The poor photoelectrochemical (PEC) performance derived from insufficient charge separation in hematite photoanode crucially limits its application. Gradient doping with band bending in a large region is then considered as a promising strategy, facilitating the charge transfer ability due to the built-in electric field. Herein, we developed a synthetic strategy to prepare gradient Ti-doped ultrathin hematite photoelectrode and systematically investigated its PEC performance. The as-synthesized electrode (1.5-6.0% doping level from the surface to the substrate) delivered a photocurrent of about 1.30 mA cm at 1.23 V versus the reversible hydrogen electrode (RHE), which is nearly 100% higher than that of homogeneously doped hematite electrode. The enhanced charge transfer property, induced by the energy band bending due to the built-in electric field, has been further confirmed by electrochemical measurements. This strategy of gradient doping should be adaptable and can be applied for other functional materials in various fields.
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机译:由赤铁矿光阳极中电荷分离不足引起的不良光电化学(PEC)性能严重限制了其应用。因此,在大区域内进行带隙弯曲的梯度掺杂被认为是一种有前途的策略,由于内置电场的存在,有利于电荷转移。在本文中,我们开发了一种合成策略,以制备梯度掺杂Ti的超薄赤铁矿光电极,并系统地研究了其PEC性能。合成后的电极(从表面到衬底的掺杂水平为1.5-6.0%)在1.23 V的电压下提供了约1.30 mA cm的光电流,而可逆氢电极(RHE)比均质掺杂的氢电极高近100%。赤铁矿电极。电化学测量进一步证实了由于内置电场引起的能带弯曲而引起的电荷转移性能增强。梯度掺杂的这种策略应该是可适应的,并且可以应用于各个领域的其他功能材料。
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