Insight into the mechanism of boron-doping of carbon aerogel for enhancing the activity of low-temperature selective catalytic reduction of NO with NH

Boron-doping of carbon aerogel (B-CA) was enabled by incorporating phenylboronic acid in the sol-gel process into the organic gel from resorcinol-formaldehyde and the role of boron-doping on the catalytic activity in selective reduction of NO with NH 3 (NH 3 -SCR) in comparison with the undoped one...

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Veröffentlicht in:	Catalysis science & technology 2021-03, Vol.11 (6), p.257-272
Hauptverfasser:	Yang, Minghe, Wang, He, Jin, Shuangling, Zhang, Rui, Wang, Yan, Huo, Wanying, Wang, Xiaorui, Jin, Minglin, Qiao, Wenming, Ling, Licheng
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container_title	Catalysis science & technology
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creator	Yang, Minghe Wang, He Jin, Shuangling Zhang, Rui Wang, Yan Huo, Wanying Wang, Xiaorui Jin, Minglin Qiao, Wenming Ling, Licheng
description	Boron-doping of carbon aerogel (B-CA) was enabled by incorporating phenylboronic acid in the sol-gel process into the organic gel from resorcinol-formaldehyde and the role of boron-doping on the catalytic activity in selective reduction of NO with NH 3 (NH 3 -SCR) in comparison with the undoped one (CA) was investigated. Results indicate that both B-CA and CA exhibit a mesopore-micropore structure while B-CA has a boron content of 3.62 at% in the forms of BC3 (each boron bonded with three carbon atoms), BC2O (each boron bonded with two carbon atoms and one oxygen atom) and BCO2 (each boron bonded with one carbon atom and two oxygen atoms). Boron doping significantly reduces the apparent activation energy of the NH 3 -SCR from 53.9 to 23.76 kJ mol −1 at the temperature regime (80-120 °C) while the apparent activation energy is a negative value of −19.15 kJ mol −1 between 140 and 200 °C. DFT calculation of a model graphene structure incorporated with BC3, BC2O and BCO2 sites reveals that NH 3 adsorption is exothermic most on BCO2 and has a negative temperature dependence, which is mainly associated with the Lewis acid sites having electron deficiency boron atoms while O 2 adsorption is endothermic least on BC3 and has a positive temperature dependence. The Lewis acid sites in B-CA play an important role in adsorption and dissociation of NH 3 and O 2 , which is favorable for NO reduction to N 2 via NH 3 -SCR. The intermediates and species identified by the time-varying in situ DRIFTS indicate that B-CA has both a higher catalytic activity for NH 3 dissociation to give more abundant hydrogen-bonded ammonia species and a higher catalytic activity for NO oxidation by O 2 to form NO 2 than CA, which jointly contribute to the higher NO conversion rate to nitrogen via NH 3 -SCR on B-CA. Moreover, carbon oxidation on CA surface by NO + O 2 is much easier than that on B-CA while the latter is negligible. Boron doped carbon aerogel could increase the number of active sites effectively and enhance NO reduction to N 2 via NH 3 -SCR.
doi_str_mv	10.1039/d0cy02006k
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Results indicate that both B-CA and CA exhibit a mesopore-micropore structure while B-CA has a boron content of 3.62 at% in the forms of BC3 (each boron bonded with three carbon atoms), BC2O (each boron bonded with two carbon atoms and one oxygen atom) and BCO2 (each boron bonded with one carbon atom and two oxygen atoms). Boron doping significantly reduces the apparent activation energy of the NH 3 -SCR from 53.9 to 23.76 kJ mol −1 at the temperature regime (80-120 °C) while the apparent activation energy is a negative value of −19.15 kJ mol −1 between 140 and 200 °C. DFT calculation of a model graphene structure incorporated with BC3, BC2O and BCO2 sites reveals that NH 3 adsorption is exothermic most on BCO2 and has a negative temperature dependence, which is mainly associated with the Lewis acid sites having electron deficiency boron atoms while O 2 adsorption is endothermic least on BC3 and has a positive temperature dependence. The Lewis acid sites in B-CA play an important role in adsorption and dissociation of NH 3 and O 2 , which is favorable for NO reduction to N 2 via NH 3 -SCR. The intermediates and species identified by the time-varying in situ DRIFTS indicate that B-CA has both a higher catalytic activity for NH 3 dissociation to give more abundant hydrogen-bonded ammonia species and a higher catalytic activity for NO oxidation by O 2 to form NO 2 than CA, which jointly contribute to the higher NO conversion rate to nitrogen via NH 3 -SCR on B-CA. Moreover, carbon oxidation on CA surface by NO + O 2 is much easier than that on B-CA while the latter is negligible. Boron doped carbon aerogel could increase the number of active sites effectively and enhance NO reduction to N 2 via NH 3 -SCR.