Laser‐Enabled Processing of Stretchable Electronics on a Hydrolytically Degradable Hydrogel

Rahimi, Rahim; Es‐haghi, S. Shams; Chittiboyina, Shirisha; Mutlu, Zeynep; Lelièvre, Sophie A.; Cakmak, Mukerrem; Ziaie, Babak

doi:10.1002/adhm.201800231

Cited by 30 publications

(34 citation statements)

References 67 publications

(117 reference statements)

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“…This geometry is particularly applicable when both adherends are thin and flexible. 81,82 The adhesive material can have a stiffer backing, which helps to prevent stretching of the sample during peeling. 82 The force required to peel the adhesive away from the bonded surface is measured as a function of peeling distance.…”

Section: Evaluation Of Practical Adhesionmentioning

confidence: 99%

Catechol-functionalized hydrogels: biomimetic design, adhesion mechanism, and biomedical applications

et al. 2020

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Section: Evaluation Of Practical Adhesionmentioning

confidence: 99%

Catechol-functionalized hydrogels: biomimetic design, adhesion mechanism, and biomedical applications

et al. 2020

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“…Stretchable hydrogels are promising materials for diverse applications, such as biomaterials 1 , force sensors 2 , 3 , supercapacitors 4 , actuators 5 , optical fibers 6 , stretchable conductors 7 and soft electronics 8 . Since the hydrogels undergo dynamic actions in these applications, such as stretching, compression and torsion, they should have appropriate mechanical strength, flexibility and stretchability under deformation.…”

Section: Introductionmentioning

confidence: 99%

Ultra-stretchable hydrogels with hierarchical hydrogen bonds

You

Yang

Zheng

et al. 2020

Sci Rep

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Hydrogels are attractive for applications in intelligent soft materials and flexible electronics. Herein, we report a new hydrogel with a hierarchical hydrogen bond system consisting of (1) weak hydrogen bonds between N,N-dimethylacrylamides (DMAA) and acrylic acids (AAc) and (2) strong multiple hydrogen bonds between 2-ureido-4[1H]-pyrimidinone units. By optimizing the ratios of DMAA and AAc and the balance of weak and strong hydrogen bonds, the hydrogels have unique properties. The transparent hydrogels have tunable Young's modulus (70-1,250 kPa) and are highly stretchable (up to 4,340% strain), tough (fracture energies of 10.8 kJ/m 2 , matching natural rubber) and insensitive to notches when it is highly stretched (λ = 19.6). Stretchable hydrogels are promising materials for diverse applications, such as biomaterials 1 , force sensors 2,3 , supercapacitors 4 , actuators 5 , optical fibers 6 , stretchable conductors 7 and soft electronics 8. Since the hydrogels undergo dynamic actions in these applications, such as stretching, compression and torsion, they should have appropriate mechanical strength, flexibility and stretchability under deformation. Intensive efforts have been devoted to developing tough and elastic hydrogels. Gong et al. 9 reported a double network hydrogel (DN hydrogel) by introducing a soft hydrogel network with slippery chains into a rigid hydrogel network. The internal fracture of covalent bonds in the brittle network, which dissipates significant energy 10. The soft network absorbs the energy and prevents the formation of macroscopic crack. DN hydrogels show robust mechanical strength and toughness. However, permanent chemical fracture in DN hydrogels led to poor fatigue resistance. The toughness and elasticity of DN hydrogel originate from the mechanism of disruption of sacrificial bonds, which dissipated energy 11. Attempts to introduce other chemical structures or physical crosslinks as sacrificial bonds have been made, such as ionic bonds 12,13 , triblock copolymers 14 and polyampholytes 15. Hybrid hydrogel systems by introducing crystallites 16 and microspheres 17 , micelles 18 , nanocomposite 19,20 into the hydrogels have also been reported. These reversible crosslinked sacrificial bonds or microstructures synergically dissipated energy, which endows hydrogels with high stretchability and toughness. Hydrogen bonds are promising dynamic bonds to impart fascinating properties, such as self-healing 21-23 , toughness 24,25 , and shape memory 26. Hydrogen bonds are stable in the presence of ions and they are different from other aggregates like micelles, inorganic fillers, which have sizes at the nano or micron level and impede the optical properties. Hydrogel base on hydrogen bonds can be transparent, which is favorable to sensors and electronics. However, hydrogels with only one energy-dissipating mechanism by H-bonds cannot achieve satisfactory overall mechanical properties. They are either soft and tough or strong and brittle 27-29. Here, we report a new multiple energy-dissipating h...

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“…Emerging nanostructured materials open a new avenue for the design and fabrication of these components [4]. The novel efficient manufacturing technologies of conductive structures promote the rapid emerging of high-performance electronics, including various sensors [5][6][7], energy devices [8][9][10], and even integrated devices [11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Laser Erasing and Rewriting of Flexible Copper Circuits

2021

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Integrating construction and reconstruction of highly conductive structures into one process is of great interest in developing and manufacturing of electronics, but it is quite challenging because these two involve contradictive additive and subtractive processes. In this work, we report an all-laser mask-less processing technology that integrates manufacturing, modifying, and restoring of highly conductive Cu structures. By traveling a focused laser, the Cu patterns can be fabricated on the flexible substrate, while these as-written patterns can be selectively erased by changing the laser to a defocused state. Subsequently, the fresh patterns with identical conductivity and stability can be rewritten by repeating the writing step. Further, this erasing–rewriting process is also capable of repairing failure patterns, such as oxidation and cracking. Owing to the high controllability of this writing–erasing–rewriting process and its excellent reproducibility for conductive structures, it opens a new avenue for rapid healing and prototyping of electronics.

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Laser‐Enabled Processing of Stretchable Electronics on a Hydrolytically Degradable Hydrogel

Cited by 30 publications

References 67 publications

Catechol-functionalized hydrogels: biomimetic design, adhesion mechanism, and biomedical applications

Catechol-functionalized hydrogels: biomimetic design, adhesion mechanism, and biomedical applications

Ultra-stretchable hydrogels with hierarchical hydrogen bonds

Laser Erasing and Rewriting of Flexible Copper Circuits

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