The magnetic plasmon (MP) modes in the metal-dielectric-metal nanosandwich structure are investigated nu-merically,and the principle of energy resonance in such a resonator is proposed.An equivalent inductance capacitance circuit analysis method is proposed and the results are in agreement with the numerical simulations.Based on the MP resonance in such a structure,a nanosandwich chain waveguide is designed.Gold and silver are chosen as the metal materials.The power transmission efficiency of the nanosandwich waveguide can be as high as 0.546 in a specific nanosandwich unit cell,even when the metal absorption loss is large,which is the perspective of the new waveguides and lasers based on MP modes.
The 850-nm oxide-confined vertical-cavity surface-emitting lasers with petal-shape holey structures are presented.An area-weighted average refractive index model is given to analyse their effective index profiles,and the graded index distribution in the holey region is demonstrated.The index step between the optical aperture and the holey region is obtained which is related merely to the etching depth.Four types of holey vertical-cavity surface-emitting lasers with different parameters are fabricated as well as the conventional oxide-confined vertical-cavity surface-emitting laser.Compared with the conventional oxide-confined vertical-cavity surface-emitting laser without etched holes,the holey vertical-cavity surface-emitting laser possesses an improved beam quality due to its graded index distribution,but has a lower output power,higher threshold current and lower slope efficiency.With the hole number increased,the holey vertical-cavity surface-emitting laser can realize the single-mode operation throughout the entire current range,and reduces the beam divergence further.The loss mechanism is used to explain the single-mode characteristic,and the reduced beam divergence is attributed to the shallow etching.High coupling efficiency of 86% to a multi-mode fibre is achieved for the single-mode device in the experiment.
The local density of states (LDOS) of two-dimensional square lattice photonic crystal (PhC) defect cavity is studied.The results show that the LDOS in the centre is greatly reduced,while the LDOS at the point off the centre (for example,at the point (0.3a,0.4a),where a is the lattice constant) is extremely enhanced.Further,the disordered radii are introduced to imitate the real devices fabricated in our experiment,and then we study the LDOS of PhC cavity with configurations of different disordered radii.The results show that in the disordered cavity,the LDOS in the centre is still greatly reduced,while the LDOS at the point (0.3a,0.4a) is still extremely enhanced.It shows that the LDOS analysis is useful.When a laser is designed on the basis of the square lattice PhC rod cavity,in order to enhance the spontaneous emission,the active materials should not be inserted in the centre of the cavity,but located at positions off the centre.So LDOS method gives a guide to design the positions of the active materials (quantum dots) in the lasers.
GaInAs/AlGaAs comprehensive-strained three-quantum-well lasers with asymmetric waveguide are designed and optimized. With this design, the optical field in the transverse direction is extended, and a semiconductor laser with large spot is obtained. For a 300-μm cavity length and 100-μm aperture device under continuous wave (CW) operation, the measured vertical and horizontal far-field divergence angles are 12.2° and 3.0°, respectively. The slope efficiency is 0.44 W/A and the lasing wavelength is 917 nm.The equivalent transverse spot size is 3 μm for the fundamental transverse mode, which is a sufficiently large value for the purpose of coupling and manipulation of light.
