Nitrogen-Doped Graphdiyne Nanotubes for Metal-Free Activation of Peroxymonosulfate and Enhanced Degradation of Recalcitrant Heterocyclic Contaminants

Zhang, Chao; Zhang, Huike; Wan, Xin; Xie, Yue; Bentel, Michael J.; Yu, Ziqing; Chen, Zhenguo; He, Jiaan; Li, Junlang; Xiang, Xuezhu; Wang, Xinzhi; Wang, Zhaoli; Ying, Guang‐Guo; Dionysiou, Dionysios D.; Huang, Mingzhi

doi:10.1021/acsestengg.3c00009

Cited by 8 publications

(5 citation statements)

References 64 publications

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“…Metal-involved catalysts have the potential to produce both radical and nonradical species. , Graphitic carbon-based materials tend to mediate electron transfer, resulting in reaction progression via nonradical pathways . Nitrogen doping is commonly considered to be an effective method to optimize the electron configuration of carbonaceous materials, thereby enhancing their catalytic ability to promote 1 O 2 generation from PS. , N-doped biochar (NBC) is the most commonly utilized method for carbon-based catalyst modification, with the active sites on the surface of NBC significantly promoting the generation of radical and nonradical species, further accelerating the degradation of pollutants . It has been shown that NBCs give better catalytic performance for tetracycline degradation of persulfate compared to that of typical graphitic carbon (graphite powder, graphene oxide and multiwalled carbon nanotubes) .…”

Section: Introductionmentioning

confidence: 99%

Deciphering N-Doped Biochar Design for Non-Radical Pathways through Hierarchical Machine Learning

Wang,

He,

Chen

et al. 2024

ACS EST Eng.

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Biochar has been widely employed for the promotion of advanced oxidation processes (AOPs) and when combined with nitrogen doping for charge distribution mediation, N-doped biochar (NBC) can serve as a highly effective catalyst for the degradation of persistent organic pollutants. However, due to the variety of doping and preparation methods, the intrinsic active sites for AOP catalysis have not been clearly identified. Furthermore, the complex relationships between preparation method, material properties, and catalytic degradation pathways remain unclear, impeding the widespread practical application of NBC. Herein, machine learning (ML) was implemented to predict the degradation pathway and identify the vital properties of N-doping required for the acceleration of AOPs. During the process of model training, an innovative method of data set splitting was applied, comparing the results generated from multiple models to enhance model interpretability. We elucidated the correlation between the primary features and nonradical pathway, focusing on the contribution of N species and the regulatory role of pyrolysis temperature. Detailed insights were further provided to enhance the ratio design of NBC for nonradical mediation. Overall, this study offers novel insights into NBC-mediated AOPs for pollution control, underscoring the significant potential of ML for accelerating catalyst applications.

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Section: Introductionmentioning

confidence: 99%

Deciphering N-Doped Biochar Design for Non-Radical Pathways through Hierarchical Machine Learning

Wang,

He,

Chen

et al. 2024

ACS EST Eng.

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“…[12] PS-AOPs are generally derived by activating peroxymonosulfate (PMS) or peroxydisulfate (PDS) with additional energy sources or catalysts, such as heat, [15] photoexcitation, [16] microwave, [17,18] ultrasound, [19,20] electrical field energies, [21] heterogenous catalysts (i.e., transition metal oxide, metal-free material, and single-atom catalyst). [13,19,[22][23][24][25][26] Although a multitude of studies have exhibited the high efficiency of catalyst activation systems in laboratory conditions, they concurrently confront formidable challenges that bear implications for practical applications. These encompass the requirement for mitigating secondary contamination factors, notably toxic ions and dispersed nanoparticles, and augmenting persulfate (PS) utilization efficiency, which, as it currently stands, demands a PS dose roughly 100 times greater than the organic concentration.…”

Section: Introductionmentioning

confidence: 99%

Sustainable and Rapid Water Purification at the Confined Hydrogel Interface

Chen,

Jiang,

Guan

et al. 2024

Advanced Materials

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Emerging organic contaminants in water matrices have challenged ecosystems and human health safety. Persulfate‐based advanced oxidation processes (PS‐AOPs) have attracted much attention as they address potential water purification challenges. However, overcoming the mass transfer constraint and the catalyst's inherent site agglomeration in the heterogeneous system remains urgent. Herein, we propose the abundant metal‐anchored loading (∼6∼8 g m−2) of alginate hydrogel membranes coupled with cross‐flow mode as an efficient strategy for water purification applications. The organic flux of the confined hydrogel interfaces sharply enlarges with the reduction of the thickness of the boundary layer via the pressure field. The normalized property of our system displayed a remarkable organic (sulfonamides) elimination rate of 4.87 × 104 mg min−1 mol−1. Furthermore, due to the fast reaction time (<1 min), cross‐flow mode only reached a meager energy cost (∼2.21 Wh m−3) under the pressure drive field. We anticipate that this finding provides insight into the novel design with ultrafast organic removal performance and low techno‐economic cost (i.e., energy operation cost, material, and reagent cost) for the field of water purification under various PS‐AOPs challenging scenarios.This article is protected by copyright. All rights reserved

