Nowości - Zaklad Optyki Atomowej, Atomic Optics Department

Zakład Optyki Atomowej

Najbliższe seminaria

12 VI

Piotr Sierant (ICFO, Barcelona, Spain)

Controlling entanglement at absorbing state phase transitions in random circuits

Gdzie: MS Teams [ZOA-test], 12:15
Seminarium Zakładowe
Online: [link]

Pokaż pozostałe

[Abstrakt, pełna informacja]

Konferencje

06-08.09.2023 - Konferencja "Time Crystals"

More details na stronie konferencji.

27.06-2.07.2022 - 6th Workshop on Algebraic Designs, Hadamard Matrices & Quanta

Więcej szczegółów on conference website.

05-11.09.2021 - Quantum Optics X

Więcej szczegółów na stronie konferencji.

Titas Chanda
	PostDoc Quantum Simulations Group Pokój: B-1-34 Telefon: 4554 email ORCID: 0000-0002-2306-7895 Publons

Publikacje

	2023
[1]	T. Chanda, M. Dalmonte, M. Lewenstein, J. Zakrzewski, L. Tagliacozzo Spectral properties of critical 1+1D Abelian-Higgs model ArXiv e-prints, 2304.01030 (2023).
[2]	P. Sierant, T. Chanda, M. Lewenstein, J. Zakrzewski Slow dynamics of a mobile impurity interacting with an Anderson insulator Physical Review B 107,144201 (2023). [arxiv]
	2022
[3]	T. Chanda, J. Zakrzewski Many-body localization regime for cavity-induced long-range interacting models Physical Review B 105,A9 (2022). [arxiv]
[4]	T. Chanda, M. Lewenstein, J. Zakrzewski, L. Tagliacozzo Phase Diagram of 1+1 D Abelian-Higgs Model and Its Critical Point Physical Review Letters 128,090601 (2022). [arxiv]
[5]	M. Aidelsburger, L. Barbiero, A. Bermudez, T. Chanda, A. Dauphin, D. González-Cuadra, P. Grzybowski, S. Hands, F. Jendrzejewski et al. Cold atoms meet lattice gauge theory Philosophical transactions. Series A, Mathematical, physical, and engineering sciences 380,20210064 (2022). [arxiv]
[6]	T. Chanda, D. Gonzalez-Cuadra, M. Lewenstein, L. Tagliacozzo, J. Zakrzewski Devil's staircase of topological Peierls insulators and Peierls supersolids SciPost Physics 12,1-22 (2022). [arxiv]
[7]	R. Kraus, T. Chanda, J. Zakrzewski, G. Morigi Quantum phases of dipolar bosons in one-dimensional optical lattices Physical Review B 106,035144 (2022). [arxiv]
[8]	T. Chanda, R. Kraus, J. Zakrzewski, G. Morigi Bond order via cavity-mediated interactions Physical Review B 106,075137 (2022). [arxiv]
	2021
[9]	R. Yao, T. Chanda, J. Zakrzewski Nonergodic dynamics in disorder-free potentials Annals of Physics ,168540 (2021). [arxiv]
[10]	A. Sinha, T. Chanda, J. Dziarmaga Nonadiabatic dynamics across a first-order quantum phase transition: Quantized bubble nucleation Physical Review B 103,L220302 (2021). [arxiv]
[11]	R. Yao, T. Chanda, J. Zakrzewski Many-body localization in tilted and harmonic potentials Physical Review B 104,014201 (2021). [arxiv]
[12]	T. Chanda, R. Kraus, G. Morigi, J. Zakrzewski Self-organized topological insulator due to cavity-mediated correlated tunneling Quantum 5, (2021). [arxiv]
[13]	S. Ghosh, T. Chanda, S. Mal, A. Sen(de) Fast charging of a quantum battery assisted by noise Physical Review A 104,032207 (2021). [arxiv]
[14]	A. Aramthottil, T. Chanda, P. Sierant, J. Zakrzewski Finite-size scaling analysis of the many-body localization transition in quasiperiodic spin chains Physical Review B 104,A4 (2021). [arxiv]
	2020
[15]	T. Chanda, J. Zakrzewski, M. Lewenstein, L. Tagliacozzo Confinement and Lack of Thermalization after Quenches in the Bosonic Schwinger Model Phys. Rev. Lett. 124,180602 (2020). [arxiv]
