**Quantum Technologies Theory**

Our research mission is to achieve a deeper understanding and precise control of quantum matter.

Solving quantum many-body problems beyond the limits of classical computers using quantum devices

Developing algorithms for solving real-world problems on today’s and tomorrow’s quantum computers

Unravelling the mysteries behind the most exotic phases of quantum matter

Shedding light on hidden properties of quantum many-body systems

Our research is geared towards leveraging the potentials of quantum matter with the aim of developing novel quantum technologies such as quantum simulation, quantum computation, and quantum metrology.

We perform theoretical studies based on analytical and numerical methods, as well as develop proposals for realizing and characterizing phase diagrams and non-equilibrium dynamics of quantum many-body systems.

These proposals draw on the astonishing abilities of quantum devices, e.g., based on ultracold quantum gases, trapped ions, or superconducting qubits, which are now reaching a level of precision and control that has been unimaginable just a few decades ago.

Go ahead and find out more about our research topics by clicking on the project cards above.

In this paper, we show the application of the Quantum Metropolis Sampling (QMS) algorithm to a toy gauge theory with discrete …

Anyonic exchange statistics can emerge when the configuration space of quantum particles is not simply-connected. Most famously, anyon …

We derive necessary and sufficient conditions for warped AdS2 solutions of Type II supergravity to preserve $\mathcal{N}=1$ …

Lattice gauge theories are fundamental to various fields, including particle physics, condensed matter, and quantum information theory. …

The topological $\theta$-angle is central to the understanding of a plethora of phenomena in condensed matter and high-energy physics …

We enlarge the dictionary between matrix models for long linear quivers preserving eight supercharges in $d=5$ and $d=3$ and type IIB …

We construct a holographic map that takes the semi-classical state of an evaporating black hole and its Hawking radiation to a …

A frequent starting point of quantum computation platforms is the two-state quantum system, i.e., the qubit. However, in the context of …

Equilibrium quantum many-body systems in the vicinity of phase transitions generically manifest universality. In contrast, limited …

We study five-dimensional $N=1$ Superconformal Field Theories of the linear quiver type. These are deformed by a relevant operator, …

Di quantum computing si sente parlare da un po’ di tempo, ma non sempre viene presentato con chiarezza.
Per raccontarlo come si deve, …

Gauge theories are at the heart of our modern understanding of physics, but solving their out-of-equilibrium dynamics is extremely …

The dynamics of lattice gauge theories is characterized by an abundance of local symmetry constraints. Although errors that break gauge …

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Our group is embedded in the Pitaevskii BEC Center — a joint interinstitutional effort between CNR-INO and the University of Trento, bringing together theorists and experimentalists with the aim of gaining a deeper understanding of the physics related to Bose–Einstein condensation as well as achieving precise experimental control over ultracold atomic systems.

Moreover, we are part of Q@TN — Quantum Science and Technology in Trento — an interdisciplinary organization bringing together Physicists, Computer Scientists, Mathematicians, Material Scientists, and Engineers to advance the development of quantum technologies.

We are members of INFN-TIFPA, where we contribute in particular to the Research Network (Iniziativa Specifica) QUANTUM, which pursues a quantum-information approach to strongly correlated matter. Aims of our research within this initiative are to design quantum simulations for lattice gauge theories and analog gravity, to illuminate the role of entanglement in many-body systems, and to design methods to extract complex observables from experimental data.

We are associated partner of the BMWi project *EnerQuant: Energiewirtschaftliche Fundamentalmodellierung mit Quantenalgorithmen* as well as
CRC 1225 ISOQUANT: Isolated quantum systems and universality in extreme conditions.

Our group is receiving funding from the
European Research Council (ERC) under the European Union’s
Horizon 2020 research and innovation programme (ERC-2018-STG project *StrEnQTh — Strong Entanglement in Quantum many-body Theory*, Grant agreement No. 804305), the Provincia Autonoma di Trento, and
Q@TN — Quantum Science and Technology in Trento.

Funded by the European Union under Horizon Europe Programme - Grant Agreement 101080086 — NeQST.