Nanowire Solar Cell Above the Radiative Limit
Ksenia Korzun, Gabriel W. Castellanos, Dick K. G. de Boer, Jaime Gómez Rivas, J. E. M. Haverkort
Abstract
Abstract A lossless solar cell operating at the Shockley–Queisser limit generates an open circuit voltage ( V oc ) equal to the radiative limit. At V oc , the highly directional beam of photons from the sun is absorbed and subsequently externally re‐emitted into a 4π solid angle, providing a large photon entropy loss. A solar cell can beat the Shockley–Queisser limit and approach the 46.7% ultimate limit by decreasing the output solid angle of the light emission at open circuit conditions. Here, a design for an indium phosphide single nanowire solar cell capable to operate 159 mV above the radiative limit is presented. The spontaneous emission factor is first optimized into a guided mode of the nanowire toward 68%. The authors subsequently launch a guided mode at the bottom straight part of the tapered nanowire yielding a photon escape probability of 81% for a tapering angle of θ = 1.2° and a top facet with a radius of 83 nm. When assuming homogeneous light emission along the nanowire, an outcoupling efficiency of 42% of the emitted light is obtained. The final optimization is the reduction of the emission cone toward 11 × 10 −3 sr by focusing the guided mode with an external lens.