Academic year 2022/2023

Upcoming Seminars

20/06/2023

h 9:00 – ex SALA RIUNIONI (EX SOFTEL) Ed. 3 – Piano 1 a via Claudio 

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Cosmo Lupo

(Politecnico di Bari)

Quantum communications with continuous variables of light

Abstract

Abstract: Quantum key distribution (QKD) and quantum random number generation (QRNG) are fundamental building blocks of quantum networks and the future quantum internet. QKD allows us to distribute secret keys between distant users through an insecure communication channel. QRNG yields high quality random bits, which are most valuable for cyber security. In this seminar I will discuss ways to realize these protocols using continuous variables of light, assessing pros and cons of this architecture compared with those based on discrete variables and photodetection.

Past Seminars

05/05/2023

h14:30 – Aula 0M03, Dipartimento di Fisica 

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Andrea Trombettoni

(Università di Trieste, Italy)

Tilted 1D Bose Gases and Atomtronics Applications

Abstract

After a brief introduction on 1D ultracold gases, I discuss how to  implement an integrable Floquet Hamiltonian for a periodically tilted 1D  Bose gas. In general, an integrable model subjected to a periodic driving  gives rise to a non-integrable Floquet Hamiltonian. Here we show that the  Floquet Hamiltonian of the integrable Lieb-Liniger model in presence of a  linear potential with a periodic time-dependent strength is instead  integrable and its quasi-energies can be determined using the Bethe ansatz  approach. We discuss various aspects of the dynamics of the system at stroboscopic times and we also propose a possible experimental realization  of the periodically driven tilting in terms of a shaken rotated ring  potential. We also discuss the micro-motion operator and the expression  for a generic time evolved state of the system. To conclude, a discussion  of the applications to atomtronics is presented.In recent years there has been an increasing interest in quantum computing from non-pundits, companies and researchers from fields other than quantum computing.

05/05/2023

h15:30 – Aula 0M03, Dipartimento di Fisica 

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Gu Zhang

(Beijing Academy of Quantum Information Sciences, China)

Does delta-T noise probe quantum statistics?

Abstract

Abstract: We  study  delta-T noise—excess  charge  noise  at  zero voltage  but  finite  temperature  bias—for weak tunneling in one-dimensional interacting systems.  We show that the sign of the delta-T noise is generically determined by the nature of the dominating tunneling process.  More specifically, the sign is governed by the leading charge-tunneling operator’s scaling dimension. We clarify the relation between the sign of delta-T noise and the quantum exchange statistics of tunneling quasiparticles.We  find  that,  for  infinite systems  hosting  chiral  channels  with  local  interactions  (e.g., quantumHall or quantum spin Hall edges), when the delta-T noise is negative, the tunneling particles are boson-like, revealing their tendency towards bunching.  However, the opposite is not true: Boson-like particles do not necessarily produce negative delta-T noise.  Importantly,  the bosonic nature of particles generating the negative delta-T is not necessarily intrinsic, but can be induced by
the interactions.  This, in particular, implies that negative delta-T noise for tunneling between the edge states cannot serve as a smoking gun for detecting “intrinsic anyons”.  We also establish a connection between the delta-T noise and the temperature derivative of the Nyquist-Johnson (thermal) noise in interacting systems, both governed by the same scaling dimensions.  As a demonstration of the above
statements, we study tunneling between two interacting quantum spin Hall edges. With bosonization and renormalization-group techniques, we find that many-body interactions can generate negative delta-T noise for both direct tunneling through a point contact and in Kondo exchange tunneling via a localized spin.  In both these setups, we show that the noise can become negative at sufficiently low temperatures, when interactions renormalize the tunneling to favor boson-like pair-tunneling of electrons rather than single-electron tunneling.  Our findings show that delta-T noise can be used to probe the nature of collective excitations in interacting one-dimensional systems.

