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2024 |
1. |
Dmitry S. Ageev, Askar A. Iliasov, “Unveiling topological modes on curved surfaces”, Phys. Rev. B, 109 (2024), 085435 , 10 pp. ; |
2. |
D. S. Ageev, I. Ya. Aref'eva, A. I. Belokon, V. V. Pushkarev, T. A. Rusalev, “Entanglement entropy in de Sitter: no pure states for conformal matter”, JHEP, 2024:5 (2024), 308 , 24 pp., arXiv: 2304.12351 ; |
3. |
Dmitry S. Ageev, Andrey A. Bagrov, Aleksandr I. Belokon, Askar Iliasov, Vasilii V. Pushkarev, Femke Verheijen, “Local quenches in fracton field theory: Lieb–Robinson bound, noncausal dynamics and fractal excitation patterns”, Phys. Rev. D, 110 (2024), 65011 , 19 pp., arXiv: 2310.11197 ; |
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2023 |
4. |
Dmitry S. Ageev, Aleksandr I. Belokon, Vasilii V. Pushkarev, “From locality to irregularity: introducing local quenches in massive scalar field theory”, JHEP, 2023, no. 5, 188 , 44 pp., arXiv: 2205.12290 ; |
5. |
D. S. Ageev, I. Ya. Aref'eva, A. I. Belokon, A. V. Ermakov, V. V. Pushkarev, T. A. Rusalev, “Infrared regularization and finite size dynamics of entanglement entropy in Schwarzschild black hole”, Phys. Rev. D, 108 (2023), 46005 , 22 pp., arXiv: 2209.00036 ; |
6. |
Dmitry S. Ageev, “Entanglement islands and black holes”, Proceeding of science - SISSA, 2023 (to appear) |
7. |
Dmitry S. Ageev, “Exploring holography with boundary fractal-like structures”, Phys. Rev. D, 108 (2023), 26009 , 7 pp., arXiv: 2208.07387 ; |
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2022 |
8. |
D. S. Ageev, I. Ya. Aref'eva, A. V. Lysukhina, “On the nonclassicality in quantum JT gravity”, Theoret. and Math. Phys., 210:2 (2022), 275–285 |
9. |
Dmitry S. Ageev, “Shaping contours of entanglement islands in BCFT”, JHEP, 2022 (2022), 33 , 17 pp., arXiv: 2107.09083 ; |
10. |
D. S. Ageev, I. Ya. Aref'eva, A. I. Belokon, A. V. Ermakov, V. V. Pushkarev, T. A. Rusalev, Entanglement Islands and Infrared Anomalies in Schwarzschild Black Hole, 2022 , 57 pp., arXiv: 2209.00036 |
11. |
Dmitry S. Ageev, Exploring uberholography, 2022 , 13 pp., arXiv: 2208.07387 |
12. |
Dmitry S. Ageev, Irina Ya. Aref'eva, “Thermal density matrix breaks down the Page curve”, Eur. Phys. J. Plus, 137 (2022), 1188 , 15 pp., arXiv: 2206.04094 ; |
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2021 |
13. |
Dmitry S. Ageev, “On Some Aspects of the Holographic Pole-Skipping Phenomenon”, Proc. Steklov Inst. Math., 313 (2021), 1–7 |
14. |
Dmitry S. Ageev, Butterfly velocity and chaos suppression in de Sitter space, 2021 , 9 pp., arXiv: 2105.02258 |
15. |
Dmitry S. Ageev, Butterflies dragging the jets: on the chaotic nature of holographic QCD, 2021 , 9 pp., arXiv: 2105.04589 |
16. |
Dmitry S. Ageev, Irina Ya. Arefeva, Anastasia V. Lysukhina, On the nonclassicality in quantum JT gravity, 2021 , 15 pp., arXiv: 2105.06444 |
17. |
Dmitry S. Ageev, Andrey A. Bagrov, Askar A. Iliasov, “Deterministic chaos and fractal entropy scaling in Floquet conformal field theories”, Phys. Rev. B, 103 (2021), L100302 , 7 pp., arXiv: 2006.11198 |
18. |
Dmitry S. Ageev, “On the entanglement contour of excited states in the holographic CFT”, Eur. Phys. J. Plus, 136 (2021), 435 , 13 pp. ; |
19. |
Dmitry S. Ageev, “Holographic local quench at finite chemical potential”, Eur. Phys. J. Plus, 136:11 (2021), 1178 , 18 pp. ; |
20. |
