Proximitized materials

Igor Žutić; Alex Matos-Abiague; Benedikt Scharf; Hanan Dery; Kirill Belashchenko

doi:10.1016/j.mattod.2018.05.003

Proximitized materials

Igor Žutić
, Alex Matos-Abiague
, Benedikt Scharf
, Hanan Dery
, Kirill Belashchenko

Physics

Wayne State University
University of Würzburg
University of Rochester
University of Nebraska-Lincoln

Research output: Contribution to journal › Review article › peer-review

277 Scopus citations

Abstract

Advances in scaling down heterostructures and having an improved interface quality together with atomically thin two-dimensional materials suggest a novel approach to systematically design materials. A given material can be transformed through proximity effects whereby it acquires properties of its neighbors, for example, becoming superconducting, magnetic, topologically nontrivial, or with an enhanced spin–orbit coupling. Such proximity effects not only complement the conventional methods of designing materials by doping or functionalization but also can overcome their various limitations. In proximitized materials, it is possible to realize properties that are not present in any constituent region of the considered heterostructure. While the focus is on magnetic and spin–orbit proximity effects with their applications in spintronics, the outlined principles also provide a broader framework for employing other proximity effects to tailor materials and realize novel phenomena.

Original language	English
Pages (from-to)	85-107
Number of pages	23
Journal	Materials Today
Volume	22
DOIs	https://doi.org/10.1016/j.mattod.2018.05.003
State	Published - Jan 1 2019

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10.1016/j.mattod.2018.05.003

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abstract = "Advances in scaling down heterostructures and having an improved interface quality together with atomically thin two-dimensional materials suggest a novel approach to systematically design materials. A given material can be transformed through proximity effects whereby it acquires properties of its neighbors, for example, becoming superconducting, magnetic, topologically nontrivial, or with an enhanced spin–orbit coupling. Such proximity effects not only complement the conventional methods of designing materials by doping or functionalization but also can overcome their various limitations. In proximitized materials, it is possible to realize properties that are not present in any constituent region of the considered heterostructure. While the focus is on magnetic and spin–orbit proximity effects with their applications in spintronics, the outlined principles also provide a broader framework for employing other proximity effects to tailor materials and realize novel phenomena.",

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AU - Žutić, Igor

AU - Matos-Abiague, Alex

AU - Scharf, Benedikt

AU - Dery, Hanan

AU - Belashchenko, Kirill

PY - 2019/1/1

Y1 - 2019/1/1

N2 - Advances in scaling down heterostructures and having an improved interface quality together with atomically thin two-dimensional materials suggest a novel approach to systematically design materials. A given material can be transformed through proximity effects whereby it acquires properties of its neighbors, for example, becoming superconducting, magnetic, topologically nontrivial, or with an enhanced spin–orbit coupling. Such proximity effects not only complement the conventional methods of designing materials by doping or functionalization but also can overcome their various limitations. In proximitized materials, it is possible to realize properties that are not present in any constituent region of the considered heterostructure. While the focus is on magnetic and spin–orbit proximity effects with their applications in spintronics, the outlined principles also provide a broader framework for employing other proximity effects to tailor materials and realize novel phenomena.

AB - Advances in scaling down heterostructures and having an improved interface quality together with atomically thin two-dimensional materials suggest a novel approach to systematically design materials. A given material can be transformed through proximity effects whereby it acquires properties of its neighbors, for example, becoming superconducting, magnetic, topologically nontrivial, or with an enhanced spin–orbit coupling. Such proximity effects not only complement the conventional methods of designing materials by doping or functionalization but also can overcome their various limitations. In proximitized materials, it is possible to realize properties that are not present in any constituent region of the considered heterostructure. While the focus is on magnetic and spin–orbit proximity effects with their applications in spintronics, the outlined principles also provide a broader framework for employing other proximity effects to tailor materials and realize novel phenomena.

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DO - 10.1016/j.mattod.2018.05.003

M3 - Review article

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SN - 1369-7021

VL - 22

SP - 85

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JO - Materials Today

JF - Materials Today

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Proximitized materials

Abstract

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