Środowiskowe Seminarium z Informacji i Technologii Kwantowych
2012/2013 | 2013/2014 | 2014/2015 | 2015/2016 | 2016/2017 | 2017/2018 | 2018/2019 | 2019/2020 | 2020/2021 | 2021/2022 | 2022/2023 | 2023/2024 | 2024/2025 | kanał YouTube
do roku 2023/2024 Seminarium Kwantowa Informacja | kanał YouTube
2018-07-19 (Czwartek)
Yink Loong Len (Centre for Quantum Technologies, National University of Singapore)
Open-system quantum error correction
In this work, we present quantum error correction (QEC) conditions for a system undergoing open-system dynamics. Here, we describe the noise on the system as originating from a joint completely-positive, trace-preserving channel on the system-environment composite, after which we trace out the environmental degree of freedom. Our noise model can be viewed as an intermediate picture between the standard system-only quantum channel model and a system-bath Hamiltonian noise model: It goes beyond a Markovian description for the system dynamics, and yet keeping a quantum dynamical semigroup structure for the problem. Our general noise model fits naturally into many physical scenarios, where one has a relatively strong coupling between the system and an ``intermediate" bath, which also couples weakly to a much larger and dissipative environment. The large dissipative large environment permits an effective quantum dynamical semigroup description on the joint system-intermediate bath composite. Despite the physical motivation from an "intermediate bath", our noise model is however mathematically general, and in turn contains both system-only quantum channel model and system-bath Hamiltonian noise model as special examples. We derive and study the QEC conditions for our general noise model, with the emphasis that the recovery operation acts on the system only. When the noise is only approximately correctable, we obtain a lower bound for the performance of the QEC, as quantified by worst-case fidelity.
2018-06-14 (Czwartek)
Marek Rams (UJ)
At the limits of criticality-based quantum metrology: apparent super-Heisenberg scaling revisited
We address the question whether the super-Heisenberg scaling for quantum estimation is indeed realizable. We unify the results of two approaches. In the first one, the original system is compared with its copy rotated by the parameter dependent dynamics. If the parameter is coupled to the one-body part of the Hamiltonian the precision of its estimation is known to scale at most as N−1 (Heisenberg scaling) in terms of the number of elementary subsystems used, N. The second approach compares the overlap between the ground states of the parameter dependent Hamiltonian.In critical systems this often leading to an apparent super-Heisenberg scaling. However, we point out that if one takes into account the scaling of time needed to perform the necessary operations, i.e. ensuring adiabaticity of the evolution, the Heisenberg limit given by the rotation scenario is recovered. We illustrate the general theory on a ferromagnetic Heisenberg spin chain example. We discuss universal scaling predictions of the estimation precision offered by natural local observables, both at zero and finite temperatures, and support them with numerical simulations in the model. We explicitly derive that the Heisenberg limit is recovered when time needed for preparation of quantum states involved is taken into account.M.M. Rams, P. Sierant, O. Dutta, P. Horodecki, J. Zakrzewski, Phys. Rev. X 8, 021022 (2018)
2018-06-07 (Czwartek)
Marcin Pawłowski (Uniwersytet Gdański)
Mutually Unbiased Bases and Random Access Codes
2018-05-24 (Czwartek)
Krzysztof Wohlfeld (IFT UW)
Fractionalization, entanglement, and separation: understanding the collective excitations in a spin-orbital chain
2018-05-17 (Czwartek)
Michał Matuszewski (IFPAN)
Quantum optics and quantum simulation with exciton-polaritons
The physics of quantum fluids of light and the related field of nonequilibrium condensation experience dynamic development in recent years. The experimental realization of exciton-polariton condensates ten years ago provided vast possibilities for investigating nonequilibrium quantum systems on an entirely new level, important for understanding of fundamentals of nonequilibrium physics. At the same time, prototypes of devices for applications, such as low-threshold polariton lasers, quantum-enhanced interferometers or low-loss polariton circuits, have been realized.In this talk I will describe the basic theory of exciton-polaritons as well as their relevance to the field of quantum optics. While most of the experiments conducted to date remained in the classical or semiclassical regimes, there is a strong incentive and experimental effort towards the realization of quantum regime. I will describe recent experiments as well as theoretical proposals for the demonstration of quantum entanglement, photon blockade, and quantum simulation in this compact, scalable platform. I will show that recent demonstrations of polariton lattices in semiconductor microcavities, in combination with their extraordinary nonlinearities, place polaritons as one of the promising candidates to achieve quantum simulation in an open system.
2018-05-10 (Czwartek)
Alex Retzker (The Hebrew University of Jerusalem)
Limits on spectral resolution measurements by quantum probes for nano NMR
The limits of frequency resolution in nano NMR experiments have been discussed extensivelyin recent years. It is believed that there is a crucial difference between the abilityto resolve a few frequencies and the precision of estimating a single one. Whereas the efficiencyof single frequency estimation gradually increases with the square root of the numberof measurements, the ability to resolve two frequencies is limited by the specific time scaleof the probe and cannot be compensated for by extra measurements. In this talk I will showthat the relationship between these quantities is more subtle and both are only limited bythe Cramer-Rao bound of a single frequency estimation.
2018-04-26 (Czwartek)
Michał Parniak (IFD UW)
Two-photon interference for superresolution imaging
2018-04-19 (Czwartek)
Marcin Jarzyna (CENT UW)
Quantum Fingerprinting
2018-04-12 (Czwartek)
Lukas Slodicka (Palacky University, Olomouc)
Coherent control of nonclassical light emission from trapped ions
2018-04-05 (Czwartek)
Aleksander Kurek (Obserwatorium Astronomiczne, Uniwersytet Jagieloński)
Parametryczne wzmacnianie światła w obrazowaniu astronomicznym
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