Your search keyword '"Zubkov, M"' showing total 862 results

1. Generalized Wigner-Weyl calculus for gauge theory and non-dissipative transport

Author

Xavier, Praveen D. and Zubkov, M. A.

Subjects

High Energy Physics - Theory

Abstract

We consider a theory of fermions interacting with a (in general, non-Abelian) gauge field. The theory is assumed to be essentially inhomogeneous, which might be provided by non-trivial background fields interacting with both fermions and gauge bosons. For this theory, a version of Wigner-Weyl calculus is constructed, in which the Wigner transformation of the fermion Green function belongs to the adjoint representation of the gauge group. We demonstrate the power of the proposed formalism through the representation of responses of vector and axial currents to the gauge field strength through the topological invariants composed of the Wigner transformed two-point Green functions. This way a new family of non-dissipative transport phenomena is introduced. In particular, we discuss the non-Abelian versions of the chiral separation effect and of the quantum Hall effect., Comment: Latex, 35 pages

Published

2024

2. Magnetoconductivity of Dirac semimetals and chiral magnetic effect from Keldysh technique

Author

Abramchuk, R. A. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Negative magnetoresistance in Dirac semimetals is typically considered as a manifestation of chiral magnetic effect (CME). The relation between these two phenomena has the status of a hypothesis and is based on sequence of assumptions. We rely on the Keldysh technique of non-equilibrium theory. It allows us to investigate the accumulation of axial charge -- the process that involves both chiral anomaly and relaxation followed by the energy dissipation. We consider the case of strong magnetic field and calculate directly both axial charge density and electric conductivity taking into account both scattering on impurities and interaction with phonons. We obtain the same dependence of axial charge density on electric and magnetic fields, and the same dependence of electric current on axial charge density as the standard heuristic CME calculation. This confirms (in the limit of strong magnetic fields) the hypothesis that the origin of magnetoconductivity in Dirac semimetals is the CME., Comment: Latex, 16 pages, 2 figures

Published

2024

3. Weyl orbits as probe of chiral separation effect in magnetic Weyl semimetals

Author

Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Phenomenology

Abstract

We consider magnetic Weyl semimetals. First of all we review relation of intrinsic anomalous Hall conductivity, band contribution to intrinsic magnetic moment, and the conductivity of chiral separation effect (CSE) to the topological invariants written in terms of the Wigner transformed Green functions (with effects of interaction and disorder taken into account). Next, we concentrate on the CSE. The corresponding bulk axial current is accompanied by the flow of the states in momentum space along the Fermi arcs. Together with the bulk CSE current this flow forms closed Weyl orbits. Their detection can be considered as experimental discovery of chiral separation effect. Previously it was proposed to detect Weyl orbits through the observation of quantum oscillations \cite{Potter_2014} . We propose the alternative way to detect existence of Weyl orbits through the observation of their contributions to Hall conductance., Comment: Latex, 23 pages, 3 figures, accepted for publication in Journal of Physics C

Published

2023

4. Effective lagrangian for the macroscopic motion of fermionic matter

Author

Selch, M., Abramchuk, R. A., and Zubkov, M. A.

Subjects

High Energy Physics - Phenomenology

Abstract

We consider macroscopic motion of quantum field systems. Zubarev statistical operator allows to describe several types of motion of such systems in thermal equilibrium. We formulate the corresponding effective theory on the language of functional integral. The effective lagrangian is calculated explicitly for the fermionic systems interacting with dynamical gauge fields. Possible applications to physics of quark - gluon plasma are discussed., Comment: Latex, 30 pages

Published

2023

5. Hall conductivity as the topological invariant in magnetic Brillouin zone in the presence of interactions

Author

Selch, M., Suleymanov, M., Zhang, C. X., and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Hall conductivity for the intrinsic anomalous quantum Hall effect in homogeneous systems is given by the topological invariant composed of the Green function depending on momentum of quasiparticle. This expression reveals correspondence with the mathematical notion of the degree of mapping. A more involved situation takes place for the quantum Hall effect in the presence of external magnetic field. In this case the mentioned expression remains valid if the Green function is taken in a specific representation, where it becomes the infinite - dimensional matrix \cite{Imai:1990zz} or if it is replaced by its Wigner transformation while ordinary products are replaced by the Moyal products \cite{ZW2019}. Both these expressions, unfortunately, are much more complicated and might be useless for the practical calculations. Here we represent the alternative representation for the Hall conductivity of a uniform system in the presence of constant magnetic field. The Hall conductivity is expressed through the Green function taken in Harper representation, when its nonhomogeneity is attributed to the matrix structure while functional dependence is on one momentum that belongs to magnetic Brillouin zone. Our consideration for the interacting systems is non - perturbative and is based on the Schwinger - Dyson equations truncated in a reasonable way. We demonstrate that in this approximation the expression for the Hall conductivity in Harper representation remains valid, where the interacting Green function is to be used instead of the non - interacting one. We, therefore, propose that the obtained expression may be used for the topological description of fractional quantum Hall effect., Comment: Latex, 27 pages, 4 figures. arXiv admin note: text overlap with arXiv:2112.03974

Published

2023

6. Precise Wigner-Weyl calculus for the honeycomb lattice

Author

Chobanyan, R. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In this paper we propose the precise Wigner-Weyl calculus for the lattice models defined on the honeycomb lattice. We construct two symbols of operators: the $\mathscr{B}$-symbol, which is similar to the symbol introduced by F. Buot, and the $W$ (or, Weyl) symbol. The latter possesses the set of useful properties. These identities allow us to use it in physical applications. In particular, we derive topological expression for the Hall conductivity through the Wigner transformed Green function. This expression may be used for the description of quantum Hall effect in the systems with artificial honeycomb lattice, when magnetic flux through the lattice cell is of the order of elementary quantum of magnetic flux., Comment: Latex, 25 pages, 11 figures. arXiv admin note: text overlap with arXiv:2201.01390

Published

2023

7. Effect of interactions on the topological expression for the chiral separation effect

Author

Zubkov, M. A. and Abramchuk, R. A.

