Your search keyword '"Kashin, I. V."' showing total 16 results

1. Searching for new ferromagnetism precursors in two-dimensional model materials in frame of local force theorem

Author

Kashin, I. V., Gerasimov, A., and Syrnikov, E. V.

Subjects

Condensed Matter - Materials Science

Abstract

In this work we conduct a numerical search of non-trivial mechanisms, leading to new tendencies towards long-range ferromagnetic ordering in two-dimensional materials. For this purpose we employ an original variant of pairwise infinitesimal spin rotations technique to establish the magnetic transition temperature as the rigid function of basic crystal's parameters. It favored the numerical optimization of this function using modified genetic algorithm, designed to harvest local extrema. It resulted in revealing the moderate metallicity, accompanied by essential orbital anisotropy, as the prime configuration, which provides the most favoring conditions to ferromagnetic ordering, related to double-exchange and superexchange mechanisms.

Published

2021

2. Reciprocal space study of Heisenberg exchange interactions in ferromagnetic metals

Author

Kashin, I. V., Gerasimov, A., and Mazurenko, V. V.

Subjects

Condensed Matter - Materials Science

Abstract

The modern quantum theory of magnetism in solids is getting commonly derived using Green's functions formalism. The popularity draws itself from remarkable opportunities to capture the microscopic landscape of exchange interactions, starting from a tight-binding representation of the electronic structure. Indeed, the conventional method of infinitesimal spin rotations, considered in terms of local force theorem, opens vast prospects of investigations regarding the magnetic environment, as well as pairwise atomic couplings. However, this theoretical concept practically does not devoid of intrinsic inconsistencies. In particular, naturally expected correspondence between single and pairwise infinitesimal spin rotations is being numerically revealed to diverge. In this work, we elaborate this question on the model example and canonical case of bcc iron. Our analytical derivations discovered the principal preference of on-site magnetic precursors if the compositions of individual atomic interactions are in focus. The problem of extremely slow or even absent spatial convergence while considering metallic compounds was solved by suggesting the original technique, based on reciprocal space framework. Using fundamental Fourier transform-inspired interconnection between suggested technique and traditional spatial representation, we shed light on symmetry breaking in bcc Fe on the level of orbitally decomposed total exchange surrounding.

Published

2021

3. Orbitally-resolved ferromagnetism of monolayer CrI$_3$

Author

Kashin, I. V., Mazurenko, V. V., Katsnelson, M. I., and Rudenko, A. N.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Few-layer CrI$_3$ is the most known example among two-dimensional (2D) ferromagnets, which have attracted growing interest in recent years. Despite considerable efforts and progress in understanding the properties of 2D magnets both from theory and experiment, the mechanism behind the formation of in-plane magnetic ordering in chromium halides is still under debate. Here, we propose a microscopic orbitally-resolved description of ferromagnetism in monolayer CrI$_3$. Starting from first-principles calculations, we construct a low-energy model for the isotropic Heisenberg exchange interactions. We find that there are two competing contributions to the long-range magnetic ordering in CrI$_3$: (i) Antiferromagnetic Anderson's superexchange between half-filled $t_{2g}$ orbitals of Cr atoms; and (ii) Ferromagnetic exchange governed by the Kugel-Khomskii mechanism, involving the transitions between half-filled $t_{2g}$ and empty $e_g$ orbitals. Using numerical calculations, we estimate the exchange interactions in momentum-space, which allows us to restore the spin-wave spectrum, as well as estimate the Curie temperature. Contrary to the nearest-neighbor effective models, our calculations suggest the presence of sharp resonances in the spin-wave spectrum at 5--7 meV, depending on the vertical bias voltage. Our estimation of the Curie temperature in monolayer CrI$_3$ yields 55--65 K, which is in good agreement with experimental data.

