Color defect centers in diamonds hold promise for various quantum technologies. In quantum computing, defect centers serve as qubits, enabling robust quantum information processing. Their long coherence times make them suitable for quantum memory, pivotal for secure communication in quantum cryptography. Color defect centers also facilitate precise sensing, offering unparalleled sensitivity for detecting magnetic and electric fields, vital for medical diagnostics and materials science. Additionally, they play a crucial role in quantum metrology, enhancing precision in measurements beyond classical limits. Harnessing color defect centers paves the path towards realizing advanced quantum technologies with profound implications across scientific and technological domains. In this talk I will touch upon the multifaceted applications of diamond.
Organization/Institution | Position | Period |
---|---|---|
Cornell University (Nonlinear optics in nano-photonic devices - Rubidium filled hollow core photonic bandgap fiber, silicon nitride microresonators and waveguides) | Graduate student | 2008-2013 |
MIT (Quantum spin gyroscope using nitrogen vacancies in diamond, single photon generation in silicon vacancies in diamond.) | Post-Doctoral Fellow | 2013-2016 |