Subjects

High Energy Physics - Phenomenology

Abstract

In the absence of interactions the conductivity of chiral separation effect (CSE) in the system of massless fermions is given by topological expression. Interactions might change the pattern drastically. However, we prove that the CSE conductivity is still given by the topological invariant composed of the Green functions at zero temperature as long as the chiral symmetry is present, and if the renormalized axial current is considered. This allows to predict its appearance with the standard value of conductivity per Dirac fermion $\sigma_{CSE} = \frac{1}{2 \pi^2}$ in quark - gluon matter at $T = 0$ and sufficiently large baryon chemical potential, in the hypothetical phase with restored chiral symmetry and without color superconductivity. This phase may be realized inside the neutron stars. We also argue that the same topological expression for the CSE may be observed in Weyl semimetals, which realize the system of interacting relativistic fermions in solid state systems. In order to estimate the non - perturbative corrections to $\sigma_{CSE}$ within QCD at finite temperatures we apply method of field correlators developed by Yu.A.Simonov. As expected, above the deconfinement crossover the topological expression is approached within the quark - gluon plasma phase, when the quark chemical potential is sufficiently large. However, we observe that this occurs only when quark chemical potential is much larger than the thermal (Debye) mass. This range of parameters appears to be far out of the region accessible at the modern colliders., Comment: Latex, 21 pages, 4 figures

Published

2023

8. Gravastar-like black hole solutions in $q$-theory

Author

Selch, M., Miller, J., and Zubkov, M. A.

Subjects

General Relativity and Quantum Cosmology

Abstract

We present a stationary spherically symmetric solution of the Einstein equations, with a source generated by a scalar field of $q$-theory. In this theory Riemannian gravity, as described by the Einstein - Hilbert action, is coupled to a three - form field that describes the dynamical vacuum. Formally it behaves like a matter field with its own stress - energy tensor, equivalent to a scalar field minimally coupled to gravity. The asymptotically flat solutions obtained to the field equations represent black holes. For a sufficiently large horizon radius the energy density is localized within a thin spherical shell situated just outside of the horizon, analogous to a gravastar. The resulting solutions to the field equations, which admit this class of configurations, satisfy existence conditions that stem from the Black Hole no - hair theorem, thanks to the presence of a region in space in which the energy density is negative., Comment: Latex, 14 figures, 28 pages

Published

2023

9. Quark mass generation due to scalar fields with zero dimension

Author

Miller, J. and Zubkov, M. A.

Subjects

High Energy Physics - Theory, High Energy Physics - Phenomenology

Abstract

We propose a model of dynamical symmetry breaking, in which a new type of fundamental scalar fields of zero mass-dimension mediate the couplings of fermions to the gravitational field, represented here as a tetrad field in the same manner as Riemann-Cartan gravity. In our model, the tetrad couples to the standard model fermions non-minimally, and the very coupling coefficients are the fundamental scalar fields. There are exactly 36 scalar fields in the model, which are distinguishable by flavor indices on the fields. This is the precise number of zero dimension scalar fields that leads to a vanishing Weyl anomaly and a vanishing vacuum energy. Precisely the same number of these very same scalar fields is required for the coupling of all of the different standard model fermions to the vielbein field. At the same time their interaction with fermions gives rise to fermion mass terms, without the need to introduce a fundamental Higgs field. Within the proposed theory we construct a toy model that deals solely with the top and bottom quarks, and we demonstrate that their observable masses can appear in the action dynamically. Moreover, this mechanism allows for the top and bottom quarks to acquire distinctly different masses, as opposed to our previous, even simpler toy model that contained only the top quark., Comment: Latex, 52 pages, 4 figures

Published

2022

10. Topological quantization of Fractional Quantum Hall conductivity

Author

Miller, J. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We consider the quantum Hall effect (QHE) in a system of interacting electrons. Our formalism is valid for systems in the presence of an external magnetic field, as well as for systems with a nontrivial band topology. That is, the expressions for the conductivity derived are valid for both the ordinary QHE and for the intrinsic anomalous QHE. The expression for the conductivity applies to external fields that may vary in an arbitrary way, and takes into account disorder. It is assumed that the ground state of the system is degenerate. We represent the QHE conductivity as $\frac{e^2}{h} \times \frac{\cal N}{K}$, where $K$ is the degeneracy of the ground state, while $\cal N$ is the topological invariant composed of the Wigner - transformed multi - leg Green functions. $\cal N$ takes discrete values, which gives rise to quantization of the fractional QHE conductivity., Comment: Latex, 52 pages

Published

2022

11. Riemann-Cartan gravity with dynamical signature

Author

Bondarenko, S. and Zubkov, M. A.

