2 research outputs found
Superconducting routing platform for large-scale integration of quantum technologies
To reach large-scale quantum computing, three-dimensional integration of
scalable qubit arrays and their control electronics in multi-chip assemblies is
promising. Within these assemblies, the use of superconducting
interconnections, as routing layers, offers interesting perspective in terms of
(1) thermal management to protect the qubits from control electronics
self-heating, (2) passive device performance with significant increase of
quality factors and (3) density rise of low and high frequency signals thanks
to minimal dispersion. We report on the fabrication, using 200 mm silicon wafer
technologies, of a multi-layer routing platform designed for the hybridization
of spin qubit and control electronics chips. A routing level couples the qubits
and the control circuits through one layer of Al0.995Cu0.005 and
superconducting layers of TiN, Nb or NbN, connected between them by W-based
vias. Wafer-level parametric tests at 300 K validate the yield of these
technologies and low temperature electrical measurements in cryostat are used
to extract the superconducting properties of the routing layers. Preliminary
low temperature radio-frequency characterizations of superconducting passive
elements, embedded in these routing levels, are presented