AI Article Synopsis
- Innovative Strategy
- : The study introduces a new method for creating a reversible shape-memory polymer that functions without external force, using a two-phase design involving a blend of crosslinked styrene-butadiene-styrene block copolymer and polycaprolactone-based polyurethane.
- Microphase Separation
- : The resulting material features a unique microphase separation structure, where the SBS is chemically bonded to the crosslinked PU, enhancing system integrity through a specific crosslinking process.
- Practical Applications
- : This method allows for effective programming of shape memory, enabling the material to expand and contract based on temperature changes, making it suitable for mass production and various applications in smart materials.
Article Abstract
The present communication reports a novel strategy to fabricate reversible shape-memory polymer that operates without the aid of external force on the basis of a two-phase structure design. The proof-of-concept material, crosslinked styrene-butadiene-styrene block copolymer (SBS, dispersed phase)/polycaprolactone-based polyurethane (PU, continuous phase) blend, possesses a closely connected microphase separation structure. That is, SBS phases are chemically bonded to crosslinked PU by means of a single crosslinking agent and two-step crosslinking process for increasing integrity of the system. Miscibility between components in the blend is no longer critical by taking advantage of the reactive blending technique. It is found that a suitable programming leads to compressed SBS, which serves as internal expansion stress provider as a result. The desired two-way shape-memory effect is realized by the joint action of the temperature-induced reversible opposite directional deformabilities of the crystalline phase of PU and compressed SBS, accompanying melting and orientated recrystallization of the former. Owing to the broadness of material selection and manufacturing convenience, the proposed approach opens an avenue toward mass production and application of the smart polymer.
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| http://dx.doi.org/10.1002/marc.201700124 | DOI Listing |
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