Subjects

General Relativity and Quantum Cosmology, High Energy Physics - Theory

Abstract

Model of Riemann-Cartan gravity with varying signature of metric is considered. The basic dynamical variables of the formalism are vierbein, spin connection, and an internal metric in the tangent space. The corresponding action contains new terms, which depend on these fields. In general case the signature of the metric is determined dynamically. The Minkowski signature is preferred dynamically because the configurations with the other signatures are dynamically suppressed. We also discuss briefly the motion of particles in the background of the modified black hole configuration, in which inside the horizon the signature is that of Euclidean space - time., Comment: Latex, 7 pages

Published

2022

12. Chiral Magnetic Effect out of equilibrium

Author

Banerjee, Chitradip, Lewkowicz, Meir, and Zubkov, M. A.

Subjects

High Energy Physics - Phenomenology, High Energy Physics - Lattice

Abstract

We consider relativistic fermionic systems in lattice regularization out of equilibrium. The chiral magnetic conductivity $\sigma_{CME}$ is calculated in spatially infinite system for the case when the chiral chemical potential depends on time while the system initially was in thermal equilibrium at small but nonzero temperature. We find that the frequency dependent $\sigma_{CME}(\omega)$ for any nonzero $\omega$ both in the limits $\omega \ll T$ and $\omega \gg T$ is equal to its conventional value $1$ when the lattice model approaches continuum limit. Notice that $\sigma_{CME} = 0$ for the case when the chiral chemical potential does not depend on time at all. We therefore confirm that the limit of vanishing $\omega$ is not regular for the spatially infinite systems of massless fermions., Comment: 15 pages, Latex, 6 figures

Published

2022

13. Fundamental scalar field with zero dimension from anomaly cancelations

Author

Miller, J., Volovik, G. E., and Zubkov, M. A.

Subjects

High Energy Physics - Theory

Abstract

In this article a novel mechanism for dynamical electroweak symmetry breaking and the ensuing appearance of fermion mass terms in the action is proposed. The action contains massless fermions of the SM coupled to gravity through a new type of non-minimal coupling to the vielbein field. The corresponding coupling constants in our approach become zero-dimension scalar fields. Such scalar fields provide the cancellation of the Weyl anomaly \cite{Boyle:2021jaz}., Comment: Latex, 12 pages, 3 figures

Published

2022

14. Wigner-Weyl calculus in description of non-dissipative transport phenomena

Author

Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Application of Wigner-Weyl calculus to the investigation of non-dissipative transport phenomena is reviewed. We focus on the quantum Hall effect, Chiral Magnetic effect, and Chiral separation effect, and discuss the role of interactions, inhomogeneity, and deviations from equilibrium., Comment: Latex, 15 pages, based on the talk presented at the 10th International Conference on New Frontiers in Physics (ICNFP 2021), August 23, 2021 to October 7, 2021, Kolymbari, Crete, Greece

Published

2022

15. Discrete Wigner-Weyl calculus for the finite lattice

Author

Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We develop the approach of Felix Buot to construction of Wigner-Weyl calculus for the lattice models. We apply this approach to the tight-binding models with finite number of lattice cells. For simplicity we restrict ourselves to the case of rectangular lattice. We start from the original Buot definition of the symbol of operator. This definition is corrected in order to maintain self-consistency of the algebraic constructions. It appears, however, that the Buot symbol for simple operators does not have a regular limit when the lattice size tends to infinity. Therefore, using a more dense auxiliary lattice we modify the Buot symbol of operator in order to build our new discrete Weyl symbol. The latter obeys several useful identities inherited from the continuum theory. Besides, the limit of infinitely large lattice becomes regular. We formulate Keldysh technique for the lattice models using the proposed Weyl symbols of operators. Within this technique the simple expression for the electric conductivity of a two dimensional non - equilibrium and non - homogeneous system is derived. This expression smoothly approaches the topological one in the limit of thermal equilibrium at small temperature and large system area., Comment: Latex, 41 pages, 1 figure

Published

2022

16. Hall conductivity as the topological invariant in magnetic Brillouin zone

Author

Suleymanov, M., Zubkov, M. A., and Zhang, C. X.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Hall conductivity for the intrinsic quantum Hall effect in homogeneous systems is given by the topological invariant composed of the Green function depending on momentum of quasiparticle. This expression reveals correspondence with the mathematical notion of the degree of mapping. A more involved situation takes place for the Hall effect in the presence of external magnetic field. In this case the mentioned expression remains valid if the Green function is replaced by its Wigner transformation while ordinary products are replaced by the Moyal products. Such an expression, unfortunately, is much more complicated and might be useless for the practical calculations. Here we represent the alternative representation for the Hall conductivity of a uniform system in the presence of constant magnetic field. The Hall conductivity is expressed through the Green function taken in Harper representation, when its nonhomogeneity is attributed to the matrix structure while functional dependence is on one momentum that belongs to magnetic Brillouin zone. Our results were obtained for the non - interacting systems. But we expect that they remain valid for the interacting systems as well. We, therefore, propose the hypothesis that the obtained expression may be used for the topological description of fractional quantum Hall effect., Comment: Latex, 38 pages, 2 figures

Published

2021

17. A Class of Low Linear Orders Having Computable Presentations

Author

Zubkov, M. V.

Published

2023

18. Punctual 1-Linear Orders

Author

Frolov, A. N. and Zubkov, M. V.

Published

2023

19. Equilibrium Chiral Magnetic Effect: spatial inhomogeneity, finite temperature, interactions

Author

Banerjee, Chitradip, Lewkowicz, Meir, and Zubkov, M. A.

