Standard

The effects of nitrogen-doping on photocatalytic mineralization of TiO2 nanocatalyst against formaldehyde in ambient air. / Lim, Dae-Hwan; Bathla, Aadil; Anwer, Hassan et al.
In: Chinese Journal of Catalysis, Vol. 59, 2024, p. 303-323.

Research output: Contribution to journalArticlepeer-review

Harvard

Lim, D-H, Bathla, A, Anwer, H, Younis, S, Boukhvalov, D & Kim, K-H 2024, 'The effects of nitrogen-doping on photocatalytic mineralization of TiO2 nanocatalyst against formaldehyde in ambient air', Chinese Journal of Catalysis, vol. 59, pp. 303-323. https://doi.org/10.1016/S1872-2067(24)60010-0

APA

Lim, D-H., Bathla, A., Anwer, H., Younis, S., Boukhvalov, D., & Kim, K-H. (2024). The effects of nitrogen-doping on photocatalytic mineralization of TiO2 nanocatalyst against formaldehyde in ambient air. Chinese Journal of Catalysis, 59, 303-323. https://doi.org/10.1016/S1872-2067(24)60010-0

Vancouver

Lim D-H, Bathla A, Anwer H, Younis S, Boukhvalov D, Kim K-H. The effects of nitrogen-doping on photocatalytic mineralization of TiO2 nanocatalyst against formaldehyde in ambient air. Chinese Journal of Catalysis. 2024;59:303-323. doi: 10.1016/S1872-2067(24)60010-0

Author

Lim, Dae-Hwan ; Bathla, Aadil ; Anwer, Hassan et al. / The effects of nitrogen-doping on photocatalytic mineralization of TiO2 nanocatalyst against formaldehyde in ambient air. In: Chinese Journal of Catalysis. 2024 ; Vol. 59. pp. 303-323.

BibTeX

@article{9216526fa1d04cfd9f84b7e7d0a8f5c4,
title = "The effects of nitrogen-doping on photocatalytic mineralization of TiO2 nanocatalyst against formaldehyde in ambient air",
abstract = "A series of proto-type photocatalytic air purifier (AP (Nx-Cy)) systems are built with a nitrogen-doped TiO2 (N-TiO2)-impregnated honeycomb (HC) filter for photocatalytic decomposition of 0.5–5 ppm formaldehyde (FA: CH2O) vapor under varying conditions and UV-LED light (1 watt). The binary codes of Nx and Cy in AP systems are used as the composition identifiers to represent N/Ti molar ratios (0 to 20) and N-TiO2 concentration (2 to 20 mg mL–1), respectively. The AP (N10-C10) is found as an optimum unit with the highest capability to boost the catalytic conversion of CH2O to CO2 (yield = 89.2% over 10th cycles and the clean air delivery rate (CADR) of 9.45 L min–1 in dry air). The superior charge carrier lifetime (τa: 1.70 ns) of N10-C10 over others (e.g., 1.37 ns for pure TiO2) should indicate the influential role of N-defects (No) in reducing the bandgap (3.10 eV) and in creating defect-related oxygen vacancy (OVs-Ti3+) states as predicted by the density functional theory (DFT) simulation. The photocatalytic oxidation pathway of CH2O, when assessed by diverse approaches (e.g., in-situ diffuse reflectance infrared Fourier transform, electron paramagnetic resonance, and DFT analyses), is found to involve several energetically favorable intermediate steps (such as exothermic covalent adsorption of CH2O to bridged O/OH groups on TiO2-OV {110} surface in the form of CH2O2 followed by catalytic dehydrogenation/oxidation reactions to yield CO2 through direct route: CH2O2/HCOO– + •OH → H2O + CO2). These steps are supported by the calculated density of states (DOS) for chemically active Ti-atom on {101} surface with N-impurity. The presence of No-defects and OVs is expected to influence the reaction energetics and intermediates for efficient mineralization in humidified conditions by lowering the activation barriers. This study offers valuable insights into the design and construction of an advanced photocatalytic system for efficient mineralization of aldehyde VOCs in ambient air. {\textcopyright} 2024 Dalian Institute of Chemical Physics, the Chinese Academy of Sciences.",
author = "Dae-Hwan Lim and Aadil Bathla and Hassan Anwer and Sherif Younis and Danil Boukhvalov and Ki-Hyun Kim",
note = "This work was supported by a grant from the National Research Foundation of Korea (NRF) funded by the Ministry of Science and ICT (MSIT) of the Korean government (2021R1A3B1068304). The authors also acknowledge the support provided by a grant from the NRF funded by MSIT of the Korean government (RS-2023-00243840) and Brain Pool program (RS-2023-00222393). D. W. Boukhvalov acknowledges support from Jiangsu Innovative and Entrepreneurial Talents Project, and the Ministry of Science and Education of Russian Federation (FEUZ-2023-0013).",
year = "2024",
doi = "10.1016/S1872-2067(24)60010-0",
language = "English",
volume = "59",
pages = "303--323",
journal = "Chinese Journal of Catalysis",
issn = "1872-2067",
publisher = "Global Science Press",

}

RIS

TY - JOUR

T1 - The effects of nitrogen-doping on photocatalytic mineralization of TiO2 nanocatalyst against formaldehyde in ambient air

AU - Lim, Dae-Hwan

AU - Bathla, Aadil

AU - Anwer, Hassan

AU - Younis, Sherif

AU - Boukhvalov, Danil

AU - Kim, Ki-Hyun

N1 - This work was supported by a grant from the National Research Foundation of Korea (NRF) funded by the Ministry of Science and ICT (MSIT) of the Korean government (2021R1A3B1068304). The authors also acknowledge the support provided by a grant from the NRF funded by MSIT of the Korean government (RS-2023-00243840) and Brain Pool program (RS-2023-00222393). D. W. Boukhvalov acknowledges support from Jiangsu Innovative and Entrepreneurial Talents Project, and the Ministry of Science and Education of Russian Federation (FEUZ-2023-0013).

