We report the mechanism of the concentration-dependent
self-assembly
of a tetrapeptide. Peptide Boc-Trp-Leu-Trp-Leu-OMe self-assembles
to form discrete nanospheres at a low concentration. Tryptophan side
chains point outwards of the nanospheres while leucine side chains
point towards the core of the nanospheres. The nanospheres fuse together
to become microspheres with the increase in the peptide concentration.
At higher concentrations of the peptide, the microspheres start clustering.
This is stabilized by the aromatic interactions between the side chains
of the tryptophan residues that cover the outer surface of the peptide
microspheres. In addition to behaving like the conventional hollow
sphere-based drug delivery vehicles which entraps the drug and performs
stimuli-responsive release, this prototype can interact, stabilize,
and intercalate hydrophobic dye carboxyfluorescein and anti-cancer
drug curcumin even on the surface through aromatic interactions. The
dye/drug can be released in acidic pH and in the presence of physiologically
relevant ions such as potassium.
Although glassy relaxation is typically associated with disorder, here we report on a new type of glassy dynamics relating to dislocations within 2-D crystals of colloidal dimers. Previous studies have demonstrated that dislocation motion in dimer crystals is restricted by certain particle orientations. Here, we drag an optically trapped particle through such dimer crystals, creating dislocations. We find a two-stage relaxation response where initially dislocations glide until encountering particles that cage their motion. Subsequent relaxation occurs logarithmically slowly through a second process where dislocations hop between caged configurations. Finally, in simulations of sheared dimer crystals, the dislocation mean squared displacement displays a caging plateau typical of glassy dynamics. Together, these results reveal a novel glassy system within a colloidal crystal.
Shape anisotropy of colloidal nanoparticles has emerged as an important design variable for engineering assemblies with targeted structure and properties. In particular, a number of polyhedral nanoparticles have been shown to exhibit a rich phase behavior [Agarwal et al., Nature Materials, 2011, 10, 230]. Since real synthesized particles have polydispersity not only in size but also in shape, we explore here the phase behavior of binary mixtures of hard convex polyhedra having similar sizes but different shapes. Choosing representative particle shapes from those readily synthesizable, we study in particular four mixtures: (i) cubes and spheres (with spheres providing a non-polyhedral reference case), (ii) cubes and truncated octahedra, (iii) cubes and cuboctahedra, and (iv) cuboctahedra and truncated octahedra. The phase behavior of such mixtures is dependent on the interplay of mixing and packing entropy, which can give rise to miscible or phase-separated states. The extent of mixing of two such particle types is expected to depend on the degree of shape similarity, relative sizes, composition, and compatibility of the crystal structures formed by the pure components. While expectedly the binary systems studied exhibit phase separation at high pressures due to the incompatible pure-component crystal structures, our study shows that the essential qualitative trends in miscibility and phase separation can be correlated to properties of the pure components, such as the relative values of the order-disorder transition pressure (ODP) of each component. Specifically, if for a mixture A+B we have that ODP B
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