Litcius/Paper detail

Black Ultra‐Thin Crystalline Silicon Wafers Reach the 4<i>n</i><sup>2</sup> Absorption Limit–Application to IBC Solar Cells

M. Garín, Toni P. Pasanen, Gema López, Ville Vähänissi, Kexun Chen, Isidro Martín, Hele Savin

2023Small16 citationsDOIOpen Access PDF

Abstract

Abstract Cutting costs by progressively decreasing substrate thickness is a common theme in the crystalline silicon photovoltaic industry for the last decades, since drastically thinner wafers would significantly reduce the substrate‐related costs. In addition to the technological challenges concerning wafering and handling of razor‐thin flexible wafers, a major bottleneck is to maintain high absorption in those thin wafers. For the latter, advanced light‐trapping techniques become of paramount importance. Here we demonstrate that by applying state‐of‐the‐art black‐Si nanotexture produced by DRIE on thin uncommitted wafers, the maximum theoretical absorption (Yablonovitch's 4 n 2 absorption limit), that is, ideal light trapping, is reached with wafer thicknesses as low as 40, 20, and 10 µm when paired with a back reflector. Due to the achieved promising optical properties the results are implemented into an actual thin interdigitated back contacted solar cell. The proof‐of‐concept cell, encapsulated in glass, achieved a 16.4% efficiency with an J SC = 35 mA cm − 2 , representing a 43% improvement in output power with respect to the reference polished cell. These results demonstrate the vast potential of black silicon nanotexture in future extremely‐thin silicon photovoltaics.

Topics & Concepts

WaferBlack siliconPhotovoltaicsMaterials scienceOptoelectronicsSiliconSolar cellPlasmonic solar cellSubstrate (aquarium)Absorption (acoustics)Thin filmCrystalline siliconOpticsPhotovoltaic systemNanotechnologyPolymer solar cellElectrical engineeringComposite materialPhysicsGeologyEngineeringOceanographyThin-Film Transistor TechnologiesSilicon and Solar Cell TechnologiesNanowire Synthesis and Applications