quantum electro-optic amplifiers for the next generation quantum and supercomputers

HORIZON.1.1HORIZON-ERCID: 101042414
EC Contribution
€19,307
Consortium Size
1 orgs
Summary

Quantum computers face many bottlenecks towards upscaling the number of qubits and increasing their computational power. One of them is the radio frequency (RF) -bottleneck between the qubit processor inside the cryostat and the room temperature control and readout electronics. And like for their classical counterparts, hope lies in replacing the RF-links by optical fibers, resulting in a hybrid situation where RF-qubits will be used for computation and optical qubits will serve for remote communication. However, electro-optical (EO) devices that parametrically amplify RF-qubits directly to optical qubits and vice versa have thus far remained elusive. Q-Amp will demonstrate a new class of EO-amplifiers that realize the required unity efficiency to achieve this goal. This is impossible with current EO-architectures which suffer from a deleterious trade-off between EO interaction strength (g) and EO losses (Q-factors). This originates from their device design and enhancing g requires bringing the RF-superconducting circuit in close vicinity of the optical waveguide, which comes at the expanse of excess EO losses. To cope with this, we will pioneer a transparent EO device technology that enhances g without the need of bringing superconductors and optical waveguides in close vicinity of each other. We will do so by concentrating the RF- and the optical field in the same nanoscale interaction volume via dipolar screening in ferroelectrics and/or ballistic transport in graphene. Confining both fields within next generation EO-materials will enable an increase of g from 100s of Hz (prior art) to Megahertz-levels. Simultaneously, light is kept away from the lossy superconducting electrodes enabling moderate Q-values of 1E5..1E6. Q-amp’s EO-amplifiers will finally overcome the scaling limitations of current superconducting quantum computers and will provide classical superconducting supercomputers with high-speed EO gateways they desperately need.

Consortium (1)

Project Results (3)

Source: CORDIS, the EU research results database.

Publications (3)
Impact of Cationic Stoichiometry on Physical, Optical and Electrical Properties of SrTiO3 Thin Films Grown on (001)-Oriented Si Substrates
Materials· 2024DOI
Marina Baryshnikova, Andries Boelen, Luca Ceccon, Vincent Herreman, Sean R. C. McMitchell, Christian Haffner and Clement Merckling
Quantum paraelectric parametric amplifiers
Quantum 2.0 Conference 2024 © Optica 2024· 2024
Anja Ulrich, Kamal Brahim, Andries Boelen, Bart Kuyken, Christian Haffner
Perspective: Nanophotonic electro-optics enabling THz bandwidths, exceptional modulation and energy efficiencies, and compact device footprints
APL Materials, 11 (5)· 2023DOI
Dalton, Larry R.; Leuthold, Juerg; id_orcid0000-0003-0111-8169; Robinson, Bruce H.; Haffner, Christian; id_orcid0000-0002-8947-5293; Elder, Delwin L.; Johnson, Lewis E.; Hammond, Scott R.; Heni, Wolfgang; id_orcid0000-0003-0861-2530; Hosessbacher, Claudia; Bäuerle, Benedikt; id_orcid0000-0001-8545-915X; De Leo, Eva; Koch, Ueli; id_orcid0000-0001-8796-2146; Habegger, Patrick; Fedoryshyn, Yuriy; Moor, David; id_orcid0000-0002-0930-4604; Ma, Ping; id_orcid0000-0003-0674-8530