Magnetoelectric properties of the multiferroic CuCrO2_2 studied by means of ab initio calculations and Monte Carlo simulations

Motivated by the discovery of multiferroicity in the geometrically frustrated triangular antiferromagnet CuCrO$_2$ below its N\'eel temperature $T_N$, we investigate its magnetic and ferroelectric properties using ab initio calculations and Monte Carlo simulations. Exchange interactions up to the third nearest neighbors in the $ab$ plane, inter-layer interaction and single ion anisotropy constants in CuCrO$_2$ are estimated by series of density functional theory calculations. In particular, our results evidence a hard axis along the [110] direction due to the lattice distortion that takes place along this direction below $T_N$. Our Monte Carlo simulations indicate that the system possesses a N\'eel temperature $T_N\approx27$ K very close to the ones reported experimentally ($T_N = 24-26$ K). Also we show that the ground state is a proper-screw magnetic configuration with an incommensurate propagation vector pointing along the [110] direction. Moreover, our work reports the emergence of spin helicity below $T_N$ which leads to ferroelectricity in the extended inverse Dzyaloshinskii-Moriya model. We confirm the electric control of spin helicity by simulating $P$-$E$ hysteresis loops at various temperatures.Comment: 6 pages, 8 figure

Half-metallicity and magnetism in the Co2_2MnAl/CoMnVAl heterostructure

We present a study of the electronic structure and magnetism of Co$_2$MnAl, CoMnVAl and their heterostructure. We employ a combination of density-functional theory and dynamical mean-field theory (DFT+DMFT). We find that Co$_2$MnAl is a half-metallic ferromagnet, whose electronic and magnetic properties are not drastically changed by strong electronic correlations, static or dynamic. Non-quasiparticle states are shown to appear in the minority spin gap without affecting the spin-polarization at the Fermi level predicted by standard DFT. We find that CoMnVAl is a semiconductor or a semi-metal, depending on the employed computational approach. We then focus on the electronic and magnetic properties of the Co$_2$MnAl/CoMnVAl heterostructure, predicted by previous first principle calculations as a possible candidate for spin-injecting devices. We find that two interfaces, Co-Co/V-Al and Co-Mn/Mn-Al, preserve the half-metallic character, with and without including electronic correlations. We also analyse the magnetic exchange interactions in the bulk and at the interfaces. At the Co-Mn/Mn-Al interface, competing magnetic interactions are likely to favor the formation of a non-collinear magnetic order, which is detrimental for the spin-polarization.Comment: 15 pages, 16 figure

Dynamical correlations in single-layer CrI3_3

Chromium triiodide is a magnetic van-der-Waals material with weak inter-layer interactions. It is one of the first materials for which intrinsic magnetism was observed down to the single-layer limit. This remarkable discovery fostered a whole new field of 2D magnetism and magnetic layered heterostructure research holding high promisses for spintronic applications. First-principles electronic structure calculations have an outstanding role in this field not only to describe the properties of existing 2D magnets, but also to predict new materials, and thus to guide the experimental progress. So far the most 2D magnet studies are based on standard density functional theory (DFT), which poorly addresses the effects of strong electron correlations. Here, we provide a first-principles description of finite-temperature magnetic and spectral properties of monolayer CrI$_3$ based on fully charge self-consistent DFT combined with dynamical mean field theory (DFT+DMFT), revealing a formation of local moments on Cr from strong local Coulomb interactions. We show that local dynamical correlations play an important role in the electronic structure of CrI$_3$. In contrast to conventional DFT+$U$ calculations, we find that the top of the valence band in monolayer CrI$_3$ demonstrates essentially different orbital character for minority and majority spin states. This results in a strong spin-polarization of the optical conductivity upon hole doping, which could be verified experimentally.Comment: 13 pages, 4 figure

Norm-conserving pseudopotentials with chemical accuracy compared to all-electron calculations

By adding a non-linear core correction to the well established Dual Space Gaussian type pseudopotentials for the chemical elements up to the third period, we construct improved pseudopotentials for the Perdew Burke Ernzerhof (PBE) functional and demonstrate that they exhibit excellent accuracy. Our benchmarks for the G2-1 test set show average atomization energy errors of only half a kcal/mol. The pseudopotentials also remain highly reliable for high pressure phases of crystalline solids. When supplemented by empirical dispersion corrections the average error in the interaction energy between molecules is also about half a kcal/mol. The accuracy that can be obtained by these pseudopotentials in combination with a systematic basis set is well superior to the accuracy that can be obtained by commonly used medium size Gaussian basis sets in all-electron calculations.Comment: 11 pages, 10 figure