Russian Academy of Sciences

Landau Institute for Theoretical Physics



  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).
  4. 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).
  5. 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:2023PhyS...98a5025L, ADS: 2023PhyS...98a5025L, InSpire: 2075494.
  6. A.S. Koshelev, A.A. Starobinsky, A. Tokareva, Post-inflationary GW production in generic higher (infinite) derivative gravity, Physics Letters B, Volume 838, 10 March 2023, 137686; arXiv:2211.02070, ADS: 2022arXiv221102070K, InSpire: 2176727.
  7. 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, ADS: 2022arXiv220600725K.
  8. N.A. Inogamov, V.A. Khokhlov, S.A. Romashevskii, Yu.V. Petrov, V.V. Zhakhovskii, S.I. Ashitkov, Opredelenie vazhneishikh parametrov metalla, obluchennogo ul’trakorotkim lazernym impul’som, Pis’ma v ZhETF, 117(2), 107-114 (2023).
  9. I.V. Kolokolov, V.V. Lebedev, M.M. Tumakova, Parnaya korrelyatsionnaya funktsiya zavikhrennosti vnutri kogerentnogo vikhrya, Pis’ma v ZhETF, 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), ... (2023)].

In books

  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).


  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. 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.
  3. S. Belan, V. Parfenyev, Footprints of loop extrusion in statistics of intra-chromosomal distances: an analytically solvable model, arXiv:2301.03856.