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Intrinsic Electrochemical and Strain Effects in Nanoparticles Full article

Journal The Journal of Physical Chemistry C
ISSN: 1932-7447 , E-ISSN: 1932-7455
Output data Year: 2013, Volume: 117, Number: 5, Pages: 2334-2343 Pages count : 10 DOI: 10.1021/jp3099494
Tags Adsorption; Catalysis; Charge transfer; Density functional theory; Electric fields; Electrocatalysis; Electronic structure; Platinum
Authors Mamatkulov Mikhail 1 , Filhol Jean-Sebastien 2
Affiliations
1 Boreskov Institute of Catalysis, Russian Academy of Sciences, 630090 Novosibirsk, Russia
2 Institut Charles Gerhardt Montpellier UMR 5253 CNRS-UM2-ENSCM-UM1 CTMM, UniversitéMontpellier 2, Batiment 15, ̂CC-15001, Place Eugene Bataillon, 34 095 Montpellier Ce ̀ dex 5, France ́

Funding (2)

1 European Commission
2 The French National Research Agency ANR-06-CIS6-014-03

Abstract: We have performed a density functional theory investigation of the {111} facet of a 201 Pt atom nanoparticle (NP), in order to explain its particular reactivity compared to a corresponding (111) surface. Then, notable differences in physical properties and reactivity between {111} facets and (111) surfaces can be correlated with (i) strain effect due to the contraction of surface Pt–Pt distance and (ii) electrochemical effects due to spontaneous negative charging of the {111} facet leading to a very strong local electric field (20 × 106 V·cm–1). The latter effect only occurs in systems of nanometric size such as nanoparticles because of the combination of the nanoparticle high capacitance and of different local work functions in facets and edges. The nanoparticle {111} facet with an adsorbed CO molecule exhibits an electronic structure, adsorption energy, and C–O stretch frequency extremely close to that of a strained and charged (111) surface. This study suggests that metallic NPs behave like intrinsic electrochemical systems with a potential tuned by their size and shape explaining part of their specific reactivity. Reciprocally, large NP facet reactivity could be investigated by simple charged strained surfaces that would give inexpensive models. Finally, this intrinsic electrochemical effect could be used to better understand charge transfer effects on catalysis and electrocatalysis and help to design new kinds of tunable catalysts.
Cite: Mamatkulov M. , Filhol J-S.
Intrinsic Electrochemical and Strain Effects in Nanoparticles
The Journal of Physical Chemistry C. 2013. V.117. N5. P.2334-2343. DOI: 10.1021/jp3099494 WOS Scopus РИНЦ ANCAN OpenAlex
Dates:
Submitted: Oct 8, 2012
Accepted: Dec 12, 2012
Published online: Jan 29, 2013
Published print: Feb 7, 2013
Identifiers:
Web of science: WOS:000314907700041
Scopus: 2-s2.0-84873426207
Elibrary: 20429622
Chemical Abstracts: 2012:1822043
Chemical Abstracts (print): 158:255792
OpenAlex: W2312298260
Citing:
DB Citing
Web of science 17
Scopus 16
Elibrary 14
OpenAlex 18
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