posted on 2021-09-08, 21:36authored byMichael
A. Anderson, Bryon W. Larson, Erin L. Ratcliff
State-of-the-art
organic photovoltaic (OPV) materials are composed
of complex, chemically diverse polymeric and molecular structures
that form highly intricate solid-state interactions, collectively
yielding exceptional tunability in performance and aesthetics. These
properties are especially attractive for semitransparent power-generating
windows or shades in living environments, greenhouses, or other architectural
integrations. However, before such a future is realized, a broader
and deeper understanding of property stability must be acquired. Stability
during operating and environmental conditions is critical, namely,
material color steadfastness, optoelectronic performance retention,
morphological rigidity, and chemical robustness. To date, no single
investigation encompasses all four distinct, yet interconnected, metrics.
Here, we present a multimodal strategy that captures a dynamic and
interconnected evolution of each property during the course of an
accelerated photobleaching experiment. We demonstrate this approach
across relevant length scales (from molecular to visual macroscale)
using X-ray photoelectron spectroscopy, grazing-incidence X-ray scattering,
microwave conductivity, and time-dependent photobleaching spectroscopies
for two high-performance semitransparent OPV blendsPDPP4T:PC60BM and PDPP4T:IEICO-4F, with comparisons to the stabilities
of the individual components. We present direct evidence that specific
molecular acceptor (fullerene vs nonfullerene) designs and the resulting
donor–acceptor interactions lead to distinctly different mechanistic
routes that ultimately arrive at what is termed “OPV degradation.”
We directly observe a chemical oxidation of the cyano endcaps of the
IEICO-4F that coincides with a morphological change and large loss
in photoconductivity while the fullerene acceptor-containing blend
demonstrates a significantly greater fraction of oxygen uptake but
retains 55% of the photoconductivity. This experimental roadmap provides
meaningful guidance for future high-throughput, multimodal studies,
benchmarking the sensitivity of the different analytical techniques
for assessing stability in printable active layers, independent of
complete device architectures.