Subjects

High Energy Physics - Phenomenology

Abstract

We discuss equilibrium relativistic fermionic systems in lattice regularization, and extend the consideration of chiral magnetic effect to systems with spatial inhomogeneity and finite temperature. Besides, we take into account interactions due to exchange by gauge bosons. We find that the equilibrium chiral magnetic conductivity remains equal to zero., Comment: 12 pages, 4 figures

Published

2021

20. Classification of emergent Weyl spinors in multi-fermion systems

Author

Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In the fermionic systems with topologically stable Fermi points the emergent two - component Weyl fermions appear. We propose the topological classification of these fermions based on the two invariants composed of the two - component Green function. We define these invariants using Wigner - Weyl formalism also in case of essentially non - homogeneous systems. In the case when values of these invariants are minimal ($\pm 1$) we deal with emergent relativistic symmetry. The emergent gravity appears, and our classification of Weyl fermions gives rise to the classification of vierbein. Transformations between emergent relativistic Weyl fermions of different types correspond to parity conjugation, time reversal, and charge conjugation., Comment: Latex, 9 pages, published version

Published

2021

21. Multilayer Haldane model

Author

Wu, Xi, Zhang, C. X., and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We propose the model of layered materials, in which each layer is described by the conventional Haldane model, while the inter - layer hopping parameter corresponds to the ABC stacking. We calculate the topological invariant $N_3$ for the resulting model, which is responsible for the conductivity of intrinsic quantum Hall effect. It has been shown that in a certain range of the values of interlayer hopping parameter, the value of $N_3$ is equal to the number of layers multiplied by the topological invariant of each layer. At the same time this value may be calculated using the low energy effective theory., Comment: Latex, 14 pages, 3 figures

Published

2021

22. Influence of interactions on Integer Quantum Hall Effect

Author

Zhang, C. X. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Conductivity of Integer Quantum Hall Effect (IQHE) may be expressed as the topological invariant composed of the two - point Green function. Such a topological invariant is known both for the case of homogeneous systems with intrinsic Anomalous Quantum Hall Effect (AQHE) and for the case of IQHE in the inhomogeneous systems. In the latter case we may speak, for example, of the AQHE in the presence of elastic deformations and of the IQHE in presence of magnetic field. The topological invariant for the general case of inhomogeneous systems is expressed through the Wigner transformed Green functions and contains Moyal product. When it is reduced to the expression for the IQHE in the homogeneous systems the Moyal product is reduced to the ordinary one while the Wigner transformed Green function (defined in phase space) is reduced to the Green function in momentum space. Originally the mentioned above topological representation has been derived for the non - interacting systems. We demonstrate that in a wide range of different cases in the presence of interactions the Hall conductivity is given by the same expression, in which the noninteracting two - point Green function is substituted by the complete two - point Green function with the interactions taken into account. Several types of interactions are considered including the contact four - fermion interactions, Yukawa and Coulomb interactions. We present the complete proof of this statement up to the two loops, and argue that the similar result remains to all orders of perturbation theory. It is based on the incorporation of Wigner - Weyl calculus to the perturbation theory. We, therefore, formulate Feynmann rules of diagram technique in terms of the Wigner transformed propagators., Comment: Latex, 44 pages, 18 figures, Accepted for publication in Annals of Physics

Published

2020

23. Wigner-Weyl calculus in Keldysh technique

Author

Banerjee, C., Fialkovsky, I. V., Lewkowicz, M., Zhang, C. X., and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We discuss the non-equilibrium dynamics of condensed matter/quantum field systems in the framework of Keldysh technique. In order to deal with the inhomogeneous systems we use the Wigner-Weyl formalism. Unification of the mentioned two approaches is demonstrated on the example of Hall conductivity. We express Hall conductivity through the Wigner transformed two-point Green's functions. We demonstrate how this expression is reduced to the topological number in thermal equilibrium at zero temperature. At the same time both at finite temperature and out of equilibrium the topological invariance is lost. Moreover, Hall conductivity becomes sensitive to interaction corrections., Comment: Latex, 29 pages

Published

2020

24. High energy scattering in Einstein-Cartan gravity

Author

Bondarenko, S., Pozdnyakov, S., and Zubkov, M. A.

Subjects

High Energy Physics - Theory

Abstract

We consider Riemann-Cartan gravity with minimal Palatini action, which is classically equivalent to Einstein gravity. Following the ideas of L.Lipatov \cite{LipGrav} we propose the effective action for this theory aimed at the description of the high-energy scattering of gravitating particles in the multi - Regge kinematics. For that purpose we add to the Palatini action the new terms responsible for the interaction of gravitational quanta with certain collective excitations that replace exchange by multiple gravitational excitations. We propose the heuristic explanation of its particular form based on an analogy to the reggeon field theory of QCD. We argue that Regge kinematics assumes the appearance of an effective two - dimensional model describing the high - energy scattering similar to that of QCD. Such a model may be formulated in a way leading to our final effective theory, which contains interaction between the ordinary quanta of spin connection and vielbein with their effective counterparts that pretend to the role of the gravitational reggeons., Comment: Latex, 14 pages

Published

2020

25. Chiral Separation effect in non-homogeneous systems

Author

Suleymanov, M. and Zubkov, M. A.

