Air‐Processed Organic Photovoltaics for Outdoor and Indoor Use Based upon a Tin Oxide‐Perylene Diimide Electron Transporting Bilayer
Rahim Munir, Edward Cieplechowicz, Renaud Miclette Lamarche, Roman Chernikov, Simon Trudel, Gregory C. Welch
Abstract
Abstract Efficient organic photovoltaics (OPV) based on SnO 2 | perylene diimide (PDI) bilayer as an electron transport layer (ETL) is fabricated and tested in an ambient environment. The PTQ10:Y6 photoactive system is used as the primary bulk‐heterojunction. Without any surface treatment, the power conversion efficiency (PCE) of SnO 2 ‐based OPV devices is 1.5%. Treating the SnO 2 nano‐particles with UV‐ozone and then applying a layer of N‐annulated PDI with a functional NH bond (PDIN‐H) on top increase device PCEs to 9.2%. For indoor applications, the OPV device PCE rises from 8.1% to 12.3% when PDIN‐H is employed on SnO 2 and tested under low light conditions, without the need for light soaking. The SnO 2 | PDIN‐H ETL bilayer is slot‐die coated and corresponding OPV devices have a PCE of 7.9%, demonstrating utility for OPV scale‐up. The hybrid ETL is tested with other photoactive systems employing Y6, Y7, and IDIC as acceptors, as well as PM6 donor, and all these cases yield OPV devices with improved PCE when compared to OPV devices with SnO 2 ‐only ETLs. These results show the successful implementation of SnO 2 | PDIN‐H as an ETL for OPV.