiate their electrocatalysis from other oxide materials, for example, the most studied oxygen-deficient perovskites. Here, a systematic study of spinel ZnFe Co O oxides (x = 0-2.0) toward the OER is presented and a highly active catalyst superior to benchmark IrO is developed. The distinctive OER activity is found to be dominated by the metal-oxygen covalency and an enlarged CoO covalency by 10-30 at% Fe substitution is responsible for the activity enhancement. While the pH-dependent OER activity of ZnFe Co O (the optimal one) indicates decoupled proton-electron transfers during the OER, the involvement of lattice oxygen is not considered as a favorable route because of the downshifted O p-band center relative to Fermi level governed by the spinel's cation deficient nature.
含钴尖晶石氧化物因其显著的活性和耐久性而成为氧析出反应 (OER) 的有前途的电催化剂。然而,其活性仍需进一步提高,相关基础研究仍未涉及。尖晶石氧化物倾向于形成阳离子缺陷这一事实可以将其电催化作用与其他氧化物材料区分开来,例如研究最多的氧缺陷钙钛矿。本文对尖晶石 ZnFe Co O 氧化物(x = 0-2.0)进行了系统的 OER 研究,并开发出了一种优于基准 IrO 的高活性催化剂。研究发现,独特的 OER 活性主要由金属-氧共价键决定,Fe 取代 10-30 at%可扩大 Co-O 共价键,从而提高了活性。而 ZnFe Co O(最佳)的 pH 依赖性 OER 活性表明在 OER 过程中质子-电子转移解耦,由于尖晶石的阳离子缺陷性质导致 O p 带中心相对于费米能级下移,晶格氧的参与并不是一个有利的途径。