PY - 2024

Y1 - 2024

N2 - A series of proto-type photocatalytic air purifier (AP (Nx-Cy)) systems are built with a nitrogen-doped TiO2 (N-TiO2)-impregnated honeycomb (HC) filter for photocatalytic decomposition of 0.5–5 ppm formaldehyde (FA: CH2O) vapor under varying conditions and UV-LED light (1 watt). The binary codes of Nx and Cy in AP systems are used as the composition identifiers to represent N/Ti molar ratios (0 to 20) and N-TiO2 concentration (2 to 20 mg mL–1), respectively. The AP (N10-C10) is found as an optimum unit with the highest capability to boost the catalytic conversion of CH2O to CO2 (yield = 89.2% over 10th cycles and the clean air delivery rate (CADR) of 9.45 L min–1 in dry air). The superior charge carrier lifetime (τa: 1.70 ns) of N10-C10 over others (e.g., 1.37 ns for pure TiO2) should indicate the influential role of N-defects (No) in reducing the bandgap (3.10 eV) and in creating defect-related oxygen vacancy (OVs-Ti3+) states as predicted by the density functional theory (DFT) simulation. The photocatalytic oxidation pathway of CH2O, when assessed by diverse approaches (e.g., in-situ diffuse reflectance infrared Fourier transform, electron paramagnetic resonance, and DFT analyses), is found to involve several energetically favorable intermediate steps (such as exothermic covalent adsorption of CH2O to bridged O/OH groups on TiO2-OV {110} surface in the form of CH2O2 followed by catalytic dehydrogenation/oxidation reactions to yield CO2 through direct route: CH2O2/HCOO– + •OH → H2O + CO2). These steps are supported by the calculated density of states (DOS) for chemically active Ti-atom on {101} surface with N-impurity. The presence of No-defects and OVs is expected to influence the reaction energetics and intermediates for efficient mineralization in humidified conditions by lowering the activation barriers. This study offers valuable insights into the design and construction of an advanced photocatalytic system for efficient mineralization of aldehyde VOCs in ambient air. © 2024 Dalian Institute of Chemical Physics, the Chinese Academy of Sciences.

AB - A series of proto-type photocatalytic air purifier (AP (Nx-Cy)) systems are built with a nitrogen-doped TiO2 (N-TiO2)-impregnated honeycomb (HC) filter for photocatalytic decomposition of 0.5–5 ppm formaldehyde (FA: CH2O) vapor under varying conditions and UV-LED light (1 watt). The binary codes of Nx and Cy in AP systems are used as the composition identifiers to represent N/Ti molar ratios (0 to 20) and N-TiO2 concentration (2 to 20 mg mL–1), respectively. The AP (N10-C10) is found as an optimum unit with the highest capability to boost the catalytic conversion of CH2O to CO2 (yield = 89.2% over 10th cycles and the clean air delivery rate (CADR) of 9.45 L min–1 in dry air). The superior charge carrier lifetime (τa: 1.70 ns) of N10-C10 over others (e.g., 1.37 ns for pure TiO2) should indicate the influential role of N-defects (No) in reducing the bandgap (3.10 eV) and in creating defect-related oxygen vacancy (OVs-Ti3+) states as predicted by the density functional theory (DFT) simulation. The photocatalytic oxidation pathway of CH2O, when assessed by diverse approaches (e.g., in-situ diffuse reflectance infrared Fourier transform, electron paramagnetic resonance, and DFT analyses), is found to involve several energetically favorable intermediate steps (such as exothermic covalent adsorption of CH2O to bridged O/OH groups on TiO2-OV {110} surface in the form of CH2O2 followed by catalytic dehydrogenation/oxidation reactions to yield CO2 through direct route: CH2O2/HCOO– + •OH → H2O + CO2). These steps are supported by the calculated density of states (DOS) for chemically active Ti-atom on {101} surface with N-impurity. The presence of No-defects and OVs is expected to influence the reaction energetics and intermediates for efficient mineralization in humidified conditions by lowering the activation barriers. This study offers valuable insights into the design and construction of an advanced photocatalytic system for efficient mineralization of aldehyde VOCs in ambient air. © 2024 Dalian Institute of Chemical Physics, the Chinese Academy of Sciences.

UR - http://www.scopus.com/inward/record.url?partnerID=8YFLogxK&scp=85191652491

U2 - 10.1016/S1872-2067(24)60010-0

DO - 10.1016/S1872-2067(24)60010-0

M3 - Article

VL - 59

SP - 303

EP - 323

JO - Chinese Journal of Catalysis

JF - Chinese Journal of Catalysis

SN - 1872-2067

ER -

ID: 56690135