Mechanical Properties and Hysteresis Behaviour of Multigraft Copolymers

Staudinger, Ulrike; Weidisch, Roland; Zhu, Yuqing; Gido, Samuel P.; Uhrig, David; Mays, Jimmy W.; Iatrou, Hermis; Hadjichristidis, Nikos

doi:10.1002/masy.200690027

Cited by 34 publications

(70 citation statements)

References 19 publications

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“…By further coupling the PS macromonomer with difunctional living polyisoprene anions, centipede‐like multigraft copolymers with two PS at the same branching points was prepared. Using a similar strategy but with different coupling agents such as methyltrichlorosilane or 1,6‐bis(trichlorosilyl)‐hexane (“hexachlorosilane”), comb‐ or barbwire‐like multigraft copolymers with one or four PS chains at each branching points were synthesized …”

Section: Regularly Spaced Multigraft Copolymers Synthesized By Chloromentioning

confidence: 99%

“…Since the final coupling reaction employs a step‐growth mechanism, the prepared multigraft copolymers generally have a PDI around 2. Using solvent/nonsolvent fractionation procedures, one can readily isolate multigraft copolymers with different average numbers of branch points and PDI (PDI ≈ 1.2), providing ideal materials with which to study the influence of number of branch points on a wide range of properties such as morphologies, chain dynamics, mechanical properties, and hysteresis behaviors . General nomenclature of these material is MG‐ x ‐ y ‐ z , where MG stands for regular multigraft, x (3, 4, and 6) is the junction point functionality, y refers to the volume percentage of PS, and z represents the average number of junction points per molecules calculated from NMR spectra.…”

Section: Regularly Spaced Multigraft Copolymers Synthesized By Chloromentioning

confidence: 99%

“…Multigraft copolymers PI‐ g ‐PS of appropriate architecture and composition are found to have exceptionally high strain at break and low residual strain in hysteresis tests, resulting in superelastic properties, as well as high tensile strength ( Figure ). For tetrafunctional multgraft copolymer with 21 vol% PS and ten branch points (MG‐4‐21‐9.9), an unprecedented elongation at break of 2100% was reported, almost double that of commercial TPEs such as Kraton (1050% at similar composition) (Figure a) .…”

Section: Structure–properties Correlations Of Multigraft Copolymers Tpesmentioning

confidence: 99%

“…These are exceptionally low values of permanent set for TPEs. The superelasticity of multigraft copolymers, in contrast to linear block copolymer TPE, is caused by their distinct molecular architecture ( Figure ), where the rubbery PI backbone is linked to multiple rigid PS domains with two or more PS branches at each junction point . Thus, the elastic PI backbone is “reminded” at multiple points where it should return to once the load is removed.…”

Section: Structure–properties Correlations Of Multigraft Copolymers Tpesmentioning

confidence: 99%

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Design and Synthesis of Multigraft Copolymer Thermoplastic Elastomers: Superelastomers

Wang

et al. 2017

Macro Chemistry & Physics

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worldwide elastomer market, as sealants, coatings, adhesives, sporting good components, automotive parts, footwear, and as biomedical materials. [1] Prepared by living anionic polymerization, styrenic thermoplastic elastomers (S-TPEs), including polystyrene-blockpolyisoprene-block-polystyrene (SIS) and polystyrene-block-polybutadiene-blockpolystyrene (SBS), were first developed by Holden and Millkvich in the early 1960s and have since then become widely used in our daily life. [2,3] The exceptional mechanical properties of S-TPEs are attributed to the microphase separation between the two chemically incompati ble domains where hard polystyrene (PS) domains serve as physical cross-links for the soft polybutadiene (PB) or polyisoprene (PI) matrix. Mechani cal properties, such as tensile strength, Young's modulus, and elasticity, are tunable based on volume fractions of hard and soft domains. One limitation of S-TPEs is the restricted upper service temperature (UST), which is limited by the glass transition temperature (T g ) of polystyrene (T g ≈ 100 °C). When the service temperature is approaching 100 °C, softening of PS domains disrupts the physical cross-links, leading to a sharp drop of storage modulus. Numerous studies have been carried to increase the UST of S-TPEs by either replacing polystyrene with another higher T g polymer [4][5][6][7][8] or using catalytic hydrogenation to fully saturate PS into polyvinylcyclohexane (T g ≈ 150 °C). [9] With recent advances in living/controlled polymerization, various nonlinear architectures, including star, [10][11][12][13][14] graft, and cyclic [15,16] architectures, or their combinations, [17][18][19][20] have been synthesized during the past three decades. These nonlinear macromolecular architectures deliver additional parameters for chemists to use in tuning mechanical properties, as well as incorporating additional functionality to TPEs [21] (Figure 1).In this short review, we focus on the progress in design and synthesis of well-defined multigraft copolymers and their application as thermoplastic elastomers. Progress in precise synthesis of graft copolymers and mechanical properties of multigraft copolymers is first summarized. Recent work on all-acrylic graft copolymer TPEs and a low-cost emulsion polymerization approach to prepare multigraft copolymers are introduced subsequently. Finally, we finish the review with conclusions and some future prospectives. Living Anionic PolymerizationsThermoplastic elastomers (TPEs) have been widely studied because of their recyclability, good processibility, low production cost, and unique performance. The building of graft-type architectures can greatly improve mechanical properties of TPEs. This review focuses on the advances in different approaches to synthesize multigraft copolymer TPEs. Anionic polymerization techniques allow for the synthesis of well-defined macromolecular structures and compositions, with great control over the molecular weight, polydispersity, branch spacing, number of branch points, and branch point ...

