Title :
Optimization of coupling between photonic crystal resonator and curved microfiber
Author :
Hwang, In-Kag ; Kim, Guk-Hyun ; Lee, Yong-Hee
Author_Institution :
Dept. of Phys., Korea Adv. Inst. of Sci. & Technol., Daejeon, South Korea
Abstract :
The evanescent coupling from a photonic crystal resonator to a micron-thick optical fiber is investigated in detail by using a three-dimensional finite-difference time-domain (3D-FDTD) method. Properly designed photonic crystal cavity and taper structures are proposed, and optimal operating conditions are found to enhance the coupling strength while suppressing other cavity losses including the coupling to the slab propagating mode and to the higher-order fiber mode. In simulation, the coupling into the fundamental fiber mode is discriminated from other cavity losses by spatial and parity filtering of the FDTD results. The coupling efficiency of more than 80% into the fundamental fiber mode together with a total Q factor of 5200 is achieved for the fiber diameter of 1.0 μm and the air gap of 200 nm between the fiber and the cavity.
Keywords :
Q-factor; cavity resonators; filtering theory; finite difference time-domain analysis; micro-optics; optical fibre couplers; optical fibre losses; optical resonators; photonic crystals; 1.0 mum; 200 nm; Q factor; air gap; cavity loss suppression; coupling optimization; coupling strength; curved microfiber; evanescent coupling; fundamental mode; higher-order fiber mode; micron-thick optical fiber; photonic crystal cavity; photonic crystal resonator; slab propagating mode; taper structures; three-dimensional finite-difference time-domain method; Design methodology; Finite difference methods; Optical coupling; Optical fiber losses; Optical fibers; Optical resonators; Photonic crystals; Propagation losses; Slabs; Time domain analysis; Microresonators; optical coupling; optical fibers; photonic crystal;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2005.861618