Subjects

High Energy Physics - Theory, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We discuss chiral separation effect in the systems with spatial non - homogeneity. It may be caused by non - uniform electric potential or by another reasons, which do not, however, break chiral symmetry of an effective low energy theory. Such low energy effective theory describes quasiparticles close to the Fermi surfaces. In the presence of constant external magnetic field the non - dissipative axial current appears. It appears that its response to chemical potential and magnetic field (the CSE conductivity) is universal. It is robust to smooth modifications of the system and is expressed through an integral over a surface in momentum space that surrounds all singularities of the Green function. In itself this expression represents an extension of the topological invariant protecting Fermi points to the case of inhomogeneous systems., Comment: Latex, 31 pages, 1 Figure

Published

2020

26. Anomalous fractional quantum Hall effect and multi-valued Hamiltonians

Author

Wu, Xi and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We discuss anomalous fractional quantum Hall effect that exists without external magnetic field. We propose that excitations in such systems may be described effectively by non-interacting particles with the Hamiltonians defined on the Brillouin zone with a branch cut. Hall conductivity of such a system is expressed through the one-particle Green function. We demonstrate that for the Hamiltonians of the proposed type this expression takes fractional values times Klitzing constant. Possible relation of the proposed construction with degeneracy of ground state is discussed as well., Comment: Latex, 14 pages, 4 figures

Published

2020

27. RF-coil with variable resonant frequency for multiheteronuclear ultra-high field MRI

Author

Ivanov, V. A., Hurshkainen, A. A., Solomakha, G. A., and Zubkov, M. A.

Subjects

Physics - Medical Physics, Physics - Applied Physics

Abstract

Here we propose double-coil setup to allow high signal-to-noise ratio broad-range heteronuclear magnetic resonance imaging experiments: two independent coils, one of them tuned to $^{1}$H frequency to perform anatomical $^{1}$H imaging, and another one, metamaterial-inspired coil, tuned to the X-nucleus frequency. In this work our goal was to design a broad-range X-nuclei coil to cover $^{2}$H, $^{11}$B, $^{13}$C, $^{23}$Na, $^{7}$Li and $^{31}$P nuclear magnetic resonance frequencies, and to combine it with $^{1}$H coil in one setup. The system was designed for 11.7 T scanner, i.e., with 76-203 MHz frequency tuning range for the X-nuclei and tuned to 500 MHz for the proton coil. X-nuclei coil operates via excitation of the fundamental eigenmode of an array of parallel non-magnetic wires. The excitation of the array is provided via non-resonant feeding loop inductively coupled to the resonator. In order to tune the X-coil over such a wide range, both structural capacitance and inductance of the coil were made variable; narrow range tuning of the $^{1}$H coil is achieved via conventional tuning-matching circuit. Here, the design principle and setup tunability were investigated in simulations and experimentally.

Published

2020

28. Quantum Hall conductivity in the presence of interactions

Author

Wu, Xi and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

We discuss quantum Hall effect in the presence of arbitrary pair interactions between electrons. It is shown that irrespective of the interaction strength the Hall conductivity is given by the filling fraction of Landau levels averaged over the ground state of the system. This conclusion remains valid for both integer and fractional quantum Hall effect., Comment: Latex, 8 pages

Published

2019

29. Precise Wigner-Weyl calculus for lattice models

Author

Fialkovsky, I. V. and Zubkov, M. A.

Subjects

Mathematical Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We propose a new version of Wigner-Weyl calculus for tight-binding lattice models. It allows to express various physical quantities through Weyl symbols of operators and Green's functions. In particular, Hall conductivity in the presence of varying and arbitrarily strong magnetic field is represented using the proposed formalism as a topological invariant., Comment: Latex, 37 pages

Published

2019

30. Feynman Rules in terms of the Wigner transformed Green functions

Author

Zhang, C. X. and Zubkov, M. A.

Subjects

High Energy Physics - Phenomenology

Abstract

In the models defined on the inhomogeneous background the propagators depend on the two space - time momenta rather than on one momentum as in the homogeneous systems. Therefore, the conventional Feynman diagrams contain extra integrations over momenta, which complicate calculations. We propose to express all amplitudes through the Wigner transformed propagators. This approach allows us to reduce the number of integrations. As a price for this the ordinary products of functions are replaced by the Moyal products. The corresponding rules of the diagram technique are formulated using an example of the model with the fermions interacting via an exchange by scalar bosons. The extension of these rules to the other models is straightforward. This approach may simplify calculations in certain particular cases. The most evident one is the calculation of various non - dissipative currents., Comment: Latex, 14 pages

Published

2019

31. Abelian Fock-Schwinger representation for the quark propagator in external gauge field

Author

Zubkov, M. A.

Subjects

High Energy Physics - Phenomenology

Abstract

We develop the Diakonov-Petrov approach to the representation of the non-Abelian Wilson loop in an Abelian form. First of all, we extend this approach to the Abelian representation of the parallel transporter corresponding to the open curve rather than to the closed contour. Next, we extend this representation to the case of the non-compact groups. The obtained expressions allow to derive the Abelian form of the Schwinger-Fock representation for the quark propagator in an external color gauge field., Comment: Latex, 12 pages

Published

2019

32. Hall conductivity as topological invariant in phase space

Author

Fialkovsky, I. V., Suleymanov, M., Wu, Xi, Zhang, C. X., and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

It is well known that the quantum Hall conductivity in the presence of constant magnetic field is expressed through the topological TKNN invariant. The same invariant is responsible for the intrinsic anomalous quantum Hall effect (AQHE), which, in addition, may be represented as one in momentum space composed of the two point Green's functions. We propose the generalization of this expression to the QHE in the presence of non-uniform magnetic field. The proposed expression is the topological invariant in phase space composed of the Weyl symbols of the two-point Green's function. It is applicable to a wide range of non-uniform tight-binding models, including the interacting ones., Comment: Latex, 11 pages, proceedings of ICNFP2019, misprints corrected. arXiv admin note: text overlap with arXiv:1905.11097

