Curie temperature engineering in a novel 2D analog of iron ore (hematene) <i>via</i> strain
Renu Singla, Timothy A. Hackett, Sarvesh Kumar, Jyotsna Sharma, Manish K. Kashyap
Abstract
depends firmly on the compressive strain and increases up to 21.1% at a compressive strain of 6% whereas it decreases significantly for tensile strain. The MAE is negatively correlated with the tensile and compressive strain. The value of MAE for all compressive strain cases is more than that of the pristine hematene. These results summarize that the studied 2D hematene has broad application prospects in spintronics, memory-based devices, and valleytronics.
Topics & Concepts
SpintronicsMaterials scienceCompressive strengthCondensed matter physicsBand gapStrain (injury)Strain engineeringUltimate tensile strengthCurie temperatureSemiconductorDensity functional theoryComposite materialFerromagnetismMetallurgyOptoelectronicsChemistryComputational chemistryPhysicsSiliconMedicineInternal medicine2D Materials and ApplicationsMultiferroics and related materialsHeusler alloys: electronic and magnetic properties