Efficient degradation of formaldehyde based on DFT-screened metal-doped C<sub>3</sub>N<sub>6</sub> monolayer photocatalysts: performance evaluation and mechanistic insights

Chen, Mengshan; Wang, Haijian; Wang, Jinhu; Sun, Mingyuzhi; Hu, Yaxuan; Zhao, Xue; Zhou, Yingtang

doi:10.1039/d3cp03160h

Cited by 13 publications

(6 citation statements)

References 49 publications

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“…The DFT calculation was performed using Vienna ab initio simulation package (VASP). , The Perdew–Burke–Ernzerhof (PBE) functional with generalized gradient approximation (GGA) are used for the exchange-correlation potentials. For structure optimization, 3 × 3 × 1 k-points mesh and 450 eV energy cutoff have been used.…”

Section: Methodsmentioning

confidence: 99%

A Full-Spectrum ZnS Photocatalyst with Gradient Distribution of Atomic Copper Dopants and Concomitant Sulfur Vacancies for Highly Efficient Hydrogen Evolution

Bao,

Ali,

Dai

et al. 2024

ACS Nano

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A rarely discussed phenomenon in the realm of photocatalytic materials involves the presence of gradient distributed dopants and defects from the interior to the surface. This intriguing characteristic has been successfully achieved in the case of ZnS through the incorporation of atomic monovalent copper ions (Cu + ) and concurrent sulfur vacancies (V s ), resulting in a photocatalyst denoted as G-CZS 1−x . Through the cooperative action of these atomic Cu dopants and Vs, G-CZS 1−x significantly extends its photoabsorption range to encompass the full spectrum (200−2100 nm), which improves the solar utilization ability. This alteration enhances the efficiency of charge separation and optimizes Δ(H*) (free energy of hydrogen adsorption) to approach 0 eV for the hydrogen evolution reaction (HER). It is noteworthy that both surface-exposed atomic Cu and V s act as active sites for photocatalysis. G-CZS 1−x exhibits a significant H 2 evolution rate of 1.01 mmol h −1 in the absence of a cocatalyst. This performance exceeds the majority of previously reported photocatalysts, exhibiting approximately 25-fold as ZnS, and 5-fold as H-CZS 1−x with homogeneous distribution of equal content Cu dopants and Vs. In contrast to G-CZS 1−x , the H adsorption on Cu sites for H-CZS 1−x (ΔG(H*) = −1.22 eV) is excessively strong to inhibit the H 2 release, and the charge separation efficiency for H-CZS 1−x is relatively sluggish, revealing the positive role of a gradient distribution model of dopants and defects on activity enhancement. This work highlights the synergy of atomic dopants and defects in advancing photoactivity, as well as the significant benefit of the controllable distribution model of dopants and defects for photocatalysis.

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Section: Methodsmentioning

confidence: 99%

A Full-Spectrum ZnS Photocatalyst with Gradient Distribution of Atomic Copper Dopants and Concomitant Sulfur Vacancies for Highly Efficient Hydrogen Evolution

Bao,

Ali,

Dai

et al. 2024

ACS Nano

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“…17 In our previous work, Zr-C 3 N 6 and Hf-C 3 N 6 were identified to exhibit efficient adsorption of HCHO. 18 However, SAs as the HCHO detection material remain short of industrial requirements and the single active site of SAs limit their adsorption for HCHO.…”

Section: Introductionmentioning

confidence: 99%

Synergistic effect of diatomic materials on efficient formaldehyde sensing and degradation

Zhu,

Tao,

Zhang

et al. 2024

J. Mater. Chem. A

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“…Among various CH 2 O remediation technologies, the photocatalytic oxidation of CH 2 O, with its green, economical, and efficient characteristics, emerges as a promising means to mitigate the hazards of CH 2 O [ 7 , 8 ]. Numerous inorganic semiconductors, such as TiO 2 [ 9 , 10 , 11 , 12 ], BiVO 4 [ 13 ], g-C 3 N 4 [ 14 ], ZnO [ 15 ], single-atom catalysts [ 16 ], and metal–organic frameworks (MOFs) [ 17 , 18 ], have been applied in the research on CH 2 O photooxidation. Despite these materials displaying certain levels of CH 2 O degradation performance, the efficient degradation of CH 2 O over inorganic semiconductors is hindered by the severe recombination of photogenerated charges [ 19 , 20 , 21 , 22 ].…”

