Progress in plasma doping semiconductor photocatalysts for efficient pollutant remediation and hydrogen generation

Tanzim Ur Rahman; Hridoy Roy; Athkia Fariha; Afrina Zaman Shoronika; Md Rashid Al-Mamun; Syed Z. Islam; Md Shahinoor Islam; Hadi M. Marwani; Aminul Islam; Abdulmohsen K.D. Alsukaibi; Mohammed M. Rahman; Md Rabiul Awual

doi:10.1016/j.seppur.2023.124141

Progress in plasma doping semiconductor photocatalysts for efficient pollutant remediation and hydrogen generation

Tanzim Ur Rahman, Hridoy Roy, Athkia Fariha, Afrina Zaman Shoronika, Md Rashid Al-Mamun, Syed Z. Islam, Md Shahinoor Islam, Hadi M. Marwani, Aminul Islam, Abdulmohsen K.D. Alsukaibi, Mohammed M. Rahman, Md Rabiul Awual

Soft Materials and Membranes

Research output: Contribution to journal › Review article › peer-review

52 Scopus citations

Abstract

In recent years, solar energy-driven photocatalysis materials have drawn significant attention to addressing the global energy and environmental crisis. However, many of the semiconductor photocatalysts are unable to absorb the visible light of the solar spectra due to their wide band gap. The incorporation of a foreign element such as a dopant in the lattice of these photocatalysts was shown to reduce their band gap and enhance visible light absorption. The doping of semiconductors can be performed using several techniques such as sol–gel, hydrothermal, solvothermal, and plasma-based doping. However, plasma-based doping has been considered a highly efficient approach due to the reduction of the band gap to a large extent, enhancement of visible light absorption, and remarkable photocatalytic activities under visible light illumination. The plasma-based doping approach offered many advantages such as high reactivity, process simplicity, scalability, energy efficiency, homogeneous doping, no chemical inventory, low pressure, and low-temperature operation, and flexibility of operation under gas and liquid phase media. Further advancement of plasma-based doping can be achieved through more theoretical studies allowing an in-depth understanding of the mechanisms and interactions of the species involved. This will facilitate the synthesis and application of doped photocatalysts in a cost-effective manner. This review surveyed recent advances in a wide range of semiconductor photocatalysts doped with various dopants using plasma treatment. Various plasma methods for doping semiconductor photocatalysts and their fundamental mechanisms were discussed. The performance characteristics of the plasma-doped photocatalysts were compared to other methods in terms of energy and environmental applications including degradation of environmental contaminants and solar fuel production such as hydrogen production from water splitting using visible light-driven solar energy. Finally, potential future research directions were recommended for the applications of the efficient photocatalysts developed by plasma treatment.

Original language	English
Article number	124141
Journal	Separation and Purification Technology
Volume	320
DOIs	https://doi.org/10.1016/j.seppur.2023.124141
State	Published - Sep 1 2023

Funding

The authors acknowledge the support from Bangladesh University of Engineering and Technology, Dhaka and Laboratory Directed Research and Development Fund, Oak Ridge National Laboratory, USA.

Keywords

Band gap
Environmental remediation
Hydrogen production
Photocatalysis
Plasma doping

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10.1016/j.seppur.2023.124141

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Rahman, T. U., Roy, H., Fariha, A., Shoronika, A. Z., Al-Mamun, M. R., Islam, S. Z., Islam, M. S., Marwani, H. M., Islam, A., Alsukaibi, A. K. D., Rahman, M. M., & Awual, M. R. (2023). Progress in plasma doping semiconductor photocatalysts for efficient pollutant remediation and hydrogen generation. Separation and Purification Technology, 320, Article 124141. https://doi.org/10.1016/j.seppur.2023.124141

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title = "Progress in plasma doping semiconductor photocatalysts for efficient pollutant remediation and hydrogen generation",

abstract = "In recent years, solar energy-driven photocatalysis materials have drawn significant attention to addressing the global energy and environmental crisis. However, many of the semiconductor photocatalysts are unable to absorb the visible light of the solar spectra due to their wide band gap. The incorporation of a foreign element such as a dopant in the lattice of these photocatalysts was shown to reduce their band gap and enhance visible light absorption. The doping of semiconductors can be performed using several techniques such as sol–gel, hydrothermal, solvothermal, and plasma-based doping. However, plasma-based doping has been considered a highly efficient approach due to the reduction of the band gap to a large extent, enhancement of visible light absorption, and remarkable photocatalytic activities under visible light illumination. The plasma-based doping approach offered many advantages such as high reactivity, process simplicity, scalability, energy efficiency, homogeneous doping, no chemical inventory, low pressure, and low-temperature operation, and flexibility of operation under gas and liquid phase media. Further advancement of plasma-based doping can be achieved through more theoretical studies allowing an in-depth understanding of the mechanisms and interactions of the species involved. This will facilitate the synthesis and application of doped photocatalysts in a cost-effective manner. This review surveyed recent advances in a wide range of semiconductor photocatalysts doped with various dopants using plasma treatment. Various plasma methods for doping semiconductor photocatalysts and their fundamental mechanisms were discussed. The performance characteristics of the plasma-doped photocatalysts were compared to other methods in terms of energy and environmental applications including degradation of environmental contaminants and solar fuel production such as hydrogen production from water splitting using visible light-driven solar energy. Finally, potential future research directions were recommended for the applications of the efficient photocatalysts developed by plasma treatment.",

