Eintrag weiter verarbeiten
Online-Ressource

High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species

Gespeichert in:

Bibliographische Detailangaben
Zeitschriftentitel: Catalysts
Personen und Körperschaften: Gao, Yan, Jiang, Wenchao, Luan, Tao, Li, Hui, Zhang, Wenke, Feng, Wenchen, Jiang, Haolin
In: Catalysts, 9, 2019, 1, S. 103
Format: E-Article
Sprache: Englisch
veröffentlicht:
MDPI AG
Schlagwörter:
Physical and Theoretical Chemistry
Catalysis
author_facet Gao, Yan
Jiang, Wenchao
Luan, Tao
Li, Hui
Zhang, Wenke
Feng, Wenchen
Jiang, Haolin
Gao, Yan
Jiang, Wenchao
Luan, Tao
Li, Hui
Zhang, Wenke
Feng, Wenchen
Jiang, Haolin
author Gao, Yan
Jiang, Wenchao
Luan, Tao
Li, Hui
Zhang, Wenke
Feng, Wenchen
Jiang, Haolin
spellingShingle Gao, Yan
Jiang, Wenchao
Luan, Tao
Li, Hui
Zhang, Wenke
Feng, Wenchen
Jiang, Haolin
Catalysts
High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
Physical and Theoretical Chemistry
Catalysis
author_sort gao, yan
spelling Gao, Yan Jiang, Wenchao Luan, Tao Li, Hui Zhang, Wenke Feng, Wenchen Jiang, Haolin 2073-4344 MDPI AG Physical and Theoretical Chemistry Catalysis http://dx.doi.org/10.3390/catal9010103 <jats:p>Three typical Mn-based bimetallic nanocatalysts of Mn−Fe/TiO2, Mn−Co/TiO2, Mn−Ce/TiO2 were synthesized via the hydrothermal method to reveal the synergistic effects of dielectric barrier discharge (DBD) plasma and bimetallic nanocatalysts on NOx catalytic conversion. The plasma-catalyst hybrid catalysis was investigated compared with the catalytic effects of plasma alone and nanocatalyst alone. During the catalytic process of catalyst alone, the catalytic activities of all tested catalysts were lower than 20% at ambient temperature. While in the plasma-catalyst hybrid catalytic process, NOx conversion significantly improved with discharge energy enlarging. The maximum NOx conversion of about 99.5% achieved over Mn−Ce/TiO2 under discharge energy of 15 W·h/m3 at ambient temperature. The reaction temperature had an inhibiting effect on plasma-catalyst hybrid catalysis. Among these three Mn-based bimetallic nanocatalysts, Mn−Ce/TiO2 displayed the optimal catalytic property with higher catalytic activity and superior selectivity in the plasma-catalyst hybrid catalytic process. Furthermore, the physicochemical properties of these three typical Mn-based bimetallic nanocatalysts were analyzed by N2 adsorption, Transmission Electron Microscope (TEM), X-ray diffraction (XRD), H2-temperature-programmed reduction (TPR), NH3-temperature-programmed desorption (TPD), and X-ray photoelectron spectroscopy (XPS). The multiple characterizations demonstrated that the plasma-catalyst hybrid catalytic performance was highly dependent on the phase compositions. Mn−Ce/TiO2 nanocatalyst presented the optimal structure characteristic among all tested samples, with the largest surface area, the minished particle sizes, the reduced crystallinity, and the increased active components distributions. In the meantime, the ratios of Mn4+/(Mn2+ + Mn3+ + Mn4+) in the Mn−Ce/TiO2 sample was the highest, which was beneficial to plasma-catalyst hybrid catalysis. Generally, it was verified that the plasma-catalyst hybrid catalytic process with the Mn-based bimetallic nanocatalysts was an effective approach for high-efficiency catalytic conversion of NOx, especially at ambient temperature.</jats:p> High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species Catalysts
doi_str_mv 10.3390/catal9010103
facet_avail Online
Free
finc_class_facet Chemie und Pharmazie
Physik
format ElectronicArticle
fullrecord blob:ai-49-aHR0cDovL2R4LmRvaS5vcmcvMTAuMzM5MC9jYXRhbDkwMTAxMDM
id ai-49-aHR0cDovL2R4LmRvaS5vcmcvMTAuMzM5MC9jYXRhbDkwMTAxMDM
institution DE-Zi4
DE-Gla1
DE-15
DE-Pl11
DE-Rs1
DE-14
DE-105
DE-Ch1
DE-L229
DE-D275
DE-Bn3
DE-Brt1
DE-Zwi2
DE-D161
imprint MDPI AG, 2019
imprint_str_mv MDPI AG, 2019
issn 2073-4344
issn_str_mv 2073-4344
