Directing the photogenerated charge flow in a photocathodic metal protection system with single-domain ferroelectric PbTiO3 nanoplates

Electron Pub Date : 2024-06-26 DOI:10.1002/elt2.51
Hui Xie, Jianyou Yu, Yuchen Fang, Zhijun Wang, Shihe Yang, Zheng Xing
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Abstract

Photocathodic protection (PCP) is arguably an ideal alternative technology to the conventional electrochemical cathodic protection methods for corrosion mitigation of metallic infrastructure due to its eco-friendliness and low-energy-consumption, but the construction of highly-efficient PCP systems still remains challenging, caused primarily by the lack of driving force to guide the charge flow through the whole PCP photoanodes. Here, we tackle this key issue by equipping the PCP photoanode with ferroelectric single-domain PbTiO3 nanoplates, which can form a directional “macroscopic electric field” throughout the entire photoanode controllable by external polarization. The properly poled PCP photoanode allows the photogenerated electrons and holes to migrate in opposite directions, that is, electrons to the protected metal and holes to the photoanode/electrolyte interface, leading to largely suppressed charge annihilation and consequently a considerable boost in the overall solar energy conversion efficiency of the PCP system. The as-fabricated photoanode can not only supply sufficient photocurrent to 304 stainless steel to initiate cathodic protection, but also shift the metal potential to the corrosion-free range. Our findings provide a viable design strategy for future high-performance PCP systems based on ferroelectric nanomaterials with enhanced charge flow manipulation.

Abstract Image

利用单域铁电 PbTiO3 纳米板引导光阴极金属保护系统中的光生电荷流
光电阴极保护(PCP)因其生态友好性和低能耗,可以说是金属基础设施腐蚀缓解领域传统电化学阴极保护方法的理想替代技术,但高效 PCP 系统的构建仍面临挑战,主要原因是缺乏引导电荷流经整个 PCP 光阳极的驱动力。在这里,我们通过在 PCP 光阳极中加入铁电单域 PbTiO3 纳米板来解决这一关键问题,这种纳米板可以在整个光阳极中形成定向的 "宏观电场",并可通过外部极化进行控制。经过适当极化的 PCP 光阳极允许光生电子和空穴向相反的方向迁移,即电子迁移到受保护的金属,空穴迁移到光阳极/电解质界面,从而在很大程度上抑制了电荷湮灭,从而大大提高了 PCP 系统的整体太阳能转换效率。制作完成的光阳极不仅能为 304 不锈钢提供足够的光电流以启动阴极保护,还能将金属电位转移到无腐蚀范围。我们的研究结果为未来基于铁电纳米材料的高性能 PCP 系统提供了一种可行的设计策略,该系统具有更强的电荷流操控能力。
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