Shape Memory Micro- and Nanowire Libraries for the High-Throughput Investigation of Scaling Effects

The scaling behavior of Ti–Ni–Cu shape memory thin-film micro- and nanowires of different geometry is investigated with respect to its influence on the martensitic transformation properties. Two processes for the high-throughput fabrication of Ti–Ni–Cu micro- to nanoscale thin film wire libraries an...

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Veröffentlicht in:	ACS combinatorial science 2017-09, Vol.19 (9), p.574-584
Hauptverfasser:	Oellers, Tobias, König, Dennis, Kostka, Aleksander, Xie, Shenqie, Brugger, Jürgen, Ludwig, Alfred
Format:	Artikel
Sprache:	eng
Schlagworte:	Alloys - chemistry Copper - chemistry Dental Alloys - chemistry Materials Testing Nanowires - chemistry Nickel - chemistry Particle Size Small Molecule Libraries - chemistry Temperature Titanium - chemistry
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container_title	ACS combinatorial science
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creator	Oellers, Tobias König, Dennis Kostka, Aleksander Xie, Shenqie Brugger, Jürgen Ludwig, Alfred
description	The scaling behavior of Ti–Ni–Cu shape memory thin-film micro- and nanowires of different geometry is investigated with respect to its influence on the martensitic transformation properties. Two processes for the high-throughput fabrication of Ti–Ni–Cu micro- to nanoscale thin film wire libraries and the subsequent investigation of the transformation properties are reported. The libraries are fabricated with compositional and geometrical (wire width) variations to investigate the influence of these parameters on the transformation properties. Interesting behaviors were observed: Phase transformation temperatures change in the range from 1 to 72 °C (austenite finish, (Af), 13 to 66 °C (martensite start, Ms) and the thermal hysteresis from −3.5 to 20 K. It is shown that a vanishing hysteresis can be achieved for special combinations of sample geometry and composition.
doi_str_mv	10.1021/acscombsci.7b00065
format	Article
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subjects	Alloys - chemistry Copper - chemistry Dental Alloys - chemistry Materials Testing Nanowires - chemistry Nickel - chemistry Particle Size Small Molecule Libraries - chemistry Temperature Titanium - chemistry
title	Shape Memory Micro- and Nanowire Libraries for the High-Throughput Investigation of Scaling Effects
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