posted on 2021-12-22, 20:44authored byMary K. Danielson, Jie Chen, Anna K. Vaclavek, Nathan D. Colley, Abdul-Haq Alli, Richard A. Loomis, Jonathan C. Barnes
Bipyridiniums, also
known as viologens, are well-documented electron
acceptors that are generally easy to synthesize on a large scale and
reversibly cycle between three oxidation states (V2+, V•+, and V0). Accordingly, they have been
explored in a number of applications that capitalize on their dynamic
redox chemistry, such as redox-flow batteries and electrochromic devices.
Viologens are also particularly useful in photoinduced electron transfer
(PET) processes and therefore are of interest in photovoltaic applications
that typically rely on electron-rich donors like polythiophene (PTh).
However, the PET mechanism and relaxation dynamics between interfacing
PTh and viologen-based thin films has not been well studied as a function
of thickness of the acceptor layer. Here, a novel, bilayered thin
film composite was fabricated by first spin-coating PTh onto glass
slides, followed by spin-coating and curing polyviologen (PV)-based
micron-sized films of variable thicknesses (0.5–11.3 μm)
on top of the PTh layer. The electron-transfer mechanism and relaxation
dynamics from the PTh sublayer into the upper PV film were investigated
using femtosecond transient absorption (fTA) spectroscopy and electrochemistry
to better understand how the charge-transfer/relaxation lifetimes
could be extended using thicker PV acceptor films. The fTA experiments
were performed under inert N2 conditions as well as in
ambient O2. The latter shortened the lifetimes of the electrons
in the PV layer, presumably due to O2 triplet-based trap
sites. Contact angle measurements using H2O and MeI were
also performed on top of the bilayered films to measure changes in
surface free energy that would aid the assessment related to efficiency
of the combined processes involving light penetration, photoexcitation,
electron mobility, and relaxation from within the bilayered thin films.
Insights gained from this work will support the development of future
devices that employ viologen-based materials as an alternative electron-acceptor
that is both easily processable and scalable.