Viscoelastic, Mechanical, and Glasstomeric Properties of Precision Polyolefins Containing a Phenyl Branch at Every Five Carbons

Kieber, Robert J.; Neary, William J.; Kennemur, Justin G.

doi:10.1021/acs.iecr.7b05395

Cited by 13 publications

(16 citation statements)

References 79 publications

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“…P4PCP and H 2 –P4PCP are rubbery amorphous materials with a nearly identical T g (17 ± 2 °C) just below ambient temperature which is a key attribute for sound and vibration dampening materials . Further exploration of the viscoelastic and mechanical properties revealed that both share similar density (ρ 24°C = 1.03 ± 0.01 g cm –3 ), but P4PCP has a much higher entanglement molar mass ( M e = 10.0 kg mol –1 ) versus H 2 –P4PCP (3.6 kg mol –1 ) leading to differing mechanical properties at similar M n . H 2 –P4PCP, which can be likened to an ethylene–styrene (ES) copolymer with exactly 71.4% w/w styrene, is a model material for studying property differences between precise and imprecise microstructure.…”

Section: Challenges With Admetmentioning

confidence: 99%

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Polypentenamer Renaissance: Challenges and Opportunities

2018

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This Viewpoint highlights the viability and increasing variety of functionalized polypentenamers as unique and valuable materials created through enthalpydriven ring-opening metathesis polymerization (ROMP) of low ring strain cyclopentene monomers. The terms "low ring strain" and "enthalpy-driven" are typically conflicting ideologies for successful ROMP; however, these monomers possess a heightened sensitivity to reaction conditions, which may be leveraged in a number of ways to provide performance elastomers with good yield and precise functional topologies. Over the last several years, a rekindled interest in these systems has led to a renaissance of research aimed at improving their synthesis and exploring their potential. Their chemistry, applications, and future outlook are discussed. Figure 7. (a) Sulfonation of H 2 −P4PCP produces a precision polyelectrolyte similar to polystyrenesulfonate (PSS) but with precise 5-carbon distances along the chain. This material has an accessible T g (109°C) allowing it to be thermally molded (inset). Adapted with permission from ref 86. Copyright 2018 John Wiley and Sons. (b) Design of a polypentenamer bottlebrush polymer from ROMP of BIB-functionalized CP followed by ATRP. Block polymer grafts of PS and PMMA, monitored by SEC traces, produce a core−shell polymer visualized by AFM (inset). Adapted with permission from ref 57.

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Section: Challenges With Admetmentioning

confidence: 99%

“…Statistical ES copolymers previously reported display higher values, which vary greatly with only a 4% difference in composition. Values are from ref .…”

Section: Challenges With Admetmentioning

confidence: 99%

Polypentenamer Renaissance: Challenges and Opportunities

2018

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“…We note that due to the odd integer branch topology, an alternative descriptor is a perfectly alternating trimethylene‐styrene copolymer. This material, which we term here as p 5Ph, has a reduced T g (17 ± 2 °C) and entanglement molar mass ( M e ) of 3.6 kg mol −1 when compared to PS (13 kg mol −1 ) due to the trimethylene segment . In a recent study, we reported interesting “glasstomeric” behavior of p 5Ph, which has an elongation at break >1000% and has an elastic recovery of ≈95% from 500% strain at a rate of 0.02 s −1 .…”

Section: Introductionmentioning

confidence: 98%

“…This material, which we term here as p 5Ph, has a reduced T g (17 ± 2 °C) and entanglement molar mass ( M e ) of 3.6 kg mol −1 when compared to PS (13 kg mol −1 ) due to the trimethylene segment . In a recent study, we reported interesting “glasstomeric” behavior of p 5Ph, which has an elongation at break >1000% and has an elastic recovery of ≈95% from 500% strain at a rate of 0.02 s −1 . Given the markedly different properties between PS and p 5Ph, we rationalized that sulfonation of p 5Ph could potentially lead to an analog of PSS with advantageous properties and the potential ability to be thermally processed.…”

Section: Introductionmentioning

confidence: 98%

Precision Polyelectrolytes with Phenylsulfonic Acid Branches at Every Five Carbons

Kendrick

Neary

Delgado

et al. 2018

Macromol. Rapid Commun.

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A precision polyethylene containing phenyl branches at every fifth carbon (p5Ph) is nearly quantitatively functionalized (≈95%) with sulfonic acid groups on the para-position of each phenyl branch (p5PhS-H). Unlike polystyrene sulfonate (PSS), p5PhS-H has a glass transition temperature (T = 109 °C) well below its thermal decomposition temperature (T ≈ 200 °C), making this new material capable of thermal processing into molds and films at temperatures between these thermal limits. Neutralization of the sulfonic acid groups with varying counter cations (Li , Na , Cs ) produces a new class of precision polyelectrolytes. Neutralization and increasing size of the counter cation improves the thermal decomposition temperature (T ) to over 400 °C for the Cs form. Neutralization causes T to increase above T for the Li and Na form. The Cs form is found to have an accessible T = 294 °C. Further investigations of water absorption and the polyelectrolyte effect of these systems are discussed.

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“…The parent poly(4-phenylcyclopentene) (P4PCP) and its hydrogenated analog (p5Ph) are both amorphous, have a low glass transition temperature (T g ≈ 17 °C), and are well entangled at the degree of polymerization (~712) used in this study. [13][14][15][16] We recently investigated p5PhSA neutralized with a variety of metal cations, and found that in the dry state the ions and sulfonate groups strongly nanophase separate from the polymer backbone and self-assemble into percolated ionic aggregates. 17 We thus anticipated that p5PhSA would also nanophase separate into hydrophilic and hydrophobic domains.…”

Section: Introductionmentioning

confidence: 99%

Fluorine-Free Precise Polymer Electrolyte for Efficient Proton Transport: Experiments and Simulations

et al. 2021

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Designing polymers with controlled nanoscale morphologies and scalable synthesis is of great interest in the development of fluorine-free materials for proton exchange membranes in fuel cells. This study focuses on a precision polyethylene with phenylsulfonic acid branches at every 5 th carbon, p5PhSA, with a high ion-exchange capacity (4.2 mmol/g). The polymers selfassemble into hydrophilic and hydrophobic co-continuous nanoscale domains. In the hydrated state, the hydrophilic domain, comprised of the polar sulfonic acid moieties and water, serves as a pathway for efficient mesoscopic proton conductivity. The morphology and proton transport of p5PhSA are evaluated under hydrated conditions using in situ X-ray scattering and electrochemical impedance spectroscopy techniques. At 40 °C and 95% relative humidity, the proton conductivity of p5PhSA is 0.28 S/cm, which is four times greater than Nafion™ 117 under the same conditions. Atomistic molecular dynamics (MD) simulations are also used to elucidate the interplay between the structure and the water dynamics. The MD simulations show strong nanophase separation between the percolated hydrophilic and hydrophobic domains over a wide range of water contents. The percolated hydrophilic nanoscale domain facilitates the rapid proton transport in p5PhSA and demonstrates the potential of precise hydrocarbon-based polymers as processible and effective proton exchange membranes.

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Viscoelastic, Mechanical, and Glasstomeric Properties of Precision Polyolefins Containing a Phenyl Branch at Every Five Carbons

Cited by 13 publications

References 79 publications

Polypentenamer Renaissance: Challenges and Opportunities

Polypentenamer Renaissance: Challenges and Opportunities

Precision Polyelectrolytes with Phenylsulfonic Acid Branches at Every Five Carbons

Fluorine-Free Precise Polymer Electrolyte for Efficient Proton Transport: Experiments and Simulations

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