language English
mega_collection MDPI AG (CrossRef)
match_str gao2019highefficiencycatalyticconversionofnoxbythesynergyofnanocatalystandplasmaeffectofmnbasedbimetallicactivespecies
publishDateSort 2019
publisher MDPI AG
recordtype ai
record_format ai
series Catalysts
source_id 49
title High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_unstemmed High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_full High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_fullStr High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_full_unstemmed High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_short High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_sort high-efficiency catalytic conversion of nox by the synergy of nanocatalyst and plasma: effect of mn-based bimetallic active species
topic Physical and Theoretical Chemistry
Catalysis
url http://dx.doi.org/10.3390/catal9010103
publishDate 2019
physical 103
description <jats:p>Three typical Mn-based bimetallic nanocatalysts of Mn−Fe/TiO2, Mn−Co/TiO2, Mn−Ce/TiO2 were synthesized via the hydrothermal method to reveal the synergistic effects of dielectric barrier discharge (DBD) plasma and bimetallic nanocatalysts on NOx catalytic conversion. The plasma-catalyst hybrid catalysis was investigated compared with the catalytic effects of plasma alone and nanocatalyst alone. During the catalytic process of catalyst alone, the catalytic activities of all tested catalysts were lower than 20% at ambient temperature. While in the plasma-catalyst hybrid catalytic process, NOx conversion significantly improved with discharge energy enlarging. The maximum NOx conversion of about 99.5% achieved over Mn−Ce/TiO2 under discharge energy of 15 W·h/m3 at ambient temperature. The reaction temperature had an inhibiting effect on plasma-catalyst hybrid catalysis. Among these three Mn-based bimetallic nanocatalysts, Mn−Ce/TiO2 displayed the optimal catalytic property with higher catalytic activity and superior selectivity in the plasma-catalyst hybrid catalytic process. Furthermore, the physicochemical properties of these three typical Mn-based bimetallic nanocatalysts were analyzed by N2 adsorption, Transmission Electron Microscope (TEM), X-ray diffraction (XRD), H2-temperature-programmed reduction (TPR), NH3-temperature-programmed desorption (TPD), and X-ray photoelectron spectroscopy (XPS). The multiple characterizations demonstrated that the plasma-catalyst hybrid catalytic performance was highly dependent on the phase compositions. Mn−Ce/TiO2 nanocatalyst presented the optimal structure characteristic among all tested samples, with the largest surface area, the minished particle sizes, the reduced crystallinity, and the increased active components distributions. In the meantime, the ratios of Mn4+/(Mn2+ + Mn3+ + Mn4+) in the Mn−Ce/TiO2 sample was the highest, which was beneficial to plasma-catalyst hybrid catalysis. Generally, it was verified that the plasma-catalyst hybrid catalytic process with the Mn-based bimetallic nanocatalysts was an effective approach for high-efficiency catalytic conversion of NOx, especially at ambient temperature.</jats:p>
container_issue 1
container_start_page 0
container_title Catalysts
container_volume 9
format_de105 Article, E-Article
format_de14 Article, E-Article
format_de15 Article, E-Article
format_de520 Article, E-Article
format_de540 Article, E-Article
format_dech1 Article, E-Article
format_ded117 Article, E-Article
format_degla1 E-Article
format_del152 Buch
format_del189 Article, E-Article
format_dezi4 Article
format_dezwi2 Article, E-Article
format_finc Article, E-Article
format_nrw Article, E-Article
_version_ 1792341568963739650
geogr_code not assigned
last_indexed 2024-03-01T16:22:00.515Z
geogr_code_person not assigned
