Co-adsorption enhancement of formaldehyde/carbon dioxide over modified hexagonal boron nitride for whole-surface capture purification

Co-adsorption enhancement of formaldehyde/carbon dioxide over modified hexagonal boron nitride for whole-surface capture purification

Simultaneous capture of formaldehyde (HCHO) and carbon dioxide (CO2) in indoor air is promising of achieving indoor-air purification. Of all potential adsorbents, hexagonal boron nitride (h-BN) is one of the most suitable species owing to facile formation of attraction points. Therefore, in this stu...

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Veröffentlicht in:Journal of environmental management 2024-04, Vol.356, p.120586-120586, Article 120586
Hauptverfasser: Nan, Yanli, Feng, Chi, Zhuo, Yuqun, Hu, Pengbo
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Sprache:eng
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adsorbents
adsorption
air
boron nitride
Carbon dioxide
Co-adsorption enhancement
deformation
density functional theory
DFT
environmental management
Formaldehyde
hydrogen
Indoor air purification
species
thermodynamics
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container_title Journal of environmental management
container_volume 356
creator Nan, Yanli
Feng, Chi
Zhuo, Yuqun
Hu, Pengbo
description Simultaneous capture of formaldehyde (HCHO) and carbon dioxide (CO2) in indoor air is promising of achieving indoor-air purification. Of all potential adsorbents, hexagonal boron nitride (h-BN) is one of the most suitable species owing to facile formation of attraction points. Therefore, in this study, performances of HCHO and CO2 being adsorbed over pure/modified h-BN are systematically investigated via density functional theory (DFT) calculations. Minutely speaking, direct interaction between HCHO and CO2, single-point adsorption enhancement of HCHO over modified h-BN, co-adsorption reinforcement of HCHO/CO2 as well as relevant thermodynamic characteristics are major research contents. According to calculation results, there is relatively strong attraction between HCHO and CO2 owing to hydrogen bonds, which is in favor of co-adsorption of HCHO/CO2. As to single-adsorption of HCHO, C-doped h-BN shows better adsorption features than P-doped h-BN and C/P-doped h-BN is slightly weakened in adsorption ability due to surficial deformation caused by P atoms. For co-adsorption of HCHO/CO2, CO2 is the protagonist via formation of quasi-carbonate with the help of delocalized π-orbital electrons. Regarding effects of temperatures on adsorption strengths, they depend on interelectronic interactions among dopant atoms and finally derives from dispersion of π bonds across adsorbents. Overall, this study provides detailed mechanisms for co-capture of HCHO/CO2 to accomplish indoor-air purification. [Display omitted] •Adsorption of HCHO is weak over pure h-BN and improved by doping of C and P atoms.•Doping of C atoms is more useful owing to active electrons and deformed surfaces.•CO2 is a leading role in co-adsorption and HCHO is adsorbed mainly through CO2.•Dispersion of delocalized π-bonds is key to co-adsorption at different temperature.•Linkage effects of HCHO/CO2 over modified h-BN help capture more HCHO than pure one.
doi_str_mv 10.1016/j.jenvman.2024.120586
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For co-adsorption of HCHO/CO2, CO2 is the protagonist via formation of quasi-carbonate with the help of delocalized π-orbital electrons. Regarding effects of temperatures on adsorption strengths, they depend on interelectronic interactions among dopant atoms and finally derives from dispersion of π bonds across adsorbents. Overall, this study provides detailed mechanisms for co-capture of HCHO/CO2 to accomplish indoor-air purification. [Display omitted] •Adsorption of HCHO is weak over pure h-BN and improved by doping of C and P atoms.•Doping of C atoms is more useful owing to active electrons and deformed surfaces.•CO2 is a leading role in co-adsorption and HCHO is adsorbed mainly through CO2.•Dispersion of delocalized π-bonds is key to co-adsorption at different temperature.•Linkage effects of HCHO/CO2 over modified h-BN help capture more HCHO than pure one.