Published

2019

4. Band filling dependence of the Curie temperature in CrO2

Author

Solovyev, I. V., Kashin, I. V., and Mazurenko, V. V.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

Rutile CrO$_2$ is an important half-metallic ferromagnetic material, which is also widely used in magnetic recording. In an attempt to find the conditions, which lead to the increase the Curie temperature ($T_{\rm C}$), we study theoretically the band-filling dependence of interatomic exchange interactions in the rutile compounds. For these purposes, we use the effective low-energy model for the magnetic $t_{2g}$ bands, derived from the first-principles electronic structure calculations in the Wannier basis, which is solved by means of dynamical mean-field theory. After the solution, we calculate the interatomic exchange interactions, by using the theory of infinitesimal spin rotations, and evaluate $T_{\rm C}$. We argue that, as far as the Curie temperature is concerned, the band filling realized in CrO$_2$ is far from being the optimal one and much higher $T_{\rm C}$ can be obtained by decreasing the number of $t_{2g}$ electrons ($n$) via the hole doping. We find that the optimal $n$ is close to $1$, which should correspond to the case of VO$_2$, provided that it is crystallized in the rutile structure. This finding was confirmed by using the experimental rutile structure for both CrO$_2$ and VO$_2$ and reflects the general tendency towards ferromagnetism for the narrow-band compounds at the beginning of the band filling. In particular, our results suggest that the strong ferromagnetism can be achieved in the thin films of VO$_2$, whose crystal structure is controlled by the substrate., Comment: 13 pages, 6 figures

Published

2016

5. On-the-fly exact diagonalization solver for quantum electronic models

Author

Kashin, I. V. and Mazurenko, V. V.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We propose a distinct numerical approach to effectively solve the problem of partial diagonalization of the super-large-scale quantum electronic Hamiltonian matrices. The key ingredients of our scheme are the new method for arranging the basis vectors in the computer's RAM and the algorithm allowing not to store a matrix in RAM, but to regenerate it on-the-fly during diagonalization procedure. This scheme was implemented in the program, solving the Anderson impurity model in the framework of dynamical mean-field theory (DMFT). The DMFT equations for electronic Hamiltonian with 18 effective orbitals that corresponds to the matrix with the dimension of 2.4 * 10^9 were solved on the distributed memory computational cluster., Comment: 4 pages, 6 figures, 4 tables

Published

2015

6. Mechanisms and origins of half-metallic ferromagnetism in CrO2

Author

Solovyev, I. V., Kashin, I. V., and Mazurenko, V. V.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

Chromium dioxide (CrO2) offers a rare example of metallic ferromagnetism among stoichiometric transition-metal oxides. What makes it even more remarkable is the half-metallic electronic structure. Today, CrO2 is widely used in magnetorecording and regarded as a promising spintronic material. Nevertheless, the key question "Why is it ferromagnetic?" remains largely unanswered, despite general interest to the problem and practical importance of CrO2. In the present work we challenge this question by combining first-principles electronic structure calculations with the model Hamiltonian approach and modern many-body methods for treating electron correlations. Our analysis demonstrates that the problem is indeed highly nontrivial: at the first glance, the ferromagnetism in CrO2 can be easily explained by Hund's rule related exchange processes in the narrow t2g band. However, the electron correlations, rigorously treated in the frameworks of dynamical mean-field theory, tend to destabilize this state. The ferromagnetism reemerges if, besides conventional kinetic energy changes in the t2g band, to consider other mechanism, involving direct exchange and magnetic polarization of the oxygen band. We show how all these contributions can be evaluated using first-principles electronic structure calculations. Our results explain the overall stability of the ferromagnetic state and provide the firm microscopic basis for understanding the magnetism of CrO2., Comment: 37 pages, 11 figure, 5 tables

