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AuthorXu, Weiheng
AuthorFranklin, Rahul
AuthorRavichandran, Dharneedar
AuthorBawareth, Mohammed
AuthorJambhulkar, Sayli
AuthorZhu, Yuxiang
AuthorKakarla, Mounika
AuthorEjaz, Faizan
AuthorKwon, Beomjin
AuthorHassan, Mohammad K.
AuthorAl-Ejji, Maryam
AuthorAsadi, Amir
AuthorChawla, Nikhilesh
AuthorSong, Kenan
Available date2023-02-02T04:34:12Z
Publication Date2022
Publication NameAdvanced Functional Materials
ResourceScopus
URIhttp://dx.doi.org/10.1002/adfm.202204731
URIhttp://hdl.handle.net/10576/39387
AbstractAnisotropic polymer/nanoparticle composites display unique mechanical, thermal, electrical, and optical properties depending on confirmation and configuration control of the composing elements. Processes, such as vapor deposition, ice-templating, nanoparticle self-assembly, additive manufacturing, or layer-by-layer casting, are explored to design and control nanoparticle microstructures with desired anisotropy or isotropy. However, limited attempts are made toward nanoparticle patterning during continuous fiber spinning due to the thin-diameter cross section and 1D features. Thus, this research focuses on a new patterning technique to form ordered nanoparticle assembly in layered composite fibers. As a result, distinct layers can be retained with innovative tool design, unique material combinations, and precise rheology control during fiber spinning. The layer multiplying-enabled nanoparticle patterning is demonstrated in a few material systems, including polyvinyl alcohol (PVA)-boron nitride (BN)/PVA, polyacrylonitrile (PAN)-aluminum (Al)/PAN, and PVA-BN/graphene nanoplatelet (GNP)/PVA systems. This approach demonstrates an unprecedentedly reported fiber manufacturing platform for well-managed layer dimensions and nanoparticle manipulations with directional thermal and electrical properties that can be utilized in broad applications, including structural supports, heat exchangers, electrical conductors, sensors, actuators, and soft robotics.
SponsorW.X. and R.F. contributed equally to this work. This work was funded by the Global Sports Institute (GSI) at Arizona State University and the U.S. National Science Foundation (NSF, EAGER 1902172).
Languageen
PublisherJohn Wiley and Sons Inc
Subjectanisotropic
energy efficiency
multilayers
passive thermoregulators
polymer nanoparticle composites
TitleContinuous Nanoparticle Patterning Strategy in Layer-Structured Nanocomposite Fibers
TypeArticle
Issue Number35
Volume Number32
dc.accessType Abstract Only


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