Here, we have successfully designed a photonic crystal structure to improve the light absorption by increasing the optical path length of the incident light inside the absorbing material to enhance the efficiency of a thin film silicon solar cell. The current design is based on the high temperature superconducting-dielectric photonic crystals (HTcSD PCs). We have substituted the indium tin oxide as a front contact and antireflection coating in the conventional cell by HTcScD PCs. Also, we have substituted the back contact and the back reflector of the conventional cell construction by HTcScD PCs. The aim of these substitutions is to reduce the power dissipation in a thin film silicon solar cell. Numerical results of the proposed structure are obtained based on the transfer matrix method, the finite element method, and COMSOL Multiphysics software. The HTcScD PCs reduced the power dissipation in the thin film silicon solar cell due to the increase of the optical generation term of electron–hole pairs. Finally, using high temperature superconducting photonic crystals in photovoltaic applications is promising and may be of potential use in the future.
We have investigated optical properties of metallic photonic crystals using a standard transfer matrix method. The transfer matrix method for the resonant modes in MPC describes well the splitting of resonant modes and can forecasts the frequencies of split resonant modes in the transmission spectra of the multilayer metallic photonic crystals. Also we have showed that the optical properties of metallic photonic crystals multilayer can be enhanced significantly above the reciprocal metal. Moreover, we showed that the transmittance has a variation as a function of the electronic density of metals.