posted on 2017-03-15, 00:00authored byBailey E. Risteen, Alyssa Blake, Michael A. McBride, Cornelia Rosu, Jung Ok Park, Mohan Srinivasarao, Paul S. Russo, Elsa Reichmanis
Cellulose
nanocrystals (CNCs) are bioderived, rodlike particles that form a
chiral nematic liquid crystal (LC) in water. In this work, CNCs were
used to induce long-range order in a semiconducting polymer, poly[3-(potassium-4-butanoate)
thiophene-2,5-diyl] (PPBT). When mixed with CNCs, it was found that
PPBT was incorporated into the liquid crystal “template”
to form ordered structures with highly birefringent domains, as observed
under polarized light. We show that the π–π interactions
between polymer chains, which contribute considerably to the energetics
of the semiconducting system, are directly influenced by the presence
and packing of the liquid crystal phase. Upon increasing the concentration
of CNCs from the isotropic to chiral nematic regime, we observe a
bathochromic shift in the UV–vis spectra and the emergence
of the 0–0 vibrational peak, suggesting enhanced π–π
stacking leading to chain coplanarization. Furthermore, the chiral
nature of the PPBT/CNC mixture was evidenced by a negative peak in
circular dichroism (CD) spectroscopy, promoting the notion that the
polymer chains followed the helicoidal twist of the chiral nematic
liquid crystal host. At high temperatures, the peak height ratios
and overall intensities of the UV–vis and CD spectra associated
with PPBT decreased as the chiral nematic pitch grew larger in size.