Reversible stimuli-responsive self-assembly systems, particularly those involving photo-controlled assemblies and disassemblies, have attracted much attention over recent years, due to their diverse potentials in the fi elds of drug delivery, [ 1 ] switchable catalysis, [ 2 ] tunable sol-gel transition [ 3 ] and so forth. Various building blocks containing photo-responsive groups, [ 4 ] such as metal and metal oxide nanoparticles, [ 5 ] silica microspheres, [ 6 ] and polymers, [ 7 ] as well as small molecules, [ 3 , 8 ] were used to induce aggregation and dispersion in solution in response to the light stimulus. However, the integration of the smart response with specialized functions in a single system still remains a challenge. Polyoxometalates (POMs) as a class of nanoscale inorganic polyanionic clusters possess versatile properties in catalysis, redox reactions, medicines, etc . [ 9 ] The surface modifi cation with organic cations through electrostatic interactions makes possible the ready integration of various additional functional properties into POMs, [ 10 ] in addition to the improvement of the solubility in weakly polar solvents and the structural stability for diverse chemical environments as well as the promotion of catalytic reaction effi ciency. [ 11 ] In contrast to that only giant POMs are found to show self-assembling behavior in water, [ 12 ] most of these surfactant-encapsulated POM (SEP) and covalent hybrid complexes can self-assemble in organic media and the states at which they exist are dominated by the nature of solvents, [ 11a , 13 ] the amphiphilicity and structure of surfactants, as well as the size and charge density of POMs. [ 14 ] Up to date, none of these complexes have been found to undergo reversible assembly and disassembly processes, although they are very important in governing the catalytic and separation performance of the POM-based catalysts. To realize the high effi cient catalysis of water insoluble substrates, POMs were usually transferred into organic phase through a hydrophobic surface modifi cation of organic cations. In some reaction systems, the control for the reaction process is critical. Up to date, almost all the controllable POM catalyzed reactions depend on the additional chemicals, the oxidant exhaustion, or the temperature control. [ 15 ] It is found that the catalysis and catalytic effi ciency of POMs in organic phase are still strongly relied on their existing states. If one can control the catalytic reactions of POMs through the responsive assembly and disassembly, POMs will become more useful catalysts in some specifi c systems, such as microfl uid, patterned local reactions and catalyst separations. It is usually critical to introduce responsive groups into the SEPs for smart and switchable assemblies. [ 16 ] Considering that light can offer a convenient pathway for the direct modulation of the assembled state of SEPs without introducing chemical additives, it is of interest to develop photo-responsive SEPs for the fabrication of POM-based functional m...
