Yaxuan Wu scite author profile

Atomically two-dimensional materials with direct band-gap and high carrier mobility are highly desirable due to their promising applications in electronic devices. Here, on the basis of ab initio calculations and global particle-swarm optimization method, we predict the B2S3 monolayer as a new semiconductor with favorable functional properties. The B2S3 monolayer possesses a high electron mobility of 553 cm2 V−1 s−1 and a direct band-gap of 1.85 eV. The direct band-gap can be manipulated under biaxial strain. Furthermore, B2S3 monolayer can absorb sunlight efficiently in the entire range of the visible light spectrum. Besides, this monolayer holds good dynamical, thermal, and mechanical stabilities. All the desired properties render B2S3 monolayer a promising candidate for future applications in high-speed (opto)electronic devices.

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Two-dimensional 4f magnetic EuSn2X2 (X = P, As) monolayers: A first-principles study

Bai

Jia

et al. 2023

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Two-dimensional (2D) ferromagnetic semiconductors (FMSs) hold exciting and promising potential for application in spintronic devices at the nanoscale. Currently, most 2D FMSs are based on 3d electrons; 4f electrons can provide nontrivial magnetism but have been much less studied to date. This paper presents a theoretical study, via first-principles calculations, of EuSn2X2 (X = P, As) monolayers based on rare-earth cations with f-electrons. The results show that EuSn2X2 monolayers possess a large magnetization (7 μB/Eu), a controllable magnetic anisotropy energy, and a unique d-electron-mediated f–f exchange mechanism. Both types of EuSn2X2 (X = P, As) monolayers are FMSs with indirect bandgaps of 1.00 and 0.99 eV, respectively, based on the Heyd–Scuseria–Ernzerhof (HSE06) method, which can be transform to direct bandgap semiconductors under biaxial strain. Interestingly, under the latter, spin–orbit coupling interaction gradually replaces the dipole–dipole interaction in the dominant position of magnetic anisotropy, resulting in the magnetic easy axis changing from in-plane to the more desirable out-of-plane. Considering their excellent dynamic, thermal, and mechanical stabilities and small cleavage energy, these EuSn2X2 monolayers can be exfoliated from their synthesized bulk. Our study not only helps to understand the properties of 2D 4f rare-earth magnets but also signposts a route toward improving the performance of EuSn2X2 monolayers in nano-electronic devices.

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Cr₂XTe₄ (X = Si, Ge) monolayers: a new type of two-dimensional high-T _C Ising ferromagnetic semiconductors with a large magnetic anisotropy

Bai¹,

Wu²,

Wang³

et al. 2022

J. Phys.: Condens. Matter

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Two-dimensional (2D) ferromagnetic semiconductor (FMS) provides the ideal platform for the development of quantum information technology in nanoscale devices. However, most of them suffer from low Curie temperature and small magnetic anisotropic energy (MAE), severely limiting their practical application. In this work, by using first-principles calculations, we predicted two stable 2D materials, namely, Cr2SiTe4 and Cr2GeTe4 monolayers. Interestingly, both of them are intrinsic direct band gap FMSs (∼1 eV) with a large magnetization (8 µ B f.u.−1) and sizable MAE (∼500 μ eV Cr−1). Monte Carlo simulations based on Heisenberg model suggest markedly high Curie temperatures of these monolayers (∼200 K). Besides, their high mechanical, dynamical, and thermal stabilities are further verified by elastic constants, phonon dispersion calculations, and ab initio molecular dynamics simulations. The outstanding attributes render Cr2XTe4 (X = Si, Ge) monolayers broadening the candidates of 2D FMS for a wide range of applications.

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High temperature ferromagnetic metal: a Janus CrSSe monolayer

Liu

Shi

et al. 2023

Phys. Chem. Chem. Phys.

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Yaxuan Wu

Ni(NCS)₂ monolayer: a robust bipolar magnetic semiconductor

B₂S₃ monolayer: a two-dimensional direct-gap semiconductor with tunable band-gap and high carrier mobility

Two-dimensional 4f magnetic EuSn2X2 (X = P, As) monolayers: A first-principles study

Cr₂XTe₄ (X = Si, Ge) monolayers: a new type of two-dimensional high-T _C Ising ferromagnetic semiconductors with a large magnetic anisotropy

High temperature ferromagnetic metal: a Janus CrSSe monolayer

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Yaxuan Wu

Ni(NCS)2 monolayer: a robust bipolar magnetic semiconductor

B2S3 monolayer: a two-dimensional direct-gap semiconductor with tunable band-gap and high carrier mobility

Two-dimensional 4f magnetic EuSn2X2 (X = P, As) monolayers: A first-principles study

Cr2XTe4 (X = Si, Ge) monolayers: a new type of two-dimensional high-T C Ising ferromagnetic semiconductors with a large magnetic anisotropy

High temperature ferromagnetic metal: a Janus CrSSe monolayer

Contact Info

Product

Resources

About

Ni(NCS)₂ monolayer: a robust bipolar magnetic semiconductor

B₂S₃ monolayer: a two-dimensional direct-gap semiconductor with tunable band-gap and high carrier mobility

Cr₂XTe₄ (X = Si, Ge) monolayers: a new type of two-dimensional high-T _C Ising ferromagnetic semiconductors with a large magnetic anisotropy