Институт теоретической физики им. Л.Д. Ландау


Российской академии наук

Публикации

Статьи

  1. A.A. Mazanik, Ya.V. Fominov, Peculiarities of the density of states in SN junctions, Annals of Physics 449, 169199 (2023); arXiv:2205.06171, ADS: 2023AnPhy.44969199M.
  2. G.E. Volovik, Painlevé-Gullstrand coordinates for Schwarzschild-de Sitter spacetime, Annals of Physics, 449, 169219 (2023); arXiv:2209.02698, ADS: 2022arXiv220902698V, InSpire: 2148169.
  3. S.A. Romashevskiy, A.I. Ignatov, V.V. Zhakhovsky, E.M. Eganova, E.A. Pershina, N.A. Inogamov, S.I. Ashitkov, Embossing of silicon with an ultrashort laser pulse diffracted by a bubble in liquid, Applied Surface Science, 615, 156212 (2023), ADS: 2023ApSS..61556212R.
  4. A. Artemev, V. Belavin, Torus one-point correlation numbers in minimal Liouville gravity, JHEP 2023(02), 116 (2023); arXiv:2210.14568, InSpire: 2170991.
  5. A.S. Osin, Ya.V. Fominov, Comment on "Josephson Current as a Boundary Condition for Gor’kov Equations", Journal of Superconductivity and Novel Magnetism, 36(1), 55-58 (2023).
  6. P.D. Grigoriev, V.D. Kochev, A.P. Orlov, A.V. Frolov, A.A. Sinchenko, Inhomogeneous superconductivity onset in FeSe studied by transport properties, Materials, 16(5), 1840 (2023); arXiv:2301.06185, ADS: 2023arXiv230106185G.
  7. J. Slim, N.N. Nikolaev, F. Rathmann, A. Wirzba, Quantum mechanical derivation of radio-frequency-driven coherent beam oscillations in storage rings, Phys. Rev. Accel. Beams 26, 014201 (2023); arXiv:2111.08444, ADS: 2021arXiv211108444S, InSpire: 1969346.
  8. D.S. Antonenko, E. Khalaf, P.M. Ostrovsky, M.A. Skvortsov, Anderson localization at the boundary of a two-dimensional topological superconductor, Phys. Rev. B 107, 075417 (2023); arXiv:2112.06890, ADS: 2021arXiv211206890A.
  9. O. Andreev, QQqq¯q quark system, compact pentaquark, and gauge/string duality, Phys. Rev. D 107, 026023 (2023); arXiv:2211.12305, ADS: 2022arXiv221112305A, InSpire: 2513665.
  10. M. Lashkevich, The free field representation for the GL(1|1) WZW model revisited, Physica Scripta, 98(1), 015025 (2023) (Published online 26 December 2022); arXiv:2205.00557, ADS: 2023PhyS...98a5025L, InSpire: 2075494.
  11. A.S. Koshelev, A.A. Starobinsky, A. Tokareva, Post-inflationary GW production in generic higher (infinite) derivative gravity, Physics Letters B 838, 137686 (2023); arXiv:2211.02070, ADS: 2023PhLB..83837686K, InSpire: 2176727.
  12. A.O. Korotkevich, P.M. Lushnikov, A.A. Semenova, S.A. Dyachenko, Superharmonic instability of Stokes waves, Studies in Applied Mathematics, 150(1), 119-134 (2023); arXiv:2206.00725, WoS: 000865088200001, ADS: 2022arXiv220600725K.
  13. З.З. Алисултанов, Г.О. Абдуллаев, П.Д. Григорьев, Н.А. Демиров, Квантовые осцилляции межслойной проводимости в многослойном топологическом изоляторе, ЖЭТФ, 163 (3), 401-416 (2023).
  14. А.А. Левченко, Л.П. Межов-Деглин, А.А. Пельменёв, Вихри на свободной поверхности слоя нормального гелия He-I в широкой ячейке, ЖЭТФ, 163 (4), 545-560 (2023), EDN: MCGOFI.
  15. Н.А. Иногамов, В.А. Хохлов, С.А. Ромашевский, Ю.В. Петров, В.В. Жаховский, С.И. Ашитков, Определение важнейших параметров металла, облученного ультракоротким лазерным импульсом, Письма в ЖЭТФ, 117(2), 107-114 (2023) [N.A. Inogamov, V.A. Khokhlov, S.A. Romashevskiy, Yu.V. Petrov, V.V. Zhakhovsky, S.I. Ashitkov, Determination of the Most Important Parameters of a Metal Irradiated by an Ultrashort Laser Pulse, JETP Letters, 117(2), 104-110 (2023)], EDN: oefbbu.
  16. И.В. Колоколов, В.В. Лебедев, М.М. Тумакова, Парная корреляционная функция завихренности внутри когерентного вихря, Письма в ЖЭТФ, 117(2), 127-131 (2023) [I.V. Kolokolov, V.V. Lebedev, M.M. Tumakova, Pair correlation function of vorticity in a coherent vortex, JETP Letters, 117(2), 122-125 (2023)], ADS: 2023JETPL.tmp....4K, EDN: oerbul.
  17. G.E. Volovik, Dimensionless physics: Planck constant as an element of Minkowski metric, Письма в ЖЭТФ, 117(3), 248-249 (2023) [JETP Letters, 117(3), 122-125 (2023)]; arXiv:2209.15426, ADS: 2023JETPL.tmp....6V, InSpire: 2158985, EDN: oxtlrm.
  18. В.П. Рубан, "Капиллярные" структуры в поперечно захваченных нелинейных оптических пучках, Письма в ЖЭТФ, 117(4), 292-295 (2023) [V.P. Ruban, "Capillary'' structures in transversely trapped nonlinear optical beams, JETP Letters, 117(4), ... (2023)]; arXiv:2212.13429, ADS: 2022arXiv221213429R, EDN: piwlzm.
  19. К.Д. Бакланова, В.К. Долганов, Е.И. Кац, П.В. Долганов, Последовательность трехмерных (3D), двумерных (2D) и одномерных (1D) структур, образующихся из холестерического жидкого кристалла при изменении хиральности, Письма в ЖЭТФ, 117(7), 537-542 (2023), EDN: kbzcaa.
  20. G.E. Volovik, Acoustic metric and Planck constants, Письма в ЖЭТФ, 117(7), 556-557 (2023) [JETP Letters, 117(7), ... (2023)]; arXiv:2302.08894, ADS: 2023arXiv230208894V, InSpire: 2634063, EDN:  klnumv.
  21. С.Н. Вергелес, Н.Н. Николаев, Ю.Н. Обухов, А.Я. Силенко, О.В. Теряев, Эффекты общей теории относительности в прецизионных спиновых экспериментах по проверке фундаментальных симметрий, УФН, 193(2), 113-154 (2023) [S.N. Vergeles, N.N. Nikolaev, Yu.N. Obukhov, A.Ya. Silenko, O.V. Teryaev, General relativity effects in precision spin experiments on tests of fundamental symmetries, Phys. Usp., 66(2), ... (2023)]; arXiv:2204.00427, ADS: 2022arXiv220400427V, InSpire: 2061519.