Published

2019

33. Hall conductivity of strained $Z_2$ crystals

Author

Fialkovsky, I. V. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We establish topological nature of Hall conductivity of graphene and other $Z_2$ crystals in 2D and 3D in the presence of inhomogeneous perturbations. To this end the lattice Weyl-Wigner formalism is employed. The non-uniform mechanical stress is considered, along with spatially varying magnetic field. The relation of the obtained topological invariant to level counting is clarified., Comment: Latex, 13 pages, prepared for the proceedings of ICNFP2019

Published

2019

34. A Note on Bloch theorem

Author

Zhang, C. X. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Bloch theorem in ordinary quantum mechanics means the absence of the total electric current in equilibrium. In the present paper we analyze the possibility that this theorem remains valid within quantum field theory relevant for the description of both high energy physics and condensed matter physics phenomena. First of all, we prove that the total electric current in equilibrium is the topological invariant for the gapped fermions that are subject to periodical boundary conditions, i.e. it is robust to the smooth modification of such systems. This property remains valid when the inter - fermion interactions due to the exchange by bosonic excitations are taken into account perturbatively. We give the proof of this statement to all orders in perturbation theory. Thus we prove the weak version of the Bloch theorem, and conclude that the total current remains zero in any system, which is obtained by smooth modification of the one with the gapped charged fermions, periodical boundary conditions, and vanishing total electric current. We analyse several examples, in which the fermions are gapless. In some of them the total electric current vanishes. At the same time we propose the counterexamples of the equilibrium gapless systems, in which the total electric current is nonzero., Comment: Latex, 12 pages, 10 figures, accepted for publication in Phys.Rev.D

Published

2019

35. Emergent gravity in superplastic crystals and cosmological constant problem

Author

Zubkov, M. A.

Subjects

General Relativity and Quantum Cosmology

Abstract

We discuss emergent gravity in the superplastic crystals. We restrict ourselves by the consideration of the gapped (massive) fermions coupled to gravity. In this approach the stress - energy tensor may be defined in such a way, that being integrated over the whole volume it is a topological invariant provided that the background metric weakly depends on coordinates. In equilibrium its value is not changed if the system is modified smoothly. The cosmological constant in this pattern is a topological invariant as well., Comment: Latex, 13 pages

Published

2019

36. Hall conductivity as the topological invariant in phase space in the presence of interactions and non-uniform magnetic field

Author

Zhang, C. X. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The quantum Hall conductivity in the presence of constant magnetic field may be represented as the topological TKNN invariant. Recently the generalization of this expression has been proposed for the non - uniform magnetic field. \rev{The quantum Hall conductivity is represented as the topological invariant in phase space in terms of the Wigner transformed two - point Green function.} This representation has been derived when the inter - electron interactions were neglected. It is natural to suppose, that in the presence of interactions the Hall conductivity is still given by the same expression, in which the non - interacting Green function is substituted by the complete two - point Green function \rev{ including the interaction contributions}. We prove this conjecture within the framework of the $2+1$ D tight - binding model of rather general type using the ordinary perturbation theory., Comment: Latex, 7 pages, 4 figures, accepted for publication in JETP letters

Published

2019

37. Classical limit for Dirac fermions with modified action in the presence of the black hole

Author

Lewkowicz, M. and Zubkov, M. A.

Subjects

General Relativity and Quantum Cosmology

Abstract

We consider the model of Dirac fermions coupled to gravity as proposed in \cite{VolovikBH}, in which superluminal velocities of particles are admitted. In this model an extra term is added to the conventional Hamiltonian that originates from Planck physics. Due to this term a closed Fermi surface is formed in equilibrium inside the black hole. In this paper we propose the covariant formulation of this model and analyse its classical limit. We consider the dynamics of gravitational collapse. It appears that the Einstein equations admit a solution identical to that of the ordinary general relativity. Next, we consider motion of particles in the presence of the black hole. Numerical solutions of the equations of motion are found which demonstrate that the particles are able to escape from the black hole., Comment: Latex, 13 pages, 5 figures

Published

2019

38. Elastic deformations and Wigner-Weyl formalism in graphene

Author

Fialkovsky, I. V. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Lattice

Abstract

We discuss the tight-binding models of solid state physics with the $Z_2$ sublattice symmetry in the presence of elastic deformations, and their important particular case -the tight binding model of graphene. In order to describe the dynamics of electronic quasiparticles we explore Wigner-Weyl formalism. It allows to calculate the two-point Green's function in the presence of both slowly varying external electromagnetic fields and the inhomogeneous modification of the hopping parameters resulted from the elastic deformations. The developed formalism allows us to consider the influence of elastic deformations and the variations of magnetic field on the quantum Hall effect., Comment: Latex, 34 pages

Published

2019

39. Influence of interactions on the anomalous quantum Hall effect

Author

Zhang, C. X. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The anomalous quantum Hall conductivity in the 2+1D topological insulators in the absence of interactions may be expressed as the topological invariant composed of the two - point Green function. For the noninteracting system this expression is the alternative way to represent the TKNN invariant. It is widely believed that in the presence of interactions the Hall conductivity is given by the same expression, in which the noninteracting two - point Green function is substituted by the complete two - point Green function with the interactions taken into account. However, the proof of this statement has not been given so far. In the present paper we give such a proof in the framework of the particular tight - binding models of the $2+1$ D topological insulator. Besides, we extend our consideration to the $3+1$ D Weyl semimetals. It was known previously that with the interactions neglected the Hall conductivity in those systems is expressed through the two - point Green function in the way similar to that of the $2+1$ D topological insulators. Again, the influence of interactions on this expression has not been investigated previously. We consider this problem within the framework of the particular $3+1$D model of Weyl semimetal in the presence of the contact four - fermion interactions and Coulomb interactions. We prove (up to the one - loop approximation), that the Hall conductivity is given by the same expression as in the noninteracting case, in which the noninteracting Green function is substituted by the complete two - point Green function with the interactions included. Basing on the obtained expressions we discuss the topological phase transitions accompanied by the change of Hall conductivity., Comment: Latex, 33 pages. arXiv admin note: text overlap with arXiv:2011.04030

