Refined electron-spin transport model for single-element ferromagnetic systems: Application to nickel nanocontacts

W. Dednam; C. Sabater; O. Tal; J. J. Palacios; A. E. Botha; M. J. Caturla

doi:10.1103/PhysRevB.102.245415

Refined electron-spin transport model for single-element ferromagnetic systems: Application to nickel nanocontacts

W. Dednam, C. Sabater, O. Tal, J. J. Palacios, A. E. Botha, M. J. Caturla

Department of Chemical and Biological Physics

Weizmann Institute of Science

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

Abstract

Through a combination of atomistic spin-lattice dynamics simulations and relativistic ab initio calculations of electronic transport we shed light on unexplained electrical measurements in nickel nanocontacts created by break junction experiments under cryogenic conditions (4.2 K). We implement post-self-consistent-field corrections in the conductance calculations to account for spin-orbit coupling and the noncollinearity of the spins, resulting from the spin-lattice dynamics. We find that transverse magnetic domain walls are formed preferentially in (111)-oriented face-centered-cubic nickel atomic-sized contacts, which also form elongated constrictions, giving rise to enhanced individual domain wall magnetoresistance. Our calculations show that the ambiguity surrounding the conductance of a priori uniformly magnetized nickel nanocontacts can be traced back to the crystallographic orientation of the nanocontacts, rather than spontaneously formed magnetic domain walls "pinned"at their narrowest points.

Original language	English
Article number	245415
Number of pages	11
Journal	Physical Review B
Volume	102
Issue number	24
DOIs	https://doi.org/10.1103/PhysRevB.102.245415
State	Published - 15 Dec 2020

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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http://rua.ua.es/dspace/handle/10045/111262License: Unspecified

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@article{5d677d9d75644c6286cacb427bcf4934,

title = "Refined electron-spin transport model for single-element ferromagnetic systems: Application to nickel nanocontacts",

abstract = "Through a combination of atomistic spin-lattice dynamics simulations and relativistic ab initio calculations of electronic transport we shed light on unexplained electrical measurements in nickel nanocontacts created by break junction experiments under cryogenic conditions (4.2 K). We implement post-self-consistent-field corrections in the conductance calculations to account for spin-orbit coupling and the noncollinearity of the spins, resulting from the spin-lattice dynamics. We find that transverse magnetic domain walls are formed preferentially in (111)-oriented face-centered-cubic nickel atomic-sized contacts, which also form elongated constrictions, giving rise to enhanced individual domain wall magnetoresistance. Our calculations show that the ambiguity surrounding the conductance of a priori uniformly magnetized nickel nanocontacts can be traced back to the crystallographic orientation of the nanocontacts, rather than spontaneously formed magnetic domain walls {"}pinned{"}at their narrowest points.",

author = "W. Dednam and C. Sabater and O. Tal and Palacios, \{J. J.\} and Botha, \{A. E.\} and Caturla, \{M. J.\}",

note = "W.D. thanks J. Fern{\'a}ndez-Rossier for helpful discussions and suggestions to improve the manuscript. This work was supported by the Generalitat Valenciana through Grant No. PROMETEO2017/139. C.S. gratefully acknowledges financial support from the Dean Fellowship of the Weizmann Institute of Science and Generalitat Valenciana (Grant No. CDEIGENT2018/028). O.T. appreciates the support of the Harold Perlman family, and acknowledges funding by a research grant from Dana and Yossie Hollander, the Israel Science Foundation (Grant No. 1089/15), the Minerva Foundation (Grant No. 120865), and The Ministry of Science and Technology of Israel (Grant No. 3-16244). J.J.P. acknowledges financial support from Spanish MINECO through Grants No. FIS2016-80434-P and No. PID2019-109539GB-C43, the Fundaci{\'o}n Ram{\'o}n Areces, the Mar{\'i}a de Maeztu Program for Units of Excellence in R\&D (Grant No. CEX2018-000805-M), the Comunidad Aut{\'o}noma de Madrid through the Nanomag COST-CM Program (Grant No. S2018/NMT-4321), the European Union Seventh Framework Programme under Grant Agreement No. 604391 Graphene Flagship, the Centro de Computaci{\'o}n Cient{\'i}fica of the Universidad Aut{\'o}noma de Madrid and the computer resources at MareNostrum and the technical support provided by the Barcelona Supercomputing Center (Grant No. FI-2019-2-0007). The SLD and DFT calculations in this paper were performed on the high-performance computing facilities of the University of Alicante and the University of South Africa.",

year = "2020",

month = dec,

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doi = "10.1103/PhysRevB.102.245415",

language = "الإنجليزيّة",

volume = "102",

number = "24",

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TY - JOUR

T1 - Refined electron-spin transport model for single-element ferromagnetic systems

T2 - Application to nickel nanocontacts

AU - Dednam, W.

