Carrier-doping and strain driven tuning of magnetic properties in the p-orbital monolayer metal-free ferromagnet T-XN2 (X = Sb, Bi)

IF 4.6 3区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

RSC Advances Pub Date : 2025-10-02 DOI:10.1039/D5RA05842B

Jiajun Zhu, Guangsheng Liu and Duohui Huang

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Abstract

Two-dimensional non-metallic ferromagnetic states have attracted widespread attention due to their complete spin polarization, long spin relaxation times, and abundant availability, highlighting their potential applications in next-generation spintronic devices. Based on first-principles calculations, we predict the two-dimensional non-metallic ferromagnet T-XN₂ (X = Sb, Bi), which has a structure similar to T-MoS₂. Calculations of thermodynamic, kinetic, and mechanical properties confirm that they possess good stability. Spin polarization results indicate that the ground state of monolayer T-XN2 is ferromagnetic, with its magnetism arising from the direct p-orbital interactions between N atoms, unlike conventional d/f orbital magnetic materials. Furthermore, the ferromagnetism retains good stability under strain engineering and carrier doping. These results suggest that the magnetic properties of monolayer T-XN₂ hold significant fundamental research implications and make it a potential candidate material for non-metallic ferromagnetic devices.

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p轨道单层无金属铁磁体T-XN2 （X = Sb, Bi）的载流子掺杂和应变驱动的磁性调谐

二维非金属铁磁态因其完全的自旋极化、较长的自旋弛豫时间和丰富的可用性而受到广泛关注，突出了其在下一代自旋电子器件中的潜在应用。基于第一性原理计算，我们预测了具有类似于T-MoS2结构的二维非金属铁磁体T-XN2 （X = Sb, Bi）。热力学、动力学和力学性能的计算证实它们具有良好的稳定性。自旋极化结果表明，单层T-XN2基态是铁磁性的，其磁性来自于N原子之间的p轨道直接相互作用，而不像传统的d/f轨道磁性材料。此外，在应变工程和载流子掺杂的作用下，材料的铁磁性保持了良好的稳定性。这些结果表明，单层T-XN2的磁性具有重要的基础研究意义，并使其成为非金属铁磁器件的潜在候选材料。

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来源期刊

RSC Advances chemical sciences-

CiteScore

7.50

自引率

2.60%

发文量

3116

审稿时长

1.6 months

期刊介绍： An international, peer-reviewed journal covering all of the chemical sciences, including multidisciplinary and emerging areas. RSC Advances is a gold open access journal allowing researchers free access to research articles, and offering an affordable open access publishing option for authors around the world.