Epitaxial GaInP/GaAs/Si Triple‐Junction Solar Cell with 25.9% AM1.5g Efficiency Enabled by Transparent Metamorphic Al<sub><i>x</i></sub>Ga<sub>1−<i>x</i></sub>As<sub><i>y</i></sub>P<sub>1−<i>y</i></sub> Step‐Graded Buffer Structures
Markus Feifel, David Lackner, Jonas Schön, Jens Ohlmann, Jan Benick, Gerald Siefer, Felix Predan, Martin Hermle, Frank Dimroth
Abstract
III–V/Si multi‐junction solar cells are potential successors to the silicon single‐junction cell due to their efficiency potential of up to 40% in the radiative limit. [1] Herein, latest results of epitaxially integrated GaInP/GaAs/Si triple‐junction cells are presented. To reduce parasitic absorption losses, which have limited the current density in the Si bottom cell in the previous devices, transparent Al x Ga 1– x As y P 1– y step‐graded metamorphic buffers are investigated. Compared with previous GaAs y P 1– y step‐graded buffers, the transmittance is enhanced significantly, while no significant impact on the threading dislocation density is observed. Implemented into a new triple‐junction solar cell, an increase in short‐circuit current density from 10.0 to 12.2 mA cm − 2 is achieved, leading to a new record conversion efficiency of 25.9% under AM1.5g conditions.