Extraordinary magnetoresistance in a 2-terminal structure

Jeremy Letang; Stefano Lumetti; Perla Malago; Stefan Dan Costea; Wolfgang Hauer; Jürgen Kosel; Michael Ortner

doi:10.1109/INTERMAGShortPapers58606.2023.10228838

Extraordinary magnetoresistance in a 2-terminal structure

Jeremy Letang, Stefano Lumetti, Perla Malago, Stefan Dan Costea, Wolfgang Hauer, Jürgen Kosel, Michael Ortner

Publikation: Konferenzbeitrag › Poster

Abstract

Extraordinary magnetoresistance (EMR) is a phenomenon discovered by Solin et al. [1] at the interface between a metal (high-conductivity material) and a semiconductor (high-mobility material). EMR is a much larger effect than the other magnetoresistive (MR) phenomena, reaching values up to 107 % [2]. In this work, we present simulation results to determine if it is possible to realize EMR-based power limiters [3], by defining more clearly the differences between 4- and 2-terminal geometries in terms of performance for current limiter applications, as well as the dependence of the EMR on different material properties and shapes.

Originalsprache	Englisch
DOIs	https://doi.org/10.1109/INTERMAGShortPapers58606.2023.10228838
Publikationsstatus	Veröffentlicht - 16 Mai 2023
Veranstaltung	Intermag 2023: IEEE International Magnetics Conference 2023 - Sendai, Japan Dauer: 15 Mai 2023 → 19 Mai 2023

Konferenz

Konferenz	Intermag 2023: IEEE International Magnetics Conference 2023
Kurztitel	Intermag 2023
Land/Gebiet	Japan
Ort	Sendai
Zeitraum	15/05/23 → 19/05/23

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10.1109/INTERMAGShortPapers58606.2023.10228838

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title = "Extraordinary magnetoresistance in a 2-terminal structure",

abstract = "Extraordinary magnetoresistance (EMR) is a phenomenon discovered by Solin et al. [1] at the interface between a metal (high-conductivity material) and a semiconductor (high-mobility material). EMR is a much larger effect than the other magnetoresistive (MR) phenomena, reaching values up to 107 % [2]. In this work, we present simulation results to determine if it is possible to realize EMR-based power limiters [3], by defining more clearly the differences between 4- and 2-terminal geometries in terms of performance for current limiter applications, as well as the dependence of the EMR on different material properties and shapes.",

author = "Jeremy Letang and Stefano Lumetti and Perla Malago and Costea, {Stefan Dan} and Wolfgang Hauer and J{\"u}rgen Kosel and Michael Ortner",

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TY - CONF

T1 - Extraordinary magnetoresistance in a 2-terminal structure

AU - Letang, Jeremy

AU - Lumetti, Stefano

AU - Malago, Perla

AU - Costea, Stefan Dan

AU - Hauer, Wolfgang

AU - Kosel, Jürgen

AU - Ortner, Michael

PY - 2023/5/16

Y1 - 2023/5/16

N2 - Extraordinary magnetoresistance (EMR) is a phenomenon discovered by Solin et al. [1] at the interface between a metal (high-conductivity material) and a semiconductor (high-mobility material). EMR is a much larger effect than the other magnetoresistive (MR) phenomena, reaching values up to 107 % [2]. In this work, we present simulation results to determine if it is possible to realize EMR-based power limiters [3], by defining more clearly the differences between 4- and 2-terminal geometries in terms of performance for current limiter applications, as well as the dependence of the EMR on different material properties and shapes.

AB - Extraordinary magnetoresistance (EMR) is a phenomenon discovered by Solin et al. [1] at the interface between a metal (high-conductivity material) and a semiconductor (high-mobility material). EMR is a much larger effect than the other magnetoresistive (MR) phenomena, reaching values up to 107 % [2]. In this work, we present simulation results to determine if it is possible to realize EMR-based power limiters [3], by defining more clearly the differences between 4- and 2-terminal geometries in terms of performance for current limiter applications, as well as the dependence of the EMR on different material properties and shapes.

U2 - 10.1109/INTERMAGShortPapers58606.2023.10228838

DO - 10.1109/INTERMAGShortPapers58606.2023.10228838

M3 - Poster

T2 - Intermag 2023: IEEE International Magnetics Conference 2023

Y2 - 15 May 2023 through 19 May 2023

ER -

Extraordinary magnetoresistance in a 2-terminal structure

Abstract

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