Published

2019

40. Topological invariant in terms of the Green functions for the Quantum Hall Effect in the presence of varying magnetic field

Author

Zubkov, M. A. and Wu, Xi

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Recently the Wigner - Weyl formalism has been applied to the lattice models of solid state physics and to the lattice regularized quantum field theory. This allows to demonstrate that the electric current of intrinsic Anomalous Quantum Hall effect is expressed through the momentum space topological invariant composed of the Green functions both for the two - and the three - dimensional systems. Here we extend this consideration to the case of the Quantum Hall Effect existing in the presence of arbitrarily varying external magnetic field. The corresponding electric current appears to be proportional to the topological invariant in phase space composed of the Wigner transformed Green function that depends both on coordinates and momenta., Comment: Latex, 26 pages

Published

2019

41. Momentum Space Topology and Non-Dissipative Currents

Author

Zubkov, M. A., Khaidukov, Z. V., and Abramchuk, R. A.

Subjects

High Energy Physics - Phenomenology

Abstract

Relativistic heavy ion collisions represent an arena for the probe of various anomalous transport effects. Those effects, in turn, reveal the correspondence between the solid state physics and the high energy physics, which share the common formalism of quantum field theory. It may be shown that for the wide range of {field-theoretic} models, the response of various nondissipative currents to the external gauge fields is determined by the momentum space topological invariants. Thus, the anomalous transport appears to be related to the investigation of momentum space topology -- the approach developed earlier mainly in the condensed matter theory. Within this methodology we analyse systematically the anomalous transport phenomena, which include, in particular, the anomalous quantum Hall effect, the chiral separation effect, the chiral magnetic effect, the chiral vortical effect and the rotational Hall effect., Comment: This paper is based on the talk at the 7th International Conference on New Frontiers in Physics (ICNFP~2018), Crete, Greece, 4--12 July 2018

Published

2018

42. Chiral torsional effect

Author

Khaidukov, Z. V. and Zubkov, M. A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Phenomenology

Abstract

We propose the new nondissipative transport effect - the appearance of axial current of thermal quasiparticles in the presence of background gravity with torsion. For the non-interacting model of massless Dirac fermions the response of the axial current to torsion is derived. The chiral vortical effect appears to be the particular case of the chiral torsional effect. The proposed effect may be observed in the condensed matter systems with emergent relativistic invariance (Weyl/Dirac semimetals and the $^3$He-A superfluid)., Comment: to appear in Jetp Lett. (2018)

Published

2018

43. Analogies between the Black Hole Interior and the Type II Weyl Semimetals

Author

Zubkov, M. A.

Subjects

General Relativity and Quantum Cosmology

Abstract

In the Painleve--Gullstrand (PG) reference frame, the description of elementary particles in the background of a black hole (BH) is similar to the description of non-relativistic matter falling toward the BH center. The velocity of the fall depends on the distance to the center, and it surpasses the speed of light inside the horizon.~Another analogy to non-relativistic physics appears in the description of the massless fermionic particle. Its Hamiltonian inside the BH, when written in the PG reference frame, is identical to the Hamiltonian of the electronic quasiparticles in type~II Weyl semimetals (WSII) that reside in the vicinity of a type~II Weyl point. When these materials are in the equilibrium state, the type II Weyl point becomes the crossing point of the two pieces of the Fermi surface called Fermi pockets. {It was previously stated} that there should be a Fermi surface inside a black hole in equilibrium. In real materials, type II Weyl points come in pairs, and the descriptions of the quasiparticles in their vicinities are, to a certain extent, inverse. Namely, the directions of their velocities are opposite. In line with the mentioned analogy, we propose the hypothesis that inside the equilibrium BH there exist low-energy excitations moving toward the exterior of the BH. These excitations are able to escape from the BH, unlike ordinary matter that falls to its center. The important consequences to the quantum theory of black holes follow., Comment: Latex, 7 pages

Published

2018

44. Wigner - Weyl formalism and the propagator of Wilson fermions in the presence of varying external electromagnetic field

Author

Suleymanov, M. and Zubkov, M. A.

Subjects

High Energy Physics - Lattice, High Energy Physics - Phenomenology

Abstract

We develop Wigner - Weyl formalism for the lattice models. For the definiteness we consider Wilson fermions in the presence of $U(1)$ gauge field. The given technique reduces calculation of the two point fermionic Green function to solution of the Groenewold equation. It relates Wigner transformation of the Green function with the Weyl symbol $Q_W$ of Wilson Dirac operator. We derive the simple expression for $Q_W$ in the presence of varying external $U(1)$ gauge field. Next, we solve the Groenewold equation to all orders in powers of the derivatives of $Q_W$. Thus the given technique allows to calculate the fermion propagator in the lattice model with Wilson fermions in the presence of arbitrary background electromagnetic field. The generalization of this method to the other lattice models is straightforward., Comment: Latex 25 pages, accepted for publication in Nuclear Physics B (2018)

Published

2018

45. Anomalous transport phenomena and momentum space topology

Author

Zubkov, M. A. and Khaidukov, Z. V.

