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形态及电极/电解质界面对基于FeO体系的光电化学响应的影响——两种制备技术的比较

Effect of morphology and impact of the electrode/electrolyte interface on the PEC response of FeO based systems - comparison of two preparation techniques.

作者信息

Asha Kumari, Satsangi Vibha Rani, Shrivastav Rohit, Kant Rama, Dass Sahab

机构信息

Department of Chemistry, Faculty of Science, Dayalbagh Educational Institute Dayalbagh Agra 282005 India

Department of Physics & Computer Science, Faculty of Science, Dayalbagh Educational Institute Dayalbagh Agra 282005 India.

出版信息

RSC Adv. 2020 Nov 19;10(69):42256-42266. doi: 10.1039/d0ra07870k. eCollection 2020 Nov 17.

DOI:10.1039/d0ra07870k
PMID:35516748
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9057922/
Abstract

The present study is a comparative account of FeO based photoelectrodes prepared by two different techniques, namely spray pyrolysis and electrochemical deposition, followed by photoelectrochemical analysis at pH 13 (highly alkaline) and pH 8 (near neutral) in 0.1 M NaOH solution for solar hydrogen generation. The study also investigates the influence of morphology at the semiconductor electrode/electrolyte interface along with quantitative determination of the morphological parameters of the rough electrode surface affecting the photoelectrochemical response using power spectral density analysis. Studies revealed that the FeO sample (E_100cy) prepared with 100 cycles of electrochemical deposition showed the highest photocurrent density of 2.37 mA cm and 1.18 mA cm at 1 V SCE at pH 13 and 8 respectively. Power spectral density analysis exhibited that E_100cy possesses smallest surface features contributing to the PEC response with a lower cut off length scale of 17.23, upper cut off length scale of 150.45, maximum fractal dimension of 2.62 and maximum average rms roughness of 17.52 nm, offering the maximum surface area for charge transfer reactions at the electrode/electrolyte interface. The sample E_100cy exhibited the highest ABPE of 1.29% and IPCE of 37.5%.

摘要

本研究对通过两种不同技术制备的基于FeO的光电极进行了比较描述,这两种技术分别是喷雾热解和电化学沉积,随后在pH值为13(强碱性)和pH值为8(接近中性)的0.1 M NaOH溶液中进行光电化学分析以用于太阳能制氢。该研究还研究了半导体电极/电解质界面处形态的影响,以及使用功率谱密度分析对影响光电化学响应的粗糙电极表面形态参数进行定量测定。研究表明,经过100次电化学沉积循环制备的FeO样品(E_100cy)在pH值为13和8时,在1 V SCE下分别显示出最高的光电流密度,即2.37 mA/cm²和1.18 mA/cm²。功率谱密度分析表明,E_100cy具有最小的表面特征,对光电化学响应有贡献,其下限截止长度尺度为17.23,上限截止长度尺度为150.45,最大分形维数为2.62,最大平均均方根粗糙度为17.52 nm,为电极/电解质界面处的电荷转移反应提供了最大的表面积。样品E_100cy表现出最高的光阳极光电转换效率(ABPE),为1.29%,以及最高的入射光子到电流的转换效率(IPCE),为37.5%。

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