In the last few decades,
the attention of scientific community
has been driven toward the research on renewable energies. In particular,
the photovoltaic (PV) thin-film technology has been widely explored
to provide suitable candidates as top cells for tandem architectures,
with the purpose of enhancing current PV efficiencies. One of the
most studied absorbers, made of earth-abundant elements, is kesterite
Cu
2
ZnSnS
4
(CZTS), showing a high absorption
coefficient and a band gap around 1.4–1.5 eV. In particular,
thanks to the ease of band-gap tuning by partial/total substitution
of one or more of its elements, the high-band-gap kesterite derivatives
have drawn a lot of attention aiming to find the perfect partner as
a top absorber to couple with silicon in tandem solar cells (especially
in a four-terminal architecture). In this work, we report the effects
of the substitution of tin with different amounts of germanium in
CZTS-based solar cells produced with an extremely simple sol–gel
process, demonstrating how it is possible to fine-tune the band gap
of the absorber and change its chemical–physical properties
in this way. The precursor solution was directly drop-cast onto the
substrate and spread with the aid of a film applicator, followed by
a few minutes of gelation and annealing in an inert atmosphere. The
desired crystalline phase was obtained without the aid of external
sulfur sources as the precursor solution contained thiourea as well
as metal acetates responsible for the in situ coordination and thus
the correct networking of the metal centers. The addition of KCl in
dopant amounts to the precursor solution allowed the formation of
well-grown compact grains and enhanced the material quality. The materials
obtained with the optimized procedure were characterized in depth
through different techniques, and they showed very good properties
in terms of purity, compactness, and grain size. Moreover, solar-cell
prototypes were produced and measured, exhibiting poor charge extraction
due to heavy back-contact sulfurization as studied in depth and experimentally
demonstrated through Kelvin probe force microscopy.
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