Phonocatalysis. An ab initio simulation experiment

Phonocatalysis. An ab initio simulation experiment

Using simulations, we postulate and show that heterocatalysis on large-bandgap semiconductors can be controlled by substrate phonons, i.e., phonocatalysis. With ab initio calculations, including molecular dynamic simulations, the chemisorbed dissociation of XeF6 on h-BN surface leads to formation of...

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Main Authors: Kwangnam Kim, Massoud Kaviany
Format: Article
Language:English
Published: AIP Publishing LLC 2016-06-01
Series:AIP Advances
Online Access:http://dx.doi.org/10.1063/1.4955054
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spelling doaj-29402dc2886644f5939d70493fe21cbf2020-11-25T02:26:19ZengAIP Publishing LLCAIP Advances2158-32262016-06-0166065124065124-1010.1063/1.4955054098606ADVPhonocatalysis. An ab initio simulation experimentKwangnam Kim0Massoud Kaviany1 University of Michigan, Department of Mechanical Engineering, Ann Arbor, MI 48105-2125, USA University of Michigan, Department of Mechanical Engineering, Ann Arbor, MI 48105-2125, USAUsing simulations, we postulate and show that heterocatalysis on large-bandgap semiconductors can be controlled by substrate phonons, i.e., phonocatalysis. With ab initio calculations, including molecular dynamic simulations, the chemisorbed dissociation of XeF6 on h-BN surface leads to formation of XeF4 and two surface F/h-BN bonds. The reaction pathway and energies are evaluated, and the sorption and reaction emitted/absorbed phonons are identified through spectral analysis of the surface atomic motion. Due to large bandgap, the atomic vibration (phonon) energy transfer channels dominate and among them is the match between the F/h-BN covalent bond stretching and the optical phonons. We show that the chemisorbed dissociation (the pathway activation ascent) requires absorption of large-energy optical phonons. Then using progressively heavier isotopes of B and N atoms, we show that limiting these high-energy optical phonons inhibits the chemisorbed dissociation, i.e., controllable phonocatalysis.http://dx.doi.org/10.1063/1.4955054
collection DOAJ
language English
format Article
sources DOAJ
author Kwangnam Kim
Massoud Kaviany
spellingShingle Kwangnam Kim
Massoud Kaviany
Phonocatalysis. An ab initio simulation experiment
AIP Advances
author_facet Kwangnam Kim
Massoud Kaviany
author_sort Kwangnam Kim
title Phonocatalysis. An ab initio simulation experiment
title_short Phonocatalysis. An ab initio simulation experiment
title_full Phonocatalysis. An ab initio simulation experiment
title_fullStr Phonocatalysis. An ab initio simulation experiment
title_full_unstemmed Phonocatalysis. An ab initio simulation experiment
title_sort phonocatalysis. an ab initio simulation experiment
publisher AIP Publishing LLC
series AIP Advances
issn 2158-3226
publishDate 2016-06-01
description Using simulations, we postulate and show that heterocatalysis on large-bandgap semiconductors can be controlled by substrate phonons, i.e., phonocatalysis. With ab initio calculations, including molecular dynamic simulations, the chemisorbed dissociation of XeF6 on h-BN surface leads to formation of XeF4 and two surface F/h-BN bonds. The reaction pathway and energies are evaluated, and the sorption and reaction emitted/absorbed phonons are identified through spectral analysis of the surface atomic motion. Due to large bandgap, the atomic vibration (phonon) energy transfer channels dominate and among them is the match between the F/h-BN covalent bond stretching and the optical phonons. We show that the chemisorbed dissociation (the pathway activation ascent) requires absorption of large-energy optical phonons. Then using progressively heavier isotopes of B and N atoms, we show that limiting these high-energy optical phonons inhibits the chemisorbed dissociation, i.e., controllable phonocatalysis.
url http://dx.doi.org/10.1063/1.4955054
work_keys_str_mv AT kwangnamkim phonocatalysisanabinitiosimulationexperiment
AT massoudkaviany phonocatalysisanabinitiosimulationexperiment
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