Oxide 2D-electron systems are characterized by extraordinary functional properties, including large Rashba-like spin-orbit coupling and unconventional superconductivity. In this contribution I will give an overview of possible application of oxide 2DEGs as topological and spin-orbit qubits
https://drive.google.com/open?id=19MRyNn_uqRGBspLuMsDmlyJbbODjg9DX
Ultracold quantum gases can be manipulated with arbitrary optical potentials to implement elementary circuits for atomtronics and spintronics applications. Here we present experiments performed on fermionic lithium atoms in Florence and bosonic spin mixtures of sodium in Trento.
https://drive.google.com/open?id=10u5Se9vKPeRQ6IQyZxgVx_MKfkcN2n9R
We present an efficient and CMOS compatible solution to realize a monolithic integration between SIN or SiON PICs (operating at 850 nm) and single-photon detectors, fabricated on the same silicon chip, operating at room temperature
https://drive.google.com/open?id=14phwGTt9VtM0lZDtXB408m2yBO2LHfRt
We discuss our experimental exploration of how spontaneous photonic crystals form supported by polarization supercrystals (PSCs) in near-transition potassium-lithium-tantalate-niobate (KTN:Li) and its implications for topologically-protected photonic waveguides and memory bits.
In Linear Optics Quantum Computing, the research aims to optimize a Silicon Photonic Integrated Circuit, focusing on the universal two-qubit Controlled-NOT gate prototype, which operates on a linear, coincidence basis with single-photon inputs.
https://drive.google.com/open?id=1KQUxgrPyyXXEi3nWbmdir-Ciyh2fQKBd
Ultra low-noise and broadband amplification is an essential ingredient to read out superconducting qubits. We present the development of Travelling Wave Parametric Amplifiers based on NbTiN films, towards the integration of a quantum-limited read-out chain.
https://drive.google.com/open?id=1iYfLR_s4gFjPSbF_rFVveWaahxLWn2dD
We have carried out a theoretical and experimental study of collective quantum dynamics of a superconducting quantum network (SQN) embedded in resonators.
https://drive.google.com/open?id=1_n0IBwh7GHQ1mQXIub6VmiiE-EFf9Zc5
The performance of single superconducting circuital components fundamentally limits the performance of complex multi-qubit circuits. We therefore optimise the design and microfabrication of elementary building blocks, maximising control and reproducibility and minimising microwave losses.
https://drive.google.com/open?id=15EwTqjMfeHfiLgOfqLjYyrFtfG6_PhF4
3D architectures with superconducting qubits are very attractive solutions for several quantum applications. We report here our recent progress in design and fabrication of such devices and in their characterization.
https://drive.google.com/open?id=1oicw8eMYfuO3E29CqKhXB-c-SetsrrgW
We present an open-source tool designed for control and readout of superconducting qubits using Radio-Frequency System on Chip (RFSoC) FPGA boards. This tool facilitates swift calibration experiments and enables the deployment of gate-based applications.
https://drive.google.com/open?id=1-bVOiubiMvm4QIlGWbv5PnX9cD5ToiUU
Quantum sensing with superconducting qubits opens new directions for exploring fundamental physics, offering unprecedented improvements in sensitivity. This presentation includes preliminary results and ongoing developments in transmon qubits specifically designed for this application.
https://drive.google.com/open?id=1q-PhFx0kZ6s6-XU2-oViOOAfR2Bc7pOk
To advance quantum sensing we develop an integrated stack for microwave single-photon detection. Utilizing superconducting qubits, parametric amplifiers, and RFSoC-based quantum electronics, we aim to exceed current standards. Preliminary results and ongoing developments are presented.
https://drive.google.com/open?id=1WWIHv8Q-7nFhLZrkQK-40N2pchP_GSuP