Molecular and particle-based self-assembly is of importance for studies in the fabrication of uniformly patterned functional surfaces, novel membranes, and delivery vehicles.[1±6] For example, self-assembly of molecular monolayers can be accomplished readily on a variety of flat metal or metal oxide substrates, or at the air/water interface, to give so-called selfassembled monolayers (SAMs).[7±17] When such monolayer assemblies bear functionality, crosslinking chemistries can be used to covalently link the monolayer into a network; [10±13] alternatively, polymerization chemistry can be performed from the surface of appropriately functionalized substrates to impart new properties through such grafting chemistry.[14±16]Relative to flat substrates or interfaces, the spherical surface of a droplet offers four times the surface area, provides greater access to the surrounding environment, and offers a means for encapsulation within a droplet. Nanoparticle assemblies on droplets represent, in many respects, ideal platforms for tuning capsule-environment interactions, as the ligands associated with each nanoparticle provide rich opportunities for tailored interfacial interactions and chemistries.[17±21] In addition, the fluid environment of the assembly provides opportunities for chemical modification of the nanoparticles from either fluid phase. Moreover, the use of nanoparticles rather than micrometer-sized particles for oil/water interfacial assembly leads to a weak dynamic confinement of the particles to the interface, enabling new opportunities to generate complex interfacial patterns.[22]A unique aspect associated with the interfacial assembly of nanoparticles in fluids is the highly mobile nature of the assembly, which gives a rapid diffusion within the interface, and a fast equilibration of the assembly. We have previously shown that tri-n-octylphosphine oxide (TOPO)-covered CdSe nanoparticles segregate to the toluene/water interface to reduce interfacial tension and minimize the Helmholtz free energy of the system. [18] This segregation is strongly size dependent, as larger particles cause a greater reduction in the interfacial energy per particle, and thus exhibit longer residence times at the interface.[23] Our experiments with TOPO-covered CdSe quantum dots revealed the weak nature of this nanoparticle interfacial assembly (a few k b T for particles in the 3±4 nm size range), which becomes even less stable with increasing temperature (e.g., for effecting reactive chemistry in the ligands associated with the nanoparticles). Thus, methods are needed to convert these nanoparticle-based assemblies into nanoparticle-based materials with appreciable mechanical integrity. Our previous efforts towards such structures utilized crosslinking chemistry on functionalized ligands attached to the nanoparticles. For example, on flat oil/water interfacial assemblies, freeradical-induced crosslinking of vinylbenzene-functionalized CdSe nanoparticles was performed successfully to give ultrathin sheets of nanoparticles.[17] ...
