Litcius/Paper detail

Impact of Semiconductor Band Tails and Band Filling on Photovoltaic Efficiency Limits

Joeson Wong, Stefan T. Omelchenko, Harry A. Atwater

2020ACS Energy Letters97 citationsDOIOpen Access PDF

Abstract

Since the seminal work of Shockley and Queisser, assessing the detailed balance between absorbed and emitted radiative fluxes from a photovoltaic absorber has been the standard method for evaluating solar cell efficiency limits. The principle of detailed balance is one dictated by reciprocity and steady state, so that photons can be absorbed and emitted with equal probability. This basic principle has also been extended to evaluate the effects of multiple junctions, hot carriers, nanostructured geometries, multiexciton generation, subunity radiative efficiency, and many other solar cell configurations and nonidealities to estimate limiting efficiencies via modifications to the detailed balance model.

Topics & Concepts

SemiconductorDetailed balanceBand gapOptoelectronicsMaterials scienceTheory of solar cellsSolar cellDirect and indirect band gapsPhotoluminescenceSpontaneous emissionPhotovoltaic systemMultiple exciton generationWide-bandgap semiconductorAbsorption (acoustics)Radiative transferThermalOpticsElectronic band structureSolar cell efficiencyEnergy conversion efficiencyEnhanced Data Rates for GSM EvolutionAbsorption edgeDensity of statesSolar energyAbsorbanceLimit (mathematics)PhotovoltaicsPhysicsPhotovoltaic effectsolar cell performance optimizationSilicon and Solar Cell TechnologiesChalcogenide Semiconductor Thin Films