openURL url_ver=Z39.88-2004&ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fvufind.svn.sourceforge.net%3Agenerator&rft.title=High-Efficiency+Catalytic+Conversion+of+NOx+by+the+Synergy+of+Nanocatalyst+and+Plasma%3A+Effect+of+Mn-Based+Bimetallic+Active+Species&rft.date=2019-01-18&genre=article&issn=2073-4344&volume=9&issue=1&pages=103&jtitle=Catalysts&atitle=High-Efficiency+Catalytic+Conversion+of+NOx+by+the+Synergy+of+Nanocatalyst+and+Plasma%3A+Effect+of+Mn-Based+Bimetallic+Active+Species&aulast=Jiang&aufirst=Haolin&rft_id=info%3Adoi%2F10.3390%2Fcatal9010103&rft.language%5B0%5D=eng
SOLR
_version_ 1792341568963739650
author Gao, Yan, Jiang, Wenchao, Luan, Tao, Li, Hui, Zhang, Wenke, Feng, Wenchen, Jiang, Haolin
author_facet Gao, Yan, Jiang, Wenchao, Luan, Tao, Li, Hui, Zhang, Wenke, Feng, Wenchen, Jiang, Haolin, Gao, Yan, Jiang, Wenchao, Luan, Tao, Li, Hui, Zhang, Wenke, Feng, Wenchen, Jiang, Haolin
author_sort gao, yan
container_issue 1
container_start_page 0
container_title Catalysts
container_volume 9
description <jats:p>Three typical Mn-based bimetallic nanocatalysts of Mn−Fe/TiO2, Mn−Co/TiO2, Mn−Ce/TiO2 were synthesized via the hydrothermal method to reveal the synergistic effects of dielectric barrier discharge (DBD) plasma and bimetallic nanocatalysts on NOx catalytic conversion. The plasma-catalyst hybrid catalysis was investigated compared with the catalytic effects of plasma alone and nanocatalyst alone. During the catalytic process of catalyst alone, the catalytic activities of all tested catalysts were lower than 20% at ambient temperature. While in the plasma-catalyst hybrid catalytic process, NOx conversion significantly improved with discharge energy enlarging. The maximum NOx conversion of about 99.5% achieved over Mn−Ce/TiO2 under discharge energy of 15 W·h/m3 at ambient temperature. The reaction temperature had an inhibiting effect on plasma-catalyst hybrid catalysis. Among these three Mn-based bimetallic nanocatalysts, Mn−Ce/TiO2 displayed the optimal catalytic property with higher catalytic activity and superior selectivity in the plasma-catalyst hybrid catalytic process. Furthermore, the physicochemical properties of these three typical Mn-based bimetallic nanocatalysts were analyzed by N2 adsorption, Transmission Electron Microscope (TEM), X-ray diffraction (XRD), H2-temperature-programmed reduction (TPR), NH3-temperature-programmed desorption (TPD), and X-ray photoelectron spectroscopy (XPS). The multiple characterizations demonstrated that the plasma-catalyst hybrid catalytic performance was highly dependent on the phase compositions. Mn−Ce/TiO2 nanocatalyst presented the optimal structure characteristic among all tested samples, with the largest surface area, the minished particle sizes, the reduced crystallinity, and the increased active components distributions. In the meantime, the ratios of Mn4+/(Mn2+ + Mn3+ + Mn4+) in the Mn−Ce/TiO2 sample was the highest, which was beneficial to plasma-catalyst hybrid catalysis. Generally, it was verified that the plasma-catalyst hybrid catalytic process with the Mn-based bimetallic nanocatalysts was an effective approach for high-efficiency catalytic conversion of NOx, especially at ambient temperature.</jats:p>
doi_str_mv 10.3390/catal9010103
facet_avail Online, Free
finc_class_facet Chemie und Pharmazie, Physik
format ElectronicArticle
format_de105 Article, E-Article
format_de14 Article, E-Article
format_de15 Article, E-Article
format_de520 Article, E-Article
format_de540 Article, E-Article
format_dech1 Article, E-Article
format_ded117 Article, E-Article
format_degla1 E-Article
format_del152 Buch
format_del189 Article, E-Article
format_dezi4 Article
format_dezwi2 Article, E-Article
format_finc Article, E-Article
format_nrw Article, E-Article
geogr_code not assigned
geogr_code_person not assigned
id ai-49-aHR0cDovL2R4LmRvaS5vcmcvMTAuMzM5MC9jYXRhbDkwMTAxMDM
imprint MDPI AG, 2019
imprint_str_mv MDPI AG, 2019
