Abstract The exploit of magnetic devices with high magnetoresistance is vital for the development of magnetic sensing and data storage technologies. Here, using density functional calculations combined with Monte Carlo… Click to show full abstract
Abstract The exploit of magnetic devices with high magnetoresistance is vital for the development of magnetic sensing and data storage technologies. Here, using density functional calculations combined with Monte Carlo simulations, we explore the magnetic properties and spin-dependent transport of CrI3 monolayer under an electrostatic hole doping. Extraordinarily, the magnetoresistance can be controlled over 106% within a certain doping density range. The hole doping can render CrI3 monolayer half-metallic and nearly 100% spin-polarization at Fermi energy level can be achieved. Moreover, the hole doping can significantly enhance the stability of itinerant ferromagnetism. The Heisenberg exchange parameters can be significantly improved and meanwhile, the Curie temperature can be boosted to room temperature via a doping density of 8.49 × 1014 cm−2. This study reveals that the carrier doping engineering can enable two-dimensional CrI3 as a remarkable material for developing practical and high-performance spintronic nanodevices.
               
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