Abstract

Emergent phenomena in interacting quantum systems arise from collective behavior that cannot be reduced to single-particle physics. Understanding these phenomena requires platforms capable of both synthesizing many-body states under controlled conditions and probing them at the microscopic scale where correlations originate. Solid-state spin defects, including nitrogen-vacancy (NV) centers in diamond and negatively charged boron vacancy centers in hexagonal boron nitride (hBN), offer precisely this dual capability. In the first part of this dissertation, a strongly interacting NV ensemble is subjected to periodic and quasi-periodic drives to access a long-lived prethermal regime and realize a discrete time quasicrystal (DTQC). In the second part, the boron vacancy center in hBN is developed as a two-dimensional quantum sensor through coherence characterization and isotope engineering, then deployed inside a diamond anvil cell to image stress and magnetism simultaneously at gigapascal pressures, resolving a pressure-induced magnetic phase transition in a Cr$_{1+\delta}$Te$_2$/hBN heterostructure. Moreover, NV scanning cross-relaxometry enables nanoscale mapping of spin defects in hBN, while noise spectroscopy is applied to probe superconducting fluctuations and vortex dynamics in a cuprate thin film. Together, these results demonstrate that solid-state spins provide a versatile experimental framework in which quantum simulation, sensor development, and materials characterization inform and reinforce one another.

Committee Chair

Chong Zu

Committee Members

Alex Seidel; Chuanwei Zhang; Erik Henriksen; Lan Yang

Degree

Doctor of Philosophy (PhD)

Author's Department

Physics

Author's School

Graduate School of Arts and Sciences

Document Type

Dissertation

Date of Award

4-17-2026

Language

English (en)

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Physics Commons

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