posted on 2013-11-12, 00:00authored byCarson
J. Bruns, David J. Herman, Julian
B. Minuzzo, Jessica A. Lehrman, Samuel I. Stupp
Previous work has shown that nanoscale
lamellar inorganic–organic
hybrid materials can be synthesized on transparent conductive substrates
via the electrodeposition of Zn(OH)2 in the presence of
conjugated surfactants. These surfactants introduce p-type semiconducting supramolecular phases; thus, following conversion
of the Zn(OH)2 phase to the n-type semiconductor
ZnO, the lamellar hybrids exhibit high photoconductive gains and can
exhibit photovoltaic activity. We report here on a family of carboxylated
terthiophene-based surfactants designed with systematic modifications
to molecular geometry, valency, and flexibility to investigate how
these features affect the synthesis of the p-type/n-type semiconducting hybrid materials. We use scanning
electron microscopy (SEM) and two-dimensional (2D) grazing-incidence
X-ray diffraction (2D-GIXD) to correlate molecular features of the
surfactants with growth and orientation of the nanoscale lamellae
that form during electrodeposition on either hydrophilic or hydrophobic
substrates. We find that molecularly flexible, monovalent terthiophene
amphiphiles with linear geometries generate highly oriented and homogeneous
films of the nanoscale hybrids, whereas T-shaped geometries, rigid
molecules, or divalent surfactants tend to produce more heterogeneous
and isotropically oriented lamellae under the same conditions. The
critical aggregation concentrations (CAC) of the amphiphiles are higher
than the concentrations used during electrodeposition, indicating
that the growth and orientation of lamellar structures are mediated
by surfactant–substrate interactions, rather than the assemblies
they form in bulk solutions. Molecular design in these hybrid systems
is a key factor in optimizing function, since dense and macroscopically
oriented growth is necessary in both photoconductivity and photovoltaic
efficiency of solar cells.