Polypyrrole-Doped Conductive Supramolecular Elastomer with Stretchability, Rapid Self-Healing, and Adhesive Property for Flexible Electronic Sensors

Chen, Jingsi; Liu, Jifang; Thundat, Thomas; Zeng, Hongbo

doi:10.1021/acsami.9b03346

Cited by 139 publications

(92 citation statements)

References 64 publications

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“…Even so, intrinsic healing materials, capable of healing under ambient conditions are generally soft and deformable and mostly in the form of hydrogels or elastomers that feature high polymer chain mobility/flexibility. 6,23,25,[33][34][35][36][37][38][39][40][41][42] Unfortunately, it is a formidable challenge to fabricate high-strength and stiff polymeric materials that could heal damages intrinsically under ambient conditions. This is because the diffusion of the polymer chains in rigid materials is hindered significantly, and the rigidity is not favorable for the intimate contact between fractured interfaces.…”

Section: Introductionmentioning

confidence: 99%

Mechanically Strong and Highly Stiff Supramolecular Polymer Composites Repairable at Ambient Conditions

Zhu

Chen

et al. 2020

CCS Chem

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It is a formidable challenge to fabricate healable polymeric materials with high mechanical strength and stiffness due to the highly suppressed diffusion of their polymer chains. Herein, a high-strength, highly stiff, and repairable/healable supramolecular polymer composite was fabricated by complexing poly(acrylic acid) (PAA) and poly(allylamine hydrochloride) (PAH) in aqueous solutions, followed by molding into desired shapes. Exquisitely tuning the electrostatic and H-bonding interactions between PAA and PAH led to associative phase-separation and in situ formation of nanostructures in the resultant PAA-PAH composites. The H-bonded assembly of PAA-PAH complexes existed as nanospheres were dispersed homogeneously in the continuous phase as an electrostatic assembly of PAA-PAH complexes. Such a structural feature endowed the PAA-PAH copolymer with a doublecross-linked structure, enabling significant reinforcement of the material. a The PAA-PAH composites exhibited a tensile strength and an elastic modulus as high as ∼ 67 MPa and ∼ 2.0 GPa, respectively. Due to the benefits from the reconstruction of the complexes, such as reversible electrostatic interactions and H-bonds between PAA and PAH, the PAA-PAH composite could be repaired/healed readily under ambient conditions (25°C, 40% humidity) by using the liquid-like form of the PAA-PAH complexes (i.e., coacervate). The healing strategy reported here provides a supplementary method for easy repair or healing of high-strength and stiff supramolecular polymer materials.

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Section: Introductionmentioning

confidence: 99%

Mechanically Strong and Highly Stiff Supramolecular Polymer Composites Repairable at Ambient Conditions

Zhu

Chen

et al. 2020

CCS Chem

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“…The presence of a series of tunneling junctions makes the device sensitive to small modulations in the surface potential. [ 15,21 ] This is further confirmed by having a reference electrode with the device (a three electrode set‐up) in aqueous medium and using it to act as a liquid gate. [ 21 ] The change in the gate voltage modulates the current in the device and even changes of 0.5 mV in gate potential can be detected (Figure S8, Supporting Information) with a sensitivity of 1.2 µA V −1 .…”

Section: Figurementioning

confidence: 91%

“…[ 10–13 ] At the same time the wearable device should be made from materials that can be safely handled by users without any health hazards. A variety of materials and strategies have been used to make devices that can accomplish such tasks, typically using a combination of materials such as CNT, [ 14 ] elastomers, [ 15 ] trace patterns of thin films of metals, [ 5 ] metallic [ 16,17 ] and semi conducting nanomaterials, [ 18 ] piezoelectric materials, [ 19 ] thermoelectric materials, [ 11 ] and so on. The fabrication of the devices typically involves multiple steps with deposition of a variety of materials which act as the sensing layers for different stimuli, interconnects and the electrodes.…”

Section: Figurementioning

confidence: 99%

Wearable Devices Using Nanoparticle Chains as Universal Building Blocks with Simple Filtration‐Based Fabrication and Quantum Sensing

Fan

Maheshwari

2020

Adv Materials Technologies

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Self‐assembled micrometer long gold nanoparticle chains are used as building block to fabricate a range of flexible devices to monitor human physiological signals by an easy filtration method. The chains serve as the base material for all the devices and their interconnects and contact pads as well. The micrometer long chains are an array of nanoparticles with gaps of 1–2 nm between adjacent particles. The gaps serve as quantum tunneling barrier and their modulation is basis of signal sensing in these devices. Deposited on a flexible membrane, the chains monitor temperature, artery pulsation, and electrocardiograms (ECG) signals with ease. This simple method provides an avenue to fabricate low cost integrated wearable devices based on quantum phenomena.

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“…Varying the PEIE concentration allows researchers to tune the mechanical characteristics as the PEIE additive will soften mechanical modulus and increase stretchability and adhesion force of the adapted PDMS elastomer [ 208 ]. Other chemical modifications involve polymerizing supramolecular elastomers with conductive polymers that display both self-healing and self-adhesive properties [ 209 ].…”

Section: Mechanical Sensor Characteristics Of Interestmentioning

confidence: 99%

Advances in Materials for Soft Stretchable Conductors and Their Behavior under Mechanical Deformation

Nguyen

Khine

2020

Polymers

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Soft stretchable sensors rely on polymers that not only withstand large deformations while retaining functionality but also allow for ease of application to couple with the body to capture subtle physiological signals. They have been applied towards motion detection and healthcare monitoring and can be integrated into multifunctional sensing platforms for enhanced human machine interface. Most advances in sensor development, however, have been aimed towards active materials where nearly all approaches rely on a silicone-based substrate for mechanical stability and stretchability. While silicone use has been advantageous in academic settings, conventional silicones cannot offer self-healing capability and can suffer from manufacturing limitations. This review aims to cover recent advances made in polymer materials for soft stretchable conductors. New developments in substrate materials that are compliant and stretchable but also contain self-healing properties and self-adhesive capabilities are desirable for the mechanical improvement of stretchable electronics. We focus on materials for stretchable conductors and explore how mechanical deformation impacts their performance, summarizing active and substrate materials, sensor performance criteria, and applications.

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Polypyrrole-Doped Conductive Supramolecular Elastomer with Stretchability, Rapid Self-Healing, and Adhesive Property for Flexible Electronic Sensors

Cited by 139 publications

References 64 publications

Mechanically Strong and Highly Stiff Supramolecular Polymer Composites Repairable at Ambient Conditions

Mechanically Strong and Highly Stiff Supramolecular Polymer Composites Repairable at Ambient Conditions

Wearable Devices Using Nanoparticle Chains as Universal Building Blocks with Simple Filtration‐Based Fabrication and Quantum Sensing

Advances in Materials for Soft Stretchable Conductors and Their Behavior under Mechanical Deformation

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