A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Halloysite clay nanotubes: Innovative applications by smart systems
Abstract Halloysite clay nanotubes (HNTs) are unique porous aluminosilicates that have assumed the role of a multiplex, adaptable, low-cost, and sustainably sourced nanocomposite across a vast array of applications. HNTs have presented diverse opportunities to researchers from different fields, leading to substantial advances in the applications and innovative uses of HNT as a multifaceted nanocomposite in smart system designs. This review focuses on the role of HNTs in intelligent systems that have wholly realized the potential of HNTs and discusses the important structural, chemical, and physical properties of HNTs concerning different applications and as a core element in complex systems. This review highlights the key challenges HNT-based nanocomposites address and provides prospects for the potential applications of HNTs. This review found that smart materials take advantage of the structure, composition, and morphology of HNTs simultaneously, achieving application-specific results due to the passive and active impact of the HNTs on other elements of the smart system and the surrounding environment. Pioneering efforts stemming from the assortment of performance-enhancing options HNTs can offer have revived the application potential of sustainable materials, which have conventionally suffered from low stability, retention, effectiveness, poor mechanical performance, or overall material incompatibility. Furthermore, the dynamic behavior of the HNTs rising from the structural stability of these natural nanotubes across various physical and chemical conditions has permitted researchers to design smart systems based on the operative contributions of HNTs to application-oriented material performance under fluctuating settings. This review highlighted how HNTs are poised to be a component of next-generation materials in sectors vital to sustainable development, ranging from biotechnology to energy storage.
Highlights Halloysite nanotubes are an essential class of materials for sustainable development. The structure of halloysite nanotubes allow for a myriad of modifications and applications. This review discusses smart, responsive, and sustainable halloysite-based systems. Intelligent halloysite-based systems have utilized the full potential of the nanoclay. The choice of the type of halloysite regarding the application should be justified.
Halloysite clay nanotubes: Innovative applications by smart systems
Abstract Halloysite clay nanotubes (HNTs) are unique porous aluminosilicates that have assumed the role of a multiplex, adaptable, low-cost, and sustainably sourced nanocomposite across a vast array of applications. HNTs have presented diverse opportunities to researchers from different fields, leading to substantial advances in the applications and innovative uses of HNT as a multifaceted nanocomposite in smart system designs. This review focuses on the role of HNTs in intelligent systems that have wholly realized the potential of HNTs and discusses the important structural, chemical, and physical properties of HNTs concerning different applications and as a core element in complex systems. This review highlights the key challenges HNT-based nanocomposites address and provides prospects for the potential applications of HNTs. This review found that smart materials take advantage of the structure, composition, and morphology of HNTs simultaneously, achieving application-specific results due to the passive and active impact of the HNTs on other elements of the smart system and the surrounding environment. Pioneering efforts stemming from the assortment of performance-enhancing options HNTs can offer have revived the application potential of sustainable materials, which have conventionally suffered from low stability, retention, effectiveness, poor mechanical performance, or overall material incompatibility. Furthermore, the dynamic behavior of the HNTs rising from the structural stability of these natural nanotubes across various physical and chemical conditions has permitted researchers to design smart systems based on the operative contributions of HNTs to application-oriented material performance under fluctuating settings. This review highlighted how HNTs are poised to be a component of next-generation materials in sectors vital to sustainable development, ranging from biotechnology to energy storage.
Highlights Halloysite nanotubes are an essential class of materials for sustainable development. The structure of halloysite nanotubes allow for a myriad of modifications and applications. This review discusses smart, responsive, and sustainable halloysite-based systems. Intelligent halloysite-based systems have utilized the full potential of the nanoclay. The choice of the type of halloysite regarding the application should be justified.
