Colloidal Quantum Dot Photovoltaics Using Ultrathin, Solution-Processed Bilayer In2O3/ZnO Electron Transport Layers with Improved Stability

Ahmad R. Kirmani; Flurin Eisner; Ahmed E. Mansour; Yuliar Firdaus; Neha Chaturvedi; Akmaral Seitkhan; Mohamad Nugraha; Emre Yarali; F. Pelayo Garcia de Arquer; Edward H. Sargent; Thomas D. Anthopoulos; Aram Amassian

doi:10.1021/acsaem.0c00831

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Colloidal Quantum Dot Photovoltaics Using Ultrathin, Solution-Processed Bilayer In2O3/ZnO Electron Transport Layers with Improved Stability

Journal article

Peer reviewed

Colloidal Quantum Dot Photovoltaics Using Ultrathin, Solution-Processed Bilayer In2O3/ZnO Electron Transport Layers with Improved Stability

Ahmad R. Kirmani, Flurin Eisner, Ahmed E. Mansour, Yuliar Firdaus, Neha Chaturvedi, Akmaral Seitkhan, Mohamad Nugraha, Emre Yarali, F. Pelayo Garcia de Arquer, Edward H. Sargent, …

ACS applied energy materials, Vol.3(6), pp.5135-5141

22/06/2020

DOI: https://doi.org/10.1021/acsaem.0c00831

Abstract

Chemistry

Chemistry, Physical

Energy & Fuels

Materials Science

Materials Science, Multidisciplinary

Physical Sciences

Science & Technology

Technology

Solution-processed colloidal quantum dot (CQD) photovoltaics (PVs) continue to mature with improvements in device architectures and ligand exchange strategies. Carrier selective contacts extract photogenerated charge carriers from the CQD absorber; however, the role of the electron-transporting layer (ETL) in stability remains unclear. Herein, we find that the typically used >100 nm thick ZnO ETL suffers from parasitic absorption and carrier recombination resulting in unstable n-i-p solar cells with faster UV-degradation. We address this by developing an ultrathin (ca. 20 nm), quantum-confined, solution-processed In2O3/ZnO ETL. This bilayer ETL results in solar cells with significantly improved overall stability without compromising performance, with an 11.1% power conversion efficiency hero device.

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Title: Colloidal Quantum Dot Photovoltaics Using Ultrathin, Solution-Processed Bilayer In2O3/ZnO Electron Transport Layers with Improved Stability
Creators - without role: Ahmad R. Kirmani - King Abdullah University of Science and Technology
Flurin Eisner - Imperial College London
Ahmed E. Mansour - King Abdullah University of Science and Technology
Yuliar Firdaus - King Abdullah University of Science and Technology
Neha Chaturvedi - King Abdullah University of Science and Technology
Akmaral Seitkhan - King Abdullah University of Science and Technology
Mohamad Nugraha - King Abdullah University of Science and Technology
Emre Yarali - King Abdullah University of Science and Technology
F. Pelayo Garcia de Arquer - University of Toronto
Edward H. Sargent - University of Toronto
Thomas D. Anthopoulos - King Abdullah University of Science and Technology
Aram Amassian - King Abdullah University of Science and Technology
Publication Details: ACS applied energy materials, Vol.3(6), pp.5135-5141
Publisher: Amer Chemical Soc
Number of pages: 7
Grant note: King Abdullah University of Science and Technology (KAUST); King Abdullah University of Science & Technology
Identifiers: 9941891008331
Academic Unit: King Abdullah University of Science & Technology
Language: English
Resource Type: Journal article