Published

2015

7. Correlation effects in insulating surface nanostructures

Author

Mazurenko, V. V., Iskakov, S. N., Rudenko, A. N., Kashin, I. V., Sotnikov, O. M., Valentyuk, M. V., and Lichtenstein, A. I.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We study the role of static and dynamical Coulomb correlation effects on the electronic and magnetic properties of individual Mn, Fe and Co adatoms deposited on the CuN surface. For these purposes, we construct a realistic Anderson model, solve it by using finite-temperature exact diagonalization method and compare the calculated one-particle spectral functions with the LDA+$U$ densities of states. In contrast to Mn/CuN and Fe/CuN, the cobalt system tends to form the electronic excitations at the Fermi level. Based on the calculated magnetic response functions, the relative relaxation times for the magnetic moments of impurity orbitals are estimated. To study the effect of the dynamical correlations on the exchange interaction in nanoclusters, we solve the two-impurity Anderson model for the Mn dimer on the CuN surface. It is found that the experimental exchange interaction can be well reproduced by employing $U$=3 eV, which is two times smaller than the value used in static mean-field LDA+$U$ calculations. This suggests on important role of dynamical correlations in the interaction between adatoms on a surface., Comment: 8 pages, 8 figures

Published

2013

8. ТЕОРЕТИЧЕСКОЕ ИССЛЕДОВАНИЕ МАГНОННЫХ СПЕКТРОВ МОНОСЛОЯ ТРИЙОДИДА ХРОМА

Author

Kashin, I. V., Mazurenko, V. V., Katsnelson, M. I., and Rudenko, A. N.

Subjects

Condensed Matter::Materials Science

Abstract

The magnetic properties of CrI3 monolayer, considered by means of magnon spectra, are the prime focus of this work. Using first-principles calculations and microscopic model tech-niques, we found that ferromagnetism of the system cannot be exhaustively described only by effective nearest-neighbour (1NN) isotropic exchange interactions. Accounting for longer ranged couplings, accomplished in terms of magnetic force theorem, yields distinct peaks in the magnon spectra, which are absent in the case of 1NN model. It highlights the comprehen-sive theoretical investigation to be the only tool to reveal the mechanisms, lying behind the CrI3 monolayer ferromagnetism. Работа поддержана грантом Российского Научного Фонда №17-72-20041.

Published

2020

9. НЕЙРОСЕТИ РАСШИРЕННОЙ ТОПОЛОГИИ В ЗАДАЧЕ КОМПРЕССИИ

Author

Maibakh, E. A. and Kashin, I. V

Subjects

Computer Science::Neural and Evolutionary Computation

Abstract

We consider the fundamental ability of neural networks to capture the eigenstate of arbi-trary many-body quantum system. Training procedure was accomplished by genetic algo-rithm designed to minimize the error function. Numerical calculations revealed the perceptron to represent the eigenstate of arbitrary quantum system with reasonable accuracy.

Published

2020

10. Orbitally-resolved ferromagnetism of monolayer CrI3

Author

Kashin, I., V, Mazurenko, V.V., Katsnelson, M.I., Rudenko, A.N., Kashin, I., V, Mazurenko, V.V., Katsnelson, M.I., and Rudenko, A.N.

Abstract

Contains fulltext : 219077.pdf (publisher's version ) (Closed access)

Published

2020

11. Orbitally-resolved ferromagnetism of monolayer CrI3

Author

Kashin, I. V., Mazurenko, V. V., Katsnelson, M. I., Rudenko, A. N., Kashin, I. V., Mazurenko, V. V., Katsnelson, M. I., and Rudenko, A. N.

Abstract

Few-layer CrI3 is the most known example among two-dimensional (2D) ferromagnets, which have attracted growing interest in recent years. Despite considerable efforts and progress in understanding the properties of 2D magnets both from theory and experiment, the mechanism behind the formation of in-plane magnetic ordering in chromium halides is still under debate. Here, we propose a microscopic orbitally-resolved description of ferromagnetism in monolayer CrI3. Starting from first-principles calculations, we construct a low-energy model for the isotropic Heisenberg exchange interactions. We find that there are two competing contributions to the long-range magnetic ordering in CrI3: (i) Antiferromagnetic Anderson's superexchange between half-filled t 2g orbitals of Cr atoms; and (ii) Ferromagnetic exchange governed by the Kugel-Khomskii mechanism, involving the transitions between half-filled t 2g and empty e g orbitals. Using numerical calculations, we estimate the exchange interactions in momentum-space, which allows us to restore the spin-wave spectrum, as well as estimate the Curie temperature. Contrary to the nearest-neighbor effective models, our calculations suggest the presence of sharp resonances in the spin-wave spectrum at 5-7 meV, depending on the vertical bias voltage. Our estimation of the Curie temperature in monolayer CrI3 yields 55-65 K, which is in good agreement with experimental data. © 2020 IOP Publishing Ltd.

