Achieving a Record Fill Factor for Silicon–Organic Hybrid Heterojunction Solar Cells by Using a Full‐Area Metal Polymer Nanocomposite Top Electrode

Carrier collection in conventional n‐type Si (n‐Si)/organic hybrid heterojunction solar cells (HHSCs) is mainly limited by the nonoptimized top grid‐electrode and inadequate work function (WF) of the PH1000‐type poly(3,4‐ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS). Here, a novel modified metal polymer nanocomposite top electrode (M‐MPNTE) is designed to achieve a full‐area carrier collection in n‐Si/PEDOT:PSS HHSCs. The carrier collection in both lateral and vertical directions is significantly improved by the introduction of an ultrathin Au/MoO x modified layer between 6 nm ultrathin Ag film and AI4083‐type PEDOT:PSS layer. In addition, the carrier separation is boosted by the enhanced built‐in potential owing to a high WF of M‐MPNTE, which also suppresses the carrier recombination at the surface of n‐Si. Due to these collaborative improvements, a record fill factor of 80.21% is obtained, which is even comparable to the best value of the traditional Si‐based solar cells. With the addition of a MoO x antireflective coating layer on top of M‐MPNTE, the short‐circuit current density and open‐circuit voltage are finally increased to 23.13 mA cm −2 and 621.07 mV, respectively, yielding a power conversion efficiency of 10.82%. The finding suggests a novel strategy for the development of highly efficient HHSCs with ideal carrier transport mechanism.