We show that metallic wires in CMOS chips can provide dual functionalities as electronic interconnects and as plasmonic/metamaterial devices. We demonstrate plasmonic resonances in a chip fabricated in a bulk Si CMOS foundry (TSMC, 65 nm node). Through minimal post processing, we integrate the designed nanophotonic CMOS chip with liquid crystals and demonstrate a high-speed liquid crystal-based electro-optic modulator.
This talk will focus on the development of material platforms and physical mechanisms for high-fidelity control, storage, and transmission of quantum information. In particular, emerging quantum materials - novel diamond impurities - featuring long-lived, optically addressable quantum states are promising candidates fulfilling most of these requirements. We will discuss possible mechanisms for efficient interfacing of these novel solid-state qubits, in particular allowing for high-fidelity quantum-state transduction to superconducting qubits or to the long-lived nuclear spins. Finally, the physical phenomena enabling local quantum control in these materials, including strain-mediated or optically mediated state-transfer and two-qubit gates, will be discussed.
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