Статьи в сборниках

  1. A.G. Lebed, Breakdown of the Einstein’s Equivalence Principle for a Quantum Body, Breakdown of Einstein's Equivalence Principle, Ed. by A. Lebed, World Scientific, pp. 1-37 (2023).

Труды конференций

  1. Y. Senichev, A. Aksentyev, S. Kolokolchikov, A. Melnikov, V. Ladygin, E. Syresin, N. Nikolaev, Quasi-frozen spin concept of magneto-optical structure of NICA adapted to study the electric dipole moment of the deuteron and to search for the axion, J. Phys.: Conf. Ser. 2420, 012052 (2023), ADS: 2023JPhCS2420a2052S, InSpire: 2137256.
  2. A.G. Lebed, Breakdown of the Equivalence Principle for a composite quantum body, Proc. Sixteenth Marcel Grossmann Meeting, pp. 2551-2556 (2023).

Препринты

  1. R. Calderón, B. L'Huillier, D. Polarski, A. Shafieloo, A.A. Starobinsky, Joint reconstructions of growth and expansion histories from stage-IV surveys with minimal assumptions II: Modified gravity and massive neutrinos, arXiv:2301.00640, ADS: 2023arXiv230100640C, InSpire: 2620237.
  2. Gang Li, V. Pokrovsky, Amplitude representation of Landau-Lifshitz equation and its application to ferromagnetic films, arXiv:2301.01391, РИНЦ: 2023arXiv230101391L.
  3. S.N. Vergeles, Another Friedman-type solution that eliminates the problem of the divergent cosmological constant, implemented in the framework of the lattice regularization of the theory of gravity, arXiv:2301.01692, ADS: 2023arXiv230101692V, InSpire: 2620316.
  4. S. Belan, V. Parfenyev, Footprints of loop extrusion in statistics of intra-chromosomal distances: an analytically solvable model, arXiv:2301.03856, ADS: 2023arXiv230103856B.
  5. P.A. Nosov, D.S. Shapiro, M. Goldstein, I.S. Burmistrov, Reaction-diffusive dynamics of number-conserving dissipative quantum state preparation, arXiv:2301.05258, ADS: 2023arXiv230105258N, InSpire: 2623139.
  6. V. Parfenyev, E. Mogilevskiy, G. Falkovich, Sum-of-squares bounds on correlation functions in a minimal model of turbulence, arXiv:2302.03757, ADS: 2023arXiv230203757P.
  7. I. Timoshuk, Yu. Makhlin, Quantum computations with topological edge states, arXiv:2302.10101, ADS: 2023arXiv230210101T, InSpire: 2634887.
  8. I. Timoshuk, K. Tikhonov, Yu. Makhlin, Quantum computation at the edge of a disordered Kitaev honeycomb lattice, arXiv:2302.10123, ADS: 2023arXiv230210123T, InSpire: 2634908.
  9. P.D. Grigoriev, A.V. Sadovnikov, V.D. Kochev, A.M. Dyugaev, Improving of ultracold neutron traps coated with liquid helium using capillarity and electric field, arXiv:2303.04429, ADS: 2023arXiv230304429G, InSpire: 2639472.
  10. M. Lashkevich, O. Lisovyy, T. Ushakova, Semiclassical approach to form factors in the sinh-Gordon model, arXiv:2303.11933, ADS: 2023arXiv230311933L, InSpire: 2644511.