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
2020-06-04 (Thursday)
join us at 11:15 
Yink Loong Len (QOT UW)Resolution limits of spatial mode demultiplexing with noisy detection
2020-05-28 (Thursday)
join us at 11:15
Manuel Gessner (ENS Paris, France)Squeezing Revisited: Non-Gaussian States and Multiparameter Estimation [ZOOM ID: 652-672-1604, pass: 8RZpnR]
Squeezing is the leading strategy to achieve quantum-enhanced precision measurements and entanglement in atomic and optical experiments today. By characterizing the nonclassical features through average values and variances of linear observables, squeezing can be exploited with simple measurements but applications are limited to Gaussian states. Here we show how squeezing, i.e., the reduction of quantum fluctuations, of optimally chosen nonlinear observables captures the metrological properties and the entanglement of highly sensitive non-Gaussian states. We further show how squeezing of multimode systems can achieve quantum enhancements in multiparameter estimation problems and leads to accessible lower bounds on the quantum Fisher matrix.
2020-05-21 (Thursday)
join us at 10:15
Ludwig Kunz (QOT UW)Classical Communication with displacement receivers via noisy quantum channels [TIME CHANGED!] [ZOOM ID: 976 9672 6563, pass: 314297]
For reliable optical communication state discrimination is a critical task. Quantum measurements can provide significant enhancement in information transfer compared to classical techniques and enable detection below the shot-noise limit. Noise in the communication channel or the measurement, however, limits the benefits of quantum-enhanced techniques. Whereas linear losses result in a simple rescaling of the complex field amplitude, the effects of phase diffusion are less trivial. Phase noise can arise as linear noise or nonlinear phase noise caused by nonlinear interactions. Already when communicating via a lossy Kerr medium nonlinear phase noise arises fundamentally and limits the information transfer.Here we consider a receiver based on a displacement operation followed by photon counting with finite photon number resolution. For binary alphabets of coherent states such a receiver provides a near optimal scaling of the error probability with the energy of the signal close to the Dolinar receiver, while having less stringent technical requirements. We analyze the performance of the displacement receiver compared to conventional measurements and present a novel strategy to mitigate the effects of phase noise, both linear and nonlinear.
2020-05-14 (Thursday)
join us at 11:15
Krzysztof Pawłowski (CFT PAN)A practical limitation to phase coherence of a two-component Bose-Einstein Condensate [ZOOM ID: 6526721604, PASSWD: 8RZpnR]
2020-05-07 (Thursday)
join us at 10:15
Klaus Mølmer (University of Aarhus, Denmark)Quantum physics with pulses of radiation [TIME CHANGED!!!] [ZOOM ID: 976 9672 6563 PASSWORD: 314297]
he ability to control quantum systems and prepare special superposition and entangled states of light and matter is pursued with many experimental platforms and forms the basis of strategies for quantum computing, communication and metrology. Such, task oriented research may confront us with “blind spots” in our knowledge, i.e., entire research questions that are not treated by our text book formalism, or are dealt with in manners that are not consistent and accurate.In this talk, I shall discuss one such case: the interaction of a quantum system with a single incident pulse of radiation. While crucial for multiple effects in quantum optics and for the entire concept of flying and stationary qubits, quantum optics textbooks do not provide a formal description of this foundational and elementary interaction process.I shall present a new (and simple) theoretical formalism that, indeed, accounts for the interaction of travelling pulses of quantized radiation with a local quantum system such as a qubit, a spin or a non-linear resonator. We discuss applications of our theory to quantum pulses of optical, microwave and acoustic excitations and we show examples of relevance to recent experiments.
2020-04-30 (Thursday)
join us at 11:15
Matteo Rosati (Universitat Autònoma de Barcelona)Real-time calibration of coherent-state receivers: learning by trial and error [ZOOM ID: 652 672 1604]
Optical communications technology uses light propagating in free space and optical fiber to transmit data for telecommunications and networking. When the communication takes place over very long distances, the light signals get extremely damped and Heisenberg's uncertainty principle bounds the ability to recover the message perfectly. In this regime, one has to consider that classical information is encoded in quantum states of light and transferred on a bosonic channel. The ultimate information transmission rate is provided by the Holevo capacity of these channels and it can be attained by encoding the information on coherent-state sequences with several uses of the channel, or communication modes. Unfortunately, it is still an open problem to realize an efficient receiver capable of distinguishing these quantum states with current technology, since it would require to perform a joint measurement in a coherent-superposition basis. Known receiver structures for coherent states make use of simple Gaussian operations, photodetection and feedback. In this setting, we present several reinforcement learning methods that allow an automated agent to learn near-optimal receivers from scratch. Each agent is trained and tested in real time over several runs of independent discrimination experiments and has no knowledge about the energy of the states nor the receiver setup nor the quantum-mechanical laws governing the experiments. Based exclusively on the observed photodetector outcomes, the agent adaptively chooses among a set of ~3 10^3 possible receiver setups, and obtains a reward at the end of each experiment if its guess is correct. Importantly, the information gathered in each run is intrinsically stochastic and thus insufficient to evaluate exactly the performance of the chosen receiver. Nevertheless, we present families of agents that: (i) discover a receiver beating the best Gaussian receiver after ~3 10^2 experiments; (ii) surpass the cumulative reward of the best Gaussian receiver after ~10^3 experiments; (iii) simultaneously discover a near-optimal receiver and attain its cumulative reward after ~10^5 experiments. Our results show that reinforcement learning techniques are suitable for on-line control of quantum receivers and can be employed for long-distance communications over potentially unknown channels.
