As a Lead Quantum Device Theorist, you will play a central role in advancing the performance of our superconducting quantum processors.
\nThis position requires deep expertise in circuit QED, quantum device physics, and noise modeling for quantum error correction (QEC).
\nYou will work closely with experimental teams to model processor dynamics and lead efforts to improve qubit readout fidelity and quantum gate performance across our R&D platforms.
\nThis role demands strong cross-functional collaboration with specialists in qubit readout, gate calibration, control systems, and superconducting circuit design.
\nTogether, you will drive innovations that support scalable architectures, quantum advantage, and fault-tolerant error correction.
\nKey Responsibilities:
\nDevelop and maintain advanced simulation tools to accurately model noise sources in flux-tunable superconducting qubits
\nModel and analyze entangling gate operations on superconducting quantum processors
\nApply optimal control techniques to improve quantum gate and readout performance
\nDevelop analytical tools to interpret experimental measurements and diagnose performance anomalies
\nPerform detailed error-budget modeling to support quantum error correction (QEC) efforts
\nCollaborate cross-functionally with teams in gate operations, measurement, device design, applications, algorithms, and control engineering.
\nRequired Qualifications:
\nPh.D. in Physics, Applied Physics, Electrical Engineering, or a related field, plus 5+ years of relevant work experience
\nModeling noise in large scale processors and inform Hamiltonian designs
\nExperience simulating open quantum systems
\nExperience collaborating with experimentalists on readout and noise characterization; analyzing and interpreting experimental data, and predicting anomalies
\nBackground in gate-based quantum computing or superconducting circuits, either academically or in industry
\nDemonstrated depth and breadth in circuit QED physics, including Hamiltonian modeling, dispersive readout theory, and multi-qubit coupling architectures
\nProven expertise in noise modeling for quantum error correction, including coherent and incoherent error channels, leakage, crosstalk, and correlated noise
\nStrong programming skills in Python for scientific applications
\nPreferred Qualifications:
\nExperience with optimal control theory applied to superconducting qubits
\nFamiliarity with quantum error correction codes and fault-tolerant architectures
\nTrack record of publications in relevant peer-reviewed journals
\nExperience with high-performance computing or GPU-accelerated simulations
\nProficiency with scientific computing libraries such as QuTiP, or Stim
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