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“…Many previous studies regarding SACs present the substrates based on sp 2 -hybridized carbon materials, e.g., nanotubes − and graphene. − However, sp-hybridized carbon-based substrates have rarely been studied in the synthesis of SACs. Graphdiyne and γ-graphyne, as artificial π-conjugated carbon allotropes, possess a 2D framework with sp 2 - and sp-hybridized carbon atoms. − Compared to sp 2 -hybridized carbon frameworks, the structural linearity of the carbon–carbon triple bond (sp-hybridized carbons) avoids the fluctuation arising from cis – trans isomerization and has small steric demands. , Importantly, the absence of hexagonal symmetry and two self-doped nonequivalent distorted Dirac cones endow graphdiyne and γ-graphyne with electronic conduction properties superior to those of sp 2 -hybridized carbons. , Previous studies also show that graphdiyne substrates are more appropriate for nitrogen-doping modification compared with graphene series materials . The abundant nitrogen sites on carbonaceous substrates were verified in previous studies to anchor atomically dispersed metal sites .…”

Section: Introductionmentioning

confidence: 99%

High-Loading Single-Atom Ru Catalysts Anchored on N-Doped Graphdiyne/γ-Graphyne Quantum Dots for Selective Hydrodehalogenation and Hydrodearomatization

Zhang,

Li,

Xie

et al. 2023

ACS Catal.

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Selective hydrodehalogenation and hydrodearomatization of toxic chlorophenols into value-added chemicals represents a grand challenge for their efficient reutilization. For this purpose, single-atom catalysts (SACs) could be a strategy with relatively high catalytic selectivity and atom utilization but suffer from the catalytic limitation caused by low metal loading densities. Graphdiyne and γ-graphyne are considered promising substrates of SACs with excellent catalytic properties. Additionally, their quantum dots with nanometer size are expected to supply numerous surface anchoring sites and large atom spacing to confine metal cations to synthesize high-loading SACs. Here we report a synthesis approach for high-loading Ru SACs anchored on graphdiyne/γ-graphyne quantum dots (GDQD-Ru/GNQD-Ru), which exhibit remarkably higher turnover frequency (TOF) and selectivity (>99%) of hydrodehalogenation and hydrodearomatization of chlorophenols than graphdiyne/γ-graphyne nanosheet-based Ru SACs and nanoparticles. There is no significant selectivity decrease in chlorophenol transformation by GDQD-Ru/GNQD-Ru observed in 5 catalyst reuse cycles. GDQD-Ru/GNQD-Ru contribute to nearly exclusive hydrodehalogenation and hydrodearomatization without altering any other bonds in chlorophenols. Experimental results and theoretical calculations reveal that GDQD-Ru is more prone to lower energies of rate-limiting steps in H 2 -driven chlorophenol transformation than GNQD-Ru. The results confirm that graphdiyne/γ-graphyne quantum dots play crucial roles in facilitating the metal atom loading of SACs. Ru loadings are 27.6 and 16.0 wt % in GDQD-Ru/ GNQD-Ru, approximately 7-fold and 4-fold higher than reported Ru SACs, respectively. This study provides mechanistic insights toward the roles of high-loading Ru SACs on sp-and sp 2 -hybridized carbonaceous substrates in selective hydrodehalogenation and hydrodearomatization.

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Nitrogen-Doped Graphdiyne Nanotubes for Metal-Free Activation of Peroxymonosulfate and Enhanced Degradation of Recalcitrant Heterocyclic Contaminants

Cited by 8 publications

References 64 publications

Deciphering N-Doped Biochar Design for Non-Radical Pathways through Hierarchical Machine Learning

Deciphering N-Doped Biochar Design for Non-Radical Pathways through Hierarchical Machine Learning

Sustainable and Rapid Water Purification at the Confined Hydrogel Interface

High-Loading Single-Atom Ru Catalysts Anchored on N-Doped Graphdiyne/γ-Graphyne Quantum Dots for Selective Hydrodehalogenation and Hydrodearomatization

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