Thermally Controlled On/Off Switch in a Living Anionic Polymerization of 1-Cyclopropylvinylbenzene with an Anion Migrated Ring-Opening Mechanism

Synthesis of Alternating Copolymers with Substituents Containing Heteroatoms and the Regulation of Nontraditional Intrinsic Luminescence

Compared with other sequence structure polymers, alternating polymers usually have several unique properties, but their properties are more sensitive to changes in structure. By investigating the relationship between the structure and properties of alternating polymer chains, polymers with desired properties can likely be synthesized. In this study, a series of alternating copolymers of 1,1-diphenylethylene (DPE) derivatives and styrene derivatives, which exhibit nontraditional intrinsic luminescence (NTIL), are synthesized using living anionic polymerization. By changing the bridge plane structure of the DPE derivatives and the substituent groups of the styrene derivatives, the rigid chain structure of the alternating copolymers containing styrene derivative with a large steric hindrance is altered, and this change is observed by the altered fluorescence properties. Based on the results from experimental tests and theoretical simulations, copolymers with bridge plane structures have higher fluorescence emission intensities; moreover, a balance is observed between the electronic and steric hindrance effects of substituents on the fluorescence intensities, and polymer chains that are too rigid cause a decrease in the fluorescence intensities. Thus, the influence of the chain structure on the fluorescence properties of NTIL polymers cannot be disregarded.

Vinylogous Anionic Ring-Opening Polymerization of Vinylidenecyclopropanes with Native C-H Bonds as the Dormant Species

Since its inception in 2023, the concept of "C-H bonds as the dormant species" to control chain growth has emerged as a promising, though still evolving, strategy for precision polymer synthesis. Beyond offering a simpler polymerization method, this concept is expected to promote unprecedented reaction pathways. In this study, we report the first vinylogous anionic ring-opening polymerization (ROP) of vinylidenecyclopropanes. Cooperative La(OTf)3/DBU catalysis, in conjunction with various sp3 and sp2 C-H bonds, has streamlined the synthesis of well-defined alkyne polymers, which are amenable to further chemical modifications. Control experiments and density functional theory (DFT) calculations provide insights into the origin of selectivity and the role of dormant C-H bonds in the reversible-deactivation equilibrium.

1,3-Pentadiene-Assistant Living Anionic Terpolymerization: Composition Impact on Kinetics and Microstructure Sequence Primary Analysis

The combination of a living anionic technology and a unique alternating strategy provided an exciting opportunity to prepare novel and well-defined poly(1,3-pentadiene-co-syrene-co-1,1-diphenylethylene) resins consisting of three alternating sequences of modules (A/B/C zwitterions). "A" being Styrene (St)/1,3-pentadiene (PD), "B" being diphenylethylene (DPE)/PD, "A" being DPE/St, respectively, A wide composition range of new polyolefin resins, i.e., poly (A-co-B), poly (A-co-C), and poly (B-co-C), with controlled molecular weight and very narrow molecular weight and composition distributions have been prepared by a one-pot living characteristic method. In the section of kinetic analysis, the terpolymer yields and kinetic parameters were strongly dependent on the feed/comonomer ratio as well as the content of the alternating structure. The competition copolymerization behaviors of A/B, B/C, and A/C were studied in detail in this work. By contrast, the microstructure and the thermal property of the resulting terpolymer were investigated via Nuclear magnetic resonance (NMR) and Differential scanning calorimetry (DSC) analysis. The results of 1H NMR tracking the change of [Aromatic ring]/[C=C] value indicated the distinctive copolymer-ization behavior of the selective "alternating-modules". The glass transition temperature (T_g) was very sensitive to the terpolymer composition. By contrast to poly(A-ran-B) with only one obvious T_g, there were two T_gs in the A/C and B/C copolymerization cases. Moreover, the desirable high T_g ~ 140 °C resin was limited to the terpolymers with up to 50 mol % DPE. Finally, the "ABC-X" mechanism was proposed to interpret the unique terpolymerization behavior, which belongs to the classical "bond-forming initiation" theory.

Quo Vadis Carbanionic Polymerization?

Living anionic polymerization will soon celebrate 70 years of existence. This living polymerization is considered the mother of all living and controlled/living polymerizations since it paved the way for their discovery. It provides methodologies for synthesizing polymers with absolute control of the essential parameters that affect polymer properties, including molecular weight, molecular weight distribution, composition and microstructure, chain-end/in-chain functionality, and architecture. This precise control of living anionic polymerization generated tremendous fundamental and industrial research activities, developing numerous important commodity and specialty polymers. In this Perspective, we present the high importance of living anionic polymerization of vinyl monomers by providing some examples of its significant achievements, presenting its current status, giving several insights into where it is going (Quo Vadis) and what the future holds for this powerful synthetic method. Furthermore, we attempt to explore its advantages and disadvantages compared to controlled/living radical polymerizations, the main competitors of living carbanionic polymerization.

Introducing a 1,1-diphenylethylene analogue for vinylpyridine: anionic copolymerisation of 3-(1-phenylvinyl)pyridine (m-PyPE)

3-(1-Phenylvinyl)pyridine is a structural analogue of 1,1-diphenylethylene, with one phenyl group replaced by pyridine. Its suitability for the random copolymerisation with vinylpyridine is demonstrated and the resulting copolymers are characterized.