Published

2020

12. MODELING OF ANTIMONY MONOLAYER PHOTOEMISSION SPECTRA

Author

Kashin, I. V., Mazurenko, V. V., and Rudenko, A. N.

Abstract

Based on the minimal tight-binding model, angle-resolved photoemission spectra of the antimony monolayer was simulated in terms of dynamical mean-field theory. The dynamical Coulomb correlations were found to strongly affect the energy gap. It reveals electron-electron interplays to be essential to describe the experimentally available properties of the system. Работа поддержана грантом Российского Научного Фонда №17-72-20041.

Published

2018

13. DESIGNING OF AN ELEMENTARY TRANSMITTER BASED ON SURFACE

Author

Вялова, С. A., Vyalova, S. A., and Kashin, I. V.

Abstract

Co adatoms on the Cu(111) surface are known to exhibit strong ferromagnetic character of the exchange interaction, if coupled directly, and explicit antiferromagnetic one, if separated by two Cu atoms [1]. Our calculations, carried out in terms of Heisenberg model, re-vealed a possibility to design an elementary transmitting unit by adjusting geometry of the system. The transmittance of the unit was found stable up to ≈100 Å (100 bonds of FM chain) in small magnetic fields (~1 meV) at room temperature.

Published

2018

14. PECULIARITY OF COLLECTIVE MAGNETIC EXCITATIONS MODELING IN TRANSITION METAL-BASED COMPOUNDS

Author

Kashin, I. V., Andreev, S. N., and Mazurenko, V. V.

Abstract

The question of applicability for different numerical methods to estimate the basic characteristic of the spin spirals in transition metal-based compounds is investigated. Depending on localization of the magnetic moment (bcc Fe and FeGe systems were taken as the example), methods, which include the spatial summing, were found converging or not. It reveals the significance of delocalized magnetic moment in forming of the collective magnetic excitations in real transition metal-based materials. Работа выполнена при поддержке гранта РФФИ № 16–32–00076.

Published

2018

15. Теоретическое исследование магнитных взаимодействий в диоксиде хрома

Author

Kashin, I. V. and Solovyev, I. V.

Subjects

Condensed Matter::Strongly Correlated Electrons

Abstract

We investigate behavior of the interatomic magnetic interactions in CrO2, starting from original and static variant of DMFT, based on the exact diagonalization of the effective Anderson impurity Hamiltonian, and Hartree-Fock approach. The contributions of double exchange, superexchange and higher order interactions, obtained from 1/A expansion (A being the intraatomic exchange splitting), were found to play an important role in stabilizing the ferromagnetic phase in CrO2. Работа выполнена при поддержке гранта РНФ №14-12-00306.

Published

2015

16. Теоретическое исследование магнитных взаимодействий в диоксиде хрома

Author

Кашин, И. В., Соловьев, И. В., Kashin, I. V., Solovyev, I. V., Кашин, И. В., Соловьев, И. В., Kashin, I. V., and Solovyev, I. V.

Abstract

We investigate behavior of the interatomic magnetic interactions in CrO2, starting from original and static variant of DMFT, based on the exact diagonalization of the effective Anderson impurity Hamiltonian, and Hartree-Fock approach. The contributions of double exchange, superexchange and higher order interactions, obtained from 1/A expansion (A being the intraatomic exchange splitting), were found to play an important role in stabilizing the ferromagnetic phase in CrO2.

Published

2015