High Strength Self‐Healing Magnetic Elastomers With Shape Memory Effect

Feng, Xian Qi; Zhang, Gong Zheng; Bai, Quan; Jiang, Hao; Xu, Bo; Li, Huan Jun

doi:10.1002/mame.201500226

Cited by 32 publications

(18 citation statements)

References 63 publications

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“…The FTIR spectra of pure Fe 3 O 4 NPs (a) and Fe 3 O 4 @NVP‐DVB NPs (b, c) in Figure A were tested to measure the bonding on the surface of the pure Fe 3 O 4 NPs in Fe 3 O 4 @NVP‐DVB NPs. The blue rectangle area shows the characteristic absorption peak of Fe−O bond at about 580 cm −1 . The two grey rectangle areas whose peaks range from 750 cm −1 to 900 cm −1 and 1350 cm −1 to 1550 cm −1 are corresponded to the unsaturation C−H bending vibration of benzene ring and the C=C stretching vibration of benzene ring .…”

Section: Resultsmentioning

confidence: 89%

“…The blue rectangle area shows the characteristic absorption peak of FeÀ O bond at about 580 cm À 1 . [32] The two grey rectangle areas whose peaks range from 750 cm À 1 to 900 cm À 1 and 1350 cm À 1 to 1550 cm À 1 are corresponded to the unsaturation CÀ H bending vibration of benzene ring and the C=C stretching vibration of benzene ring. [47] The peak from 1000 cm À 1 to 1100 cm À 1 in the green rectangle area are related to the characteristic absorption peak of SiÀ O bond which represents the KH570 molecule embellished on the pure Fe 3 O 4 NPs.…”

Section: Resultsmentioning

confidence: 99%

“…Zhang developed a magnetic self‐healing hydrogel based on Fe 3 O 4 NPs materials to make hydrogel controllable and can be used for drug delivery, separation, remote controlled actuators. Feng incorporated Fe 3 O 4 NPs into polymeric matrices and created a self‐healing magnetic elastomer with high strength. He manufactured a stretchable Fe 3 O 4 NPs multiple nitrile butadiene rubber.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Synthesis and Properties of Magnetic Self‐Healing Polymers: An Effective Method for Improving Interface Compatibility of Doped Functional Polymers

Zhao

Liao

et al. 2019

ChemNanoMat

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Doped functional polymers, such as magnetic self‐healing polymers based on magnetic inorganic nanoparticles, have raised great attention and been applied in many fields recently due to their superior properties. However, the deficiency of interface compatibility between the inorganic nanoparticles and organic polymers, and the sedimentation and non‐uniform dispersion of the inorganic nanoparticles led to difficulties in the fabrication and development of doped functional polymer materials. In this work, we took magnetic doped self‐healing polymers as an example and proposed an accessible method to solve the problem. We prepared organic‐polymer‐coated Fe3O4 nanoparticles with high interface compatibility and then applied them to successfully synthesize magnetic self‐healing polymers. The average size of the resulting coated Fe3O4 nanoparticles was 8.82±1.09 nm, the practical saturation magnetization of the nanoparticles and the magnetic self‐healing polymers was 83.35, 24.29 emu/g, respectively. In addition, the self‐healing efficiency of the magnetic self‐healing polymers could reach 74.3% when healing for 1 hour and 78.4% when adding a magnetic field compared with 75.8% for the pure self‐healing polymers and 34.5% of magnetic polymers based on pure Fe3O4 nanoparticles. This work may offer a reference in fabricating doped functional polymers based on inorganic nanoparticles with high interface compatibility.

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Section: Resultsmentioning

confidence: 89%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Synthesis and Properties of Magnetic Self‐Healing Polymers: An Effective Method for Improving Interface Compatibility of Doped Functional Polymers

Zhao

Liao

et al. 2019

ChemNanoMat

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“…[72] Exposing OMF at the targeted damage location will generate a high local magnetic heating that activates the nanoparticles and enhances the damage expansion at crack edges and accelerate the narrowing of macroscopic cracks. [299][300][301][302] As the polymer melt drives progressively into the damaged region, the nanoparticles keep migrating toward the edge of the crack because of the entropic depletion attraction. [300] Yang et al observed no obvious geometrical change when a millimeter cut in the polymer sample (0.23 vol% nanoparticles) was triggered by a 60 min magnetic field treatment.…”

