A molecular approach to self-supported cobalt-substituted ZnO materials as remarkably stable electrocatalysts for water oxidation

Johannes Pfrommer; Michael Lublow; Anahita Azarpira; Caren Göbel; Marcel Lücke; Alexander Steigert; Martin Pogrzeba; Prashanth W Menezes; Anna Fischer; Thomas Schedel-Niedrig; Matthias Driess

doi:10.1002/anie.201400243

A molecular approach to self-supported cobalt-substituted ZnO materials as remarkably stable electrocatalysts for water oxidation

Angew Chem Int Ed Engl. 2014 May 12;53(20):5183-7. doi: 10.1002/anie.201400243. Epub 2014 Apr 28.

Authors

Johannes Pfrommer¹, Michael Lublow, Anahita Azarpira, Caren Göbel, Marcel Lücke, Alexander Steigert, Martin Pogrzeba, Prashanth W Menezes, Anna Fischer, Thomas Schedel-Niedrig, Matthias Driess

Affiliation

¹ Department of Chemistry, Technische Universität Berlin, Strasse des 17. Juni 135, 10623 Berlin (Germany).

PMID: 24777630
DOI: 10.1002/anie.201400243

Abstract

In regard to earth-abundant cobalt water oxidation catalysts, very recent findings show the reorganization of the materials to amorphous active phases under catalytic conditions. To further understand this concept, a unique cobalt-substituted crystalline zinc oxide (Co:ZnO) precatalyst has been synthesized by low-temperature solvolysis of molecular heterobimetallic Co(4-x)Zn(x) O4 (x = 1-3) precursors in benzylamine. Its electrophoretic deposition onto fluorinated tin oxide electrodes leads after oxidative conditioning to an amorphous self-supported water-oxidation electrocatalyst, which was observed by HR-TEM on FIB lamellas of the EPD layers. The Co-rich hydroxide-oxidic electrocatalyst performs at very low overpotentials (512 mV at pH 7; 330 mV at pH 12), while chronoamperometry shows a stable catalytic current over several hours.

Keywords: amorphous materials; electrocatalysis; heterogeneous catalysis; self-activation; water oxidation.