Designing Flexible and Self-Healing Electronics Using Hybrid Carbon Black/Nanoclay Composites Based on Diels–Alder Dynamic Covalent Networks

Sahraeeazartamar, Fatemeh; Yang, Zeyu; Terryn, Seppe; Jozić, Dražan; Vanderborght, Bram; Van Assche, Guy; Brancart, Joost

doi:10.1021/acs.macromol.3c01904

Cited by 6 publications

(2 citation statements)

References 44 publications

(76 reference statements)

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“…These results are consistent with the thermal transitions observed in the DSC thermograms (Figure ). The rubbery plateau in the PDMS network lasts for higher temperatures in comparison with the PPO network, which is attributed to the gel transition temperature of the networks ( T gel ), where the network’s behavior transits reversibly from predominantly elastic to liquid-like behavior and vice versa . Before T gel , the gradual decrease of storage and loss modulus (increase of tan δ) is a result of a shift in the DA equilibrium toward the dissociation of adducts and decreased cross-link density.…”

Section: Results and Discussionmentioning

confidence: 99%

Diels–Alder Network Blends as Self-Healing Encapsulants for Liquid Metal-Based Stretchable Electronics

Sahraeeazartamar,

Terryn,

Sangma

et al. 2024

ACS Appl. Mater. Interfaces

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Two dynamic covalent networks based on the Diels−Alder reaction were blended to exploit the properties of the dissimilar polymer backbones. Furan-functionalized polyether amines based on poly(propylene oxide) (PPO) FD4000 and polydimethylsiloxane (PDMS) FS5000 were mixed in a common solvent and reversibly cross-linked with the same bismaleimide DPBM. The morphology of the phase-separated blends is primarily controlled by the concentration of backbones. Increasing the PDMS content of the blends results in a dilute droplet morphology at 25 wt %, with a growing size and concentration of droplets and the formation of two separate PPO-and PDMS-rich layers at 50 wt %. Further increasing the PDMS content to 75 wt % leads to larger droplets and a thicker layer of the secondary phase. The hydrophobic PDMS phase creates a barrier against water, while the more hydrophilic PPO phase enhances the resistance against oxygen diffusion. Lowering the maleimide-to-furan stoichiometric ratio resulted in a decrease in cross-link density and thus more flexible and stretchable encapsulants. Changes in the stoichiometric ratio also affected the phase morphology due to resulting changes in phase separation and network formation kinetics. Lowering the stoichiometric ratio also resulted in enhanced self-healing properties of 96% at room temperature as a consequence of the increased chain mobility in the blended networks. The self-healing blends were used to encapsulate liquid metal circuits to create stretchable strain sensors with a linear electro-mechanical response without much drift or hysteresis, which could be efficiently recovered by 90% after the damage-healing cycles.

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Section: Results and Discussionmentioning

confidence: 99%

Diels–Alder Network Blends as Self-Healing Encapsulants for Liquid Metal-Based Stretchable Electronics

Sahraeeazartamar,

Terryn,

Sangma

et al. 2024

ACS Appl. Mater. Interfaces

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“…The synergistic effect of the Cloisite 15A enhanced the healing efficiency to 88%, while the electrical conductivity of the polymer increased by 70%. It was noted that by increasing the compatibility between the polymer and Cloisite (30A), the mechanical properties exhibited an upward trajectory by increasing the extent of crosslinking, providing a healing efficiency of 193%, but at this concentration the electrical conductivity of the polymer nanocomposite reduced significantly (28%) [ 61 ].…”

Section: Methods Of Self-healing In Self-healable Polymer Nanocompositesmentioning

confidence: 99%

Recent Advances in Polymer Nanocomposites: Unveiling the Frontier of Shape Memory and Self-Healing Properties—A Comprehensive Review

Jamil,

Faizan,

Adeel

et al. 2024

Molecules

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Shape memory and self-healing polymer nanocomposites have attracted considerable attention due to their modifiable properties and promising applications. The incorporation of nanomaterials (polypyrrole, carboxyl methyl cellulose, carbon nanotubes, titania nanotubes, graphene, graphene oxide, mesoporous silica) into these polymers has significantly enhanced their performance, opening up new avenues for diverse applications. The self-healing capability in polymer nanocomposites depends on several factors, including heat, quadruple hydrogen bonding, π–π stacking, Diels–Alder reactions, and metal–ligand coordination, which collectively govern the interactions within the composite materials. Among possible interactions, only quadruple hydrogen bonding between composite constituents has been shown to be effective in facilitating self-healing at approximately room temperature. Conversely, thermo-responsive self-healing and shape memory polymer nanocomposites require elevated temperatures to initiate the healing and recovery processes. Thermo-responsive (TRSMPs), light-actuated, magnetically actuated, and Electrically actuated Shape Memory Polymer Nanocomposite are discussed. This paper provides a comprehensive overview of the different types of interactions involved in SMP and SHP nanocomposites and examines their behavior at both room temperature and elevated temperature conditions, along with their biomedical applications. Among many applications of SMPs, special attention has been given to biomedical (drug delivery, orthodontics, tissue engineering, orthopedics, endovascular surgery), aerospace (hinges, space deployable structures, morphing aircrafts), textile (breathable fabrics, reinforced fabrics, self-healing electromagnetic interference shielding fabrics), sensor, electrical (triboelectric nanogenerators, information energy storage devices), electronic, paint and self-healing coating, and construction material (polymer cement composites) applications.

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Self‐healing reversible network from furfuryl‐functionalized copoly(triazine‐r‐polypropylene glycol‐r‐polydimethylsiloxane)

Truong,

Nguyen,

et al. 2024

Polymer Engineering & Sci

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New shape‐memory networks composed of both reversible Diels–Alder covalent crosslinks and the hydrogen and π–π stacking bonds of triazine functional groups, with self‐healing properties as a result of the reversibility of these dynamic bonds were achieved from a furfuryl‐functionalized copoly(triazine‐r‐polypropylene glycol‐r‐polydimethylsiloxane), crosslinked with a maleimide end‐capped polycaprolactone and a long polycaprolactone‐based chain extender. The presence of multiple dynamic bonds, including the Diels–Alder and triazine‐derived π–π stacking and H‐bond interactions as well as the enhanced network mobility arising from polypropylene glycol, polydimethylsiloxane and polycaprolactone segments upon triggering the shape memory effect resulted in a material with high toughness (~200 MPa J−1) and efficient healing ability (with a recoveries of tensile strength and toughness after being cut and healed of 87% and 94%, respectively).Highlights Furfuryl dichlorotriazine was coupled with PPG and PDMS forming a copolymer. The copolymer was crosslinked with PCL‐dimaleimide and PCL‐difuran extender. Multiple dynamic bonds (Diels–Alder, π–π stacking and H‐bond) were present. The network showed high toughness and good healing performance.

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Designing Flexible and Self-Healing Electronics Using Hybrid Carbon Black/Nanoclay Composites Based on Diels–Alder Dynamic Covalent Networks

Cited by 6 publications

References 44 publications

Diels–Alder Network Blends as Self-Healing Encapsulants for Liquid Metal-Based Stretchable Electronics

Diels–Alder Network Blends as Self-Healing Encapsulants for Liquid Metal-Based Stretchable Electronics

Recent Advances in Polymer Nanocomposites: Unveiling the Frontier of Shape Memory and Self-Healing Properties—A Comprehensive Review

Self‐healing reversible network from furfuryl‐functionalized copoly(triazine‐r‐polypropylene glycol‐r‐polydimethylsiloxane)

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