Section: Self-healing and Self-testingmentioning

confidence: 99%

Progress and Roadmap for Intelligent Self‐Healing Materials in Autonomous Robotics

et al. 2020

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self-repair in order to survive and thrive. Soft to hard tissues can self-regenerate when injured, including the skin and bones. [6] Some of the living tissues, such as nails and bones, can even continuously remodeling themselves, removing the damaged tissues unintentionally and replaced by newly grown tissues. However, unlike regenerative and remodeling capabilities in nature, robots are made from nonliving synthetic materials such as polymers and metals. Hence, as we develop robots to have greater autonomy and capabilities, having the ability to self-heal or self-repair is becoming more critical, if not, essential, especially from an environmental sustainability point of view. [2,[7][8][9][10][11] The term self-healing materials, also often referred to as self-mending or selfrepairing materials, are materials that can regain some or most of its original material properties when damaged. In synthetic materials, the self-healing materials repair their damage without regenerative origins. As these selfhealing materials undergo self-repair, they regain their original intended functions through the recovery of the desired material properties, without an increase in original mass.As the number of self-healing materials is growing at a rapid clip, we first establish a brief history in this review to help the reader gain a broader perspective on self-healing materials. We emphasize on self-healing materials that recover their mechanical properties, because mechanical properties often dictate the possible applications. Figure 1 highlights the various selfhealing materials from high modulus to low modulus materials that can be used for robotic applications.There are two broad classifications for self-healing materials: a) autonomic versus nonautonomic self-healing materials; b) intrinsic versus extrinsic self-healing. [8] These self-healing materials can recover their properties either autonomously, i.e., without significant external intervention, much like human tissues; or they can also heal with external intervention, such as when some external environment changes cause temperature increment or via various triggers such as mechanical stimuli. Intrinsic self-healing materials do not need external healing agents, while extrinsic self-healing materials contain external healing agents for the healing of the matrix materials. In addition to those classifications, we will provide new insights on classifying these materials further into this review.In Section 2, we discuss various types of smart biomimetic robots where self-healing materials can be beneficial. Section 3 Robots are increasingly assisting humans in performing various tasks. Like special agents with elite skills, they can venture to distant locations and adverse environments, such as the deep sea and outer space. Micro/nanobots can also act as intrabody agents for healthcare applications. Self-healing materials that can autonomously perform repair functions are useful to address the unpredictability of the environment and the increasing drive toward the autonom...

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“…nitinol alloy), SMPs have attracted tremendous interest due to their dramatically larger recovery strain (up to 800 per cent vs less than 8 per cent), light weight, low cost, good processability and biocompatibility (Behl et al , 2010a; Yakacki and Gall, 2009; Xie, 2011; Habault et al , 2013; Hager et al , 2015). They have been extensively explored for a wide application, for example, heat-shrinkable tubes, reconfigurable morphing wings (Felton et al , 2013; Yakacki, 2013), smart textiles (Leng et al , 2009), sensors and actuators (Sun et al , 2014a, 2014b; Li and Serpe, 2016), self-healing materials (Wang et al , 2012a; Feng et al , 2016), surgical stents and sutures (Lendlein and Langer, 2002; Huang et al , 2013; Jing et al , 2016), deployable structures (Santo et al , 2012; Liu et al , 2014a) and implants for minimally invasive surgery (Yakacki et al , 2007; Liu et al , 2014b). Traditional thermo-responsive shape-memory effect (SME) is usually achieved in the process called “programming”, which makes the material retain a temporary shape for a long period at ambient conditions (Lendlein and Kelch, 2002).…”

Section: Introductionmentioning

confidence: 99%

Tunable shape recovery progress of thermoplastic polyurethane by solvents

Wang

Kou

Hang

et al. 2018

PRT

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Purpose This study aims to present that the chemo-responsive shape recovery of thermoplastic polyurethane (TPU) is tunable by solvents with different solubility parameters, and it is generic for chemo-responsive shape-memory polymer and its composites. Design/methodology/approach Two kinds of commercial TPU samples with different thicknesses were prepared by panel vulcanizer and injection molding (an industrial manner) to investigate their chemo-responsive shape memory properties in acetic ether and acetone. Findings Results showed that all of TPU films with different thicknesses can fully recover their original shapes weather they recover in acetic ether or acetone. But the recovery time of TPU films in acetone is greatly reduced, especially for the twisting samples. The residual strains of recovery TPU samples after extension reduce obviously. Research limitations/implications The great decrement of recovery time is related to two factors. One is due to the bigger solubility parameter of acetone with higher dipole moment compared with those of acetic ether, and the other is the remained internal stress of TPU films after preparation. The internal stress is identified to have an effect on the shape-memory properties by comparing the recovery process of samples with/without annealing. The reduced residual strains of recovery TPU samples after extension is due to the increasing mobility of polymer segments after molecules of acetic ether penetrates into the polymeric chains. Originality/value This is a universal strategy to control the recovery process of shape-memory materials or composites. The underlying mechanism is generic and should be applicable to chemo-responsive shape-memory polymers or their composites.

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High Strength Self‐Healing Magnetic Elastomers With Shape Memory Effect

Cited by 32 publications

References 63 publications

Synthesis and Properties of Magnetic Self‐Healing Polymers: An Effective Method for Improving Interface Compatibility of Doped Functional Polymers

Synthesis and Properties of Magnetic Self‐Healing Polymers: An Effective Method for Improving Interface Compatibility of Doped Functional Polymers

Progress and Roadmap for Intelligent Self‐Healing Materials in Autonomous Robotics

Tunable shape recovery progress of thermoplastic polyurethane by solvents

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