Ultrastretchable Graphene-Based Molecular Barriers for Chemical Protection, Detection, and Actuation. Chen, P., Zhang, M., Liu, M., Wong, I. Y., & Hurt, R. H. ACS Nano, 12(1):234–244, 2018.
doi  abstract   bibtex   
A wide range of technologies requires barrier films to impede molecular transport between the external environment and a desired internal microclimate. Adding stretchability to barrier films would enable the applications in packaging, textiles, and flexible devices, but classical barrier materials utilize dense, ordered molecular architectures that easily fracture under small tensile strain. Here, we show that textured graphene-based coatings can serve as ultrastretchable molecular barriers expandable to 1500% areal strain through programmed unfolding that mimics the elasticity of polymers. These coatings retain barrier function under large deformation and can be conformally applied to planar or curved surfaces, where they are washfast and mechanically robust to cycling. These graphene-polymer bilayer structures also function as sensors or actuators by transducing chemical stimuli into mechanical deformation and electrical resistance change through asymmetric polymer swelling. These results may enable multifunctional fabrics that integrate chemical protection, sensing, and actuation, with further applications as selective barriers, membranes, stretchable electronics, or soft robotics.
@article{chen_ultrastretchable_2018,
	title = {Ultrastretchable {Graphene}-{Based} {Molecular} {Barriers} for {Chemical} {Protection}, {Detection}, and {Actuation}},
	volume = {12},
	issn = {1936-086X},
	doi = {10.1021/acsnano.7b05961},
	abstract = {A wide range of technologies requires barrier films to impede molecular transport between the external environment and a desired internal microclimate. Adding stretchability to barrier films would enable the applications in packaging, textiles, and flexible devices, but classical barrier materials utilize dense, ordered molecular architectures that easily fracture under small tensile strain. Here, we show that textured graphene-based coatings can serve as ultrastretchable molecular barriers expandable to 1500\% areal strain through programmed unfolding that mimics the elasticity of polymers. These coatings retain barrier function under large deformation and can be conformally applied to planar or curved surfaces, where they are washfast and mechanically robust to cycling. These graphene-polymer bilayer structures also function as sensors or actuators by transducing chemical stimuli into mechanical deformation and electrical resistance change through asymmetric polymer swelling. These results may enable multifunctional fabrics that integrate chemical protection, sensing, and actuation, with further applications as selective barriers, membranes, stretchable electronics, or soft robotics.},
	language = {eng},
	number = {1},
	journal = {ACS Nano},
	author = {Chen, Po-Yen and Zhang, Mengke and Liu, Muchun and Wong, Ian Y. and Hurt, Robert H.},
	year = {2018},
	pmid = {29165991},
	pmcid = {PMC5780244},
	keywords = {Diffusion, Elasticity, Electronics, Graphite, Humans, Membranes, Artificial, Models, Molecular, Nanostructures, Polymers, Protective Clothing, Robotics, Textiles, Wearable Electronic Devices, broad-range chemical rejection, chemomechanical actuators, chemoresistive sensors, graphene oxide membrane, ultrastretchable molecular barriers},
	pages = {234--244},
}
Downloads: 0
About
Documentation
Keywords
Search
Users
Terms and Conditions of Use
Privacy Policy
Sitemap
© BibBase.org 2021