Halloysite clay nanotubes: Innovative applications by smart systems
Fahimizadeh, Mohammad (author) / Wong, Li Wen (author) / Baifa, Zhang (author) / Sadjadi, Samahe (author) / Auckloo, Sheik Ambarine Banon (author) / Palaniandy, Khanisya (author) / Pasbakhsh, Pooria (author) / Tan, Joash Ban Lee (author) / Singh, R.K. Raman (author) / Yuan, Peng (author)
Applied Clay Science ; 251
2024-02-22
Article (Journal)
Electronic Resource
English
Nanoclay , General mineralogy , Aluminosilicates , Multifunctional materials , Nanocomposite , Sustainable development , 2,2-Diphenyl-1-picrylhydrazyl , (DPPH) , (3-aminopropyl) triethoxysilane , (APTES) , 8-hydroxyquinoline , (8HQ) , aluminum diethylphosphinic acid , (AlPi) , atom transfer radical polymerization , (ATRP) , benzotriazole , (BTA) , blood-brain barrier , (BBB) , Brain microvascular endothelial cells , (BMVECs) , Calcium alginate , (CaAlg) , calcium-(aluminate)-silicate-hydrate , (C-(A)-S-H) , calcium-silicate-hydrate , (C–S–H) , cetrimonium bromide , (CTAB) , chitosan , (CS) , chlorantraniliprole , (CAP) , chlorpyrifos , (CPF) , clove essential oil , (CEO) , diammonium phosphate , (DAP) , doxorubicin , (DOX) , Electrochemical impedance spectroscopy , (EIS) , ethanol extract of <italic>eupatorium adenophora spreng</italic> , (AIEAS) , Ethylenediaminetetraacetic acid , (EDTA) , Folic acid , (FA) , gold nanoparticles , (AuNPs) , graphene aerogel , (GA) , graphene oxide , (GO) , Halloysite , (Hal) , Halloysite clay nanotubes , (HNTs) , HeLa , (human epithelial adenocarcinoma cell line , hollow nanotubular clay composited comb-like methoxy poly(ethylene glycol) acrylate polymer electrolyte , (HCPE) , Li bis(trifluoromethanesulphonyl)imide , (LiTFSI) , Li<inf>0.9</inf>Ni<inf>0.5</inf>Co<inf>0.5</inf>O<inf>2-x</inf>/LiFeO<inf>2</inf> , (HNT-LNCO/LFO) , limestone calcined clay cement , (LC3) , limiting oxygen index , (LOI) , Li-polysulfides , (LiPSs) , lower critical solution temperature , (LCST) , magnesium phosphate-based cements , (MPC) , metal-organic frameworks , (MOFs) , <italic>N</italic>-[3-(trimethoxysilyl)propyl) ethylenediamine , (DAS) , Ordinary Portland cement , (OPC) , phase change materials , (PCM) , poly(ethylene imine) , (PEI) , polyamide 6 , (PA6) , polyaniline , (PANI) , polydimethylsiloxane , (PDMS) , polyethylene glycol , (PEG) , polyethylene oxide , (PEO) , polyglycerol , (PG) , polylactic acid , (PLA) , polyphosphazene , (PZE) , Polystyrene sulfonic acid , (PSSA) , polyvinyl alcohol , (PVA) , praseodymium nitrate , (Pr) , protocatechuic acid , (PCA) , S and N-doped graphene quantum dots , (S, N-GQDs) , slow-release fertilizer , (SRF) , solid polymer electrolyte , (SPE) , Sulfonated halloysite , (SHal) , sulfonated poly(aryl ether sulfone) , (SPES) , sulfonated poly(ether ether ketone) , (SPEEK) , supplementary cementitious materials , (SCMs) , Transmission electron microscopy , (TEM) , ultrasonic pulse velocity , (UPV) , ultraviolet , (UV) , ultraviolet-visible-near infrared , (UV–Vis-NIR) , vinylene carbonate , (VC) , waterborne epoxy , (WEP) , yeast extract , (YE)
Halloysite clay nanotubes hold promise
| British Library Online Contents | 2016
Halloysite clay nanotubes hold promise
| British Library Online Contents | 2016
Halloysite clay nanotubes hold promise
| British Library Online Contents | 2016