</description><identifier>ISSN: 2044-4753</identifier><identifier>EISSN: 2044-4761</identifier><identifier>DOI: 10.1039/d0cy02006k</identifier><ispartof>Catalysis science & technology, 2021-03, Vol.11 (6), p.257-272</ispartof><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27922,27923</link.rule.ids></links><search><creatorcontrib>Yang, Minghe</creatorcontrib><creatorcontrib>Wang, He</creatorcontrib><creatorcontrib>Jin, Shuangling</creatorcontrib><creatorcontrib>Zhang, Rui</creatorcontrib><creatorcontrib>Wang, Yan</creatorcontrib><creatorcontrib>Huo, Wanying</creatorcontrib><creatorcontrib>Wang, Xiaorui</creatorcontrib><creatorcontrib>Jin, Minglin</creatorcontrib><creatorcontrib>Qiao, Wenming</creatorcontrib><creatorcontrib>Ling, Licheng</creatorcontrib><title>Insight into the mechanism of boron-doping of carbon aerogel for enhancing the activity of low-temperature selective catalytic reduction of NO with NH</title><title>Catalysis science & technology</title><description>Boron-doping of carbon aerogel (B-CA) was enabled by incorporating phenylboronic acid in the sol-gel process into the organic gel from resorcinol-formaldehyde and the role of boron-doping on the catalytic activity in selective reduction of NO with NH 3 (NH 3 -SCR) in comparison with the undoped one (CA) was investigated. Results indicate that both B-CA and CA exhibit a mesopore-micropore structure while B-CA has a boron content of 3.62 at% in the forms of BC3 (each boron bonded with three carbon atoms), BC2O (each boron bonded with two carbon atoms and one oxygen atom) and BCO2 (each boron bonded with one carbon atom and two oxygen atoms). Boron doping significantly reduces the apparent activation energy of the NH 3 -SCR from 53.9 to 23.76 kJ mol −1 at the temperature regime (80-120 °C) while the apparent activation energy is a negative value of −19.15 kJ mol −1 between 140 and 200 °C. DFT calculation of a model graphene structure incorporated with BC3, BC2O and BCO2 sites reveals that NH 3 adsorption is exothermic most on BCO2 and has a negative temperature dependence, which is mainly associated with the Lewis acid sites having electron deficiency boron atoms while O 2 adsorption is endothermic least on BC3 and has a positive temperature dependence. The Lewis acid sites in B-CA play an important role in adsorption and dissociation of NH 3 and O 2 , which is favorable for NO reduction to N 2 via NH 3 -SCR. The intermediates and species identified by the time-varying in situ DRIFTS indicate that B-CA has both a higher catalytic activity for NH 3 dissociation to give more abundant hydrogen-bonded ammonia species and a higher catalytic activity for NO oxidation by O 2 to form NO 2 than CA, which jointly contribute to the higher NO conversion rate to nitrogen via NH 3 -SCR on B-CA. Moreover, carbon oxidation on CA surface by NO + O 2 is much easier than that on B-CA while the latter is negligible. 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Results indicate that both B-CA and CA exhibit a mesopore-micropore structure while B-CA has a boron content of 3.62 at% in the forms of BC3 (each boron bonded with three carbon atoms), BC2O (each boron bonded with two carbon atoms and one oxygen atom) and BCO2 (each boron bonded with one carbon atom and two oxygen atoms). Boron doping significantly reduces the apparent activation energy of the NH 3 -SCR from 53.9 to 23.76 kJ mol −1 at the temperature regime (80-120 °C) while the apparent activation energy is a negative value of −19.15 kJ mol −1 between 140 and 200 °C. DFT calculation of a model graphene structure incorporated with BC3, BC2O and BCO2 sites reveals that NH 3 adsorption is exothermic most on BCO2 and has a negative temperature dependence, which is mainly associated with the Lewis acid sites having electron deficiency boron atoms while O 2 adsorption is endothermic least on BC3 and has a positive temperature dependence. The Lewis acid sites in B-CA play an important role in adsorption and dissociation of NH 3 and O 2 , which is favorable for NO reduction to N 2 via NH 3 -SCR. The intermediates and species identified by the time-varying in situ DRIFTS indicate that B-CA has both a higher catalytic activity for NH 3 dissociation to give more abundant hydrogen-bonded ammonia species and a higher catalytic activity for NO oxidation by O 2 to form NO 2 than CA, which jointly contribute to the higher NO conversion rate to nitrogen via NH 3 -SCR on B-CA. Moreover, carbon oxidation on CA surface by NO + O 2 is much easier than that on B-CA while the latter is negligible. Boron doped carbon aerogel could increase the number of active sites effectively and enhance NO reduction to N 2 via NH 3 -SCR.</abstract><doi>10.1039/d0cy02006k</doi><tpages>16</tpages></addata></record>
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title	Insight into the mechanism of boron-doping of carbon aerogel for enhancing the activity of low-temperature selective catalytic reduction of NO with NH
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