Spintronic Logic Devices Based on Skyrmioniums and Magnetic Defects

Sebastian Rodrigo Navarro Vilca; Silvana Rocio Urcia Romero; Helmunt Eduardo Vigo Cotrina

doi:10.1021/acsaelm.5c00137

Spintronic Logic Devices Based on Skyrmioniums and Magnetic Defects

Sebastian Rodrigo Navarro Vilca, Silvana Rocio Urcia Romero, Helmunt Eduardo Vigo Cotrina

Science

Universidad Nacional Jorge Basadre Grohmann

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

Abstract

This study uses micromagnetic simulations to investigate how skyrmioniums can function as information carriers in logic devices. By deliberately placing magnetic defects within a device and adjusting the applied current using the spin-orbit torque effect, we can control the trajectory of skyrmioniums. This control allows us to either displace or trap the skyrmioniums at specific locations due to the attractive or repulsive interactions between the magnetic defects and the skyrmioniums. The geometry used is a reconfigurable logic gate that enables various universal logic operations. We also demonstrate that it is possible to create more complex systems, such as Half Adders and Full Adders, by utilizing magnetic defects with a specific Dzyaloshinskii-Moriya interaction constant.

Original language	English
Journal	ACS Applied Electronic Materials
DOIs	https://doi.org/10.1021/acsaelm.5c00137
State	Accepted/In press - 2025

Keywords

full adder
half adder
logic gate
magnetic defect
micromagnetic simulation
skyrmionium
spintronic logic device

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10.1021/acsaelm.5c00137

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title = "Spintronic Logic Devices Based on Skyrmioniums and Magnetic Defects",

abstract = "This study uses micromagnetic simulations to investigate how skyrmioniums can function as information carriers in logic devices. By deliberately placing magnetic defects within a device and adjusting the applied current using the spin-orbit torque effect, we can control the trajectory of skyrmioniums. This control allows us to either displace or trap the skyrmioniums at specific locations due to the attractive or repulsive interactions between the magnetic defects and the skyrmioniums. The geometry used is a reconfigurable logic gate that enables various universal logic operations. We also demonstrate that it is possible to create more complex systems, such as Half Adders and Full Adders, by utilizing magnetic defects with a specific Dzyaloshinskii-Moriya interaction constant.",

keywords = "full adder, half adder, logic gate, magnetic defect, micromagnetic simulation, skyrmionium, spintronic logic device",

author = "{Navarro Vilca}, {Sebastian Rodrigo} and {Urcia Romero}, {Silvana Rocio} and {Vigo Cotrina}, {Helmunt Eduardo}",

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AU - Navarro Vilca, Sebastian Rodrigo

AU - Urcia Romero, Silvana Rocio

AU - Vigo Cotrina, Helmunt Eduardo

PY - 2025

Y1 - 2025

N2 - This study uses micromagnetic simulations to investigate how skyrmioniums can function as information carriers in logic devices. By deliberately placing magnetic defects within a device and adjusting the applied current using the spin-orbit torque effect, we can control the trajectory of skyrmioniums. This control allows us to either displace or trap the skyrmioniums at specific locations due to the attractive or repulsive interactions between the magnetic defects and the skyrmioniums. The geometry used is a reconfigurable logic gate that enables various universal logic operations. We also demonstrate that it is possible to create more complex systems, such as Half Adders and Full Adders, by utilizing magnetic defects with a specific Dzyaloshinskii-Moriya interaction constant.

AB - This study uses micromagnetic simulations to investigate how skyrmioniums can function as information carriers in logic devices. By deliberately placing magnetic defects within a device and adjusting the applied current using the spin-orbit torque effect, we can control the trajectory of skyrmioniums. This control allows us to either displace or trap the skyrmioniums at specific locations due to the attractive or repulsive interactions between the magnetic defects and the skyrmioniums. The geometry used is a reconfigurable logic gate that enables various universal logic operations. We also demonstrate that it is possible to create more complex systems, such as Half Adders and Full Adders, by utilizing magnetic defects with a specific Dzyaloshinskii-Moriya interaction constant.

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KW - spintronic logic device

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SN - 2637-6113

JO - ACS Applied Electronic Materials

JF - ACS Applied Electronic Materials

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Spintronic Logic Devices Based on Skyrmioniums and Magnetic Defects

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