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Środowiskowe Seminarium z Informacji i Technologii Kwantowych

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do roku 2023/2024 Seminarium Kwantowa Informacja | kanał YouTube

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Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Gabriela Wójtowicz (University of Ulm)

Tensor network methods for quantum metrology

The quantum Fisher information (QFI) is a geometric measure of state deformation calculated along the trajectory parametrizing an ensemble of quantum states. It serves as a key concept in quantum metrology, where it is linked to the fundamental limit on the precision of the parameter that we estimate. However, the QFI is notoriously difficult to calculate due to its non-linear mathematical form. For mixed states, standard numerical procedures based on eigendecomposition quickly become impractical with increasing system size. To overcome this limitation, we introduce a numerical approach based on Lyapunov integrals that combines the concept of symmetric logarithmic derivative and tensor networks. In this talk I will present details of the numerical approach and discuss the advantages and limitations of our methodology through an illustrative example, where the thermal state of the transverse-field Ising model is used to estimate magnetic field amplitude.

[1] G. Wójtowicz, S. F. Huelga, M. M. Rams, M. B. Plenio, Phys. Rev. A 112, 052454 (2025) DOI: https://doi.org/10.1103/xjln-7ddy

Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Stanisław Sieniawski (IFT UW)

Adaptive quantum channel discrimination using methods of quantum metrology

Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Wojciech Górecki (Freie Universitat Berlin)

Protecting Heisenberg scaling in quantum metrology via engineered dressed states

Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Jacek Dziarmaga (Uniwersytet Jagieloński)

2D tensor networks for quantum simulations

I will make a brief introduction to tensor network (TN) states and algorithms that became a method of choice for strongly correlated quantum many body systems on a lattice in one and two dimensions. I will emphasize the 2D TN known as PEPS (pair-entangled projected state) and its two recent applications to unitary time evolution and thermal Gibbs states. One is the recent quantum computational advantage demonstration with the coherent D-Wave quantum annealer [1], where TN served, on the one hand, as a benchmark for the quantum simulator and, on the other hand, as the most competitive classical method that, nevertheless, in the end failed the competition with the quantum hardware. The other is tensor network simulation of finite temperature states in the Hubbard and t − J models – the two paradigmatic models of high-Tc superconductivity – that proved notoriously hard to solve analytically/numerically and, therefore, are subject to intensive experimental effort in the ultracold atoms community aiming at their quantum simulation. I will present some PEPS results [2,3] down to temperatures of one tenth of the hopping rate, in the pseudogap regime. These results, obtained directly in the thermodynamic limit, can serve as a guide/benchmark for the current experimental efforts. References

[1] A.D. King, A. Nocera, M.M. Rams, J. Dziarmaga,..., Science 388 (6743), 199
[2] A. Sinha, M.M. Rams, P. Czarnik, and J. Dziarmaga, Physical Review B 106 (19), 195105
[3] Y. Zhang, A. Sinha, M.M. Rams, J. Dziarmaga, Phys. Rev. B 113, 085113

Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Sławomir Sujecki (WAT, Instytut Systemów Łączności)

Implementation of QKD in Backbone DWDM Networks

Recently, increasing attention is given to an application of QKD in DWDM networks. In this contribution selected aspects of sending quantum signals through a DWDM network are discussed in the context of practical optical backbone telecom networks and modern cryptographic systems.

Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Andrzej Dragan (IFT UW)

Relativistic reason for quantum probability amplitudes

Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Stanisław Kurdziałek (IFT UW)

Super-resolution microscopy via fluctuation-enhanced spatial mode demultiplexing

Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Michał Oszmaniec (CFT PAN)

Optimal interferometric certification of multi-photon indistinguishability

Multiphoton indistinguishability is a resource for photonic quantum technologies, but its characterisation can be resource-intensive. Here we present an efficient interferometric protocol certifying closeness (in Ulhmann fidelity) of an unknown N-photon state to the state of perfectly indistinguishable photons. The protocol uses a single Fourier interferometer followed by particle-number measurements and a simple classical post-processing. The sample complexity of certifying fidelity to the perfectly indistinguishable case has optimal sampling complexity and is independent of the number of photons N, unlike previous approaches which exhibit exponential scaling. Our efficient method, based on a generalisation of the Hong-Ou-Mandel test, brings the rigorous and operationally grounded certification of multiphoton indistinguishability within reach of current-day photonic technologies.

Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Yink Loong Len (National Cheng Kung University, Taiwan)

Various efforts in implementing quantum information processing under realistic considerations

We will share the recent direction and progress in our research group, which mainly focus on implementation of quantum information processing under realistic considerations. Specifically, we will discuss an example with quantum thermometry, and another one on fusion-based quantum computing.

Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 11:15

Marco Genoni (University of Milan)

Attaining Quantum Metrology Enhancement in Monitored Dissipative Time Crystals

We investigate quantum-enhanced parameter estimation through continuous monitoring in open quantum systems that exhibit a dissipative time crystal phase. We first analytically derive the global quantum Fisher information (QFI) rate for boundary time crystals (BTCs), demonstrating that within the time-crystal phase, the ultimate precision exhibits a cubic scaling with the system size. We then generalize this finding to a broader class of dynamics, including the transverse collective dephasing (TCD) model, which achieves a time-crystal phase through a closing Liouvillian gap without requiring a dissipative phase transition. We proceed to numerically demonstrate that this maximal global QFI rate is experimentally attainable for both the BTC and TCD models, even at finite system sizes, via continuous homodyne and photodetection. Moving towards practical implementations, we analyze the precision limits under inefficient detection, revealing a critical difference: for BTC dynamics, inefficiencies asymptotically restore a classical scaling, and only a constant-factor quantum advantage remains possible. In contrast, for TCD dynamics, a super-classical scaling is still in principle observable, and our numerical simulations confirm its presence, even under inefficient measurement conditions.

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