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Section: Regularly Spaced Multigraft Copolymers Synthesized By Chloromentioning

confidence: 99%

Section: Regularly Spaced Multigraft Copolymers Synthesized By Chloromentioning

confidence: 99%

Section: Structure–properties Correlations Of Multigraft Copolymers Tpesmentioning

confidence: 99%

Section: Structure–properties Correlations Of Multigraft Copolymers Tpesmentioning

confidence: 99%

See 2 more Smart Citations

Design and Synthesis of Multigraft Copolymer Thermoplastic Elastomers: Superelastomers

Wang

et al. 2017

Macro Chemistry & Physics

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“…Structure-property relationship of these graft copolymers was elucidated by characterizing morphology [76,77] and mechanical properties [78][79][80] of grafted polymers with different compositions (14-23 vol% of PS) and architectures (trifunctional, tetrafunctional, and hexafunctional junction points). From their research, multigraft polymers with tetrafunctional junction points showed 1550% strain at break which is 500% higher than that for the commercial product Kraton 1102.…”

Section: Graft Copolymer-type Tpesmentioning

confidence: 99%

Thermoplastic Elastomers Based on Block, Graft, and Star Copolymers

Wang¹,

Lu²,

Kang³

et al. 2017

Elastomers

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In this book chapter, we focus on recent advances in thermoplastic elastomers based on synthetic polymers from the aspects of polymer architectures such as linear block, graft, and star copolymers. The irst section is an introduction that covers a brief history and classiication of thermoplastic elastomers (TPEs). The second section summarizes ABA triblock copolymers synthesized by various methods for TPE applications. The third section reviews TPEs based on graft copolymers, and the fourth section reviews TPEs based on star copolymers. The diferences between TPE research in academia and industry are addressed in the last section as a perspective, with a view toward the generation of new, advanced, commercially viable TPEs.

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Influence of Carbon Nanotubes on the Morphology and Properties of Styrene‐Butadiene Based Block Copolymers

Staudinger

Satapathy

2017

Macromolecular Symposia

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Summary Structure property correlations in a styrene‐butadiene star block copolymer melt mixed with varying amounts of multiwalled carbon nanotubes (MWCNTs) were evaluated. The MWCNTs are well dispersed within the matrix and do not significantly impact the star block copolymer morphology or the glass transition temperature. The electrical percolation threshold was found to be at ∼1 wt% of MWCNT concentration. A distinct increase in Young's modulus could be observed at a nanofiller content of 0.1 wt% while maintaining the elastomeric matrix property profile, an observation in tune with the rule‐of‐mixture prediction. Additionally the existence of double yielding was detected in these nanocomposites with a pronounced first yield point indicating a significant enhancement of stiffness in composites with low MWCNT content. Analysis of elastic moduli using Halpin‐Tsai and two‐phase Takayanagi model revealed a matrix‐controlled elastic response without any interfacial contribution due to MWCNT incorporation.

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Mechanical Properties and Hysteresis Behaviour of Multigraft Copolymers

Cited by 34 publications

References 19 publications

Design and Synthesis of Multigraft Copolymer Thermoplastic Elastomers: Superelastomers

Design and Synthesis of Multigraft Copolymer Thermoplastic Elastomers: Superelastomers

Thermoplastic Elastomers Based on Block, Graft, and Star Copolymers

Influence of Carbon Nanotubes on the Morphology and Properties of Styrene‐Butadiene Based Block Copolymers

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