Yvonne Gao

Yvonne Gao's picture
Research Areas: 
Condensed Matter Physics
Research Type: 
Experimentalist
Education: 
Ph.D. 2018, Yale University
Advisor: 
Rob Schoelkopf
Dissertation Title: 
Multi-cavity Operations in Circuit Quantum Electrodynamics
Dissertation Abstract: 

The eventual success of a quantum computer relies on our ability to robustly initialise, manipulate, and measure quantum bits in presence of the inevitable occurrence of errors. This requires us to encode quantum information redundantly in systems that are suitable for Quantum Error Correction (QEC). One promising implementation is to use three dimensional (3D) superconducting microwave cavities coupled to one or more non-linear ancillae in the circuit quantum electrodynamics (cQED) framework. Such systems have the advantage of good intrinsic coherence properties and large Hilbert space, making them ideal for storing redundantly encoded quantum bits. Recent progress has demonstrated the universal control and realisation of QEC beyond the break-even point on a logical qubit encoded in a mulitphoton state of a single cavity. This thesis presents the first experiments in implementing quantum operations between multiphotons states stored in two separate cavities. We first explore our ability to create complex two-mode entangled states and perform fully characterisation in a novel multi-cavity architecture. Subsequently, we will demonstrate the capability to implement conditional quantum gates between two cavity modes, assisted by a single ancilla. Further, we develop a direct, tunable coupling between two cavities and use it to study complex multiphoton interference between two stationary bosonic states. Combining this with robust single cavity controls, we construct a universal entangling operation between multiphoton states. The results presented in this thesis demonstrate the vast potential of 3D superconducting systems as robust, error-correctable quantum modules and the techniques developed constitute an important toolset towards realising universal quantum computing on error-corrected qubits.