Combining Sub-nanometer Adhesion and Capping Layers for Thermally Stable Nanometer-Thick Au Films

William M. Abbott; Christopher P. Murray; Frank Bello; Chuan Zhong; Christopher Smith; Cormac McGuinness; Daniyar Mamyraimov; Amanda K. Petford-Long; David McCloskey; John F. Donegan

doi:10.1021/acsanm.0c01836

Combining Sub-nanometer Adhesion and Capping Layers for Thermally Stable Nanometer-Thick Au Films

William M. Abbott, Christopher P. Murray, Frank Bello, Chuan Zhong, Christopher Smith, Cormac McGuinness, Daniyar Mamyraimov, Amanda K. Petford-Long, David McCloskey, John F. Donegan

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

Abstract

Improving the thermal stability of Au thin films is critical if thermo-plasmonic applications such as heat-assisted magnetic recording are to become commercially viable. In this work, Al capping layers are deposited on M/Au films, where adhesion metal M = Ti or Ta, and are investigated for their utility in stabilizing Au thin films against dewetting. Contrary to previous investigations, it was found that thinner capping layers (0.5 nm) result in a greater stability than that conferred by thicker (1-5 nm) layers. Deposition of 0.5 nm of Al, which subsequently oxidizes when exposed to air, resulted in up to 10× stability enhancement. Similarly, capping with 0.5 nm Al resulted in less damping of the plasmonic response than with thicker capping layers. Finally, based on this work and previous work on metallic adhesion layers, optimally stable systems for thermo-plasmonic applications are proposed.

Original language	English
Pages (from-to)	10628-10633
Number of pages	6
Journal	ACS Applied Nano Materials
Volume	3
Issue number	11
DOIs	https://doi.org/10.1021/acsanm.0c01836
Publication status	Published - 25 Nov 2020

Keywords

adhesion
capping
dewetting
HAMR
plasmonic
thin-film

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10.1021/acsanm.0c01836

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title = "Combining Sub-nanometer Adhesion and Capping Layers for Thermally Stable Nanometer-Thick Au Films",

abstract = "Improving the thermal stability of Au thin films is critical if thermo-plasmonic applications such as heat-assisted magnetic recording are to become commercially viable. In this work, Al capping layers are deposited on M/Au films, where adhesion metal M = Ti or Ta, and are investigated for their utility in stabilizing Au thin films against dewetting. Contrary to previous investigations, it was found that thinner capping layers (0.5 nm) result in a greater stability than that conferred by thicker (1-5 nm) layers. Deposition of 0.5 nm of Al, which subsequently oxidizes when exposed to air, resulted in up to 10× stability enhancement. Similarly, capping with 0.5 nm Al resulted in less damping of the plasmonic response than with thicker capping layers. Finally, based on this work and previous work on metallic adhesion layers, optimally stable systems for thermo-plasmonic applications are proposed.",

keywords = "adhesion, capping, dewetting, HAMR, plasmonic, thin-film",

author = "Abbott, \{William M.\} and Murray, \{Christopher P.\} and Frank Bello and Chuan Zhong and Christopher Smith and Cormac McGuinness and Daniyar Mamyraimov and Petford-Long, \{Amanda K.\} and David McCloskey and Donegan, \{John F.\}",

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year = "2020",

month = nov,

day = "25",

doi = "10.1021/acsanm.0c01836",

language = "English",

volume = "3",

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T1 - Combining Sub-nanometer Adhesion and Capping Layers for Thermally Stable Nanometer-Thick Au Films

AU - Abbott, William M.

AU - Murray, Christopher P.

AU - Bello, Frank

AU - Zhong, Chuan

AU - Smith, Christopher

AU - McGuinness, Cormac

AU - Mamyraimov, Daniyar

AU - Petford-Long, Amanda K.

AU - McCloskey, David

AU - Donegan, John F.

N1 - Publisher Copyright: ©

PY - 2020/11/25

Y1 - 2020/11/25

N2 - Improving the thermal stability of Au thin films is critical if thermo-plasmonic applications such as heat-assisted magnetic recording are to become commercially viable. In this work, Al capping layers are deposited on M/Au films, where adhesion metal M = Ti or Ta, and are investigated for their utility in stabilizing Au thin films against dewetting. Contrary to previous investigations, it was found that thinner capping layers (0.5 nm) result in a greater stability than that conferred by thicker (1-5 nm) layers. Deposition of 0.5 nm of Al, which subsequently oxidizes when exposed to air, resulted in up to 10× stability enhancement. Similarly, capping with 0.5 nm Al resulted in less damping of the plasmonic response than with thicker capping layers. Finally, based on this work and previous work on metallic adhesion layers, optimally stable systems for thermo-plasmonic applications are proposed.

AB - Improving the thermal stability of Au thin films is critical if thermo-plasmonic applications such as heat-assisted magnetic recording are to become commercially viable. In this work, Al capping layers are deposited on M/Au films, where adhesion metal M = Ti or Ta, and are investigated for their utility in stabilizing Au thin films against dewetting. Contrary to previous investigations, it was found that thinner capping layers (0.5 nm) result in a greater stability than that conferred by thicker (1-5 nm) layers. Deposition of 0.5 nm of Al, which subsequently oxidizes when exposed to air, resulted in up to 10× stability enhancement. Similarly, capping with 0.5 nm Al resulted in less damping of the plasmonic response than with thicker capping layers. Finally, based on this work and previous work on metallic adhesion layers, optimally stable systems for thermo-plasmonic applications are proposed.

KW - adhesion

KW - capping

KW - dewetting

KW - HAMR

KW - plasmonic

KW - thin-film

UR - https://www.scopus.com/pages/publications/85097105100

U2 - 10.1021/acsanm.0c01836

DO - 10.1021/acsanm.0c01836

M3 - Article

AN - SCOPUS:85097105100

SN - 2574-0970

VL - 3

SP - 10628

EP - 10633

JO - ACS Applied Nano Materials

JF - ACS Applied Nano Materials

IS - 11

ER -

Combining Sub-nanometer Adhesion and Capping Layers for Thermally Stable Nanometer-Thick Au Films

Abstract

Keywords

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