Joint Seminar on Quantum Information and Technologies
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 | YouTube channel
until 2023/2024 Quantum Information Seminar | YouTube channel
2019-02-28 (Thursday)
room 1.03, Pasteura 5 at 11:15 
Mohammad Mehboudi (ICFO, Barcelona)Linear response theory for quantum Gaussian processes
Fluctuation dissipation theorems connect the linear response of a physical system to a perturbation to the steady-state correlation functions. Until now, most of these theorems have been derived for finite-dimensional systems. However, many relevant physical processes are described by systems of infinite dimension in the Gaussian regime. In this work, we find a linear response theory for quantum Gaussian systems subject to time dependent Gaussian channels. In particular, we establish a fluctuation dissipation theorem for the covariance matrix that connects its linear response at any time to the steady state two-time correlations. The theorem covers non-equilibrium scenarios as it does not require the steady state to be at thermal equilibrium. We further show how our results simplify the study of Gaussian systems subject to a time dependent Lindbladian master equation. Finally, we illustrate the usage of our new scheme through some examples. Due to broad generality of the Gaussian formalism, we expect our results to find an application in many physical platforms, such as opto-mechanical systems in the presence of external noise or driven quantum heat devices.
room 1.03, Pasteura 5 at 11:15
Jan Kołodyński, Alexander Streltsov (Centre for Quantum Optical Technologies, UW)Entanglement negativity as a universal non-Markovianity witness
In order to engineer an open quantum system and its evolution, it is essential to identify and control the memory effects. These are formally attributed to the non-Markovianity of dynamics that manifests itself by the evolution being indivisible in time, a property which can be witnessed by a non-monotonic behavior of contractive functions or correlation measures. We show that by monitoring directly the entanglement behavior of a system in a tripartite setting it is possible to witness all invertible non-Markovian dynamics, as well as all (also non-invertible) qubit evolutions. This is achieved by using negativity, a computable measure of entanglement, which in the usual bipartite setting is not a universal non-Markovianity witness. We emphasize further the importance of multipartite states by showing that non-Markovianity cannot be faithfully witnessed by any contractive function of single qubits. We support our statements by an explicit example of eternally non-Markovian qubit dynamics, for which negativity can witness non-Markovianity at arbitrary time scales.
2019-02-14 (Thursday)
room 1.03, Pasteura 5 at 11:15
Alexander Mikhalychev (Centre for Quantum Optics and Quantum Information, IP NASB, Minsk, Belarus)Informational approach for nonlinear estimation problems with parametrically localized measurements
An efficient iterative inference scheme of nonlinear estimation, connecting the features of the Fisher information with the parametric locality of the problem, will be presented. The iterative scheme reconstructs only a subset of the whole set of parameters in each step and is linear on the total number of parameters. We apply our scheme to quantum near-field imaging and demonstrate super-resolution for measurements of higher-order correlation functions. Using entangled photons and a pseudo-thermal light source for the imaging of objects, we predict and experimentally confirm the existence of optimal photon correlations providing for the best image resolution. Also, a short overview of the scientific activities of the Centre for Quantum Optics and Quantum Information (IP NASB, Minsk, Belarus) will be presented.
2019-01-24 (Thursday)
room 1.03, Pasteura 5 at 11:15
Ludwig Kunz and Konrad Banaszek (Centre for Quantum Optical Technologies, University of Warsaw)Asymptotic low-cost limit of classical communication
2019-01-17 (Thursday)
room 1.03, Pasteura 5 at 11:15
Martin Ringbauer (Universitat Innsbruck, Austria)Experimental metaphysics: Probing the foundations of quantum theory
Quantum mechanics is our most successful physical theory, yet the debate over what it actually says about the world remains as active as ever. I will explore some of the topics at the heart of this debate and discuss how they are moving more and more from the realm of philosophy to the realm of experimental physics. In particular, I will discuss the implications of recent photonic experiments that shed light on the very questions of reality, the nature of the wavefunction, and observer independence in quantum mechanics.
2019-01-10 (Thursday)
room 1.03, Pasteura 5 at 11:15
Swapan Rana (Centre for Quantum Optical Technologies UW)Resource theory of coherence
In this informal talk, I shall first introduce the notion of quantum resource theories with some examples. Then I shall describe the structure of resource theory of coherence (or superposition), both at the level of the states and operations. I expect to cover an overview of coherence theory, including it's various models, recent progress, and current challenges.
2018-12-20 (Thursday)
room 1.03, Pasteura 5 at 11:15
Aleksander Kubica (Perimeter Institute for Theoretical Physics, Waterloo, Canada)The disjointness and limitations on fault-tolerant gates
Stabilizer codes are a simple and successful class of quantum error-correcting codes. Yet this success comes in spite of some harsh limitations on the ability of these codes to fault-tolerantly compute. In the talk, I will discuss a new metric for these codes, the disjointness, and use it to prove that transversal gates are necessarily in a finite level of the Clifford hierarchy. I will also derive similar bounds on constant-depth circuits for topological codes, regardless of geometric locality of the gates. Based on arXiv:1710.07256.
2018-12-13 (Thursday)
room 1.03, Pasteura 5 at 11:15
Joel Corney (The University of Queensland, Brisbane, Australia.)Stochastic Phase-Space Methods for Light-Matter Interactions
Nonclassical states of light are created when light propagates through a nonlinear medium. For example, laser light can become quantum squeezed in a material whose refractive index depends on the intensity of light (optical Kerr effect). Although this effect is qualitatively captured by a simple anharmonic oscillator model, an accurate quantitative prediction of the quantum correlations requires careful modelling of the light-matter interaction, together with the capability to solve or simulate the model in a way that doesn’t neglect quantum effects. In this talk I will discuss the use of stochastic methods derived from generalised phase-space representations for simulations of light-matter interactions. I will focus on the example of propagation of light in optical fibre, which has been found to be an efficient means of squeezing light and which has potential for creating non-Gaussian correlations.
2018-11-29 (Thursday)
room 1.03, Pasteura 5 at 11:15
Krzysztof Giergiel (Uniwersytet Jagieloński)Condensed matter physics in time crystals
Time crystals are systems that reveal condensed matter behavior butin the time domain. In solid state physics properties of space crystalsare often investigated with the help ofexternal potentials that are spatially periodic and reflect variouscrystalline structures. Similar approach can be applied for timecrystals because periodically driven systems constitute counterparts ofspatially periodic systems but in the time domain. Wide class ofcondensed matter problems can be realized in the time domain ifsingle-particle or many-body systems are resonantly driven.In particular we propose quantum simulators, which promise access toprogrammable exotic long-range interactions in solid state-likemany-body systems.
2018-11-22 (Thursday)
room 1.03, Pasteura 5 at 11:15
Adam Sawicki (CFT PAN)Quantum entanglement from single particle information
Despite considerable interest in recent years, understanding of quantum correlations in multipartite finite dimensional quantum systems is still incomplete. I will consider a simple scenario in which we have access to the results of all one-particle measurements of such system. The aim is to understand how much information about quantum correlations is encoded in this data. It turns out that mathematically consistent way of studying this problem involves methods that are used in classical mechanics to describe phase spaces with symmetries. In this talk I will review these methods and show their usefulness to our problem.