13/04/2023

h15:00 – Aula Caianiello, Dipartimento di Fisica 

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Costanza Toninelli

(CNR-INO, Italy)

Single Organic Molecules for Photonic Quantum Technologies

Abstract

The generation and manipulation of quantum states of light is required for key applications, such as photonic quantum simulation, linear optical quantum computing, quantum communication protocols, and quantum metrology. In this context, single organic molecules in the family of polycyclic aromatic hydrocarbons (PAH), once embedded in suitable host matrices, offer competitive properties and key advantages. Being very small and with well-defined transition dipole moments, they can be used as nanoscopic sensors of e.g. pressure, strain, temperature, electric and magnetic fields, as well as optical fields. Furthermore, PAH molecules can be easily fabricated and exhibit strong zero-phonon lines, which reach their Fourier-limited natural linewidth at liquid helium temperature, thus providing very bright and stable sources of coherent photons in the solid state.
Here, I will present our recent advances on the coupling of single PAH molecules to nanophotonic structures for the enhancement and control of their interaction with quantum light. Furthermore, I will discuss two-photon interference (TPI) experiments performed between single-photons emitted by distinct molecules on the same chip, which stands as a fundamental challenge in the context of solid-state platforms for photonic quantum technologies. In this context, we attain and combine together different milestones: simultaneously addressing on the same sample several single molecules operating as on-demand single-photon sources, tuning independently their relative optical frequency, measuring in semi-real-time their TPI, and extracting information about joint properties of the photon pairs.
Finally, I will present our recent results on the use of organic molecules as nanoscopic thermal sensors, allowing semi-invasive local temperature measurement in a temperature range (3 K to 30 K) where most commercial technologies cannot be used. These results can lead to a deeper understanding of the local phononic environment in geometrically complex structures and in an unexplored temperature regime.

05/04/2023

h15:00 – Aula Caianiello, Dipartimento di Fisica 

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Nicola Lo Gullo

(University of Calabria, Italy)

Enhancing quit readout with Bayesian Learning

Abstract

In recent years there has been an increasing interest in quantum computing from non-pundits, companies and researchers from fields other than quantum computing.
This is undoubtedly due to the deployment of quantum computing resources to research institutions and companies, which fostered the search for new applications of quantum computing.
Currently available quantum processing units (QPUs) are typically small and are plagued by noise. Two main solutions are being investigated to improve them: on the one hand there is an ongoing technological effort in scaling up these devices controlling the noise and, at the same time, develop error correction codes which will make the QPUs robust to errors; on the other hand there are efforts in making the current small and noisy devices useful. Quantum error mitigation is a class of techniques aiming at reducing the errors in running codes on quantum computers.
Within this framework we introduce an efficient and accurate readout measurement scheme for single and multi-qubit states. Our method uses Bayesian inference to build an assignment probability distribution for each qubit state based on a reference characterization of the detector response functions. This allows us to account for system imperfections and thermal noise within the assignment of the computational basis. We benchmark our protocol on a quantum device with five superconducting qubits, testing initial state preparation for single and two-qubit states and an application of the Bernstein-Vazirani algorithm executed on five qubits. Our method shows a substantial reduction of the readout error
and promises advantages for near-term and future quantum devices.

28/02/2023

h15:00 – Aula Caianiello, Dipartimento di Fisica 

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Halima Giovanna Ahmad

(University of Naples Federico II, Italy)

Novel tuning approaches for unconventional superconducting qubits 

Abstract

In the last decades, the search for novel quantum platforms has increased due to the request for high-performing quantum computing. Superconducting quantum processors have the advantage to be strongly engineerable, in terms of both integrated materials, circuital designs and easy-interface with commercially available readout/control electronics. In spite of the enormous advancements in the field, the research community is still facing several challenges in terms of scalability and coherence.

