File Download

There are no files associated with this item.

  • Find it @ UNIST can give you direct access to the published full text of this article. (UNISTARs only)
Related Researcher

김진영

Kim, Jin Young
Next Generation Energy Lab.
Read More

Views & Downloads

Detailed Information

Cited time in webofscience Cited time in scopus
Metadata Downloads

A highly transparent thin film hematite with multi-element dopability for an efficient unassisted water splitting system

Author(s)
Park, JuhyungYoon, Ki-YongKim, TaehyoJang, HyungsuKwak, Myung-JunKim, Jin YoungJang, Ji-Hyun
Issued Date
2020-06
DOI
10.1016/j.nanoen.2020.105089
URI
https://scholarworks.unist.ac.kr/handle/201301/48350
Fulltext
https://www.sciencedirect.com/science/article/pii/S2211285520306662?via%3Dihub
Citation
NANO ENERGY, v.76
Abstract
A tandem system consisting of a combined hematite photoanode/perovskite solar cell is a novel configuration enabling unbiased solar-driven water splitting in a cost-efficient way. However, similar light absorption spectrums between hematite and perovskite, causing significant optical loss of the solar cell located behind the photoelectrochemical cell, have been a critical issue, resulting in a substantial reduction in the overall photoelectrochemical performance in the bias-free tandem system. Herein, we report an efficient thin film hematite/perovskite tandem cell optimized with consideration of both quantum efficiency of the hematite photoanode and optical loss of the solar cell. Ti,Si co-doping with controlled dopability and deposition of transparent NiFeOx co-catalyst on hematite (NiFeOx@Ti:Si–Fe2O3(t)) allowed for highly improved surface reaction kinetics and charge transport behaviors, endowing our thin film with state-of-the-art performance among thin film hematite photoanodes reported to date, with a photocurrent density of 2.62mAcm−2 at 1.23VRHE and an onset potential of 0.71V. The perovskite solar cell in the thin hematite/solar cell exhibited an anodic shift of Voc from 1.08V to 1.16V and a three-fold increased photocurrent density (15.5mAcm−2) compared to the solar cell of the conventional thick hematite/solar cell system. The assembled dual photoanodes (dual NiFeOx@Ti:Si–Fe2O3) reached a maximum photocurrent density of 4.0mAcm−2 at 1.23VRHE. Our tandem photoelectrochemical system comprising assembled dual thin film NiFeOx@Ti:Si–Fe2O3/solar cell showed outstanding performance of an unbiased solar-to-hydrogen (STH) conversion efficiency of 4.49%, which is the highest recorded value in the hematite/perovskite tandem cell systems. This work provides a great potential for further development of an unassisted solar water splitting system with the thin film hematite. © 2020
Publisher
Elsevier BV
ISSN
2211-2855
Keyword (Author)
Controlled dopabilityOptical lossPerovskiteTandem systemThin film hematiteUnbiased solar-driven water splitting
Keyword
Photoelectrochemical performancePhotoelectrochemical systemSolar water splittingSolar-to-hydrogen conversionsState-of-the-art performanceSubstantial reductionTransparent thin filmWater splitting systemThin filmsAbsorption spectroscopyDepositionEfficiencyHematiteLight absorptionNickel compoundsPerovskitePerovskite solar cellsPhotocurrentsPhotoelectrochemical cellsReaction kineticsSemiconductor dopingSiliconSilicon compoundsSolar power generationSurface reactionsThin film solar cells

qrcode

Items in Repository are protected by copyright, with all rights reserved, unless otherwise indicated.