Enhanced wetting of Cu on ZnO by migration of subsurface oxygen vacancies

Igor Beinik; Matti Helström; Thomas Nørregaard Jensen; Peter Broqvist; Jeppe Vang Lauritsen

doi:10.1038/ncomms9845

Enhanced wetting of Cu on ZnO by migration of subsurface oxygen vacancies

Igor Beinik, Matti Helström, Thomas Nørregaard Jensen, Peter Broqvist, Jeppe Vang Lauritsen

Interdisciplinary Nanoscience Center - INANO-Fysik, iNANO-huset

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

57 Citations (Scopus)

Abstract

Metal adhesion on metal oxides is strongly controlled by the oxide surface structure and composition, but lack of control over the surface conditions often limits the possibilities to exploit this in opto- and micro-electronics applications and heterogeneous catalysis where nanostructural control is of utmost importance. The Cu/ZnO system is among the most investigated of such systems in model studies, but the presence of subsurface ZnO defects and their important role for adhesion on ZnO have been unappreciated so far. Here we reveal that the surface-directed migration of subsurface defects affects the Cu adhesion on polar ZnO(0001) in the technologically interesting temperature range up to 550 K. This leads to enhanced adhesion and ultimately complete wetting of ZnO(0001) by a Cu overlayer. On the basis of our experimental and computational results we demonstrate a mechanism which implies that defect concentrations in the bulk are an important, and possibly controllable, parameter for the metal-on-oxide growth.

Original language	English
Article number	8845
Journal	Nature Communications
Volume	6
ISSN	2041-1723
DOIs	https://doi.org/10.1038/ncomms9845
Publication status	Published - 16 Nov 2015

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10.1038/ncomms9845

http://www.nature.com/ncomms/2015/151116/ncomms9845/full/ncomms9845.html?WT.ec_id=NCOMMS-20151123

Cite this

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title = "Enhanced wetting of Cu on ZnO by migration of subsurface oxygen vacancies",

abstract = "Metal adhesion on metal oxides is strongly controlled by the oxide surface structure and composition, but lack of control over the surface conditions often limits the possibilities to exploit this in opto- and micro-electronics applications and heterogeneous catalysis where nanostructural control is of utmost importance. The Cu/ZnO system is among the most investigated of such systems in model studies, but the presence of subsurface ZnO defects and their important role for adhesion on ZnO have been unappreciated so far. Here we reveal that the surface-directed migration of subsurface defects affects the Cu adhesion on polar ZnO(0001) in the technologically interesting temperature range up to 550 K. This leads to enhanced adhesion and ultimately complete wetting of ZnO(0001) by a Cu overlayer. On the basis of our experimental and computational results we demonstrate a mechanism which implies that defect concentrations in the bulk are an important, and possibly controllable, parameter for the metal-on-oxide growth.",

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T1 - Enhanced wetting of Cu on ZnO by migration of subsurface oxygen vacancies

AU - Beinik, Igor

AU - Helström, Matti

AU - Jensen, Thomas Nørregaard

AU - Broqvist, Peter

AU - Lauritsen, Jeppe Vang

PY - 2015/11/16

Y1 - 2015/11/16

N2 - Metal adhesion on metal oxides is strongly controlled by the oxide surface structure and composition, but lack of control over the surface conditions often limits the possibilities to exploit this in opto- and micro-electronics applications and heterogeneous catalysis where nanostructural control is of utmost importance. The Cu/ZnO system is among the most investigated of such systems in model studies, but the presence of subsurface ZnO defects and their important role for adhesion on ZnO have been unappreciated so far. Here we reveal that the surface-directed migration of subsurface defects affects the Cu adhesion on polar ZnO(0001) in the technologically interesting temperature range up to 550 K. This leads to enhanced adhesion and ultimately complete wetting of ZnO(0001) by a Cu overlayer. On the basis of our experimental and computational results we demonstrate a mechanism which implies that defect concentrations in the bulk are an important, and possibly controllable, parameter for the metal-on-oxide growth.

AB - Metal adhesion on metal oxides is strongly controlled by the oxide surface structure and composition, but lack of control over the surface conditions often limits the possibilities to exploit this in opto- and micro-electronics applications and heterogeneous catalysis where nanostructural control is of utmost importance. The Cu/ZnO system is among the most investigated of such systems in model studies, but the presence of subsurface ZnO defects and their important role for adhesion on ZnO have been unappreciated so far. Here we reveal that the surface-directed migration of subsurface defects affects the Cu adhesion on polar ZnO(0001) in the technologically interesting temperature range up to 550 K. This leads to enhanced adhesion and ultimately complete wetting of ZnO(0001) by a Cu overlayer. On the basis of our experimental and computational results we demonstrate a mechanism which implies that defect concentrations in the bulk are an important, and possibly controllable, parameter for the metal-on-oxide growth.

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DO - 10.1038/ncomms9845

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