Josephson devices integrating unconventional barriers, such as topological insulators, Van der Waals heterostructures and hybrid ferromagnetic/superconducting devices, offer the possibility to establish novel tunability schemes not only in superconducting qubits, but also in other Josephson-based quantum devices, ranging from cryogenic amplifiers to interconnecting bus and coupling devices. Moreover, hybrid superconducting quantum devices provide a novel platform for the study of quantum phenomena at the interface between different materials and noise fluctuations in solid-state devices.

We here report on the study of novel tunability schemes for flux-tunable superconducting transmon qubits, by integrating in the device unconventional low-dissipative tunnel ferromagnetic Josephson junctions (SFS JJs). In this novel hybrid ferromagnetic transmon qubit, namely the ferrotransmon, the qubit frequency can be tuned by means of in-plane magnetic field pulses, by exploiting the magnetic hysteretic behavior in the ferromagnetic barrier, rather than continuous magnetic flux fields, thus possibly reducing the impact of flux-noise decoherence. The enhanced tunability of SFS junctions can be of reference for a large variety of superconducting quantum devices. 

24/01/2023

h11:30 – Aula 0M01, Dipartimento di Fisica 

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Bereneice Sephton

(University of Naples Federico II, Italy)

Towards teleporting quantum images 

Abstract

Quantum teleportation allows the disembodied transferral of information between two destinations. A general teleportation approach exploits entanglement between two photons to convey information between two destinations without the information physically existing in the path between them. Indirect (Bell) measurements, between one of the entangled photons and a state one desires to transmit, then allows the disembodied information to be conveyed elsewhere, moderated by classical communication. Physically developing such a protocol is of interest across a variety of quantum information tasks as it forms a salient toolbox from quantum computing to security and quantum networks, sparking much research into the practical implementation thereof. This has been demonstrated with a variety of approaches ranging from NMR to solid state systems, but the highest dimension teleported is limited to three and requires an extra (ancillary) photon pair for every dimensional increase. A trade-off for higher dimensions has been setups that are difficult to scale and resource intensive if further dimensions are desired.

In an effort towards practically feasible teleportation of systems such as images, multi-level atoms or molecules, we consider side-stepping the scalability issue with and explore a non-linear approach in place of the traditional linear implementation for the entangling Bell step. With this, we experimentally show high-dimensional teleportation exceeding 10 dimensions for twisted light as well as other spatial states with fidelities beyond the classical limit. The results open the way towards implementing teleportation in a practically useful way with an encouraging paradigm allowing versatile and high-capacity optical quantum communication protocols for on-demand states.

25/11/2022

h11:30 – Aula Caianiello, Dipartimento di Fisica 

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Alexandre Dauphin

(The Institute of Photonic Sciences – ICFO, Spain)

Self-trapped polarons and topological defects in a topological Mott insulator 

Abstract

In the last decades, topological insulators have attracted great interest and also have promising applications in topics such as metrology or quantum computation. These exotic materials go beyond the standard classification of phases of matter: they are insulating in their bulk, conducting on their edges, and characterized by a global topological invariant, in contrast to a local order parameter as in the conventional Ginzburg-Landau theory of phases of matter. 

Such topological phases have been experimentally observed in condensed matter systems and more recently in quantum simulators. The latter are very versatile platforms that allow one to simulate a material with another quantum system in a very controllable environment. In the case of topological insulators, this degree of control is particularly promising to unveil the mechanisms leading to these phases. 

The quantum simulation of these exotic materials typically relies on the generation of artificial gauge fields. However, recent studies have shown that topological phases can also emerge from particle interactions. The latter mechanism leads to the concept of interaction-induced topological phases, in which topology is acquired through a spontaneous symmetry breaking process. The interplay of the spontaneous symmetry breaking with the global topological properties can lead to very interesting effects.

In this talk, I will discuss how such interplay can lead to new strongly-correlated topological effects in a 2D material. In particular, I will show how interactions can localize particles in the insulating bulk at incommensurate fillings, leading to self-trapped polarons. Furthermore  at higher filling,  the interacting nature of the topological insulator gives rise to domains in the bulk. Interestingly, the nontrivial topology associated to each domain leads to the appearance of protected conducting states in the bulk, localized at the domain boundaries. Finally, I will discuss the possibility of quantum simulating such phases with cold laser-excited Rydberg atoms in an optical lattice.

