Cyclopentadiene-Maleimide Platform for Thermally Reversible Polymers

Stegall, Jeremy Brent

04 December 2014

This dissertation describes a new platform for the synthesis of thermally reversible polymers, based on Diels-Alder reactions of bis-cyclopentadienes (bis-CPDs) and bis-maleimides (bis-MIs), that meets two main objectives. First, the bis-CPD must resist characteristic self-coupling. Second, the CPD-MI adducts should undergo the retro-Diels-Alder (rDA) reaction (i.e., thermal depolymerization) in a temperature regime that is comparable or slightly higher than that of the freely reversible bis-furan/bis-MI polymers (rDA between 80 °C and 130 °C) but much lower than that of bis-CPD homopolymers (rDA above 160 °C). Structure-reactivity relationships gleaned from the literature and from related but as yet unpublished work in our own laboratories led to our main hypothesis that a CPD moiety bearing one sterically encumbering substituent such as isopropyl (𝑖Pr) or tert-butyl (𝑡Bu) and one electronwithdrawing substituent such as perfluoroaryl would have the desired reactivity and adduct stability in combination with an 𝑁-substituted maleimide. Synthetic considerations led to a bisCPD monomer design in which two alkylcyclopentadiene groups (alkyl = 𝑖Pr or 𝑡Bu) are connected by an octafluorobiphenylene linker. As an initial fundamental step (Chapter 3), 1-(nonafluorobiphenyl-4’-yl)-4-tertbutylcyclopentadiene (1) was synthesized to provide a monofunctional model for the proposed difunctional CPD monomer. Reactions of 1 and 𝑁-(4-fluorophenyl)maleimide (FMI) afforded up to five regio- and stereo-isomeric adducts (of fourteen possible). Variable-temperature reactivity studies combined with NMR spectroscopic analysis, X-ray crystallography, and computational modeling enabled product distributions to be understood according to a conventional kinetic-vs- iii thermodynamic framework. These studies also predicted the microstructure of polymers derived from the proposed bis-CPD monomer, which is structurally analogous to 1, and bis-MIs. Moreover, 1 does not undergo DA self-coupling under ordinary conditions (T < 180 °C). Thermolysis studies of the major adducts revealed that the rDA becomes observable on a laboratory timescale (hours) at about 140 °C, which is at the upper end of the temperature range reported for furan+MI adducts but well below that of CPD+CPD adducts. In contrast, adducts formed from either of the analogous monosubstituted cyclopentadienes (𝑡BuC₅H₅ and C₆F₅C₅H₅) do not undergo rDA below 180 °C. These results strongly support the proposed bis-CPD monomer design. In a second fundamental step (Chapter 4), the hypothesis that an electron-withdrawing CPD substituent would destabilize a CPD-MI adduct was further tested by reacting 𝑁-(4- fluorophenyl)maleimide with a series of triarylated cyclopentadienes (1,2,3-Ar₃C₅H₃ and 1,2,4- Ar₃C₅H₃, Ar = C₆F₅, C₆F₄CF₃, and Ar = C₅F₄N). The perfluorophenyl- and perfluorotolylsubstituted compounds were previously reported, but the perfluoropyridyl-substituted cyclopentadienes were prepared for this study using SNAr reactions of pentafluoropyridine and sodium cyclopentadienide. The least electron deficient cyclopentadiene in each series (Ar = C₆F₅) reacted the most quickly and with the highest ultimate equilibrium binding constant, confirming the electron-effects hypothesis as well as the underlying presumption that DA reactions of even relatively electron-poor CPDs with MI would behave according to normal-electron-demand principles. In the main section of this dissertation (Chapter 5) the proposed bis(cyclopentadiene)s reacted with a series of previously reported bis(maleimides) to form linear polymers having molecular weights (Mn) up to 40 kDa. Relationships among the length and flexibility of the bis-MI linker (C₆H₁₂, C₁₂H₂₄, C₆H₄OC₆H₄, and (C₂H₄O)₂), the identity of the CPD alkyl substitutent (CHMe₂, CMe₃ and CMe₂Ph) and the glass transition temperature (Tg) as measured by differential scanning calorimetry (DSC) were understood in terms of a general model of local segmental mobility and free volume. Solution thermolysis of a model polymer system (bis-MI linker = C₆H₁₂ (7), CPD alkyl substituent = 𝑡Bu) showed a rapid decrease in molecular weight at 160 °C as determined by size exclusion chromatography (SEC). Solution thermolysis in the presence of excess FMI (as a trap for free CPD moieties) revealed that the onset temperature for rDA on a laboratory time scale (hours) was as low as 120 °C. In the bulk, thermolysis above 250 °C under vacuum led to recovery of a small portion of the bis-CPD monomer, but bulk thermolysis at 200 °C did not reveal a change in molecular weight as determined by SEC. The current interpretation of these observations is that limited mobility in these glassy polymers prohibits retro-DA decoupling. These findings largely validate the main hypothesis of this dissertation. / Ph. D.