[16]	T. Chanda, P. Sierant, J. Zakrzewski Time dynamics with matrix product states: Many-body localization transition of large systems revisited Phys. Rev. B 101,035148 (2020). [arxiv]
[17]	S. Ghosh, T. Chanda, A. Sende Enhancement in the performance of a quantum battery by ordered and disordered interactions Physical Review A 101,032115 (2020). [arxiv]
[18]	S. Haldar, S. Roy, T. Chanda, A. Sen(de), U. Sen Multipartite entanglement at dynamical quantum phase transitions with nonuniformly spaced criticalities Physical Review B 101, (2020). [arxiv]
[19]	T. Chanda, P. Sierant, J. Zakrzewski Many-body localization transition in large quantum spin chains: The mobility edge Physical Review Research 2,032045 (2020). [arxiv]
[20]	T. Chanda, R. Yao, J. Zakrzewski Coexistence of localized and extended phases: Many-body localization in a harmonic trap Physical Review Research 2,032039 (2020). [arxiv]
[21]	S. Haldar, S. Roy, T. Chanda, A. De Sen Response of macroscopic and microscopic dynamical quantifiers to the quantum critical region Physical Review Research 2,033249 (2020). [arxiv]
	2019
[22]	S. Rethinasamy, S. Roy, T. Chanda, A. Sen, U. Sen Universality in distribution of monogamy scores for random multiqubit pure states Physical Review A 99,042302 (2019). [arxiv]
[23]	S. Roy, T. Chanda, T. Das, D. Sadhukhan, A. Sen De, U. Sen Phase boundaries in an alternating-field quantum XY model with Dzyaloshinskii-Moriya interaction: Sustainable entanglement in dynamics Physical Review B 99,064422 (2019). [arxiv]
	2018
[24]	S. Roy, T. Chanda, T. Das, A. Sen, U. Sen Response in the violation of the Bell inequality to imperfect photon addition and subtraction in noisy squeezed states of light Physical Review A 98,052131 (2018). [arxiv]
[25]	T. Chanda, T. Das, S. Mal, A. Sen, U. Sen Canonical Leggett-Garg inequality: Nonclassicality of temporal quantum correlations under energy constraint Physical Review A 98,022138 (2018). [arxiv]
[26]	T. Chanda, T. Das, D. Sadhukhan, A. Pal, A. Sen, U. Sen Scale-invariant freezing of entanglement Physical Review A 97,062324 (2018). [arxiv]
[27]	T. Chanda, T. Das, D. Sadhukhan, A. Pal, A. Sen, U. Sen Emergence of entanglement with temperature and time in factorization-surface states Physical Review A 97,012316 (2018). [arxiv]
[28]	S. Roy, T. Chanda, T. Das, A. Sen(De), U. Sen Deterministic quantum dense coding networks Physics Letters, Section A: General, Atomic and Solid State Physics 382,1709-1715 (2018). [arxiv]
	2016
[29]	T. Chanda, T. Das, D. Sadhukhan, A. Pal, A. Sen, U. Sen Static and dynamical quantum correlations in phases of an alternating-field XY model Physical Review A 94,042310 (2016). [arxiv]
[30]	T. Chanda, T. Das, D. Sadhukhan, A. Pal, U. Sen Statistics of leading digits leads to unification of quantum correlations EPL 114,30004 (2016). [arxiv]
[31]	T. Chanda, S. Bhattacharya Delineating incoherent non-Markovian dynamics using quantum coherence Annals of Physics 366,1-12 (2016). [arxiv]
	2015
[32]	T. Chanda, T. Das, D. Sadhukhan, A. Pal, A. Sen De, U. Sen Reducing computational complexity of quantum correlations Physical Review A - Atomic, Molecular, and Optical Physics 92,062301 (2015). [arxiv]
[33]	T. Chanda, A. Pal, A. Biswas, A. Sen, U. Sen Freezing of quantum correlations under local decoherence Physical Review A - Atomic, Molecular, and Optical Physics 91,062119 (2015). [arxiv]