马格农
凝聚态物理
物理
哈密顿量(控制论)
声子
各向异性
联轴节(管道)
反铁磁性
范德瓦尔斯力
拉曼散射
拉曼光谱
谱线
散射
感应耦合
光谱学
量子
垂直的
磁场
交换互动
量子力学
铁磁性
激发态
电子
太赫兹辐射
磁各向异性
化学
量子点
作者
Somsubhra Ghosh,Mainak Palit,Sujan Maity,Subhadeep Datta
标识
DOI:10.1002/pssr.202500373
摘要
We present a fully analytical model of hybridization between magnons, and phonons observed experimentally in magneto‐Raman scattering in van der Waals (vdW) antiferromagnets (AFM). Here, the representative material, FePS 3 , has been shown to be a quasi‐2D‐Ising antiferromagnet, with additional features of spin‐phonon coupling in the Raman spectra emerging below the Néel temperature ( T N ) of approximately 120 K. Using magneto‐Raman spectroscopy as an optical probe of magnetic structure, we show that one of these Raman‐active modes in the magnetically ordered state is a magnon with a frequency of 3.7 THz (∼122 cm −1 ). In addition, one magnon band and three phonon bands are coupled via the magneto‐elastic coupling, evidenced by anticrossing in the complete spectra. We consider a simple model involving only in‐plane nearest neighbor exchange couplings (designed to give rise to a similar magnetic structure) and perpendicular anisotropy in the presence of an out‐of‐plane magnetic field. Exact diagonalization of the Hamiltonian leads to energy bands which show that the interaction term gives rise to avoided crossings between the hybridized magnon and phonon branches. Realizing magnon‐phonon coupling in 2D AFMs is important for the verification of the theoretical predictions on exotic quantum transport phenomena like spin‐caloritronics, topological magnonics, etc.
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