Joint Seminar on Quantum Information and Technologies
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until 2023/2024 Quantum Information Seminar | YouTube channel
2023-05-11 (Thursday)
room 1.02, Pasteura 5 at 11:15 
Seminar Cancelled!!!
2023-04-27 (Thursday)
room 1.02, Pasteura 5 at 11:15
Matheus Bezerra (Santo Andre, Brazil)Generalizations of the Hong-Ou-Mandel effect for non-symmetric interferometers
The Hong-Ou-Mandel effect is a fundamental quantum interference phenomena of two photons in a ballanced beamsplitter, which consists in the cancelation of the amplitude of the two photons being detected separated. Generalizations of this effect in higher order interferometers are called suppression laws. It was recently suggested that the bosonic suppression laws follow from a common permutation symmetry in the input quantum state and in the unitary matrix of the interferometer. Our results reveals that, even on asymmetric interferometers, there are a whole families of suppression laws for the interference of Fock states, beyond the previously formulated permutation symmetry principle.
2023-04-20 (Thursday)
room 1.02, Pasteura 5 at 11:15
Ray Ganardi (QOT CENT UW)Quantitative non-classicality of mediated interactions
In plethora of physical situations one can distinguish a mediator -- a system that couples other, non-interacting systems. Often the mediator itself is not directly accessible to experimentation, yet it is interesting and sometimes crucial to understand if it admits non-classical properties. An example of this sort that recently enjoys considerable attention are two quantum masses coupled via gravitational field. It has been argued that the gain of quantum entanglement between the masses indicates non-classical states of the whole tripartite system. Here, we focus on non-classical properties of the involved interactions rather than the involved states. We derive inequalities whose violation indicates non-commutativity and non-decomposability (open system generalisation of non-commuting unitaries) of interactions through the mediators. The derivations are based on properties of general quantum formalism and make minimalistic assumptions about the studied systems, in particular the interactions can remain uncharacterised throughout the assessment. Furthermore, we also present conditions that solely use correlations between the coupled systems, excluding the need to measure the mediator. Next, we show that the amount of violation places a lower bound on suitably defined degree of non-decomposability. This makes the methods quantitative and at the same time experiment ready. We give applications of these techniques in two different fields: for detecting non-classicality of gravitational interaction and in bounding the Trotter error in quantum simulations.
2023-04-13 (Thursday)
room 1.02, Pasteura 5 at 11:15
Steven Sagona (Imperial College London)Temporal bin to mode conversion using a quantum memory
2023-03-30 (Thursday)
room 1.03, Pasteura 5 at 11:15
Javid Naikoo (QOT CENT UW)Multiparameter estimation perspective on non-Hermitian singularity-enhanced sensing
2023-03-23 (Thursday)
room 1.02, Pasteura 5 at 11:15
Arpan Das (IFT UW)Precision bound in periodically modulated continuous quantum thermal machines
We use Floquet formalism to study fluctuations in periodically modulated continuous quantum thermal machines. We present a generic theory for such machines, followed by specific examples of sinusoidal, optimal, and circular modulations respectively. The thermodynamic uncertainty relations (TUR) hold for all modulations considered. Interestingly, in the case of sinusoidal modulation, the TUR ratio assumes a minimum at the heat engine to refrigerator transition point, while the Chopped Random Basis (CRAB) optimization protocol allows us to keep the ratio small for a wide range of modulation frequencies. Furthermore, our numerical analysis suggests that TUR can show signatures of heat engine to refrigerator transition, for more generic modulation schemes. We also study bounds in fluctuations in the efficiencies of such machines; our results indicate that fluctuations in efficiencies are bounded from above for a refrigerator, and from below for an engine. Overall, this study emphasizes the crucial role played by different modulation schemes in designing practical quantum thermal machines.
Ref: arXiv: 2204.14005v1
Ref: arXiv: 2204.14005v1
2023-03-16 (Thursday)
room 1.02, Pasteura 5 at 11:15
Michele Notarnicola (Universita degli Studi di Milano, Italy, QOT CENT)Hybrid near-optimum binary receiver with photon-number-resolving detectors
2023-03-09 (Thursday)
room 1.02, Pasteura 5 at 11:15
Kornikar Sen (Harish-Chandra Research Institute, India)Regional vs global operations: Quantum battery and state discrimination tasks
We will consider energy extraction from quantum batteries and quantum state discrimination by using local quantum operations. Considering a two-party quantum battery comes with the dichotomy between choosing global and local measurements, since the former provides more energy but the latter is cheaper. We introduce the concept of local passivity for shared quantum batteries with local Hamiltonians and characterise the set of all locally passive battery states. For generic battery states, whether noiseless or noisy, we find that the relationship between energy extractions by local and global operations is closely related to the entanglement content. The relation between incompatibility of measurements and quantum state discrimination tasks is well explored in the context of global operations. We examine the same by considering state discrimination using local operations and classical communication.
2023-03-02 (Thursday)
room 1.02, Pasteura 5 at 11:15
Andrzej Dragan (IFT UW)Universality of quantum time dilation
Time dilation is a difference in measured time between two clocks that either move with different velocities or experience different gravitational potentials. Both of these effects stem from the theory of relativity and are usually associated with classically defined trajectories, characterized by position, momentum, and acceleration. However, when spatial degrees of freedom are treated in a quantum way and a clock is allowed to be in a coherent superposition of either two momenta or two heights, additional quantum corrections to classical time dilation appear, called kinematic and gravitational quantum time dilations, respectively. We show that similarly to its classical counterpart, kinematic quantum time dilation is universal for any clock mechanism, while gravitational quantum time dilation is not. We also show that although both of these effects reduce to incoherent averaging of different classical time dilation contributions, there exists an additional quantum time dilation effect that has no classical analog and can be extracted from higher-order corrections to the system's Hamiltonian.
2023-02-23 (Thursday)