286 research outputs found
Validity and limitations of the superexchange model for the magnetic properties of Sr2IrO4 and Ba2IrO4 mediated by the strong spin-orbit coupling
Layered perovskites Sr2IrO4 and Ba2IrO4 are regarded as the key materials for
understanding the properties of magnetic relativistic insulators, mediated by
the strong spin-orbit (SO) coupling. One of the most fundamental issues is to
which extent these properties can be described by the superexchange (SE) model,
formulated in the limit of the large Coulomb repulsion. In the present work we
address this issue by deriving the relevant models and extracting parameters of
these models from the first-principles calculations. First, we construct the
effective Hubbard-type model for the t2g bands, by recasting the problem in the
language of Wannier orbitals. Then, we map the obtained electron model onto the
pseudospin model by applying the theory of SE interactions. We discuss the
microscopic origin of anisotropic SE interactions, inherent to the compass
Heisenberg model, and the appearance of the antisymmetric Dzyaloshinskii-Moriya
term, associated with the additional rotation of the IrO6 octahedra in Sr2IrO4.
In order to evaluate the Neel temperature (TN), we employ the non-linear sigma
model. While for Sr2IrO4 our value of TN agrees with the experimental one, for
Ba2IrO4 it is overestimated by a factor two. We argue that this discrepancy is
related to limitations of the SE model: while for more localized t2g states in
Sr2IrO4 it works reasonably well, the higher-order terms, beyond the SE model,
play a more important role in the more "itinerant" Ba2IrO4, giving rise to the
new type of isotropic and anisotropic exchange interactions. This conclusion is
supported by unrestricted Hartree-Fock calculations for the same electron
model, where in the case of Ba2IrO4, already on the mean-field level, we were
able to reproduce the experimentally observed magnetic ground state, while for
Sr2IrO4 the main results are essentially the same as in the SE model.Comment: 37 pages, 9 figure
Microscopic analysis of the magnetic form factor in low-dimensional cuprates
We analyze the magnetic form factor of Cu in low-dimensional quantum
magnets by taking the metal-ligand hybridization into account explicitly. In
this analysis we use the form of magnetic Wannier orbitals, derived from the
first-principles calculations, and identify the contributions of different
atomic sites. Having performed local density approximation calculations for
cuprates with different types of ligand atoms, we discuss the influence of the
on-site Coulomb correlations on the structure of the magnetic orbital. The
typical composition of Wannier functions for copper oxides, chlorides and
bromides is defined and related to features of the magnetic form factor. We
propose easy-to-use approximations of the partial orbital contributions to the
magnetic form factor in order to give a microscopic explanation for the results
obtained in previous first-principles studies.Comment: 5 pages, 4 figure
Profile approach for recognition of three-dimensional magnetic structures
We propose an approach for low-dimensional visualisation and classification
of complex topological magnetic structures formed in magnetic materials. Within
the approach one converts a three-dimensional magnetic configuration to a
vector containing the only components of the spins that are parallel to the z
axis. The next crucial step is to sort the vector elements in ascending or
descending order. Having visualized profiles of the sorted spin vectors one can
distinguish configurations belonging to different phases even with the same
total magnetization. For instance, spin spiral and paramagnetic states with
zero total magnetic moment can be easily identified. Being combined with a
simplest neural network our profile approach provides a very accurate phase
classification for three-dimensional magnets characterized by complex
multispiral states even in the critical areas close to phases transitions. By
the example of the skyrmionic configurations we show that profile approach can
be used to separate the states belonging to the same phase
Bimeron nanoconfined design
We report on the stabilization of the topological bimeron excitations in
confined geometries. The Monte Carlo simulations for a ferromagnet with a
strong Dzyaloshinskii-Moriya interaction revealed the formation of a mixed
skyrmion-bimeron phase. The vacancy grid created in the spin lattice
drastically changes the picture of the topological excitations and allows one
to choose between the formation of a pure bimeron and skyrmion lattice. We
found that the rhombic plaquette provides a natural environment for
stabilization of the bimeron excitations. Such a rhombic geometry can protect
the topological state even in the absence of the magnetic field.Comment: 5 pages, 7 figure
Hybridization and spin-orbit coupling effects in quasi-one-dimensional spin-1/2 magnet Ba3Cu3Sc4O12
We study electronic and magnetic properties of the quasi-one-dimensional
spin-1/2 magnet Ba3Cu3Sc4O12 with a distinct orthogonal connectivity of CuO4
plaquettes. An effective low-energy model taking into account spin-orbit
coupling was constructed by means of first-principles calculations. On this
basis a complete microscopic magnetic model of Ba3Cu3Sc4O12, including
symmetric and antisymmetric anisotropic exchange interactions, is derived. The
anisotropic exchanges are obtained from a distinct first-principles numerical
scheme combining, on one hand, the local density approximation taking into
account spin-orbit coupling, and, on the other hand, projection procedure along
with the microscopic theory by Toru Moriya. The resulting tensors of the
symmetric anisotropy favor collinear magnetic order along the structural chains
with the leading ferromagnetic coupling J1 = -9.88 meV. The interchain
interactions J8 = 0.21 meV and J5 = 0.093 meV are antiferromagnetic. Quantum
Monte Carlo simulations demonstrated that the proposed model reproduces the
experimental Neel temperature, magnetization and magnetic susceptibility data.
The modeling of neutron diffraction data reveals an important role of the
covalent Cu-O bonding in Ba3Cu3Sc4O12.Comment: 11 pages, 12 figure
Nanoskyrmion engineering with -electron materials: Sn monolayer on SiC(0001) surface
Materials with -magnetism demonstrate strongly nonlocal Coulomb
interactions, which opens a way to probe correlations in the regimes not
achievable in transition metal compounds. By the example of Sn monolayer on
SiC(0001) surface, we show that such systems exhibit unusual but intriguing
magnetic properties at the nanoscale. Physically, this is attributed to the
presence of a significant ferromagnetic coupling, the so-called direct
exchange, which fully compensates ubiquitous antiferromagnetic interactions of
the superexchange origin. Having a nonlocal nature, the direct exchange was
previously ignored because it cannot be captured within the conventional
density functional methods and significantly challenges ground state models
earlier proposed for Sn/SiC(0001). Furthermore, heavy adatoms induce strong
spin-orbit coupling, which leads to a highly anisotropic form of the spin
Hamiltonian, in which the Dzyaloshinskii-Moriya interaction is dominant. The
latter is suggested to be responsible for the formation of a nanoskyrmion state
at realistic magnetic fields and temperatures.Comment: 4 pages, supplemental materia
Renormalized spectral function for Co adatom on the Pt(111) surface
The strong Coulomb correlations effects in the electronic structure of
magnetic Co adatom on the Pt(111) surface have been investigated. Using a
realistic five d-orbital impurity Anderson model at low temperatures with
parameters determined from first-principles calculations we found a striking
change of the electronic structure in comparison with the LDA results. The
spectral function calculated with full rotationally invariant Coulomb
interaction is in good agreement with the quasiparticle region of the STM
conductance spectrum. Using the calculated spin-spin correlation functions we
have analyzed the formation of the magnetic moments of the Co impurity
orbitals.Comment: 4 pages, 4 figure
- …