</description><identifier>ISSN: 0301-4797</identifier><identifier>EISSN: 1095-8630</identifier><identifier>DOI: 10.1016/j.jenvman.2024.120586</identifier><identifier>PMID: 38513581</identifier><language>eng</language><publisher>England: Elsevier Ltd</publisher><subject>adsorbents ; adsorption ; air ; boron nitride ; Carbon dioxide ; Co-adsorption enhancement ; deformation ; density functional theory ; DFT ; environmental management ; Formaldehyde ; hydrogen ; Indoor air purification ; species ; thermodynamics</subject><ispartof>Journal of environmental management, 2024-04, Vol.356, p.120586-120586, Article 120586</ispartof><rights>2024 Elsevier Ltd</rights><rights>Copyright © 2024 Elsevier Ltd. 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Of all potential adsorbents, hexagonal boron nitride (h-BN) is one of the most suitable species owing to facile formation of attraction points. Therefore, in this study, performances of HCHO and CO2 being adsorbed over pure/modified h-BN are systematically investigated via density functional theory (DFT) calculations. Minutely speaking, direct interaction between HCHO and CO2, single-point adsorption enhancement of HCHO over modified h-BN, co-adsorption reinforcement of HCHO/CO2 as well as relevant thermodynamic characteristics are major research contents. According to calculation results, there is relatively strong attraction between HCHO and CO2 owing to hydrogen bonds, which is in favor of co-adsorption of HCHO/CO2. As to single-adsorption of HCHO, C-doped h-BN shows better adsorption features than P-doped h-BN and C/P-doped h-BN is slightly weakened in adsorption ability due to surficial deformation caused by P atoms. For co-adsorption of HCHO/CO2, CO2 is the protagonist via formation of quasi-carbonate with the help of delocalized π-orbital electrons. Regarding effects of temperatures on adsorption strengths, they depend on interelectronic interactions among dopant atoms and finally derives from dispersion of π bonds across adsorbents. Overall, this study provides detailed mechanisms for co-capture of HCHO/CO2 to accomplish indoor-air purification. 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Of all potential adsorbents, hexagonal boron nitride (h-BN) is one of the most suitable species owing to facile formation of attraction points. Therefore, in this study, performances of HCHO and CO2 being adsorbed over pure/modified h-BN are systematically investigated via density functional theory (DFT) calculations. Minutely speaking, direct interaction between HCHO and CO2, single-point adsorption enhancement of HCHO over modified h-BN, co-adsorption reinforcement of HCHO/CO2 as well as relevant thermodynamic characteristics are major research contents. According to calculation results, there is relatively strong attraction between HCHO and CO2 owing to hydrogen bonds, which is in favor of co-adsorption of HCHO/CO2. As to single-adsorption of HCHO, C-doped h-BN shows better adsorption features than P-doped h-BN and C/P-doped h-BN is slightly weakened in adsorption ability due to surficial deformation caused by P atoms. For co-adsorption of HCHO/CO2, CO2 is the protagonist via formation of quasi-carbonate with the help of delocalized π-orbital electrons. Regarding effects of temperatures on adsorption strengths, they depend on interelectronic interactions among dopant atoms and finally derives from dispersion of π bonds across adsorbents. Overall, this study provides detailed mechanisms for co-capture of HCHO/CO2 to accomplish indoor-air purification. [Display omitted] •Adsorption of HCHO is weak over pure h-BN and improved by doping of C and P atoms.•Doping of C atoms is more useful owing to active electrons and deformed surfaces.•CO2 is a leading role in co-adsorption and HCHO is adsorbed mainly through CO2.•Dispersion of delocalized π-bonds is key to co-adsorption at different temperature.•Linkage effects of HCHO/CO2 over modified h-BN help capture more HCHO than pure one.</abstract><cop>England</cop><pub>Elsevier Ltd</pub><pmid>38513581</pmid><doi>10.1016/j.jenvman.2024.120586</doi><tpages>1</tpages><orcidid>https://orcid.org/0000-0002-4019-751X</orcidid></addata></record>
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subjects adsorbents
adsorption
air
boron nitride
Carbon dioxide
Co-adsorption enhancement
deformation
density functional theory
DFT
environmental management
Formaldehyde
hydrogen
Indoor air purification
species
thermodynamics
title Co-adsorption enhancement of formaldehyde/carbon dioxide over modified hexagonal boron nitride for whole-surface capture purification
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