Interface dominated mechanical properties of ultra-fine grained and nanoporous Au at elevated temperatures

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Interface dominated mechanical properties of ultra-fine grained and nanoporous Au at elevated temperatures. / Leitner, Alexander; Maier-Kiener, Verena; Jeong, Jiwon et al.
in: Acta materialia, Jahrgang 121.2016, Nr. December, 2016, S. 104-116.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Vancouver

Leitner A, Maier-Kiener V, Jeong J, Abad MD, Hosemann P, Oh SH et al. Interface dominated mechanical properties of ultra-fine grained and nanoporous Au at elevated temperatures. Acta materialia. 2016;121.2016(December):104-116. doi: 10.1016/j.actamat.2016.08.071

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@article{c1108d97140c4ae590954c9a8f17f286,
title = "Interface dominated mechanical properties of ultra-fine grained and nanoporous Au at elevated temperatures",
abstract = "Modern design and engineering of highly efficient devices and machines demand innovative materials to satisfy requirements such as high strength at low density. The purpose of this study was to oppose the mechanical properties and deformation behavior of ultra-fine grained Au to those of nanoporous Au, to study the influence of different types of interfaces. Microstructural investigations of the foam surrendered a ligament size of ∼100 nm which themselves consist of 70 nm grains in average, while the ultra-fine grained gold features a mean grain size of 325 nm. Nanoindentation lends itself as a convenient technique to obtain material properties at ambient as well as high temperature conditions. In this work, a substantial indentation test series was performed in order to determine hardness, Young's modulus, strain-rate sensitivity and activation volume at room and elevated temperatures up to 300 °C. On account of the small characteristic dimensions, high hardness values were noted for both materials, which rapidly drop at elevated temperature. Additionally, an enhanced strain-rate sensitivity accompanied by low activation volumes was determined at room temperature, which further increased at elevated temperatures. This behavior is associated with thermally activated interactions between dislocations and interfaces. For nanoporous Au, due to the presence of free surfaces, a considerable increase of hardness was observed upon annealing. This can be attributed to a reduced number of mobile dislocations in the material after annealing, as supported by implemented porosity maps on indent cross-sections, showing distinct differences for tests at varying temperature.",
keywords = "Nanoindentation, Nanoporous Au, Ultra-fine grained Au, High-temperature deformation, Deformation mechanisms",
author = "Alexander Leitner and Verena Maier-Kiener and Jiwon Jeong and Abad, {Manuel D.} and Peter Hosemann and Oh, {Sang Ho} and Daniel Kiener",
year = "2016",
doi = "10.1016/j.actamat.2016.08.071",
language = "English",
volume = "121.2016",
pages = "104--116",
journal = "Acta materialia",
issn = "1359-6454",
publisher = "Elsevier",
number = "December",

}

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TY - JOUR

T1 - Interface dominated mechanical properties of ultra-fine grained and nanoporous Au at elevated temperatures

AU - Leitner, Alexander

AU - Maier-Kiener, Verena

AU - Jeong, Jiwon

AU - Abad, Manuel D.

AU - Hosemann, Peter

AU - Oh, Sang Ho

AU - Kiener, Daniel

PY - 2016

Y1 - 2016

N2 - Modern design and engineering of highly efficient devices and machines demand innovative materials to satisfy requirements such as high strength at low density. The purpose of this study was to oppose the mechanical properties and deformation behavior of ultra-fine grained Au to those of nanoporous Au, to study the influence of different types of interfaces. Microstructural investigations of the foam surrendered a ligament size of ∼100 nm which themselves consist of 70 nm grains in average, while the ultra-fine grained gold features a mean grain size of 325 nm. Nanoindentation lends itself as a convenient technique to obtain material properties at ambient as well as high temperature conditions. In this work, a substantial indentation test series was performed in order to determine hardness, Young's modulus, strain-rate sensitivity and activation volume at room and elevated temperatures up to 300 °C. On account of the small characteristic dimensions, high hardness values were noted for both materials, which rapidly drop at elevated temperature. Additionally, an enhanced strain-rate sensitivity accompanied by low activation volumes was determined at room temperature, which further increased at elevated temperatures. This behavior is associated with thermally activated interactions between dislocations and interfaces. For nanoporous Au, due to the presence of free surfaces, a considerable increase of hardness was observed upon annealing. This can be attributed to a reduced number of mobile dislocations in the material after annealing, as supported by implemented porosity maps on indent cross-sections, showing distinct differences for tests at varying temperature.

AB - Modern design and engineering of highly efficient devices and machines demand innovative materials to satisfy requirements such as high strength at low density. The purpose of this study was to oppose the mechanical properties and deformation behavior of ultra-fine grained Au to those of nanoporous Au, to study the influence of different types of interfaces. Microstructural investigations of the foam surrendered a ligament size of ∼100 nm which themselves consist of 70 nm grains in average, while the ultra-fine grained gold features a mean grain size of 325 nm. Nanoindentation lends itself as a convenient technique to obtain material properties at ambient as well as high temperature conditions. In this work, a substantial indentation test series was performed in order to determine hardness, Young's modulus, strain-rate sensitivity and activation volume at room and elevated temperatures up to 300 °C. On account of the small characteristic dimensions, high hardness values were noted for both materials, which rapidly drop at elevated temperature. Additionally, an enhanced strain-rate sensitivity accompanied by low activation volumes was determined at room temperature, which further increased at elevated temperatures. This behavior is associated with thermally activated interactions between dislocations and interfaces. For nanoporous Au, due to the presence of free surfaces, a considerable increase of hardness was observed upon annealing. This can be attributed to a reduced number of mobile dislocations in the material after annealing, as supported by implemented porosity maps on indent cross-sections, showing distinct differences for tests at varying temperature.

KW - Nanoindentation

KW - Nanoporous Au

KW - Ultra-fine grained Au

KW - High-temperature deformation

KW - Deformation mechanisms

U2 - 10.1016/j.actamat.2016.08.071

DO - 10.1016/j.actamat.2016.08.071

M3 - Article

VL - 121.2016

SP - 104

EP - 116

JO - Acta materialia

JF - Acta materialia

SN - 1359-6454

IS - December

ER -