CMT/LTC Seminars

Mesoscopic Fluctuations and Multifractality at and across Measurement-Induced Phase Transition

Name: Mesoscopic Fluctuations and Multifractality at and across Measurement-Induced Phase Transition
Start: 2025-09-02T11:00:00+02:00
End: 2025-09-02T12:00:00+02:00
Location: No location set

by Prof. Alexander Mirlin (Karlsruhe Institute of Technology)

Tuesday 2 Sept 2025, 11:00 → 12:00 Europe/Zurich

WBBC/111

https://teams.microsoft.com/l/meetup-join/19%3ameeting_YzVmOTgzMjctMTAwNC00YTY3LWIxOGQtNmNjODYxNjY5M2Rh%40thread.v2/0?context=%7b%22Tid%22%3a%2250f89ee2-f910-47c5-9913-a6ea08928f11%22%2c%22Oid%22%3a%2204a638bf-9dac-4ed8-ad21-43ac02aa2cc2%22%7d Meeting ID: 360 918 567 009, Passcode: qA6Cv93s

Description

We study a problem of many-body fermionic system in d dimensions subjected to random measurements of local particle numbers. For free fermions, we have developed an analytical approach based on the Keldysh path-integral formalism and replica trick, and derived a non-linear sigma model in d+1 dimensions as an effective field theory of the problem [1]. This theory predicts, in d>1 dimensions, a measurement-induced phase transition, which has a meaning of localization transition for entanglement and quantum charge correlations [2], as supported by also supported by numerical simulations for d=2.

The talk will focus on statistical fluctuations of observables characterizing measurement-induced many-body quantum states over the ensemble of quantum trajectories [3]. The key observables are the two-point density correlation function C(r) and the particle-number covariance between spatially separated regions, G_{AB}. We explore their fluctuations in the delocalized and localized phases, as well as at the transition point. Our results exhibit a remarkable analogy to Anderson localization and mesoscopic physics of disordered systems, with C(r) and G_{AB} corresponding to two-point and two-terminal conductances, respectively. Our numerical and analytical findings lay the groundwork for mesoscopic theory of monitored systems, paving the way for various extensions.

If the time permits, I will also briefly discuss the emergence of Levy flights of quantum information in monitored systems [4] as well as the effect of interaction between fermions [5].

[1] I. Poboiko, P. Pöpperl, I.V. Gornyi, A.D. Mirlin, Phys. Rev. X 13, 041046 (2023)

[2] I. Poboiko, I.V. Gornyi, A.D. Mirlin, Phys. Rev. Lett. 132, 110403 (2024)

[3] I. Poboiko, I.V. Gornyi, A.D. Mirlin, arXiv: 2507.11312

[4] I. Poboiko, M. Szyniszewski, C.J. Turner, I.V. Gornyi, A.D. Mirlin, A. Pal, arXiv: 2501.12903

[5] I. Poboiko, P. Pöpperl, I.V. Gornyi, A.D. Mirlin, Phys. Rev. B 111, 024204 (2025)

Organised by

Laboratory for Theoretical and Computational Physics

Host: Dr. Markus Müller

markus.mueller@psi.ch