2020-04-23 (Thursday)
join us at 10:15
Klaus Mølmer (University of Aarhus, Denmark)Quantum physics with pulses of radiation [SEMINAR CANCELLED!!!]
The ability to control quantum systems and prepare special superposition and entangled states of light and matter is pursued with many experimental platforms and forms the basis of strategies for quantum computing, communication and metrology. Such, task oriented research may confront us with “blind spots” in our knowledge, i.e., entire research questions that are not treated by our text book formalism, or are dealt with in manners that are not consistent and accurate.
In this talk, I shall discuss one such case: the interaction of a quantum system with a single incident pulse of radiation. While crucial for multiple effects in quantum optics and for the entire concept of flying and stationary qubits, quantum optics textbooks do not provide a formal description of this foundational and elementary interaction process.
I shall present a new (and simple) theoretical formalism that, indeed, accounts for the interaction of travelling pulses of quantized radiation with a local quantum system such as a qubit, a spin or a non-linear resonator. We discuss applications of our theory to quantum pulses of optical, microwave and acoustic excitations and we show examples of relevance to recent experiments.
In this talk, I shall discuss one such case: the interaction of a quantum system with a single incident pulse of radiation. While crucial for multiple effects in quantum optics and for the entire concept of flying and stationary qubits, quantum optics textbooks do not provide a formal description of this foundational and elementary interaction process.
I shall present a new (and simple) theoretical formalism that, indeed, accounts for the interaction of travelling pulses of quantized radiation with a local quantum system such as a qubit, a spin or a non-linear resonator. We discuss applications of our theory to quantum pulses of optical, microwave and acoustic excitations and we show examples of relevance to recent experiments.
2020-04-16 (Thursday)
join us at 11:15
Paweł Kurzyński (UAM Poznań)Synchronizing the simplest classical system and then quantizing it
I propose a discrete synchronization model of finite d-level systems and discuss what happens once superposition of states is allowed. The model exhibits various asymptotic behaviors that depend on the initial state. In particular, two antagonistic phenomena can occur: a quantum-to-classical transition and entanglement generation. Next, I generalize this model and show that it is possible to phase-lock a periodic dynamics of a single qubit to a periodic dynamics of a qudit stimulus.
2020-04-02 (Thursday)
join us at 11:15
Adam Burchardt (UJ)Stochastic Local Operations with Classical Communication of Absolutely Maximally Entangled States [Online seminar. ZOOM ID:757 838 3413]
We discuss states known as Absolutely Maximally Entangled (AME), which are maximally entangled for every bipartition of the system. AME states are being applied in several branches of quantum information theory: in quantum secret sharing protocols, in parallel teleportation, in holographic quantum error correcting codes, among many others. We present techniques for local equivalence verification under Stochastic Local operations with Classical Communication (SLOCC) of k-uniform and Absolutely Maximally Entangled (AME) states. We show that the conjecture of all AME states being SLOCC-equivalent does not hold. We also show that the existence of AME states with minimal support of 6 or more particles results in the existence of infinitely many such non-SLOCC-equivalent states. Moreover, we present AME states which are not SLOCC-equivalent to the existing AME states with minimal support.
2020-03-26 (Thursday)
join us at 11:15
Jan Kolodynski (QOT UW)Device-independent quantum key distribution with single-photon sources (ONLINE MEETING!!! ZOOM ID:757 838 3413)
Device-independent quantum key distribution protocols allow two honest users to establish a secret key with minimal levels of trust on the provider, as security is proven without any assumption on the inner working of the devices used for the distribution. Unfortunately, the implementation of these protocols is challenging, as it requires the observation of a large Bell-inequality violation between the two distant users. Here, we introduce novel photonic protocols for device-independent quantum key distribution exploiting single-photon sources and heralding-type architectures. The heralding process is designed so that transmission losses become irrelevant for security. We then show how the use of single-photon sources for entanglement distribution in these architectures, instead of standard entangled-pair generation schemes, provides significant improvements on the attainable key rates and distances over previous proposals. Given the current progress in single-photon sources, our work opens up a promising avenue for device-independent quantum key distribution implementations.