Assessing Nickel Titanium Binary Systems Using Structural Search Methods and Ab Initio Calculations

Logan Lang; Adam Payne; Irais Valencia-Jaime; Matthieu J. Verstraete; Alejandro Bautista-Hernández; Aldo H. Romero

doi:10.1021/acs.jpcc.0c10453

Assessing Nickel Titanium Binary Systems Using Structural Search Methods and Ab Initio Calculations

Logan Lang^*, Adam Payne^*, Irais Valencia-Jaime^*, Matthieu J. Verstraete^*, Alejandro Bautista-Hernández^*, Aldo H. Romero^*

^*Corresponding author for this work

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

Abstract

Nickel titanium, also know as nitinol, is a prototypical shape memory alloy, a property intimately linked to a phase transition in the microstructure, which allows the meso/macroscopic sample shape to be recovered after thermal cycling. Not much is known about the other alloys in this binary system, which prompted our computational investigation of other compositions. In this work, structures are found by probing the potential energy surfaces of NiTi binary systems using a minima hopping method, in combination with ab initio electronic structure calculations. We find stable structures in 34 different stoichiometries and calculate derived physical properties of the low energy phases. From the results of this analysis a new convex hull is formed that is lower in energy than those in the Materials Project and Open Quantum Materials Databases. Two previously unreported phases are discovered for the NiTi2 and Ni5Ti compositions, and two metastable states in NiTi and NiTi2 shows signs of negative linear compression and negative Poisson ratio, respectively.

Original language	English
Pages (from-to)	1578-1591
Number of pages	14
Journal	Journal of Physical Chemistry C
Volume	125
Issue number	2
DOIs	https://doi.org/10.1021/acs.jpcc.0c10453
Publication status	Published - 21 Jan 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
©

Funding

We acknowledge the computational resources awarded by XSEDE, a project supported by National Science Foundation Grant No. ACI-1053575. We acknowledge the support from the Texas Advances Computer Center (with the Stampede2 and Bridges supercomputers). This work was supported by the DMREF-NSF 1434897, NSF OAC-1740111, and DOE DE-SC0021375 projects. M.J.V. acknowledges funding by the Belgian FNRS (PDR G.A. T.1077.15-1/7, T.0103.19, and a sabbatical “OUT” grant at ICN2), ULiege, and the Communauté Française de Belgique (ARC AIMED G.A. 15/19-09) and computational resources from the Consortium des Equipements de Calcul Intensif (FRS-FNRS G.A. 2.5020.11) and Zenobe/CENAERO funded by the Walloon Region under G.A. 1117545.

Funders	Funder number
Belgian FNRS	PDR G.A. T.1077.15-1/7, T.0103.19
Communauté Française de Belgique
DMREF-NSF	1434897
Texas Advances Computer Center
Walloon Region	1117545
XSEDE
National Science Foundation	OAC-1740111, ACI-1053575
U.S. Department of Energy	DE-SC0021375
Automotive Research Center	2.5020.11, 15/19-09

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title = "Assessing Nickel Titanium Binary Systems Using Structural Search Methods and Ab Initio Calculations",

abstract = "Nickel titanium, also know as nitinol, is a prototypical shape memory alloy, a property intimately linked to a phase transition in the microstructure, which allows the meso/macroscopic sample shape to be recovered after thermal cycling. Not much is known about the other alloys in this binary system, which prompted our computational investigation of other compositions. In this work, structures are found by probing the potential energy surfaces of NiTi binary systems using a minima hopping method, in combination with ab initio electronic structure calculations. We find stable structures in 34 different stoichiometries and calculate derived physical properties of the low energy phases. From the results of this analysis a new convex hull is formed that is lower in energy than those in the Materials Project and Open Quantum Materials Databases. Two previously unreported phases are discovered for the NiTi2 and Ni5Ti compositions, and two metastable states in NiTi and NiTi2 shows signs of negative linear compression and negative Poisson ratio, respectively.",

author = "Logan Lang and Adam Payne and Irais Valencia-Jaime and Verstraete, {Matthieu J.} and Alejandro Bautista-Hern{\'a}ndez and Romero, {Aldo H.}",

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year = "2021",

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day = "21",

doi = "10.1021/acs.jpcc.0c10453",

language = "English",

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AU - Lang, Logan

AU - Payne, Adam

AU - Valencia-Jaime, Irais

AU - Verstraete, Matthieu J.

AU - Bautista-Hernández, Alejandro

AU - Romero, Aldo H.

PY - 2021/1/21

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N2 - Nickel titanium, also know as nitinol, is a prototypical shape memory alloy, a property intimately linked to a phase transition in the microstructure, which allows the meso/macroscopic sample shape to be recovered after thermal cycling. Not much is known about the other alloys in this binary system, which prompted our computational investigation of other compositions. In this work, structures are found by probing the potential energy surfaces of NiTi binary systems using a minima hopping method, in combination with ab initio electronic structure calculations. We find stable structures in 34 different stoichiometries and calculate derived physical properties of the low energy phases. From the results of this analysis a new convex hull is formed that is lower in energy than those in the Materials Project and Open Quantum Materials Databases. Two previously unreported phases are discovered for the NiTi2 and Ni5Ti compositions, and two metastable states in NiTi and NiTi2 shows signs of negative linear compression and negative Poisson ratio, respectively.

AB - Nickel titanium, also know as nitinol, is a prototypical shape memory alloy, a property intimately linked to a phase transition in the microstructure, which allows the meso/macroscopic sample shape to be recovered after thermal cycling. Not much is known about the other alloys in this binary system, which prompted our computational investigation of other compositions. In this work, structures are found by probing the potential energy surfaces of NiTi binary systems using a minima hopping method, in combination with ab initio electronic structure calculations. We find stable structures in 34 different stoichiometries and calculate derived physical properties of the low energy phases. From the results of this analysis a new convex hull is formed that is lower in energy than those in the Materials Project and Open Quantum Materials Databases. Two previously unreported phases are discovered for the NiTi2 and Ni5Ti compositions, and two metastable states in NiTi and NiTi2 shows signs of negative linear compression and negative Poisson ratio, respectively.

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Assessing Nickel Titanium Binary Systems Using Structural Search Methods and Ab Initio Calculations

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