New generation of epoxy networks based on ionic liquids : From structuration to final properties / Nouvelle génération de réseaux époxy à base de liquides ioniques : De la structuration aux propriétés finales

Nguyen, Thi Khanh Ly

25 November 2016

Les liquides ioniques (LIs), possédant d’excellentes propriétés intrinsèques et offrant une infinité de combinaisons possibles ouvrent de nouvelles perspectives dans le domaine des polymères, en particulier dans celui des réseaux époxyde. Ce travail de thèse présente la préparation, la caractérisation et la modification de réseaux époxy / liquides ioniques. Dans un premier temps, ce travail est dédié à étudier l'influence des LIs comme comonomères de prépolymère époxyde. Ainsi, la réactivité des LIs vers la DGEBA et leur rôle en tant qu’amorceurs et/ou durcisseurs de systèmes époxyde ont été étudiés. Ensuite, l’effet de la nature chimique des LIs sur les propriétés de réseaux époxy / LIs, y compris les propriétés thermomécaniques, la stabilité thermique, les propriétés de surface et les comportements mécaniques, a été démontré. En outre, le mécanisme de la réaction entre les prépolymères époxy et LIs a été révélé à l'aide de différentes méthodes (IRTF et RMN). Dans la deuxième partie, les agents modifiants (thermoplastiques et des particules cœur-coquille) ont été incorporés dans des réseaux époxy / LI en vue d'améliorer leurs performances mécaniques. Dans la dernière section, la combinaison des LIs et des réseaux époxyde biosourcés a été étudiée en tant que substituts partiels ou complets aux systèmes époxyde issus du pétrole afin de développer des matériaux à faible empreinte environnementale. Ainsi, l’utilisation des liquides ioniques a eu des effets bénéfiques sur la morphologie mais également sur les propriétés des réseaux. La relation entre la nature chimique des LIs, la morphologie et les propriétés obtenues a été soulignée. / Having excellent intrinsic properties with an infinity cation/anion combination, ionic liquids (ILs) have become very attractive in the field of polymer science, especially in the epoxy networks. Thus, this research work presents the preparation, characterization and modification of epoxy/IL networks. The first part of this work is dedicated to study the effect of ILs as comonomers in the formation of epoxy networks. The reactivity of ILs towards epoxy prepolymer and their role either as initiators or as curing agents in the formation of epoxy/IL networks was investigated. Then, the effect of the chemical nature of ILs on the final properties of epoxy/IL networks was demonstrated including thermomechanical properties, thermal stability, surface properties and mechanical behaviors. In addition, the mechanism of curing reaction between epoxy prepolymer and ILs was revealed using different methods (FTIR and NMR). In the second part, modifiers (thermoplastics and core-shell particles) were incorporated into epoxy/IL networks in order to improve their mechanical performances. In the last section, the combination of ILs and bio-based epoxy networks was studied as partial or complete substitutions for petroleum based epoxy systems aiming for “green materials” coatings applications. Thus, the unique properties of ionic liquids led to remarkable changes in morphology and properties of epoxy systems. The relation between the chemical nature of ILs, the morphology and the properties of obtained epoxy networks was highlighted.

Matériaux

Réseaux époxy

Liquides Ioniques

Relation structure propriétés

Réactivité

Propriété des réseaux

Mécanisme de réaction

Materials

Epoxy networks

Ionic Liquids

Structure Properties Relationship

Reactivity

Nerwork properties

Reaction mechanism

620.194 072

Step-Growth Polymerization Towards the Design of Polymers: Assembly and Disassembly of Macromolecules

