Solution Process–Based Facile Flame–Boosted Low‐Valence Transition Metal Doping on Pristine Oxide for Highly Enhanced Photoelectrochemical Solar Water Oxidation Reaction
Seung Hun Roh,
Eujin Kwak,
Won Tae Hong,
Chengkai Xia,
Sungsoon Kim,
Heeyeop Chae,
Xu Yu,
Wooseok Yang,
Jongwook Park,
Jung Kyu Kim
Affiliations
Seung Hun Roh
School of Chemical EngineeringSungkyunkwan University (SKKU)Suwon Republic of Korea
Eujin Kwak
School of Chemical EngineeringSungkyunkwan University (SKKU)Suwon Republic of Korea
Won Tae Hong
School of Chemical EngineeringSungkyunkwan University (SKKU)Suwon Republic of Korea
Chengkai Xia
School of Materials Science and EngineeringNorth University of ChinaTaiyuan Shanxi China
Sungsoon Kim
Department of Mechanical EngineeringStanford UniversityStanford California USA
Heeyeop Chae
School of Chemical EngineeringSungkyunkwan University (SKKU)Suwon Republic of Korea
Xu Yu
School of Chemistry and Chemical EngineeringYangzhou UniversityYangzhou China
Wooseok Yang
School of Chemical EngineeringSungkyunkwan University (SKKU)Suwon Republic of Korea
Jongwook Park
Integrated EngineeringDepartment of Chemical EngineeringKyung Hee UniversityGyeonggi South Korea
Jung Kyu Kim
School of Chemical EngineeringSungkyunkwan University (SKKU)Suwon Republic of Korea
ABSTRACT As for the high sustainable solar hydrogen production via water splitting, transition metal doping on an oxide photoanode in photoelectrochemical (PEC) cells has been recognized as an effective approach. However, conventional thermal‐diffusion‐mediated doping strategies face the challenge of resolving sluggish catalytic kinetics for oxygen evolution reaction (OER) and its practical utilization for the synthesis of photoanode films. Herein, we introduce facile ultrafast flame‐boosted doping of Mo into a BiVO4 (FL MoBVO) film for 20 s to achieve an efficient PEC OER. Mo elements in a low‐valence state (i.e., Mo6−δ) and Mo6+ are successfully doped into the photoanode, which manipulate the energy band structure, facilitating the downward shift of band edges and promoting the surface catalytic kinetics. Consequently, the flame‐boosted Mo‐doping results in superior PEC performance in a mild environment with neutral electrolyte without introducing any other additives or co‐catalysts, where the photocurrent density at 1.23 VRHE under 1 sun illumination in pH 7 is outstandingly enhanced, over 9‐fold higher than that of a pristine BiVO4. The flame‐boosted doping induces significantly enhanced photoexcited charge transport and catalytic reaction kinetics performances simultaneously. Our report provides the effective strategy boosting both the thermodynamic and kinetic charge migration properties for sustainable materials.