AU - Sabater, C.

AU - Tal, O.

AU - Palacios, J. J.

AU - Botha, A. E.

AU - Caturla, M. J.

N1 - W.D. thanks J. Fernández-Rossier for helpful discussions and suggestions to improve the manuscript. This work was supported by the Generalitat Valenciana through Grant No. PROMETEO2017/139. C.S. gratefully acknowledges financial support from the Dean Fellowship of the Weizmann Institute of Science and Generalitat Valenciana (Grant No. CDEIGENT2018/028). O.T. appreciates the support of the Harold Perlman family, and acknowledges funding by a research grant from Dana and Yossie Hollander, the Israel Science Foundation (Grant No. 1089/15), the Minerva Foundation (Grant No. 120865), and The Ministry of Science and Technology of Israel (Grant No. 3-16244). J.J.P. acknowledges financial support from Spanish MINECO through Grants No. FIS2016-80434-P and No. PID2019-109539GB-C43, the Fundación Ramón Areces, the María de Maeztu Program for Units of Excellence in R&D (Grant No. CEX2018-000805-M), the Comunidad Autónoma de Madrid through the Nanomag COST-CM Program (Grant No. S2018/NMT-4321), the European Union Seventh Framework Programme under Grant Agreement No. 604391 Graphene Flagship, the Centro de Computación Científica of the Universidad Autónoma de Madrid and the computer resources at MareNostrum and the technical support provided by the Barcelona Supercomputing Center (Grant No. FI-2019-2-0007). The SLD and DFT calculations in this paper were performed on the high-performance computing facilities of the University of Alicante and the University of South Africa.

PY - 2020/12/15

Y1 - 2020/12/15

N2 - Through a combination of atomistic spin-lattice dynamics simulations and relativistic ab initio calculations of electronic transport we shed light on unexplained electrical measurements in nickel nanocontacts created by break junction experiments under cryogenic conditions (4.2 K). We implement post-self-consistent-field corrections in the conductance calculations to account for spin-orbit coupling and the noncollinearity of the spins, resulting from the spin-lattice dynamics. We find that transverse magnetic domain walls are formed preferentially in (111)-oriented face-centered-cubic nickel atomic-sized contacts, which also form elongated constrictions, giving rise to enhanced individual domain wall magnetoresistance. Our calculations show that the ambiguity surrounding the conductance of a priori uniformly magnetized nickel nanocontacts can be traced back to the crystallographic orientation of the nanocontacts, rather than spontaneously formed magnetic domain walls "pinned"at their narrowest points.

AB - Through a combination of atomistic spin-lattice dynamics simulations and relativistic ab initio calculations of electronic transport we shed light on unexplained electrical measurements in nickel nanocontacts created by break junction experiments under cryogenic conditions (4.2 K). We implement post-self-consistent-field corrections in the conductance calculations to account for spin-orbit coupling and the noncollinearity of the spins, resulting from the spin-lattice dynamics. We find that transverse magnetic domain walls are formed preferentially in (111)-oriented face-centered-cubic nickel atomic-sized contacts, which also form elongated constrictions, giving rise to enhanced individual domain wall magnetoresistance. Our calculations show that the ambiguity surrounding the conductance of a priori uniformly magnetized nickel nanocontacts can be traced back to the crystallographic orientation of the nanocontacts, rather than spontaneously formed magnetic domain walls "pinned"at their narrowest points.

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U2 - 10.1103/PhysRevB.102.245415

DO - 10.1103/PhysRevB.102.245415

M3 - مقالة

SN - 2469-9950

VL - 102

JO - Physical Review B

JF - Physical Review B

IS - 24

M1 - 245415

ER -

Refined electron-spin transport model for single-element ferromagnetic systems: Application to nickel nanocontacts

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