We report the chain conformations of polymer molecules accommodated at the solid-polymer melt interfaces in equilibrium. Polystyrene "Guiselin" brushes (adsorbed layers) with different molecular weights were prepared on Si substrates and characterized by using x-ray and neutron reflectivity. The results are intriguing to show that the adsorbed layers are composed of the two different nanoarchitectures: flattened chains that constitute the inner higher density region of the adsorbed layers and loosely adsorbed polymer chains that form the outer bulklike density region. In addition, we found that the lone flattened chains, which are uncovered by the additional prolonged solvent leaching (∼120 days), are reversibly densified with increasing temperature up to 150 °C. By generalizing the chain conformations of bulks, we postulate that the change in probabilities of the local chain conformations (i.e., trans and gauche states) of polymer molecules is the origin of this densification process.
The mixing behavior of the hole- and electron-transporting
materials in bulk heterojunction (BHJ) organic photovoltaic (OPV)
blends plays a key role in determining the nanoscale morphology, which
is believed to be a decisive factor in determining device performance.
We present a systematic investigation of the mixing behavior between
poly(3-hexylthiophene) (P3HT) and [6,6]-phenyl-C61-butyric acid methyl
ester (PCBM) in model multilayer structures. The bilayer structures
are composed of amorphous PCBM that is mechanically laminated to different
P3HT layers with varying degrees of crystallinity. We find that mixing
is significantly decreased as the crystallinity of P3HT is increased.
The mixing behavior can be explained as resulting from (1) nearly
complete miscibility of PCBM with amorphous P3HT (based on our results
from regiorandom P3HT) and (2) the existence of tie chains between
crystalline P3HT domains that restrain the swelling of the P3HT layer
by PCBM. We also introduce a unique PCBM–P3HT–PCBM trilayer
structure where one of the PCBM layers is highly crystalline. The
crystalline PCBM dramatically alters the mixing behavior. Initial
mixing of the amorphous PCBM into P3HT is followed by rapid cold crystallization
at the crystalline PCBM layer, which depletes the PCBM in the P3HT
layer. These bilayer and trilayer experiments illustrate that mixing
of P3HT and PCBM is influenced by multiple factors, such as the semicrystalline
nature of P3HT (overall crystallinity, characteristics of amorphous
chains) and phase (amorphous or crystalline) of the PCBM.
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