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Magnetic Structure-Dependent Ultrafast Spin Relaxation in Magnet CrI<sub>3</sub>: A Time-Domain ab Initio Study

Haoran Lu, Run Long

2024Nano Letters19 citationsDOI

Abstract

Two-dimensional magnet CrI 3 is a promising candidate for spintronic devices. Using nonadiabatic molecular dynamics and noncollinear spin time-dependent density functional theory, we investigated hole spin relaxation in two-dimensional CrI 3 and its dependence on magnetic configurations, impacted by spin–orbit and electron–phonon interactions. Driven by in-plane and out-of-plane iodine motions, the relaxation rates vary, extending from over half a picosecond in ferromagnetic systems to tens of femtoseconds in certain antiferromagnetic states due to significant spin fluctuations, associated with the nonadiabatic spin-flip in tuning to the adiabatic flip. Antiferromagnetic CrI 3 with staggered layer magnetic order notably accelerates adiabatic spin-flip due to enhanced state degeneracy and additional phonon modes. Ferrimagnetic CrI 3 shows a transitional behavior between ferromagnetic and antiferromagnetic types as the magnetic moment changes. These insights into the spin dynamics of CrI 3 underscore its potential for rapid-response spintronic applications and advance our understanding of two-dimensional materials for spintronics.

Topics & Concepts

Ab initioMagnetCondensed matter physicsRelaxation (psychology)Ultrashort pulseAb initio quantum chemistry methodsSpin (aerodynamics)Materials scienceMagnetic domainPhysicsNuclear magnetic resonanceMolecular physicsChemical physicsMagnetic fieldMagnetizationMoleculeQuantum mechanicsThermodynamicsPsychologySocial psychologyLaser2D Materials and ApplicationsMagnetic and transport properties of perovskites and related materialsPerovskite Materials and Applications
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