Living Anionic Polymerization of 4‐(1‐Adamantyl)‐α‐Methylstyrene

Abstract: the living fashions to give the polymers of well-defined chain structures. It is noteworthy that the glass transition temperatures (T g s) of poly(AdS) and poly(Ad2S) are 234 and 232 °C. These T g values of the adamantyl-substituted polystyrenes are significantly higher than that of the parent polystyrene (T g = 100 °C). The highly symmetrical alicyclic adamantyl group has a negligible reactivity toward various chemical reagents, but it shows the drastic effect on enhancing the thermal properties of the result… Show more

“…However, the fabrication of hydrocarbon polymers with high service temperature (Tg > 250 °C) remains a challenge. Hydrogenated poly(1,3‐cyclohexadiene) (Tg = 231 °C), hydrogenated high‐molecular‐weight polyindene (Tg = 267 °C), and poly(4‐(1‐adamantyl)‐α‐methylstyrene) (Tg = 274 °C) are hydrocarbon polymers with desirable temperature capabilities reported previously.…”

“…[9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25] However, the fabrication of hydrocarbon polymers with high service temperature (Tg > 250 °C) remains a challenge. Hydrogenated poly(1,3cyclohexadiene) (Tg = 231 °C), [26] hydrogenated high-molecular-weight polyindene (Tg = 267 °C), [27] and poly(4-(1-adamantyl)α-methylstyrene) (Tg = 274 °C) [8] are hydrocarbon polymers with desirable temperature capabilities reported previously.However, further increasing the Tg values of the aforementioned polymers by using only one strategy is difficult. Previously, we proposed a method combining strategies (2) and (3) to noticeably increase the Tg of hydrocarbon polymers.…”

“…Increasing efforts have been made to prepare high‐temperature hydrocarbon polymers in recent years. These strategies have involved: 1) the enhancement of the tacticity of the polymer chain, 2) the incorporation of bulky pendant groups in the side chain, and 3) the introduction of cyclic structures in the main chain . However, the fabrication of hydrocarbon polymers with high service temperature (Tg > 250 °C) remains a challenge.…”

“…Increasing efforts have been made to prepare high-temperature hydrocarbon polymers in recent years. These strategies have involved: 1) the enhancement of the tacticity of the polymer chain, [4,5] 2) the incorporation of bulky pendant groups in the side chain, [6][7][8] and 3) the introduction of cyclic structures in the 3,4-structure content reached 94% as determined from the 1 H NMR spectrum according to previous study [29] (Figure 1A), and this was also indicated by its 13 C NMR spectrum ( Figure S2, Supporting Information). The Tg of this P(1-PB) prepolymer was 82 °C.…”

Extremely High Glass Transition Temperature Hydrocarbon Polymers Prepared through Cationic Cyclization of Highly 3,4‐Regulated Poly(Phenyl‐1,3‐Butadiene)

“…However, the fabrication of hydrocarbon polymers with high service temperature (Tg > 250 °C) remains a challenge. Hydrogenated poly(1,3‐cyclohexadiene) (Tg = 231 °C), hydrogenated high‐molecular‐weight polyindene (Tg = 267 °C), and poly(4‐(1‐adamantyl)‐α‐methylstyrene) (Tg = 274 °C) are hydrocarbon polymers with desirable temperature capabilities reported previously.…”

“…[9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25] However, the fabrication of hydrocarbon polymers with high service temperature (Tg > 250 °C) remains a challenge. Hydrogenated poly(1,3cyclohexadiene) (Tg = 231 °C), [26] hydrogenated high-molecular-weight polyindene (Tg = 267 °C), [27] and poly(4-(1-adamantyl)α-methylstyrene) (Tg = 274 °C) [8] are hydrocarbon polymers with desirable temperature capabilities reported previously.However, further increasing the Tg values of the aforementioned polymers by using only one strategy is difficult. Previously, we proposed a method combining strategies (2) and (3) to noticeably increase the Tg of hydrocarbon polymers.…”

“…Increasing efforts have been made to prepare high‐temperature hydrocarbon polymers in recent years. These strategies have involved: 1) the enhancement of the tacticity of the polymer chain, 2) the incorporation of bulky pendant groups in the side chain, and 3) the introduction of cyclic structures in the main chain . However, the fabrication of hydrocarbon polymers with high service temperature (Tg > 250 °C) remains a challenge.…”

“…Increasing efforts have been made to prepare high-temperature hydrocarbon polymers in recent years. These strategies have involved: 1) the enhancement of the tacticity of the polymer chain, [4,5] 2) the incorporation of bulky pendant groups in the side chain, [6][7][8] and 3) the introduction of cyclic structures in the 3,4-structure content reached 94% as determined from the 1 H NMR spectrum according to previous study [29] (Figure 1A), and this was also indicated by its 13 C NMR spectrum ( Figure S2, Supporting Information). The Tg of this P(1-PB) prepolymer was 82 °C.…”

Extremely High Glass Transition Temperature Hydrocarbon Polymers Prepared through Cationic Cyclization of Highly 3,4‐Regulated Poly(Phenyl‐1,3‐Butadiene)

“…Of the branched alkanes, diamondoids are highly symmetric and polycyclic, with a molecular geometry superimposable on the diamond lattice, and the smallest diamondoid, adamantane (tricyclo [3.3.1.13,7]decane), exhibits a remarkably high melting point above 220 C. 7 When incorporated as a pendant group in a range of olefins, [8][9][10][11][12][13][14][15][16][17][18] adamantane has imparted unique thermal and oxidative stability, low surface energy, high density and hydrophobicity, high refractive index and UV-transparency to polymers. 8,10,12 Tunable T g s have been observed by statistical copolymerizations varying the proportions of adamantyl-modified monomers with their parent monomers.…”

Dienes and diamondoids: poly(2‐[1‐adamantyl]‐1,3‐butadiene) and random copolymers with isoprene via redox‐emulsion polymerization and their hydrogenation

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