11/11/2022

h11:00 – Aula Caianiello, Dipartimento di Fisica 

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Marcello Dalmonte

(Abdus Salam ICTP Trieste, Italy)

Data mining the output of quantum simulators – from critical behavior to algorithmic complexity

Abstract

Recent experiments with quantum simulators and noisy intermediate-scale quantum devices have demonstrated unparalleled capabilities of probing many-body wave functions, via directly probing them at the single quantum level via projective measurements. However, very little is known about to interpret and analyse such huge datasets. In this talk, I will show how it is possible to provide such characterisation of many-body quantum hardware via a direct and assumption-free data mining. The core idea of this programme is the fact that the output of quantum simualtors and computers can be construed as a very high-dimensional manifold. Such manifold can be characterised via basic topological concepts, in particular, by their intrinsic dimension. Exploiting state of the art tools in non-parametric learning, I will discuss theoretical results for both classical and quantum many-body spin systems that illustrate how data structures undergo structural transitions whenever the underlying physical system does, and display universal (critical) behavior in both classical and quantum mechanical cases. I will conclude with remarks on the applicability of our theoretical framework to synthetic quantum systems (quantum simulators and quantum computers), and emphasize its potential to provide a direct, scalable measure of Kolmogorov complexity of output states.

02/11/2022

h15:00 – Aula Caianiello, Dipartimento di Fisica 

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Alioscia Hamma

(University of Naples Federico II, Italy)

Stabilizer Renyi Entropy and Quantum Complexity

Abstract

Quantum physics is inherently different from classical physics and this difference comes in two layers. First, quantum correlations are stronger than classical correlations and do violate Bell’s inequalities. Second, based on the assumption that P is not NP, quantum physics is exponentially harder to simulate than classical physics. 
The resource that makes quantum computers different from classical computers consists on those operations that go beyond the stabilizer formalism. In this talk, we show a new way of computing non-stabilizerness, called Stabilizer Renyi Entropy, and show how this quantity can be experimentally measured. We show how the Stabilizer Entropy determines the hardness of quantum verification, and how in turn it is involved in the onset of quantum complex behavior, as, e.g., revealed in the Out-of-Time-Order correlators. Moreover, we show how Stabilizer Renyi Entropy determines the complexity of a Black Hole. 
Time permitting, we sketch a new approach to quantum complexity based on the interplay of entanglement and non-stabilizerness.

07/10/2022

h11:00 – Aula Caianiello, Dipartimento di Fisica 

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Nicolò Crescini

Institut Néel-CNRS, Grenoble France

Dual Shapiro steps in a Josephson junctions array

Abstract

The modern primary voltage standard is based on the AC Josephson effect and the ensuing Shapiro steps, where a microwave tone applied to a Josephson junction yields a constant voltage hf/2e (h is Planck’s constant and e the electron charge) determined by only the microwave frequency f and fundamental constants. Duality arguments for current and voltage have long suggested the possibility of dual Shapiro steps–that a Josephson junction device could produce current steps with heights determined only on the applied frequency. In our setup we embed an ultrasmall Josephson junction in a high impedance array of larger junctions to reveal dual Shapiro steps. For multiple frequencies, we detect that the AC response of the circuit is synchronised with the microwave tone at frequency f, and the corresponding emergence of flat steps in the DC response with current 2ef, equal to the transport of a Cooper pair per tone period. This work sheds new light on phase-charge duality, omnipresent in condensed matter physics, and extends it to Josephson circuits. Looking forward, it opens a broad range of possibilities for new experiments in the field of circuit quantum electrodynamics and is an important step towards the long sought closure of the quantum metrology electrical triangle.