molecules simultaneously, which facilitates coupling reactions of two or more molecules. [7][8][9] On the other hand, nanoscale heating can increase the speed of molecular reorganization and surface diffusion, thereby increasing the rate of favorable reactive encounters. Several important examples of plasmon-driven bond formation were demonstrated in recent years, [10,11] including CC bond formation in hydrocarbons, [7,12] Suzuki-Miyaura type reactions, [13] and molecular dimerization reactions by NN bond formation. [7,14,15] Until recently, the question if the dominating effect of plasmonic nanoparticles is to act as charge donors [16,17] or heat sources [14,18] has been heavily debated. Nowadays, most authors agree that depending on the reaction, one or the other effect can dominate. [19] For example, the dissociation of diatomic compounds on gold-particles, in particular of H 2 [1,20] and O 2 , [21,22] is likely determined by the transfer of energetic electrons, while the fragmentation of organic molecules, such as the decomposition of dicumyl-peroxide, [18] is rather dominated by the plasmon-mediated photo-heating. Although much progress has been made in understanding such dissociation reactions, our understanding of plasmon-driven multistep bond-formation processes is still in its infancy. In these reactions, different reaction steps might profit from the presence of plasmonic excitations. As a prominent example, the dimerization reaction of 4-nitrothiophenol (4NTP) to 4-4′-dimercaptoazobenzene (DMAB) was confirmed by many