Section: Introductionmentioning

confidence: 99%

“…Thus, embedding dual-atom catalysts in COFs presents a substantial opportunity to surpass the constraints of single-atom catalysts. However, the precise design and successful construction of dual-atom catalyst loading sites on COFs remain significant experimental challenges with few successes [ 16 ]. Thus, the strategic design of dual-atom photocatalysts becomes imperative to direct experimental synthesis and unveil the underlying mechanisms of CH 2 O photooxidation.…”

Section: Introductionmentioning

confidence: 99%

Complete Photooxidation of Formaldehyde to CO2 via Ni-Dual-Atom Decorated Crystalline Triazine Frameworks: A DFT Study

Lu,

Wang

2024

Toxics

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Formaldehyde (CH2O) emerges as a significant air pollutant, necessitating effective strategies for its oxidation to mitigate adverse impacts on human health and the environment. Among various technologies, the photooxidation of CH2O stands out owing to its affordability, safety, and effectiveness. Nitrogen-rich crystalline triazine-based organic frameworks (CTFs) exhibit considerable potential in this domain. Nevertheless, the weak and unstable CH2O adsorption hinders the overall oxidation efficiency of CTF. To address this limitation, we incorporate single and dual Ni atoms into nitrogen-rich CTFs by density functional theory (DFT) calculations, resulting in CTF-Ni and CTF-2Ni. This strategic modification significantly enhances the adsorption capability of CH2O. Notably, this synergy between Ni dual atoms activates CH2O by strong chemical adsorption, thereby reducing the energy barrier of CH2O oxidation and achieving the complete oxidation of CH2O to CO2. Moreover, the introduction of dual-atom Ni over CTF ameliorates visible and near-infrared light absorption and facilitates photoexcited charge transfer and separation. Finally, the underlying mechanisms of complete CH2O oxidation over CTF-2Ni are proposed. This work offers novel insights into the rational design of photocatalysts for CH2O oxidation through the integration of Ni dual atoms into CTFs.

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Efficient degradation of formaldehyde based on DFT-screened metal-doped C₃N₆ monolayer photocatalysts: performance evaluation and mechanistic insights

Abstract: Photocatalytic oxidation is an efficient and promising technology for reducing indoor pollution levels of formaldehyde (HCHO).

Cited by 13 publications

References 49 publications

A Full-Spectrum ZnS Photocatalyst with Gradient Distribution of Atomic Copper Dopants and Concomitant Sulfur Vacancies for Highly Efficient Hydrogen Evolution

A Full-Spectrum ZnS Photocatalyst with Gradient Distribution of Atomic Copper Dopants and Concomitant Sulfur Vacancies for Highly Efficient Hydrogen Evolution

Synergistic effect of diatomic materials on efficient formaldehyde sensing and degradation

Complete Photooxidation of Formaldehyde to CO2 via Ni-Dual-Atom Decorated Crystalline Triazine Frameworks: A DFT Study

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Efficient degradation of formaldehyde based on DFT-screened metal-doped C3N6 monolayer photocatalysts: performance evaluation and mechanistic insights

Abstract: Photocatalytic oxidation is an efficient and promising technology for reducing indoor pollution levels of formaldehyde (HCHO).

Cited by 13 publications

References 49 publications

A Full-Spectrum ZnS Photocatalyst with Gradient Distribution of Atomic Copper Dopants and Concomitant Sulfur Vacancies for Highly Efficient Hydrogen Evolution

A Full-Spectrum ZnS Photocatalyst with Gradient Distribution of Atomic Copper Dopants and Concomitant Sulfur Vacancies for Highly Efficient Hydrogen Evolution

Synergistic effect of diatomic materials on efficient formaldehyde sensing and degradation

Complete Photooxidation of Formaldehyde to CO2 via Ni-Dual-Atom Decorated Crystalline Triazine Frameworks: A DFT Study

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Efficient degradation of formaldehyde based on DFT-screened metal-doped C₃N₆ monolayer photocatalysts: performance evaluation and mechanistic insights