June, Stephen Matthew

01 May 2012

Step-growth polymerization provided an effective method for the preparation of several high performance polymers. Step-growth polymerization was used for syntheses of poly(siloxane imides), polyesters, poly(triazole esters), poly(triazole ether esters), and epoxy networks. Each of these polymeric systems exhibited novel structures, and either photoreactive capabilities, or high performance properties. There is an increasing trend towards the development of photoactive adhesives. In particular these polymers are often used in flip bonding, lithography, stimuli responsive polymers, drug delivery, and reversible adhesives. The ability to tailor polymer properties carefully with exposure to light allows for very unique stimuli responsive properties for many applications. This dissertation primarily investigates photoreactive polymers for reversible adhesion for use in the fabrication of microelectronic devices. In particular cyclobutane diimide functionality within polyimides and poly(siloxane imides) and o-nitro benzyl ester functionality within polyesters acted effectively as chromophores to this end. Thermal solution imidization allowed for the effective synthesis of polyimides and poly(siloxane imides). 1,2,3,4-Cyclobutane tetracarboxylic dianhydride acted as the chromophore within the polymer backbone. The polyimides obtained exhibited dispersibility only in dipolar, aprotic, high boiling solvents such as DMAc or NMP. The obtained poly(siloxane imides) demonstrated enhanced dispersibility in lower boiling organic solvents such as THF and CHCl₃. Dynamic mechanical analysis and tensile testing effectively measure the mechanical properties of the photoactive poly(siloxane imides) and confirmed elastomeric properties. Atomic force microscopy confirmed microphase separation of the photoactive poly(siloxane imides). ¹H NMR spectroscopy confirmed formation of maleimide peaks upon exposure to narrow band UV light with a wavelength of 254 nm. This suggested photo-cleavage of the cyclobutane diimide units within the polymer backbone. Melt transesterification offered a facile method for the synthesis of o-nitro benzyl ester-containing polyesters. ¹H NMR spectroscopy confirmed the structures of the photoactive polyesters and size exclusion chromatography confirmed reasonable molecular weights and polydispersities of the obtained samples. ¹H NMR spectroscopy also demonstrated a decrease in the integration of the resonance corresponding to the o-nitro benzyl ester functionality relative to the photo-stable m-nitro benzyl ester functionality upon exposure to high-intensity UV light, suggesting photo-degradation of the adhesive. ASTM wedge testing verified a decrease in fracture energy of the adhesive upon UV exposure, comparable to the decrease in fracture energy of a commercial hot-melt adhesive upon an increase in temperature. Click chemistry was used to synthesize polyesters and segmented block copolyesters. Triazole-containing homopolyesters exhibited a marked increase (~40 °C) in Tg, relative to structurally analogous classical polyesters synthesized in the melt. However, the triazole-containing homopolyesters exhibited insignificant dispersibility in many organic solvents and melt-pressed films exhibited poor flexibility. Incorporation of azide-functionalized poly(propylene glycol) difunctional oligomers in the synthesis of triazole-containing polyesters resulted in segmented block copolyesters which exhibited enhanced dispersibility and film robustness relative to the triazole-containing homopolyesters. The segmented triazole-containing polyesters all demonstrated a soft segment Tg near -62 °C, indicating microphase separation. Dynamic mechanical analysis confirmed the presence of a rubbery plateau, with increasing plateau moduli as a function of hard segment content, as well as increasing flow temperatures as a function of hard segment content. Tensile testing revealed increasing tensile strength as a function of hard segment, approaching 10 MPa for the 50 wt % HS sample. Atomic force microscopy confirmed the presence of microphase separated domains, as well as semicrystalline domains. These results indicated the effectiveness of click chemistry towards the synthesis of polyesters and segmented block copolyesters. Click chemistry was also used for the synthesis of photoactive polyesters and segmented block polyesters. The preparation of 2-nitro-p-xylylene glycol bispropiolate allowed for the synthesis of triazole-containing polyesters, which exhibited poor dispersibility and flexibility of melt-pressed films. The synthesis of segmented photoactive polyesters afforded photoactive polyesters with improved dispersibility and film robustness. ¹H NMR spectroscopy confirmed the photodegradation of the o-nitro benzyl functional groups within the triazole-containing polyesters, which indicated the potential utility of these polyesters for reversible adhesion. Synthesis of the glycidyl ether of 2,2,4,4-tetramethyl-1,3-cyclobutane diol (CBDOGE) allowed for the subsequent preparation of epoxy networks which did not contain bisphenol-A or bisphenol-A derivatives. Preparation of analogous epoxy networks from the glycidyl ether of bisphenol-A (BPA-GE) provided a method for control experiments. Tensile testing demonstrated that, dependent on network Tg, the epoxy networks prepared from CBDOGE exhibited similar Young's moduli and tensile strain at break as epoxy networks prepared from BPAGE. Dynamic mechanical analysis demonstrated similar glassy moduli for the epoxy networks, regardless of the glycidyl ether utilized. Tg and rubbery plateau moduli varied as a function of diamine molecular weight. Melt rheology demonstrated a gel time of 150 minutes for the preparation of epoxy networks from CBDO-GE and 78 minutes for the preparation of epoxy networks from BPA-GE, with the difference attributed to increased sterics surrounding CBDO-GE. These results indicated the suitability of CBDO-GE as a replacement for BPA-GE in many applications. / Ph. D.

Polycondensation

Polyaddition

Step-Growth Polymers

Epoxy Networks

Microbial Fuel Cells

Photo-active Polymers

Poly(siloxane imides)

Polyesters

"Click" Chemistry

Stimuli Responsive Polymers

Bisphenol-A

BPA