Filling the oxygen vacancies in Co 3 O 4 with phosphorus: an ultra-efficient electrocatalyst for overall water splitting

• Published in: Energy & environmental science Vol. 10; no. 12; pp. 2563 - 2569
• Main Authors: Xiao, Zhaohui, Wang, Yu, Huang, Yu-Cheng, Wei, Zengxi, Dong, Chung-Li, Ma, Jianmin, Shen, Shaohua, Li, Yafei, Wang, Shuangyin
• Format: Journal Article
• Language: English
• Published: 2017
• ISSN: 1754-5692; 1754-5706
• DOI: 10.1039/C7EE01917C

It is of essential importance to design an electrocatalyst with excellent performance for both hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) in water splitting. Co 3 O 4 has been developed as a highly efficient OER electrocatalyst, but it has almost no activity for HER. In a previous study, it has been demonstrated that the formation of oxygen vacancies (V O ) in Co 3 O 4 can significantly enhance the OER activity. However, the stability of V O needs to be considered, especially under the highly oxidizing conditions of the OER process. It is a big challenge to stabilize the V O in Co 3 O 4 while reserving the excellent activity. Filling the oxygen vacancies with heteroatoms in the V O -rich Co 3 O 4 may be a smart strategy to stabilize the V O by compensating the coordination numbers and obtain an even surprising activity due to the modification of electronic properties by heteroatoms. Herein, we successfully transformed V O -rich Co 3 O 4 into an HER-OER electrocatalyst by filling the in situ formed V O in Co 3 O 4 with phosphorus (P-Co 3 O 4 ) by treating Co 3 O 4 with Ar plasma in the presence of a P precursor. The relatively lower coordination numbers in V O -Co 3 O 4 than those in pristine Co 3 O 4 were evidenced by X-ray adsorption spectroscopy, indicating that the oxygen vacancies were created after Ar plasma etching. On the other hand, the relatively higher coordination numbers in P-Co 3 O 4 than those in V O -Co 3 O 4 and nearly same coordination number as that in pristine Co 3 O 4 strongly suggest the efficient filling of P in the vacancies by treatment with Ar plasma in the presence of a P precursor. The Co–O bonds in Co 3 O 4 consist of octahedral Co 3+ (O h )–O and tetrahedral Co 2+ (T d )–O (Oh, octahedral coordination by six oxygen atoms and T d , tetrahedral coordination by four oxygen atoms). More Co 3+ (O h )–O are broken when oxygen vacancies are formed in V O -Co 3 O 4 , and more electrons enter the octahedral Co 3d orbital than those entering the tetrahedral Co 3d orbital. Then, with the filling of P in the vacancy site, electrons are transferred out of the Co 3d states, and more Co 2+ (T d ) than Co 3+ (O h ) are left in P-Co 3 O 4 . These results suggest that the favored catalytic ability of P-Co 3 O 4 is dominated by the Co 2+ (T d ) site. P-Co 3 O 4 shows superior electrocatalytic activities for HER and OER (among the best non-precious metal catalysts). Owing to its superior efficiency, P-Co 3 O 4 can directly catalyze overall water splitting with excellent performance. The theoretical calculations illustrated that the improved electrical conductivity and intermediate binding by P-filling contributed significantly to the enhanced HER and OER activity of Co 3 O 4 .