$Structural defects responsible for strain glassy transition in Ni$_{50+x}$Ti$_{50-x}$$

Structural defects responsible for strain glassy transition in Ni$_{50+x}$Ti$_{50-x}$

The strain glassy phase is produced by doping a small percentage of impurity in a martensitic alloy. Its ground state is conceived to consist of martensitic nano domains spatially separated from each other by a defect phase. The present study, by probing the local structure around the Ni and Ti in m...

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Veröffentlicht in:	arXiv.org 2021-03
Hauptverfasser:	Nevgi, R, Pollastri, Simone, Aquilanti, Giuliana, Priolkar, K R
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Sprache:	eng
Schlagworte:	Physics - Materials Science Strain
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description	The strain glassy phase is produced by doping a small percentage of impurity in a martensitic alloy. Its ground state is conceived to consist of martensitic nano domains spatially separated from each other by a defect phase. The present study, by probing the local structure around the Ni and Ti in martensitic and strain glassy compositions of Ni$_{50+x}$Ti$_{50-x}$, for the first time, identifies the defect phase that is responsible for inhibiting the long range ordering of the elastic strain vector leading to the formation of the strain glassy phase.
doi_str_mv	10.48550/arxiv.2103.07103
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title	Structural defects responsible for strain glassy transition in Ni$_{50+x}$Ti$_{50-x}$
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Structural defects responsible for strain glassy transition in Ni\(_{50+x}\)Ti\(_{50-x}\)