b S Supporting InformationH yperbranched polymers have attracted much interest because of their useful chemical and physical properties, resulting from their branching topology and a high number of end groups. 1À4 For a given weight concentration, their smaller hydrodynamic volume and functional periphery lead to a variety of current and potential applications, including their usages as coatings and resins additives, 5,6 viscosity modifiers, 7,8 and novel carriers. 4,9À11 Commonly, hyperbranched polymers are synthesized through the step-growth approach, such as polycondensation, addition step-growth reactions and cycloaddition, or the chain-growth approach, including the self-condensing vinyl copolymerization and the ring-opening multibranching polymerization. The detailed methodologies have been extensively reviewed. 1À4,12 Hyperbranched polymers with short subchains behave like small rigid and hard "balls" so that their properties are mainly related to their size. On the other hand, for hyperbranched polymers with longer subchains, proper microscopic conformation variation and entanglement can greatly affect their macroscopic properties. For example, the swollen and collapse of long subchains of a hyperbranched polymer additive in a solution or dispersion can alternate its macroscopic viscosity by a factor of hundreds. This is why the research and development of various hyperbranched polymers made of subchains longer than the entanglement length has attracted much attention in the past two decades. People coined different terms to describe them as Hyper-Macs, 13 arborescent graft polymers, 14 and dendrigrafts. 15 Using the chain-growth approach, Gnanou et al. 16 and Dworak et al. 17 tried to develop different techniques for the preparation of hyperbranched chains with a desired architecture. However, their methods involved a multistage and time-consuming process, inevitably resulting in broadly distributed subchains. While in the step-growth approach, AB 2 type of macromonomers can be interconnected into hyperbranched chains with a "controllable" architecture through polyesterification 18À20 and poly-Williamson coupling reaction 13 between two reactive A and B functional groups. Note that for a given weight concentration a solution of long initial macromonomer chains contains a very limited number of reactive A and B groups. In order to effectively couple them together, Pan et al. 21 utilized alkynylÀazide polycycloaddition to make hyperbranched polystyrene (PSt) chains with claimed short uniform subchains. On the other hand, Hutchings et al. 22 described an iterative convergent strategy to make dendritically branched chains using a multistaged Williamson coupling process.In reality, there exist two types of AB 2 macromonomers-Y-type: two reactive B groups are at one end and A is at the other end; seesaw-type: each chain end is attached with one reactive B group and A is in the middle. They lead to different topologies of hyperbranched polymers. Using Y-type macromonomers, some of B groups inevitably remain...
