For groups developing devices, materials, control electronics or cryogenic components — measure performance against real cryogenic conditions, from room temperature down to millikelvin.
Relaxation time (T₁), coherence time (T₂), dispersive readout and gate fidelity measurements on a live superconducting QPU.
Josephson junctions, superconducting and semiconducting resonators, quantum-limited amplifiers, quantum dots and nanodevices.
Wiring, filters, interconnects, couplers and parametric amplifiers tested inside the cryogenic signal chain.
FPGA-based qubit control, RF and signal-chain hardware, and warm-to-cold stack integration on the live system.
For research groups developing quantum algorithms, error-mitigation strategies or benchmarking protocols — execute, measure and iterate on a live superconducting processor under supervised sessions.
Run gate-level circuits and parameterised algorithms directly on the QPU through the FPGA control stack.
Randomised benchmarking, quantum volume, cross-entropy benchmarking and custom validation suites against measured ground truth.
Test mitigation strategies, dynamical decoupling sequences and pulse-level optimisations against real hardware noise — not modelled noise.
Iterate variational and hybrid algorithms with the system in the loop, on-site or via remote terminal access.
A control model built for academic and laboratory use — your algorithms, data and results stay exclusively yours.
During your scheduled session the system is under your complete and exclusive operational control.
Algorithms, input data, measurement data, outputs and derivative results remain solely and exclusively yours.
Qubitech personnel access your material only as required to support the session, under confidentiality — and you may direct deletion on completion.
Developing devices, junctions, amplifiers, resonators, control electronics or cryogenic components.
Validating quantum algorithms, benchmarking protocols and error-mitigation methods on real hardware.
Characterising next-generation superconductors, semiconductors, topological materials and nanodevices at millikelvin.
