There Are Two Distinct Photon Gases Present Inside Every Solar Cell

It has gradually been recognized that incoming sunlight can be trapped within a high refractive index semiconductor, n~3.5, owing to the narrow 16degree escape cone. The solar light inside a semiconductor is 4n^2 times brighter than incident sunlight. This is called light trapping and has increased the theoretical and practical efficiency of solar panels. But there is a second photon gas of equal importance that has been overlooked. Inside every forward-biased solar cell there is a gas of infrared luminescence photons, also trapped by total internal reflection. We introduce the idea of super-equilibrium, when the luminescence photon gas freely exchanges energy with the two quasi-Fermi levels. Nonetheless, the loss of a single photon from either gas is equivalent to the loss of a precious minority carrier. Therefore optical modeling & design becomes equally important as electron-hole modeling in high efficiency solar cells. It becomes possible to approach the idealistic Shockley-Queisser limit, by proper material selection and design of the solar cell optics.