Shape memory materials from rubbers

Arunima Reghunadhan; Keloth Paduvilan Jibin; Abitha Vayyaprontavida Kaliyathan; Prajitha Velayudhan; Michał Strankowski; Sabu Thomas

doi:10.3390/ma14237216

Shape memory materials from rubbers

Arunima Reghunadhan, Keloth Paduvilan Jibin, Abitha Vayyaprontavida Kaliyathan, Prajitha Velayudhan, Michał Strankowski, Sabu Thomas

Research output: Contribution to journal › Review article › peer-review

Abstract

Smart materials are much discussed in the current research scenario. The shape memory effect is one of the most fascinating occurrences in smart materials, both in terms of the phenomenon and its applications. Many metal alloys and polymers exhibit the shape memory effect (SME). Shape memory properties of elastomers, such as rubbers, polyurethanes, and other elastomers, are discussed in depth in this paper. The theory, factors impacting, and key uses of SME elastomers are all covered in this article. SME has been observed in a variety of elastomers and composites. Shape fixity and recovery rate are normally analysed through thermomechanical cycle studies to understand the effectiveness of SMEs. Polymer properties such as chain length, and the inclusion of fillers, such as clays, nanoparticles, and second phase polymers, will have a direct influence on the shape memory effect. The article discusses these aspects in a simple and concise manner.

Original language	English
Article number	7216
Journal	Materials
Volume	14
Issue number	23
DOIs	https://doi.org/10.3390/ma14237216
Publication status	Published - 1 Dec 2021
Externally published	Yes

Keywords

Applications
Elastomer
Fixity
Recovery
Shape memory

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10.3390/ma14237216

Cite this

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title = "Shape memory materials from rubbers",

abstract = "Smart materials are much discussed in the current research scenario. The shape memory effect is one of the most fascinating occurrences in smart materials, both in terms of the phenomenon and its applications. Many metal alloys and polymers exhibit the shape memory effect (SME). Shape memory properties of elastomers, such as rubbers, polyurethanes, and other elastomers, are discussed in depth in this paper. The theory, factors impacting, and key uses of SME elastomers are all covered in this article. SME has been observed in a variety of elastomers and composites. Shape fixity and recovery rate are normally analysed through thermomechanical cycle studies to understand the effectiveness of SMEs. Polymer properties such as chain length, and the inclusion of fillers, such as clays, nanoparticles, and second phase polymers, will have a direct influence on the shape memory effect. The article discusses these aspects in a simple and concise manner.",

keywords = "Applications, Elastomer, Fixity, Recovery, Shape memory",

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doi = "10.3390/ma14237216",

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volume = "14",

journal = "Materials",

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T1 - Shape memory materials from rubbers

AU - Reghunadhan, Arunima

AU - Jibin, Keloth Paduvilan

AU - Kaliyathan, Abitha Vayyaprontavida

AU - Velayudhan, Prajitha

AU - Strankowski, Michał

AU - Thomas, Sabu

PY - 2021/12/1

Y1 - 2021/12/1

N2 - Smart materials are much discussed in the current research scenario. The shape memory effect is one of the most fascinating occurrences in smart materials, both in terms of the phenomenon and its applications. Many metal alloys and polymers exhibit the shape memory effect (SME). Shape memory properties of elastomers, such as rubbers, polyurethanes, and other elastomers, are discussed in depth in this paper. The theory, factors impacting, and key uses of SME elastomers are all covered in this article. SME has been observed in a variety of elastomers and composites. Shape fixity and recovery rate are normally analysed through thermomechanical cycle studies to understand the effectiveness of SMEs. Polymer properties such as chain length, and the inclusion of fillers, such as clays, nanoparticles, and second phase polymers, will have a direct influence on the shape memory effect. The article discusses these aspects in a simple and concise manner.

AB - Smart materials are much discussed in the current research scenario. The shape memory effect is one of the most fascinating occurrences in smart materials, both in terms of the phenomenon and its applications. Many metal alloys and polymers exhibit the shape memory effect (SME). Shape memory properties of elastomers, such as rubbers, polyurethanes, and other elastomers, are discussed in depth in this paper. The theory, factors impacting, and key uses of SME elastomers are all covered in this article. SME has been observed in a variety of elastomers and composites. Shape fixity and recovery rate are normally analysed through thermomechanical cycle studies to understand the effectiveness of SMEs. Polymer properties such as chain length, and the inclusion of fillers, such as clays, nanoparticles, and second phase polymers, will have a direct influence on the shape memory effect. The article discusses these aspects in a simple and concise manner.

KW - Applications

KW - Elastomer

KW - Fixity

KW - Recovery

KW - Shape memory

UR - https://www.scopus.com/pages/publications/85119957284

U2 - 10.3390/ma14237216

DO - 10.3390/ma14237216

M3 - Review article

AN - SCOPUS:85119957284

SN - 1996-1944

VL - 14

JO - Materials

JF - Materials

IS - 23

M1 - 7216

ER -

Shape memory materials from rubbers

Abstract

Keywords

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