Jeong In Kwon, Mahadik Mahadeo A, Hwang Jun Beom, Chae Weon-Sik, Choi Sun Hee, Jang Jum Suk
Division of Biotechnology, Safety, Environment and Life Science Institute, College of Environmental and Bioresource Sciences, Chonbuk National University, Iksan 570-752, Republic of Korea.
Daegu Center, Korea Basic Science Institute, Daegu 41566, Republic of Korea.
J Colloid Interface Sci. 2021 Jan 1;581(Pt B):751-763. doi: 10.1016/j.jcis.2020.08.003. Epub 2020 Aug 3.
Herein, in situ zirconium-doped hematite nanocoral (Zr-FeO (I) NC) photoanode was prepared via a specially designed diluted hydrothermal approach and modified with Al co-doping and electrodeposited cobalt-phosphate ("Co-Pi") cocatalyst. Firstly, an unintentional in situ Zr-FeO (I)) NC photoanode was synthesized, which achieved an optimum photocurrent density of 0.27 mA/cm at 1.0 V vs. RHE but possessed a more positively shifted onset potential than conventionally prepared hematite nanorod photoelectrodes. An optimized amount of aluminum co-doping suppresses the bulk as well as surface defects, which causes a negative shift in the onset potential from 0.85 V to 0.8 V vs. RHE and enhances the photocurrent density of Zr-FeO(I) NC from 0.27 mA/cm to 0.7 mA/cm at 1.0 V vs. RHE. The electrodeposited Co-Pi modification further reduce the onset potential of Al co-doped Zr-FeO(I) NC to 0.58 V vs. RHE and yield a maximum photocurrent of 1.1 mA/cm at 1.0 V vs. RHE (1.8 mA/cm at 1.23 V vs RHE). The improved photocurrent at low onset potential can be attributed to synergistic effect of Al co-doping and Co-Pi surface modification. Further, during photoelectrochemical water-splitting, a 137 and 67 μmol of hydrogen (H) and oxygen (O) evolution was achieved over the optimum Co-Pi-modified Al-co-doped Zr-FeO(I) NC photoanode within 6 h. The proposed charge transfer mechanism in optimum Co-Pi-modified Alco-doped Zr-FeO(I) NC photoanodes during the photoelectrochemical water splitting was also studied.
在此,通过一种特别设计的稀释水热法制备了原位锆掺杂赤铁矿纳米珊瑚(Zr-FeO (I) NC)光阳极,并用铝共掺杂和电沉积钴磷酸盐(“Co-Pi”)助催化剂进行了改性。首先,合成了一种无意原位Zr-FeO (I))NC光阳极,其在相对于可逆氢电极(RHE)为1.0 V时实现了0.27 mA/cm²的最佳光电流密度,但与传统制备的赤铁矿纳米棒光电极相比,其起始电位向更正的方向移动。优化量的铝共掺杂抑制了体相和表面缺陷,这导致相对于RHE,起始电位从0.85 V负移至0.8 V,并将Zr-FeO(I) NC在相对于RHE为1.0 V时的光电流密度从0.27 mA/cm²提高到0.7 mA/cm²。电沉积的Co-Pi改性进一步将铝共掺杂Zr-FeO(I) NC的起始电位降低至相对于RHE为0.58 V,并在相对于RHE为1.0 V时产生1.1 mA/cm²的最大光电流(在相对于RHE为1.23 V时为1.8 mA/cm²)。低起始电位下光电流的提高可归因于铝共掺杂和Co-Pi表面改性的协同效应。此外,在光电化学水分解过程中,在最佳的Co-Pi改性铝共掺杂Zr-FeO(I) NC光阳极上,6小时内实现了137和67 μmol的氢气(H₂)和氧气(O₂)析出。还研究了最佳Co-Pi改性铝共掺杂Zr-FeO(I) NC光阳极在光电化学水分解过程中提出的电荷转移机制。
