TY - JOUR
T1 - Defect-engineered black indium oxide
T2 - A high-performance photothermal material for solar-driven water purification
AU - Tan, Runfa
AU - Shridharan, Tatachari Santhanagopalan
AU - Lee, Jong Ho
AU - Josline, Mukkath Joseph
AU - Lee, Jae Yeong
AU - Bae, Jong Seong
AU - Sivanantham, Arumugam
AU - Jeong, Yoo Jae
AU - Lee, Jae Hyun
AU - Lee, Sangwook
AU - Cho, In Sun
N1 - Publisher Copyright:
© 2024
PY - 2025/4/15
Y1 - 2025/4/15
N2 - Defect engineering is a core strategy for controlling the optical, electronic, electrical, and catalytic properties of oxide-based semiconductors. In this study, we used indium oxide as a model system to investigate the impact of point defects on its physicochemical properties and interfacial solar-to-steam generation (ISSG) performance. Our findings revealed that hydrogen incorporation and oxygen vacancy generation can modify the visual color of the material, create deep-level energy states, and significantly enhance sub-bandgap photon absorption. These effects increase the charge carrier concentration, promote non-radiative recombination, and enhance localized heat generation. Additionally, the defects induced high surface energy, which improved surface hydrophilicity. Notably, defect-enriched black In2O3 (b-In2O3) exhibits exceptional photothermal conversion efficiency (74 %) and ISSG performance (evaporation flux: 2.3 kg m−2 h−1) with excellent stability for 60 h under one-sun illumination. We also demonstrated the practical application of b-In₂O₃ in wastewater purification, where the purified water exhibited significantly reduced metal ion concentrations, meeting World Health Organization (WHO) standards. These findings provide valuable insights into the design of oxide-based photothermal materials and emphasize the potential of defect-engineered b-In2O3 as a novel material for efficient solar-driven water purification, thereby offering a sustainable solution for global water scarcity.
AB - Defect engineering is a core strategy for controlling the optical, electronic, electrical, and catalytic properties of oxide-based semiconductors. In this study, we used indium oxide as a model system to investigate the impact of point defects on its physicochemical properties and interfacial solar-to-steam generation (ISSG) performance. Our findings revealed that hydrogen incorporation and oxygen vacancy generation can modify the visual color of the material, create deep-level energy states, and significantly enhance sub-bandgap photon absorption. These effects increase the charge carrier concentration, promote non-radiative recombination, and enhance localized heat generation. Additionally, the defects induced high surface energy, which improved surface hydrophilicity. Notably, defect-enriched black In2O3 (b-In2O3) exhibits exceptional photothermal conversion efficiency (74 %) and ISSG performance (evaporation flux: 2.3 kg m−2 h−1) with excellent stability for 60 h under one-sun illumination. We also demonstrated the practical application of b-In₂O₃ in wastewater purification, where the purified water exhibited significantly reduced metal ion concentrations, meeting World Health Organization (WHO) standards. These findings provide valuable insights into the design of oxide-based photothermal materials and emphasize the potential of defect-engineered b-In2O3 as a novel material for efficient solar-driven water purification, thereby offering a sustainable solution for global water scarcity.
KW - Deep-level energy states
KW - Defect engineering
KW - InO
KW - Solar steam generation
KW - Wastewater purification
UR - http://www.scopus.com/inward/record.url?scp=85212155261&partnerID=8YFLogxK
U2 - 10.1016/j.desal.2024.118440
DO - 10.1016/j.desal.2024.118440
M3 - Article
AN - SCOPUS:85212155261
SN - 0011-9164
VL - 599
JO - Desalination
JF - Desalination
M1 - 118440
ER -