Subjects

High Energy Physics - Phenomenology, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Using the derivative expansion applied to the Wigner transform of the two - point Green function this is possible to derive the response of various nondissipative currents to the external gauge fields. The corresponding currents are proportional to the momentum space topological invariants. This allows to analyse systematically various anomalous transport phenomena including the anomalous quantum Hall effect and the chiral separation effect. We discuss the application of this methodology both to the solid state physics and to the high energy physics., Comment: Latex, 8 pages, proceedings of the XXth International Seminar "Quarks-2018" (27 May 2018 - 2 June 2018, Valday, Russia)

Published

2018

46. The type II Weyl semimetals at low temperatures: chiral anomaly, elastic deformations, zero sound

Author

Zubkov, M. A. and Lewkowicz, M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Phenomenology

Abstract

We consider the properties of the type II Weyl semimetals at low temperatures basing on the particular tight - binding model. In the presence of electric field directed along the line connecting the Weyl points of opposite chirality the occupied states flow along this axis giving rise to the creation of electron - hole pairs. The electrons belong to a vicinity of one of the two type II Weyl points while the holes belong to the vicinity of the other. This process may be considered as the manifestation of the chiral anomaly that exists without any external magnetic field. It may be observed experimentally through the measurement of conductivity. Next, we consider the modification of the theory in the presence of elastic deformations. In the domain of the considered model, where it describes the type I Weyl semimetals the elastic deformations lead to the appearance of emergent gravity. In the domain of the type II Weyl semimetals the form of the Fermi surface is changed due to the elastic deformations, and its fluctuations represent the special modes of the zero sound. We find that there is one - to one correspondence between them and the sound waves of the elasticity theory. Next, we discuss the influence of the elastic deformations on the conductivity. The particularly interesting case is when our model describes the intermediate state between the type I and the type II Weyl semimetal. Then without the elastic deformations there are the Fermi lines instead of the Fermi points/Fermi surface, while the DC conductivity vanishes. However, even small elastic deformations may lead to the appearance of large conductivity., Comment: Latex, 23 pages, 6 figures

Published

2018

47. Anatomy of the chiral vortical effect

Author

Abramchuk, Ruslan, Khaidukov, Z. V., and Zubkov, M. A.

Subjects

High Energy Physics - Phenomenology

Abstract

We consider the system of relativistic rotating fermions in the presence of rotation. The rotation is set up as an enhancement of the angular momentum. In this approach the angular velocity for the angular momentum plays the same role as the chemical potential for density. We calculate the axial current using the direct solutions of the Dirac equation with the MIT bag boundary conditions. Next, we consider the alternative way of the rotation description, in which the local velocity of the substance multiplied by the chemical potential serves as the effective gauge field. In this approach this is possible to relate the axial current of the chiral vortical effect for the massless fermions to the topological invariant in momentum space, which is robust to the introduction of interactions. We compare the results for the axial current obtained using the two above mentioned approaches., Comment: Latex, 16 pages, 10 figures

Published

2018

48. The dimensionally reduced description of the high energy scattering and the effective action for the reggeized gluons

Author

Bondarenko, S. and Zubkov, M. A.

Subjects

High Energy Physics - Phenomenology

Abstract

We discuss the high energy scattering of hadrons with the multi - Regge kinematics. The effective $2D$ model for the interaction between the produced hard gluons appears as a result of the dimensional reduction, which is similar to the dimensional reduction $3+1$ D $\to 3$ D of the high temperature gauge theory. It is demonstrated that being supplemented by the exchange by virtual $3+1$ D gluons this $2D$ model gives rise to the hermitian version of the effective action of Lipatov for the interaction between the ordinary and the reggeized gluons., Comment: 16 pages, Latex

Published

2018

49. Hall effect in the presence of rotation

Author

Zubkov, M. A.

Subjects

High Energy Physics - Phenomenology

Abstract

The rotating relativistic fermion system is considered. The consideration is based on the Dirac equation written in the laboratory (non - rotating) reference frame. Rotation in this approach gives rise to the effective magnetic and electric fields that act in the same way both on positive and negative electric charges. In the presence of external electric field in the given system the electric current appears orthogonal to both the electric field and the axis of rotation. The possible applications to the physics of quark - gluon plasma are discussed., Comment: Latex, 7 pages

Published

2018

50. The black hole interior and the type II Weyl fermions

Author

Zubkov, M. A.

Subjects

General Relativity and Quantum Cosmology, Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Lattice, High Energy Physics - Theory

Abstract

It was proposed recently that the black hole may undergo a transition to the state, where inside the horizon the Fermi surface is formed that reveals an analogy with the recently discovered type II Weyl semimetals. In this scenario the low energy effective theory outside of the horizon is the Standard Model, which describes excitations that reside near a certain point $P^{(0)}$ in momentum space of the hypothetical unified theory. Inside the horizon the low energy physics is due to the excitations that reside at the points in momentum space close to the Fermi surface. We argue that those points may be essentially distant from $P^{(0)}$ and, therefore, inside the black hole the quantum states are involved in the low energy dynamics that are not described by the Standard Model. We analyse the consequences of this observation for the physics of the black holes and present the model based on the direct analogy with the type II Weyl semimetals, which illustrates this pattern., Comment: Latex, 14 pages

Published

2018