Diels-Alder reaction

cyclopentadiene

maleimide

reversible

fluoroaromatic

step-growth polymer

Synthesis of Highly Fluorinated Diels-Alder Polyphenylenes

Evans, Jessica

27 August 2010

Fluoropolymers have useful properties including high thermal stability, chemical resistance, low dielectric constants, and both hydrophobic and oleophobic character, as compared to non-fluorinated analogues. Meanwhile, Diels-Alder polyphenylenes (DAPPs) are known for thermal stability as well as their rigid structure and glassy physical characteristics, which have led to a variety of film and membrane applications. This dissertation merges these two fields by demonstrating a novel and general synthetic approach to highly fluorinated DAPPs. These polymers are expected to retain the physical characteristics of glassy, non-fluorinated DAPPs while also incorporating the desirable attributes of fluoropolymers. The polymer synthesis described herein is based on the well-established polycondensation of bis(cyclopentadienone) (CPD) monomers and dialkynes. Our first main scientific contribution is a general method for preparing CPDs containing both a fluoroaromatic linker and variable fluoroaromatic head-groups. Our CPD synthesis uses nucleophilic aromatic substitution reactions of cyclopentadienyl anions and perfluoroarenes, as well as a new catalytic method of converting cyclopentadiene methylene (CH₂) groups into the corresponding ketones (C=O) that is the primary dissertation subject of Brian S. Hickory in our laboratory. The overall synthesis is notable for its use of inexpensive starting materials, its efficiency, and its structural versatility. Our second main contribution is the synthesis of novel highly fluorinated Diels-Alder polyphenylenes (DAPPs). Fluorinated DAPPs varied in their molecular weight, in the identity of the lateral fluoroaryl substituent (pentafluoro-phenyl or tetrafluoro-4-pyridyl), and in the structure of the aromatic dialkyne monomer. These polymers are glassy materials with high glass transition temperatures and high thermal stability. Since the polyphenylene structure is intrinsically rigid, the polymers form brittle films even at molecular weights of over 30,000 (M_w). Unlike many fluoropolymers, the fluorinated DAPPs are freely soluble in common organic solvents such as tetrahydrofuran and chloroform. An unknown side reaction competes with the polymer propagation and reduces the highest obtainable molecular weights, which limit the ability to form films. However, a stoichiometric imbalance leads to highly fluorinated polyphenylene oligomers terminated with either alkyne or CPD end groups (M_n = 9000). Because preliminary experiments had shown that the desired Diels-Alder propagation reaction was slower than expected, we also undertook a detailed model study of the reaction conditions needed for Diels-Alder reactions of fluorinated CPDs and aromatic alkynes. These experiments showed that protic polar solvents (e.g., m-cresol) and conventional heating at ca. 150 °C optimize reaction rate while minimizing side-reactions that can contribute to lower molecular weight in corresponding polymerization reactions. / Ph. D.

fluoroaromatic

cyclopentadienone synthesis

Diels-Alder reaction

perfluoroarene

step-growth polymerization

fluorine

polyphenylene