Advances in quantum science and technology rely on ever-improving control over quantum degrees of freedom including electron spin, photons, and magnons, which can store, transmit, and exchange information. Our research focuses on investigating the dynamics and effective couplings among these quantum degrees of freedom.
Following are the examples how we demonstrate experimental abilities to image and correlate spintronic, photonic, and magnonic quantum degrees of freedom at unparalleled spatial and temporal resolutions, and high magneto-optic sensitivities. We aim to bridge the urgent needs of the microelectronics industry by enabling new forms of nonvolatile magnetic memory, low-power computing, optical interconnects, and multifunctional hybrid materials with widespread societal impact.