Dmitry S. Ageev, “Chaotic nature of holographic QCD”, Phys. Rev. D, 104:12 (2021), 126013 , 8 pp., arXiv: 2105.04589 |
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2020 |
21. |
Dmitry S. Ageev, Sharp disentanglement in holographic charged local quench, 2020 , 22 pp., arXiv: 2003.02918 |
22. |
Dmitry S. Ageev, Andrey A. Bagrov, Askar A. Iliasov, “Coleman–Weinberg potential in $p$-adic field theory”, Eur. Phys. J. C, Part. Fields, 80 (2020), 859 , 10 pp., arXiv: 2004.03014 |
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2019 |
23. |
Dmitry S. Ageev, Irina Ya. Aref'eva, “When things stop falling, chaos is suppressed”, JHEP, 2019:1 (2019), 100 , 9 pp., arXiv: 1806.05574 |
24. |
D. S. Ageev, I. Ya. Aref'eva, A. V. Lysukhina, “Wormholes in Jackiw–Teitelboim gravity”, Theoret. and Math. Phys., 201:3 (2019), 1779–1792 |
25. |
Dmitry S. Ageev, Holographic complexity of local quench at finite temperature, 2019 , 17 pp., arXiv: 1902.03632 |
26. |
Dmitry S. Ageev, On the entanglement and complexity contours of excited states in the holographic CFT, 2019 , 17 pp., arXiv: 1905.06920 |
27. |
D. S. Ageev, “Holographic complexity of local quench at finite temperature”, Phys. Rev. D, 100:12 (2019), 126005 , 10 pp., arXiv: 1902.03632 |
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2018 |
28. |
D. S. Ageev, I. Ya. Aref'eva, “Holographic non-equilibrium heating”, JHEP, 2018:3 (2018), 103 , 19 pp., arXiv: 1704.07747 |
29. |
D. S. Ageev, I. Ya. Aref'eva, A. A. Golubtsova, E. Gourgoulhon, “Thermalization of holographic Wilson loops in spacetimes with spatial anisotropy”, Nuclear Phys. B, 931 (2018), 506–536 |
30. |
Dmitry Ageev, “Holography, quantum complexity and quantum chaos in different models”, 20th International Seminar on High Energy Physics (QUARKS-2018) (Valday, Russia, 27 May – 02 June, 2018), EPJ Web of Conf., 2018, 06006 , 8pp pp. |
31. |
Dmitry Ageev, Irina Aref'eva, Andrey Bagrov, Mikhail I. Katsnelson, “Holographic local quench and eective complexity”, JHEP, 2018:8 (2018), 71 , 30 pp., arXiv: 1803.11162 |
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2017 |
32. |
D. S. Ageev, I. Ya. Aref'eva, “Waking and scrambling in holographic heating up”, Theoret. and Math. Phys., 193:1 (2017), 1534–1546 |
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2016 |
33. |
D. S. Ageev, I. Ya. Aref'eva, “Holographic instant conformal symmetry breaking by colliding conical defects”, Theoret. and Math. Phys., 189:3 (2016), 1742–1754 |
34. |
D. S. Ageev, I. Ya. Aref'eva, M. D. Tikhanovskaya, “$(1+1)$-Correlators and moving massive defects”, Theoret. and Math. Phys., 188:1 (2016), 1038–1068 |
35. |
Dmitry S. Ageev, Irina Ya. Aref'eva, Anastasia A. Golubtsova, Eric Gourgoulhon, Holographic Wilson loops in Lifshitz-like backgrounds, 2016 , 31 pp., arXiv: 1606.03995 |
36. |
Dmitry Ageev, “Holographic Wilson loops in anisotropic quark-gluon plasma”, 19th International Seminar on High Energy Physics (QUARKS-2016), Sankt-Peterburg, 29 maya–4 iyunya 2016 g., EPJ Web of Conf., 125, 2016, 4007 , 6 pp. |
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2015 |
37. |
J. Exp. Theor. Phys., 120:3 (2015), 436–443 |
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2014 |
38. |
D. S. Ageev, I. Ya. Aref'eva, “Holography and nonlocal operators for the BTZ black hole with nonzero angular momentum”, Theoret. and Math. Phys., 180:2 (2014), 881–893 |
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