Catalytic potential of highly defective (211) surfaces of zinc blende ZnO

Chunguang Tang; Hugh F. Wilson; Michelle J.S. Spencer; Amanda S. Barnard

doi:10.1039/c5cp04521e

Catalytic potential of highly defective (211) surfaces of zinc blende ZnO

Chunguang Tang^*, Hugh F. Wilson, Michelle J.S. Spencer, Amanda S. Barnard

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

Zinc blende (ZB) ZnO has gained increasing research interest due to its favorable properties and its stabilization on the nanoscale. While surface properties are important on the nanoscale, the studies on ZB ZnO surface properties are rare. Here we have performed first principles calculations of the energies and structures of ZB and wurtzite (WZ) ZnO surfaces. Our results indicate that, among the four surfaces parallel to the polar axes, such as (1010) and (1120) of the WZ phase and (110) and (211) of the ZB phase, the polar (211) surface has substantially lower surface vacancy formation energies than the others, which makes ZB ZnO promising for catalytic applications. Our results also imply that the stabilization of ZB ZnO on the nanoscale is due to some mechanisms other than surface energies.

Original language	English
Pages (from-to)	27683-27689
Number of pages	7
Journal	Physical Chemistry Chemical Physics
Volume	17
Issue number	41
DOIs	https://doi.org/10.1039/c5cp04521e
Publication status	Published - 2015
Externally published	Yes

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title = "Catalytic potential of highly defective (211) surfaces of zinc blende ZnO",

abstract = "Zinc blende (ZB) ZnO has gained increasing research interest due to its favorable properties and its stabilization on the nanoscale. While surface properties are important on the nanoscale, the studies on ZB ZnO surface properties are rare. Here we have performed first principles calculations of the energies and structures of ZB and wurtzite (WZ) ZnO surfaces. Our results indicate that, among the four surfaces parallel to the polar axes, such as (1010) and (1120) of the WZ phase and (110) and (211) of the ZB phase, the polar (211) surface has substantially lower surface vacancy formation energies than the others, which makes ZB ZnO promising for catalytic applications. Our results also imply that the stabilization of ZB ZnO on the nanoscale is due to some mechanisms other than surface energies.",

author = "Chunguang Tang and Wilson, {Hugh F.} and Spencer, {Michelle J.S.} and Barnard, {Amanda S.}",

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year = "2015",

doi = "10.1039/c5cp04521e",

language = "English",

volume = "17",

pages = "27683--27689",

journal = "Physical Chemistry Chemical Physics",

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TY - JOUR

T1 - Catalytic potential of highly defective (211) surfaces of zinc blende ZnO

AU - Tang, Chunguang

AU - Wilson, Hugh F.

AU - Spencer, Michelle J.S.

AU - Barnard, Amanda S.

N1 - Publisher Copyright: © the Owner Societies.

PY - 2015

Y1 - 2015

N2 - Zinc blende (ZB) ZnO has gained increasing research interest due to its favorable properties and its stabilization on the nanoscale. While surface properties are important on the nanoscale, the studies on ZB ZnO surface properties are rare. Here we have performed first principles calculations of the energies and structures of ZB and wurtzite (WZ) ZnO surfaces. Our results indicate that, among the four surfaces parallel to the polar axes, such as (1010) and (1120) of the WZ phase and (110) and (211) of the ZB phase, the polar (211) surface has substantially lower surface vacancy formation energies than the others, which makes ZB ZnO promising for catalytic applications. Our results also imply that the stabilization of ZB ZnO on the nanoscale is due to some mechanisms other than surface energies.

AB - Zinc blende (ZB) ZnO has gained increasing research interest due to its favorable properties and its stabilization on the nanoscale. While surface properties are important on the nanoscale, the studies on ZB ZnO surface properties are rare. Here we have performed first principles calculations of the energies and structures of ZB and wurtzite (WZ) ZnO surfaces. Our results indicate that, among the four surfaces parallel to the polar axes, such as (1010) and (1120) of the WZ phase and (110) and (211) of the ZB phase, the polar (211) surface has substantially lower surface vacancy formation energies than the others, which makes ZB ZnO promising for catalytic applications. Our results also imply that the stabilization of ZB ZnO on the nanoscale is due to some mechanisms other than surface energies.

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DO - 10.1039/c5cp04521e

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VL - 17

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EP - 27689

JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

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ER -

Catalytic potential of highly defective (211) surfaces of zinc blende ZnO

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