Controlling the Effective Hamiltonian of a Driven Quantum Superconducting Circuit

The thesis illustrates, with a remarkable combination of theoretical analysis and experimental investigation, how the static Hamiltonian of an oscillator with both 3rd and 4th order non-linearity can morph into a profoundly different Hamiltonian under the influence of an oscillating driving force. In a classical system, such transformation would not be considered a novelty, but the author demonstrates that the new Hamiltonian can possess an exotic symmetry with surprising new quantum properties that one would never anticipate from the original Hamiltonian, with no classical equivalent. The root cause of these unexpected properties is a subtle interference effect, which is only possible in a quantum context. Carefully crafted control experiments ensure that measured data are compared with theoretical predictions with no adjustable parameters. Instrumental in this comparison is a new diagrammatic theory developed by the author.

Nominated as an outstanding PhD thesis by Yale University, USA Gives an introduction to effective Hamiltonians in physics Reveals underlying symmetries in the Hamiltonian of a simple quantum system with potential technology applications

Autorentext

Jaya, originally from Bengaluru, India, earned her Bachelor's degree in Physics from IIT Kanpur in 2016. Her introduction to quantum optics came during her undergraduate research on fast resonator reset with Alexandre Blais at Université de Sherbrooke. In 2023, she completed her Ph.D. under Michel Devoret at Yale University, where she developed experimental and theoretical tools to control superconducting circuits subjected to microwave drives for bosonic codes and continuous-variable quantum computation. In Fall 2024, she began a postdoctoral position at UCSB with Ania, focusing on enhancing quantum control of solid-state spins for quantum sensing of condensed matter systems. Outside of Physics, Jaya enjoys running, meditating, and exploring nature. She is also trained in Carnatic music and Bharatanatyam and delights in dabbling with these art forms.

Inhalt

Chapter 1: Preamble.- Chapter 2: The squeeze-driven Kerr oscillator (SKO) implemented in a driven superconducting circuit.- Chapter 3: Representations and properties of the SKO.- Chapter 4: Experimental setup.- Chapter 5: Quantum tunneling observations in the ground state manifold of the SKO.- Chapter 6: Excited state manifold: spectral kissing, multilevel degeneracies, and their fingerprint on the qubit lifetime.- Chapter 7: A decoherence model for the SKO: an RWA model and treating effects beyond the RWA.- Chapter 8: Conclusions and future directions.