Ultrahigh quality-factor microresonators fabricated in pristine lithium niobate thin film for efficient nonlinear optics applications

Optical resonators enable storage of optical power at specific resonant frequencies and also enhance the nonlinear interactions between distinct resonances. Both the power storage capability and the nonlinear enhancement are critically dependent on the quality-factor (Q) of the optical resonator. Continuous efforts to seek for suitable materials and fabrication methods to produce optical resonators are stimulated by the never-ending desire for higher Q values. The integrated microresonators are very promising among those quests due to their miniaturized size, low power consumption, high scalability and compatibility for monolithic integration of multiple functionalities. Lithium niobate (LN), usually dubbed as the silicon for photonics, attracted broad interests in integrated photonics due to its excellent electro-optic, acousto-optic and nonlinear optical properties. In this work, we have demonstrated chip-scale microresonators fabricated in pristine LN thin film with the highest Q-factors (>108) among the integrated LN microresonators. Broadband and highly efficient nonlinear frequency conversions are demonstrated in the LN microresonators without introducing the conventional domain poling, holding significant perspectives for quantum information technology, cavity electrodynamics and microwave photonics. The established micro-fabrication methods for mass-production of integrated LN photonics also promise to promote the performance of current integrated LN devices to a large extent.