Multiple shape memory effects of <i>trans</i>‐1,4‐polyisoprene and low‐density polyethylene blends

Xia, Lin; Xian, Jiayu; Geng, Jieting; Wang, Yan; Shi, Feifei; Zhou, Zuoyan; Lü, Na; Du, Ai; Xin, Zhenxiang

doi:10.1002/pi.5387

Cited by 24 publications

(17 citation statements)

References 34 publications

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“…The following assumptions about the evolution of the enthalpy H during the isothermal relaxation process are made. First, during the heating process, the isothermal relaxation is considered as a series of n independent processes and the rate of enthalpy H i change is associated with a time and temperature dependent relaxation time i such that 5) wileyonlinelibrary.com/journal/pi where H ei is the equilibrium value of enthalpy at the present temperature.…”

Section: Phase Evolution Functionmentioning

confidence: 99%

“…Compared to shape memory ceramics and shape memory alloys, SMPs have many special advantages, e.g. low density, low cost, easily tailored properties and large deformation recovery capacity . These novel properties have drawn increasing attention for utilizing SMPs in many potential applications, such as deployable structures, biomedical devices, smart textiles and self‐healing composite systems …”

Section: Introductionmentioning

confidence: 99%

“…low density, low cost, easily tailored properties and large deformation recovery capacity. 5,6 These novel properties have drawn increasing attention for utilizing SMPs in many potential applications, such as deployable structures, biomedical devices, smart textiles and self-healing composite systems. [7][8][9][10][11][12][13] SMPs triggered by temperature are known as possessing a thermally induced shape memory effect.…”

Section: Introductionmentioning

confidence: 99%

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A modified phase‐based constitutive model for shape memory polymers

Pan

Zhou

Zhang

2018

Polymer International

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Constitutive models used for predicting the thermomechanical behavior of shape memory polymers (SMPs) are critical for the development of SMP applications. Among the existing models, the phase transition concept attracts wide attention due to its good predictive capacity and great convenience. However, most of the present phase transition models for SMPs have limitations or deficiencies in considering the effect of temperature change rate on the thermomechanical behavior of SMPs. In this paper, based on the kinetics of phase transitions, we propose a constitutive model in which the temperature change rate is incorporated into the phase evolution function to consider the effect of the temperature change rate on the thermomechanical properties of SMPs. Then experimental data under different recovery conditions for two different types of SMP materials are used to validate the predictive capacity and versatility of the present model. The predicted results agree quite well with the experimental observations, which demonstrates that the present model is robust enough to predict the complex thermomechanical behavior for different SMPs. In addition, through experiments and model predictions, we find that the shape free recovery curves at different heating rates can be easily predicted by just moving a reference recovery curve along the horizontal direction by a distance whose value is calculated through the proposed equation. © 2018 Society of Chemical Industry

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Section: Phase Evolution Functionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A modified phase‐based constitutive model for shape memory polymers

Pan

Zhou

Zhang

2018

Polymer International

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“…trans ‐1,4‐Polyisoprene (TPI) and polyethylene (PE) could be used as shape memory materials with a moderate degree of cross‐linking. The shape memory properties of TPI, PE, and their blends have been investigated in recent years . However, the disadvantage of most shape memory composites is their poor mechanical properties, and TPI and PE composites are no exception.…”

Section: Introductionmentioning

confidence: 99%

“…The shape memory properties of TPI, PE, and their blends have been investigated in recent years. [27][28][29][30][31] However, the disadvantage of most shape memory composites is their poor mechanical properties, and TPI and PE composites are no exception. Inorganic fillers are ideal candidate materials with which to improve the mechanical strength of SMPs.…”

mentioning

confidence: 99%

Shape memory behavior of carbon nanotube‐reinforced trans‐1,4‐polyisoprene and low‐density polyethylene composites

Xia

Gui-xue

2019

Polymers for Advanced Techs

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Shape memory composites of trans‐1,4‐polyisoprene (TPI) and low‐density polyethylene (LDPE) with easily achievable transition temperatures were prepared by a simple physical blending method. Carbon nanotubes (CNTs) were introduced to improve the mechanical properties of the TPI/LDPE composites. The mechanical, cure, thermal, and shape memory properties of the TPI/LDPE/CNTs composites were investigated in this study. In these composites, the cross‐linked network generated in both the TPI and LDPE portions acted as a fixed domain, while the crystalline regions of the TPI and LDPE portions acted as a domain of reversible shape memory behavior. We found that CNTs acted as not only reinforced fillers but also nucleation agents, which improved the crystalline degree of the TPI and LDPE portions of the composites. Compared with the properties at the other CNT doses, the mechanical properties of the TPI/LDPE composites when the CNT dose was 1 phr were improved significantly, showing excellent shape memory properties (Rf = 97.85%, Rr = 95.70%).

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A Triple Shape Memory Material of Trans‐Polyisoprene/Polycaprolactone with Customizable Response Temperature Controlled by Crosslinking Density

Zhang,

Zou,

Pan

et al. 2024

Adv Funct Materials

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Body‐temperature responsive shape memory polymers (SMPs) attract a lot of attention with the application in biomedicine. Multiple SMPs regulate the response temperature through the proportion of their stationary and reversible phases by changing the molecular weight of the polymer or the components of the composite. Herein, a crosslinking reaction of trans‐polyisoprene (TPI) and polycaprolactone (PCL) initiated by benzoyl peroxide gave a SMP of TPI/PCL, whose shape memory property is realized by stage‐division crystallization zone. Under the fixed ratio of TPI:PCL, the crystallization performance of TPI/PCL is controlled by the crosslinking density. The response temperatures of the components in TPI/PCL are selected for the stage‐division crystallization zone, making excellent shape memory performance at corresponding response temperatures. For the further achievement in controllable response temperature within a certain range, the relationship model between crosslinking density and response temperature is established, obtaining the customizable response temperature ranging 37–55 °C. The presented facile regulation method for response temperature will provide a new idea for the SMPs development.

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Multiple shape memory effects of trans‐1,4‐polyisoprene and low‐density polyethylene blends

Cited by 24 publications

References 34 publications

A modified phase‐based constitutive model for shape memory polymers

A modified phase‐based constitutive model for shape memory polymers

Shape memory behavior of carbon nanotube‐reinforced trans‐1,4‐polyisoprene and low‐density polyethylene composites

A Triple Shape Memory Material of Trans‐Polyisoprene/Polycaprolactone with Customizable Response Temperature Controlled by Crosslinking Density

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