Fabric Nanocomposite Resistance Temperature Detector

Blasdel, Nathaniel J.; Wujcik, Evan K.; Carletta, Joan; Lee, Kye-Shin; Monty, Chelsea N.

doi:10.1109/jsen.2014.2341915

Cited by 52 publications

(38 citation statements)

References 35 publications

(31 reference statements)

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“…CNTs and graphene are quite similar in many aspects, like their compositions, electrical, thermal, and optical properties [79]. Therefore, CNTs can be applied to such areas as electronics, energy, and sensors [80][81][82][83]. They are also an effective adsorbent for metal ion removal from water [84,85].…”

Section: Carbon Nanotube-based Nanoadsorbentsmentioning

confidence: 99%

Carbon nanotubes, graphene, and their derivatives for heavy metal removal

Guo

et al. 2017

Adv Compos Hybrid Mater

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170

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Carbon nanoadsorbents have attracted tremendous interest for metal ion removal from wastewater due to their extraordinary aspect ratios, surface areas, porosities, and reactivities. However, challenges still exist as they suffer from subpar dispersion and recovery, tending to aggregate, and so on. Thus, significant research efforts focus on modification of these carbon nanomaterials to increase the dispersions and recoveries, while maintaining or even enhancing the desirable properties. This review aims to give an in-depth look at recent and impactful advances in metal ion adsorption applications involving these modified carbon nanostructures. Here, the advanced design and testing of modified carbon nanostructures for metal ion removal are emphasized with comprehensive examples, and various adsorption behaviors and mechanisms are discussed, which are hoped to help the development of more effective adsorbents for water treatment.

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Section: Carbon Nanotube-based Nanoadsorbentsmentioning

confidence: 99%

Carbon nanotubes, graphene, and their derivatives for heavy metal removal

Guo

et al. 2017

Adv Compos Hybrid Mater

Self Cite

170

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“…Polymerverbundmaterialien mit leitfähigen oder temperaturempfindlichen Additiven erwiesen sich als hoch biegsam und zeigten große Widerstandsänderungen in Abhängigkeit von der Temperatur. Viele Arten von Additiven wie CNTs, Ruße, Kohlenstofffasern und metallische Partikel konnten durch Nassspinnen, Schmelzspinnen und Beschichtungsmethoden in Polymerfasern eingearbeitet werden . Die Widerstandsänderung wird durch die Ausdehnung/Kontraktion der Polymermatrix mit steigender/sinkender Temperatur und die damit verbundene Formänderung des leitfähigen Fasernetzwerks verursacht.…”

Section: Elektrische Multifunktionstextilienunclassified

Smarte elektronische Textilien

Weng

Chen

et al. 2016

Angewandte Chemie

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Dieser Aufsatz beschreibt den aktuellen Forschungsstand auf dem Gebiet der tragbaren Elektronik (“smarte” Textilien). Wir diskutieren die hauptsächlichen Anwendungsformen smarter elektronischer Textilien zur Erzeugung, Speicherung und Nutzung von Elektrizität mit dem Fokus auf funktionellen Materialien. Ein weiterer wichtiger Aspekt ist die Integration dieser Einzelfunktionen. Verbleibende Herausforderungen werden aufgezeigt und Hinweise für zukünftige Entwicklungsrichtungen gegeben.

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“…While nanofibers have already shown their utility as electronic sensors for sweat ion, and temperature detection, the detriment to these devices is that they require the use of extra electronics, and professional expertise to accurately interpret the results. Earlier in 2016, Guder et al .…”

Section: Introductionmentioning

confidence: 99%

Morphological traits essential to electrospun and grafted Nylon‐6 nanofiber membranes for capturing submicron simulated exhaled breath aerosols

Frey

2017

J of Applied Polymer Sci

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As contagious bio‐aerosols continue to impact our society, we examine how the morphological traits of large‐scale (15 cm × 93 cm), uniformly thick, electrospun nylon membranes can contribute to the ongoing development of diagnostic, sensor driven, face masks for capturing exhaled breath content. In our study, we compare the capture efficiencies of three types of large‐scale Nylon‐6 nanofiber membranes against those of commercial control textiles for capturing in‐lab simulated salt breath aerosols. Furthermore, samples from the Nylon membranes were grafted with acrylic acid to determine the effects of membrane functionalization on capture efficiency. All nongrafted electrospun Nylon membranes captured 39% to 50% more salinated aerosol than the woven and nonwoven controls, despite weighing nearly 20× less. Ultimately, the nanofiber membranes were found to be far more robust during aerosol capture. Although the grafted membranes underperformed compared to the nongrafted ones, they still captured 20% to 40% more aerosol content sized between 3.5 and 6.0 µm (the known size range of exhaled aerosol from typical human saliva) than the woven controls. The fabrication, functionalization, and exhaled aerosol capture of these large‐scale nanofiber membranes underscores the importance of assessing the lifetime, and usability, of electrospun materials before future integration with diagnostic sensing platforms can be successfully achieved. © 2017 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2017, 134, 44759.

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Fabric Nanocomposite Resistance Temperature Detector

Cited by 52 publications

References 35 publications

Carbon nanotubes, graphene, and their derivatives for heavy metal removal

Carbon nanotubes, graphene, and their derivatives for heavy metal removal

Smarte elektronische Textilien

Morphological traits essential to electrospun and grafted Nylon‐6 nanofiber membranes for capturing submicron simulated exhaled breath aerosols

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