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Cellulosic Nanofibers Utilizing a Silicone Elastomeric Core to Form Stretchable Paper
by
Elhadad, Anwar
, Brown, Matthew S.
, Choi, Seokheun
, Rafiee, Zahra
, Dorsainvil, Joab S.
, Koh, Ahyeon
in
Actuators
/ Biocompatibility
/ Bioelectricity
/ Cellulose acetate
/ Cellulose fibers
/ coaxial electrospun cellulose fibers
/ Elastomers
/ Electronics
/ Energy storage
/ Material properties
/ Microfibers
/ paper‐based electronics
/ Sheaths
/ Silicones
/ soft bioelectronics
/ Stretchability
/ stretchable fibrous electronic substrates
/ Substrates
/ Wearable technology
2024
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Cellulosic Nanofibers Utilizing a Silicone Elastomeric Core to Form Stretchable Paper
by
Elhadad, Anwar
, Brown, Matthew S.
, Choi, Seokheun
, Rafiee, Zahra
, Dorsainvil, Joab S.
, Koh, Ahyeon
in
Actuators
/ Biocompatibility
/ Bioelectricity
/ Cellulose acetate
/ Cellulose fibers
/ coaxial electrospun cellulose fibers
/ Elastomers
/ Electronics
/ Energy storage
/ Material properties
/ Microfibers
/ paper‐based electronics
/ Sheaths
/ Silicones
/ soft bioelectronics
/ Stretchability
/ stretchable fibrous electronic substrates
/ Substrates
/ Wearable technology
2024
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Cellulosic Nanofibers Utilizing a Silicone Elastomeric Core to Form Stretchable Paper
by
Elhadad, Anwar
, Brown, Matthew S.
, Choi, Seokheun
, Rafiee, Zahra
, Dorsainvil, Joab S.
, Koh, Ahyeon
in
Actuators
/ Biocompatibility
/ Bioelectricity
/ Cellulose acetate
/ Cellulose fibers
/ coaxial electrospun cellulose fibers
/ Elastomers
/ Electronics
/ Energy storage
/ Material properties
/ Microfibers
/ paper‐based electronics
/ Sheaths
/ Silicones
/ soft bioelectronics
/ Stretchability
/ stretchable fibrous electronic substrates
/ Substrates
/ Wearable technology
2024
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Cellulosic Nanofibers Utilizing a Silicone Elastomeric Core to Form Stretchable Paper
Journal Article
Cellulosic Nanofibers Utilizing a Silicone Elastomeric Core to Form Stretchable Paper
2024
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Overview
Paper, an inexpensive material with natural biocompatibility, non‐toxicity, and biodegradability, allows for affordable and cost‐effective substrates for unconventional advanced electronics, often called papertronics. On the other hand, polymeric elastomers have shown to be an excellent success for substrates of soft bioelectronics, providing stretchability in skin wearable technology for continuous sensing applications. Although both materials hold their unique advantageous characteristics, merging both material properties into a single electronic substrate reimagines paper‐based bioelectronics for wearable and patchable applications in biosensing, energy generation and storage, soft actuators, and more. Here, a breathable, light‐weighted, biocompatible engineered stretchable paper is reported via coaxial nonwoven microfibers for unconventional bioelectronic substrates. The stretchable papers allow intimate bioconformability without adhesive through coaxial electrospinning of a cellulose acetate polymer (sheath) and a silicone elastomer (core). The fabricated cellulose‐silicone fibers exhibit a greater percent strain than commercially available paper while retaining hydrophilicity, biocompatibility, combustibility, disposable, and other natural characteristics of paper. Moreover, the nonwoven stretchable cellulose‐silicone fibrous mat can adapt conventional printing and fabrication process for paper‐based electronics, an essential aspect of advanced bioelectronic manufacturing. Paper, an inexpensive material with natural properties, allows for cost‐effective and patternable substrates for unconventional advanced electronics, often called papertronics. However, papertronics are limited by their mechanical mismatch with the epidermal layer of skin. By integrating elastomeric properties within the paper fibers, forming networks of coaxial fibers (silicone and cellulose) reimagines paper‐based bioelectronics with stretchable characteristics for wearable applications.
Publisher
John Wiley & Sons, Inc,Wiley-VCH
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