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Rahman, TU, Roy, H, Fariha, A, Shoronika, AZ, Al-Mamun, MR, Islam, SZ, Islam, MS, Marwani, HM, Islam, A, Alsukaibi, AKD, Rahman, MM & Awual, MR 2023, 'Progress in plasma doping semiconductor photocatalysts for efficient pollutant remediation and hydrogen generation', Separation and Purification Technology, vol. 320, 124141. https://doi.org/10.1016/j.seppur.2023.124141

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T1 - Progress in plasma doping semiconductor photocatalysts for efficient pollutant remediation and hydrogen generation

AU - Rahman, Tanzim Ur

AU - Roy, Hridoy

AU - Fariha, Athkia

AU - Shoronika, Afrina Zaman

AU - Al-Mamun, Md Rashid

AU - Islam, Syed Z.

AU - Islam, Md Shahinoor

AU - Marwani, Hadi M.

AU - Islam, Aminul

AU - Alsukaibi, Abdulmohsen K.D.

AU - Rahman, Mohammed M.

AU - Awual, Md Rabiul

PY - 2023/9/1

Y1 - 2023/9/1

N2 - In recent years, solar energy-driven photocatalysis materials have drawn significant attention to addressing the global energy and environmental crisis. However, many of the semiconductor photocatalysts are unable to absorb the visible light of the solar spectra due to their wide band gap. The incorporation of a foreign element such as a dopant in the lattice of these photocatalysts was shown to reduce their band gap and enhance visible light absorption. The doping of semiconductors can be performed using several techniques such as sol–gel, hydrothermal, solvothermal, and plasma-based doping. However, plasma-based doping has been considered a highly efficient approach due to the reduction of the band gap to a large extent, enhancement of visible light absorption, and remarkable photocatalytic activities under visible light illumination. The plasma-based doping approach offered many advantages such as high reactivity, process simplicity, scalability, energy efficiency, homogeneous doping, no chemical inventory, low pressure, and low-temperature operation, and flexibility of operation under gas and liquid phase media. Further advancement of plasma-based doping can be achieved through more theoretical studies allowing an in-depth understanding of the mechanisms and interactions of the species involved. This will facilitate the synthesis and application of doped photocatalysts in a cost-effective manner. This review surveyed recent advances in a wide range of semiconductor photocatalysts doped with various dopants using plasma treatment. Various plasma methods for doping semiconductor photocatalysts and their fundamental mechanisms were discussed. The performance characteristics of the plasma-doped photocatalysts were compared to other methods in terms of energy and environmental applications including degradation of environmental contaminants and solar fuel production such as hydrogen production from water splitting using visible light-driven solar energy. Finally, potential future research directions were recommended for the applications of the efficient photocatalysts developed by plasma treatment.

AB - In recent years, solar energy-driven photocatalysis materials have drawn significant attention to addressing the global energy and environmental crisis. However, many of the semiconductor photocatalysts are unable to absorb the visible light of the solar spectra due to their wide band gap. The incorporation of a foreign element such as a dopant in the lattice of these photocatalysts was shown to reduce their band gap and enhance visible light absorption. The doping of semiconductors can be performed using several techniques such as sol–gel, hydrothermal, solvothermal, and plasma-based doping. However, plasma-based doping has been considered a highly efficient approach due to the reduction of the band gap to a large extent, enhancement of visible light absorption, and remarkable photocatalytic activities under visible light illumination. The plasma-based doping approach offered many advantages such as high reactivity, process simplicity, scalability, energy efficiency, homogeneous doping, no chemical inventory, low pressure, and low-temperature operation, and flexibility of operation under gas and liquid phase media. Further advancement of plasma-based doping can be achieved through more theoretical studies allowing an in-depth understanding of the mechanisms and interactions of the species involved. This will facilitate the synthesis and application of doped photocatalysts in a cost-effective manner. This review surveyed recent advances in a wide range of semiconductor photocatalysts doped with various dopants using plasma treatment. Various plasma methods for doping semiconductor photocatalysts and their fundamental mechanisms were discussed. The performance characteristics of the plasma-doped photocatalysts were compared to other methods in terms of energy and environmental applications including degradation of environmental contaminants and solar fuel production such as hydrogen production from water splitting using visible light-driven solar energy. Finally, potential future research directions were recommended for the applications of the efficient photocatalysts developed by plasma treatment.

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KW - Environmental remediation

KW - Hydrogen production

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JO - Separation and Purification Technology

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ER -

Progress in plasma doping semiconductor photocatalysts for efficient pollutant remediation and hydrogen generation

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