Phys.org February 5, 2024
Confinement of light into nanocavities which enhances light–matter interactions generally come at the cost of absorption and low resonator quality factors. An international team of researchers (Israel, USA – Cornell University, Kansas State University, Germany, Spain) suggested an alternative optical multimodal confinement mechanism, unlocking the potential of hyperbolic phonon polaritons in isotopically pure hexagonal boron nitride. They produced deep-subwavelength cavities and demonstrated several orders of magnitude improvement in confinement approaching the intrinsic quality factor of hexagonal boron nitride polaritons. The quality factors they obtained exceeded the maximum predicted by impedance-mismatch considerations indicating that confinement was boosted by higher-order modes. According to the researchers their approach will have far-reaching implications for ultrastrong light–matter interactions, mid-infrared nonlinear optics, and nanoscale sensors… read more. TECHNICAL ARTICLE
Breaking boundaries in quantum photonics: New nanocavities unlock new frontiers in light confinement
Posted in Quantum photonics and tagged Light-matter interaction, Nanoscale sensors, Nonlinear optics.