Unveiling the dual impact of CuI layer and Se content in Sb2(S, Se)3 photocathodes for solar water splitting
Sb2(S, Se)3 is a promising photocathode for photoelectrochemical (PEC) conversion of solar energy to hydrogen due to its excellent optoelectronic properties, stability, and low toxicity. For such applications, a p–i–n device architecture is favorable for efficient charge separation, with the p-type...
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sg-ntu-dr.10356-1810432024-11-12T04:55:28Z Unveiling the dual impact of CuI layer and Se content in Sb2(S, Se)3 photocathodes for solar water splitting Chun, Hao Zhe Lie, Stener Ahmed, Mahmoud Gamal Wong, Lydia Helena School of Materials Science and Engineering Energy Research Institute @ NTU (ERI@N) Engineering Antimony sulfoselenides Copper iodides Sb2(S, Se)3 is a promising photocathode for photoelectrochemical (PEC) conversion of solar energy to hydrogen due to its excellent optoelectronic properties, stability, and low toxicity. For such applications, a p–i–n device architecture is favorable for efficient charge separation, with the p-type layer improving hole extraction while the n-type layer facilitates electron injection into the electrolyte for hydrogen evolution reaction. However, the lack of suitable p-type layers for depositing a uniform layer of Sb2(S, Se)3 photocathode constrains the device architectures for PEC water splitting. In this work, various p-type materials (e.g., NiO, CuS, and CuI) are investigated. Photocathodes fabricated on CuI demonstrate superior performance due to improved hole extraction and uniform growth of Sb2(S, Se)3 absorber layer. The Se/S ratio is adjusted to further fine-tune the photocathode's absorption, influencing the efficiency of charge carriers’ injection and separation. The overall PEC performance reaches the maximum value when Se/S = 20%, achieving up to 4.2 mA cm−2 with stable photocurrents sustained for 120 min under standard illumination conditions, achieving the highest-reported photocurrent among S-rich-solution-processed Sb2(S, Se)3 photocathodes. In this work, new avenues are opened for the design of p–i–n Sb2(S, Se)3 PEC devices. Ministry of Education (MOE) This research was financially supported by Singapore Ministry of Education Tier 1 grant (Award ID RG68/21) and Tier 2 grant (grant no. MOE T2EP50120-0008). The research is funded by the Indonesian Endowment Fund for Education (LPDP) on behalf of the Indonesia Ministry of Education, Culture, Research and Technology and managed by Universitas Indonesia under INSPIRASI Program (grant nos. PRJ-61/LPDP/2022 and 612/E1/KS.06.02/2022). 2024-11-12T04:55:28Z 2024-11-12T04:55:28Z 2024 Journal Article Chun, H. Z., Lie, S., Ahmed, M. G. & Wong, L. H. (2024). Unveiling the dual impact of CuI layer and Se content in Sb2(S, Se)3 photocathodes for solar water splitting. Solar RRL, 2400528-. https://dx.doi.org/10.1002/solr.202400528 2367-198X https://hdl.handle.net/10356/181043 10.1002/solr.202400528 2-s2.0-85204137018 2400528 en RG68/21 MOE T2EP50120-0008 Solar RRL © 2024 Wiley-VCH GmbH. All rights reserved. |
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Engineering Antimony sulfoselenides Copper iodides |
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Engineering Antimony sulfoselenides Copper iodides Chun, Hao Zhe Lie, Stener Ahmed, Mahmoud Gamal Wong, Lydia Helena Unveiling the dual impact of CuI layer and Se content in Sb2(S, Se)3 photocathodes for solar water splitting |
| description |
Sb2(S, Se)3 is a promising photocathode for photoelectrochemical (PEC) conversion of solar energy to hydrogen due to its excellent optoelectronic properties, stability, and low toxicity. For such applications, a p–i–n device architecture is favorable for efficient charge separation, with the p-type layer improving hole extraction while the n-type layer facilitates electron injection into the electrolyte for hydrogen evolution reaction. However, the lack of suitable p-type layers for depositing a uniform layer of Sb2(S, Se)3 photocathode constrains the device architectures for PEC water splitting. In this work, various p-type materials (e.g., NiO, CuS, and CuI) are investigated. Photocathodes fabricated on CuI demonstrate superior performance due to improved hole extraction and uniform growth of Sb2(S, Se)3 absorber layer. The Se/S ratio is adjusted to further fine-tune the photocathode's absorption, influencing the efficiency of charge carriers’ injection and separation. The overall PEC performance reaches the maximum value when Se/S = 20%, achieving up to 4.2 mA cm−2 with stable photocurrents sustained for 120 min under standard illumination conditions, achieving the highest-reported photocurrent among S-rich-solution-processed Sb2(S, Se)3 photocathodes. In this work, new avenues are opened for the design of p–i–n Sb2(S, Se)3 PEC devices. |
| author2 |
School of Materials Science and Engineering |
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School of Materials Science and Engineering Chun, Hao Zhe Lie, Stener Ahmed, Mahmoud Gamal Wong, Lydia Helena |
| format |
Article |
| author |
Chun, Hao Zhe Lie, Stener Ahmed, Mahmoud Gamal Wong, Lydia Helena |
| author_sort |
Chun, Hao Zhe |
| title |
Unveiling the dual impact of CuI layer and Se content in Sb2(S, Se)3 photocathodes for solar water splitting |
| title_short |
Unveiling the dual impact of CuI layer and Se content in Sb2(S, Se)3 photocathodes for solar water splitting |
| title_full |
Unveiling the dual impact of CuI layer and Se content in Sb2(S, Se)3 photocathodes for solar water splitting |
| title_fullStr |
Unveiling the dual impact of CuI layer and Se content in Sb2(S, Se)3 photocathodes for solar water splitting |
| title_full_unstemmed |
Unveiling the dual impact of CuI layer and Se content in Sb2(S, Se)3 photocathodes for solar water splitting |
| title_sort |
unveiling the dual impact of cui layer and se content in sb2(s, se)3 photocathodes for solar water splitting |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/181043 |
| _version_ |
1816858959483502592 |