posted on 2016-12-28, 00:00authored byKyoungsuk Jin, Hongmin Seo, Toru Hayashi, Mani Balamurugan, Donghyuk Jeong, Yoo Kyung Go, Jung Sug Hong, Kang Hee Cho, Hirotaka Kakizaki, Nadège Bonnet-Mercier, Min Gyu Kim, Sun Hee Kim, Ryuhei Nakamura, Ki Tae Nam
The development of
active water oxidation catalysts is critical
to achieve high efficiency in overall water splitting. Recently, sub-10
nm-sized monodispersed partially oxidized manganese oxide nanoparticles
were shown to exhibit not only superior catalytic performance for
oxygen evolution, but also unique electrokinetics, as compared to
their bulk counterparts. In the present work, the water-oxidizing
mechanism of partially oxidized MnO nanoparticles was investigated
using integrated in situ spectroscopic and electrokinetic analyses.
We successfully demonstrated that, in contrast to previously reported
manganese (Mn)-based catalysts, Mn(III) species are stably generated
on the surface of MnO nanoparticles via a proton-coupled electron
transfer pathway. Furthermore, we confirmed as to MnO nanoparticles
that the one-electron oxidation step from Mn(II) to Mn(III) is no
longer the rate-determining step for water oxidation and that Mn(IV)O
species are generated as reaction intermediates during catalysis.