institution DE-Zi4, DE-Gla1, DE-15, DE-Pl11, DE-Rs1, DE-14, DE-105, DE-Ch1, DE-L229, DE-D275, DE-Bn3, DE-Brt1, DE-Zwi2, DE-D161
issn 2073-4344
issn_str_mv 2073-4344
language English
last_indexed 2024-03-01T16:22:00.515Z
match_str gao2019highefficiencycatalyticconversionofnoxbythesynergyofnanocatalystandplasmaeffectofmnbasedbimetallicactivespecies
mega_collection MDPI AG (CrossRef)
physical 103
publishDate 2019
publishDateSort 2019
publisher MDPI AG
record_format ai
recordtype ai
series Catalysts
source_id 49
spelling Gao, Yan Jiang, Wenchao Luan, Tao Li, Hui Zhang, Wenke Feng, Wenchen Jiang, Haolin 2073-4344 MDPI AG Physical and Theoretical Chemistry Catalysis http://dx.doi.org/10.3390/catal9010103 <jats:p>Three typical Mn-based bimetallic nanocatalysts of Mn−Fe/TiO2, Mn−Co/TiO2, Mn−Ce/TiO2 were synthesized via the hydrothermal method to reveal the synergistic effects of dielectric barrier discharge (DBD) plasma and bimetallic nanocatalysts on NOx catalytic conversion. The plasma-catalyst hybrid catalysis was investigated compared with the catalytic effects of plasma alone and nanocatalyst alone. During the catalytic process of catalyst alone, the catalytic activities of all tested catalysts were lower than 20% at ambient temperature. While in the plasma-catalyst hybrid catalytic process, NOx conversion significantly improved with discharge energy enlarging. The maximum NOx conversion of about 99.5% achieved over Mn−Ce/TiO2 under discharge energy of 15 W·h/m3 at ambient temperature. The reaction temperature had an inhibiting effect on plasma-catalyst hybrid catalysis. Among these three Mn-based bimetallic nanocatalysts, Mn−Ce/TiO2 displayed the optimal catalytic property with higher catalytic activity and superior selectivity in the plasma-catalyst hybrid catalytic process. Furthermore, the physicochemical properties of these three typical Mn-based bimetallic nanocatalysts were analyzed by N2 adsorption, Transmission Electron Microscope (TEM), X-ray diffraction (XRD), H2-temperature-programmed reduction (TPR), NH3-temperature-programmed desorption (TPD), and X-ray photoelectron spectroscopy (XPS). The multiple characterizations demonstrated that the plasma-catalyst hybrid catalytic performance was highly dependent on the phase compositions. Mn−Ce/TiO2 nanocatalyst presented the optimal structure characteristic among all tested samples, with the largest surface area, the minished particle sizes, the reduced crystallinity, and the increased active components distributions. In the meantime, the ratios of Mn4+/(Mn2+ + Mn3+ + Mn4+) in the Mn−Ce/TiO2 sample was the highest, which was beneficial to plasma-catalyst hybrid catalysis. Generally, it was verified that the plasma-catalyst hybrid catalytic process with the Mn-based bimetallic nanocatalysts was an effective approach for high-efficiency catalytic conversion of NOx, especially at ambient temperature.</jats:p> High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species Catalysts
spellingShingle Gao, Yan, Jiang, Wenchao, Luan, Tao, Li, Hui, Zhang, Wenke, Feng, Wenchen, Jiang, Haolin, Catalysts, High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species, Physical and Theoretical Chemistry, Catalysis
title High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_full High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_fullStr High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_full_unstemmed High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_short High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
title_sort high-efficiency catalytic conversion of nox by the synergy of nanocatalyst and plasma: effect of mn-based bimetallic active species
title_unstemmed High-Efficiency Catalytic Conversion of NOx by the Synergy of Nanocatalyst and Plasma: Effect of Mn-Based Bimetallic Active Species
topic Physical and Theoretical Chemistry, Catalysis
url http://dx.doi.org/10.3390/catal9010103