Optimized Design and Simulation of Optical Section in Electro-Reflective Modulators Based on Photonic Crystals Integrated with Multi-Quantum-Well Structures

In the design of photonic integrated circuits (PICs), the optical connections of the PIC surface, along with the electronic components of the chips, are significant issues. One of the optoelectronics components that utilizes these surface connections are electro-reflective modulators, consisting of an optical section and an electronic section. In this paper, a novel scheme of two-dimensional photonic crystals (PhCs) is presented for the optical and reflective sections of this device. This design is two-dimensional; thus, it has less volume than the current bulky structures. The finite element method is utilized to simulate and optimize the scheme of PhCs and gold layer parameters. Furthermore, optimization of design parameters is accomplished through the Nelder-Mead method. Moreover, the modeling and simulation of the proposed hybrid PhCs has been investigated according to the structural parameters with tolerance. These tolerances, related to the nanorods' radius and lattice constants, are considered to justify and vindicate the fabrication technology limitations and conditions. In the "on" state of the modulator, the light transmission ratio is 98% for a 903 nm wavelength with a 45 degrees angle of deflection and incident light, nd the bandwidth is 20 nm. For an 897 nm wavelength with a 41 degrees angle, the transmission ratio is 95%, and the bandwidth is 7 nm.