Shape Actuation via Internal Stress-Induced Crystallization of Dual-Cure Networks

Shape‐memory polymers (SMPs) that respond near body temperature are attracting broad interest, especially in the biomedical fields. In this study, the triggering temperature of poly(caprolactone) SMP networks is precisely adjusted by inclusion of non‐crystallizable molecular linkers and by variation of prepolymer molecular weight. Longer, non‐crystalline linkers and lower molecular weight prepolymers interfere with crystallization, lowering the transition temperature. Networks are prepared with crystallization temperatures that are beneath the human body temperature and yet are above room temperature. Upon cooling such amorphous networks to room temperature, crystallization is sluggish. There, elastomers can be easily strained by several hundred‐percent to induce crystallization, thereby fixing strained states. If subsequently heated, programmed SMPs can release significant amounts of stored strain energy (∼3 MJ/m3). SMPs that combine elastic energy storage and exhibit triggering temperatures near the human body temperature could benefit emerging applications in the biomedical space. © 2016 Wiley Periodicals, Inc. J. Polym. Sci., Part B: Polym. Phys. 2016, 54, 1397–1404

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“…(b)], confirming the explanation. This phenomenon was also well understood through small‐angle X‐ray scattering (SAXS) in a few previous reports …”

Section: Resultsmentioning

confidence: 58%

Body temperature triggered shape‐memory polymers with high elastic energy storage capacity

Meng

Jiang

Anthamatten

2016

J Polym Sci B Polym Phys

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“…15 Strain-induced crystallization of PCL has enabled two-way shape memory 18 and recently stress-free shape actuation. 19 The role of network architecture on strain-induced crystallization and on the performance of cold-drawn shapememory polymers remains unclear. It is well-known that network characteristics such as the molecular weight distribution between cross-links, cross-link functionality and spatial distribution, and the presence of dangling chains and primary loops have large effects on elastomeric properties.…”

Section: ■ Introductionmentioning

confidence: 99%

Well-Defined Shape-Memory Networks with High Elastic Energy Capacity

2015

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Controlling network architecture and chain connectivity is critical to understanding elastic energy storage and improving performance of shape-memory polymers. Acrylate-terminated poly(caprolactones) were converted into thermoset networks by three different reactions: conventional free radical polymerization, radical-induced coupling with multifunctional thiols, and base-catalyzed Michael addition with multifunctional thiols. The highly efficient thiol−acrylate coupling reaction ensures that the molecular weight between cross-links is uniform, resulting in tougher, more elastic materials with a high degree of crystallinity and outstanding shapememory properties. Elastomers can be cold drawn to achieve several hundred percent of strain, and upon heating, nearly complete shape recovery is observed. Shape fixity upon cold drawing is correlated to the degree of strain-induced crystallization which is influenced by the draw rate and stress treatment immediately following cold drawing. Slow unloading of samples drawn to 400% elongation indicates the material is capable of storing greater than 1.5 MJ/m 3 of elastic energy.

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“…Shape‐memory materials are a class of smart materials that respond to external stimuli, typically temperature and their applications have expanded steadily as well as academic and industry. Shape‐memory polymers (SMP) have received more attention owing to their low cost, low density, easy processability compared with shape‐memory alloys, ceramics, hydrogels, etc . However, SMPs suffer from relatively weak recovery force due to their low stiffness when compared with most other shape memory alloys.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and properties of click coupled graphene oxide sheets with three‐dimensional macromolecules

Mahapatra

Ramasamy

Yoo

et al. 2016

J of Applied Polymer Sci

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A facile click chemistry approach to the functionalization of three‐dimensional hyperbranched polyurethane (HPU) to graphene oxide (GO) nanosheets is presented. HPU‐functionalized GO samples of various compositions were synthesized by reacting alkyne‐functionalized HPU with azide‐functionalized GO sheets. The morphological characterization of the HPU‐functionalized GO was performed using transmission electron microscopy and its chemical characterization was carried out using Fourier transform‐infrared spectroscopy, nuclear magnetic resonance spectroscopy, and X‐ray photoelectron spectroscopy. The graphene sheet surfaces were highly functionalized, leading to improved solubility in organic solvents, and consequently, enhanced mechanical, thermal, and thermoresponsive and photothermal shape memory properties. The strategy reported herein provides a very efficient method for regulating composite properties and producing high performance materials. © 2016 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2016, 133, 43358.

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Shape Actuation via Internal Stress-Induced Crystallization of Dual-Cure Networks

Cited by 105 publications

References 27 publications

Body temperature triggered shape‐memory polymers with high elastic energy storage capacity

Body temperature triggered shape‐memory polymers with high elastic energy storage capacity

Well-Defined Shape-Memory Networks with High Elastic Energy Capacity

Synthesis and properties of click coupled graphene oxide sheets with three‐dimensional macromolecules

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