An iron-cyclopentadienyl bond cleavage mechanism for the thermal ring-opening polymerization of dicarba[2]ferrocenophanes

Abstract: In order to gain insight into the mechanism for the thermal ring-opening polymerization of strained dicarba [2]ferrocenophanes, the thermal reactivity of selected examples of these species with different substitution patterns has been explored. When heated at 300 C dicarba[2]ferrocenophanes meso/rac-[Fe(h 5 -C 5 H 4 ) 2 (CHPh) 2 ] (meso/rac-7) and meso-[Fe(h 5 -C 5 H 4 ) 2 (CHCy) 2 ] (meso-13) were found to isomerize or to undergo disproportionation, respectively. These processes are apparently general for dic… Show more

“…The thermal reactivity pathways proved consistent for other dicarba[2] ferrocenophanes with similar aryl and alkyl substituents on the dicarba-bridge. [17].…”

“…NaCp) which do not attack at Si [15]. Furthermore, as discussed in the previous section, cleavage of the bridge EeE bond has been demonstrated for a variety of [2]metallocenophanes [1f, 16,17,22], Until recently, the reactivity modes of [n]metallocenophanes were confined to these aforementioned bond-cleavage processes, with the concomitant release of molecular ring-strain. However, in a recent report a new mode of [n]metallocenophane reactivity based on metalemetal bond formation was elucidated.…”

“…A further investigation into the mechanism of thermal ROP was subsequently conducted in which copolymerization experiments were performed using a series of dicarba[2]ferrocenophanes known to undergo thermal ROP [17]. Thus, mixtures of 8 and 10, and also of 10 and the isotopically labelled analogue d 4 -8 [Fe(h 5 -C 5 H 4 )(CD 2 ) 2 ], were exposed to standard thermolysis conditions, affording random, cyclic copolymeric products of moderate molecular weight and with a broad molecular weight distribution, which is typical of PFE homopolymers isolated via this route (M w ¼ 4800e96,000 Da, PDI ¼ 1.1e3.6) [15,19].…”

Recent developments with strained metallocenophanes

“…The thermal reactivity pathways proved consistent for other dicarba[2] ferrocenophanes with similar aryl and alkyl substituents on the dicarba-bridge. [17].…”

“…NaCp) which do not attack at Si [15]. Furthermore, as discussed in the previous section, cleavage of the bridge EeE bond has been demonstrated for a variety of [2]metallocenophanes [1f, 16,17,22], Until recently, the reactivity modes of [n]metallocenophanes were confined to these aforementioned bond-cleavage processes, with the concomitant release of molecular ring-strain. However, in a recent report a new mode of [n]metallocenophane reactivity based on metalemetal bond formation was elucidated.…”

“…A further investigation into the mechanism of thermal ROP was subsequently conducted in which copolymerization experiments were performed using a series of dicarba[2]ferrocenophanes known to undergo thermal ROP [17]. Thus, mixtures of 8 and 10, and also of 10 and the isotopically labelled analogue d 4 -8 [Fe(h 5 -C 5 H 4 )(CD 2 ) 2 ], were exposed to standard thermolysis conditions, affording random, cyclic copolymeric products of moderate molecular weight and with a broad molecular weight distribution, which is typical of PFE homopolymers isolated via this route (M w ¼ 4800e96,000 Da, PDI ¼ 1.1e3.6) [15,19].…”

Recent developments with strained metallocenophanes

“…40 A rationale for the differences in thermal reactivity based on the structural changes that result from differing bridge substitution has been proposed. 40 Species 37−40, with an equal number of non-hydrogen substituents on each carbon of the bridge, possess longer C−C bridge bonds relative to species 34 and 41, which have one or zero non-hydrogen substituent, respectively. Thus, for species 35 and 37−39, weakening of the C−C bridge bond, in combination with the ability of bridge substituents to stabilize the radical intermediates formed from where one or zero non-hydrogen substituent is present, the C−C bond is relatively short, hypothetical radical intermediates formed from homolytic C−C cleavage are not stabilized, and thermal ROP occurs via a heterolytic Fe−Cp bond cleavage mechanism to afford polyferrocenylethylene products.…”

Strained Ferrocenophanes

“…The versatility of ROP is also evident from the numerous spacers that can be incorporated in the polymeric main chain through this technique. These spacers that include single atom spacers such as Si, P, B, Sn, S, Ge, Ga, Al, Se; two‐atom spacers such as C–C, C–P, C–Si, C–S, C–Ge, C–Sn; as well as a four‐atom butadienylene spacer, affect the properties of macromolecules. For instance, reaction of dilithioferrocene ( 90 ) with the gallium dichloride ( 91 ) yielded the strained gallium‐bridged ferrocenophane ( 92 ), which spontaneously underwent ROP to afford the poly(ferrocenylgallane) ( 93 ) (Scheme ) .…”

Sandwich Complex‐Containing Macromolecules: Property Tunability Through Versatile Synthesis