Asymmetric photocurrent extraction in semitransparent laminated flexible organic solar cells
Artikel i vetenskaplig tidskrift, 2018

Scalable production methods and low-cost materials with low embodied energy are key to success for organic solar cells. PEDOT(PSS) electrodes meet these criteria and allow for low-cost and all solution-processed solar cells. However, such devices are prone to shunting. In this work we introduce a roll-to-roll lamination method to construct semitransparent solar cells with a PEDOT(PSS) anode and an polyethyleneimine (PEI) modified PEDOT(PSS) cathode. We use the polymer:PCBM active layer coated on the electrodes as the lamination adhesive. Our lamination method efficiently eliminates any shunting. Extended exposure to ambient degrades the laminated devices, which manifests in a significantly reduced photocurrent extraction when the device is illuminated through the anode, despite the fact that the PEDOT(PSS) electrodes are optically equivalent. We show that degradation-induced electron traps lead to increased trap-assisted recombination at the anode side of the device. By limiting the exposure time to ambient during production, degradation is significantly reduced. We show that lamination using the active layer as the adhesive can result in device performance equal to that of conventional sequential coating.

Författare

J. Bergqvist

Linköpings universitet

Thomas Österberg

Linköpings universitet

A. Melianas

Linköpings universitet

Luis Ever Aguirre

Linköpings universitet

Z. Tang

Technische Universität Dresden

Wanzhu Cai

Linköpings universitet

Z. F. Ma

Technische Universität Dresden

M. Kemerink

Linköpings universitet

Desta Antenehe Gedefaw

Flinders University

Mats Andersson

Chalmers, Kemi och kemiteknik, Tillämpad kemi

Flinders University

O.W. Inganäs

Linköpings universitet

npj Flexible Electronics

23974621 (eISSN)

Vol. 2 1 4

Ämneskategorier

Textil-, gummi- och polymermaterial

Annan kemiteknik

Annan kemi

DOI

10.1038/s41528-017-0017-6

Mer information

Senast uppdaterat

2020-09-15