Influence of Environmentally Affected Hole Transport Layers on Spatial Homogeneity and Charge Transport Dynamics of Organic Solar Cells
Huei -Ting Chien, Florian Pilat, Thomas Griesser, Harald Fitzek, Peter, Poelt, Bettina Friedel

TL;DR
This study investigates how environmental exposure affects hole transport layers in organic solar cells, revealing humidity-induced degradation impacts device performance and spatial homogeneity.
Contribution
It compares traditional PEDOT:PSS and MoO3 HTLs under environmental stress, highlighting humidity's role in device degradation and interface stability.
Findings
Humidity exposure decreases device performance due to water absorption.
PEDOT:PSS shows micro-delamination after humid air exposure.
MoO3 HTL also affected by humidity, but to a lesser extent.
Abstract
After the efficiency of organic photovoltaic (OPV) cells achieved more than 10%, the control of stability and degradation mechanisms of solar cells became a prominent task. The improvement of device efficiency due to incorporation of a hole-transport layer (HTL) in bulk-heterojunction solar cells has been extensively reported. However, the most widely used HTL material, PEDOT:PSS is frequently suspected to be the dominating source for devices instability under environmental conditions. Thereby effects like photooxidation and electrode corrosion are often reported to shorten device lifetime. However, often in environmental device studies, the source of degradation, whether being from the HTL, the active layer or the metal cathode are rather difficult to distinguish, because the external diffusion of oxygen and water affects all components. In this study, different HTLs, namely prepared…
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