Strong spin filtering by silicon nanoparticles with adsorbed bismuth atom clusters: Role of symmetry and electrostatic control of the direction of spin polarization

Saffarzadeh, Alireza; Kirczenow, George

doi:10.1103/physrevb.106.085416

Phys. Rev. B

2022

DOI: 10.1103/physrevb.106.085416

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Strong spin filtering by silicon nanoparticles with adsorbed bismuth atom clusters: Role of symmetry and electrostatic control of the direction of spin polarization

Alireza Saffarzadeh

George Kirczenow

Abstract: We present a theoretical study, based on density functional theory and tight binding modeling, of the electronic structure and spin transport properties of silicon nanoparticles with adsorbed bismuth atoms. We find the bismuth atoms to form clusters separated by quantum tunnel barriers. We predict strong spin filtering by these nanostructures in the high conductance regime when the source and drain leads are connected to the same bismuth cluster and in the low conductance regime when the source and drain leads… Show more

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2024

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Spin filtering and quantum transport with transition metal-doped hydrogenated silicon quantum dot

Arora,

Samanta

2024

Applied Physics Letters

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Spin filtering is a fundamental operation in spintronics, enabling the generation and detection of spin-polarized carriers. Here, we proposed and theoretically demonstrated that a 3d transition metal (TM) doped hydrogenated silicon quantum dot (TM:H-SiQD) is a suitable candidate for spin-filter devices. Using density functional theory, we investigate the structure, electronic properties, and magnetic behavior of TM:H-SiQD. Our calculations demonstrate that Mn:H-SiQD exhibits the highest stability. The designed spin-filter device using Mn:H-SiQD shows a spin-filtering efficiency of 99.9% at 300 K electrode temperature along with very high conductance. This remarkable efficiency positions it as a promising candidate for spintronic devices.

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Spin filtering and quantum transport with transition metal-doped hydrogenated silicon quantum dot

Arora,

Samanta

2024

Applied Physics Letters

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Strong spin filtering by silicon nanoparticles with adsorbed bismuth atom clusters: Role of symmetry and electrostatic control of the direction of spin polarization

Cited by 1 publication

References 25 publications

Spin filtering and quantum transport with transition metal-doped hydrogenated silicon quantum dot

Spin filtering and quantum transport with transition metal-doped hydrogenated silicon quantum dot

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