Unveiling the thermal management and flame retardancy of Polyimide nano-crosslinked aminosilane modified MXene aerogels DOI
Varsha D. Phadtare,

Kyu-Yeon Lee,

Vinayak G. Parale

и другие.

Polymer Degradation and Stability, Год журнала: 2025, Номер unknown, С. 111212 - 111212

Опубликована: Янв. 1, 2025

Язык: Английский

Self‐Adhesive Polydimethylsiloxane Foam Materials Decorated with MXene/Cellulose Nanofiber Interconnected Network for Versatile Functionalities DOI Open Access
Haiyang Chen,

Zuan‐Yu Chen,

Min Mao

и другие.

Advanced Functional Materials, Год журнала: 2023, Номер 33(48)

Опубликована: Июль 17, 2023

Abstract Polydimethylsiloxanes (PDMS) foam as one of next‐generation polymer materials shows poor surface adhesion and limited functionality, which greatly restricts its potential applications. Fabrication advanced PDMS with multiple functionalities remains a critical challenge. In this study, unprecedented self‐adhesive are reported worm‐like rough structure reactive groups for fabricating multifunctional nanocomposites decorated MXene/cellulose nanofiber (MXene/CNF) interconnected network by facile silicone foaming dip‐coating strategy followed silane modification. Interestingly, such produces strong interfacial the hybrid MXene/CNF nano‐coatings. Consequently, optimized have excellent super‐hydrophobicity (water contact angle ≈159 o ), tunable electrical conductivity (from 10 −8 to S m −1 stable compressive cyclic reliability in both wide‐temperature range −20 200 C) complex environments (acid, sodium, alkali conditions), outstanding flame resistance (LOI value >27% low smoke production rate), good thermal insulating performance reliable strain sensing various stress modes environmental conditions. It provides new route rational design development versatile multifunctionalities promising applications intelligent healthcare monitoring fire‐safe insulation.

Язык: Английский

Процитировано

177

2D MXenes for Fire Retardancy and Fire‐Warning Applications: Promises and Prospects DOI Creative Commons
Lei Liu,

Jiabing Feng,

Yijiao Xue

и другие.

Advanced Functional Materials, Год журнала: 2022, Номер 33(9)

Опубликована: Дек. 16, 2022

Abstract Frequent fire disasters have caused massive impacts to the environment, human beings, and economy. MXene has recently been intensively researched as potential flame retardants provide passive protection for other materials via its physical barrier catalyzing carbonization effects. In parallel, also demonstrated a great promise creating early warning sensors, which is an emerging field that active response through thermoelectric effect. This makes it possible integrate retardancy into one MXene‐based system on demand. However, fulfilling these promises needs more research. Herein, overview of flame‐retardant next‐generation smart materials/sensors based derivatives provided. study reviews their conceptual design, characterization, modification principles, performances, applications, mechanisms. A discussion challenges need be solved future practical applications opportunities presented.

Язык: Английский

Процитировано

167

Color adjustable, mechanically robust, flame-retardant and weather-resistant TiO2/MMT/CNF hierarchical nanocomposite coatings toward intelligent fire cyclic warning and protection DOI

Shen Yanbin,

Kexin Yu,

Ye‐Jun Wang

и другие.

Composites Part B Engineering, Год журнала: 2023, Номер 271, С. 111159 - 111159

Опубликована: Дек. 21, 2023

Язык: Английский

Процитировано

84

Facile fabrication of low-content surface-assembled MXene in silicone rubber foam materials with lightweight, wide-temperature mechanical flexibility, improved flame resistance and exceptional smoke suppression DOI
Haiyang Chen, Yang Li,

Peng-Huan Wang

и другие.

Composites Part A Applied Science and Manufacturing, Год журнала: 2023, Номер 177, С. 107907 - 107907

Опубликована: Ноя. 17, 2023

Язык: Английский

Процитировано

52

Natural microfibrils/regenerated cellulose-based carbon aerogel for highly efficient oil/water separation DOI
Xiang Ma, Shuang Zhou, Junting Li

и другие.

Journal of Hazardous Materials, Год журнала: 2023, Номер 454, С. 131397 - 131397

Опубликована: Апрель 12, 2023

Язык: Английский

Процитировано

49

Regenerated cellulose/chitosan composite aerogel with highly efficient adsorption for anionic dyes DOI

Shaochun He,

Junting Li, Xiaoqian Cao

и другие.

International Journal of Biological Macromolecules, Год журнала: 2023, Номер 244, С. 125067 - 125067

Опубликована: Май 26, 2023

Язык: Английский

Процитировано

47

Preparation of ambient-dried multifunctional cellulose aerogel by freeze-linking technique DOI
Xiao Hu, Shanshan Zhang, Bo Yang

и другие.

Chemical Engineering Journal, Год журнала: 2023, Номер 477, С. 147044 - 147044

Опубликована: Окт. 31, 2023

Язык: Английский

Процитировано

44

Lightweight, surface hydrophobic and flame-retardant polydimethylsiloxane foam composites coated with graphene oxide via interface engineering DOI

Fei‐Xiang Shen,

Yang Li,

Zuan‐Yu Chen

и другие.

Progress in Organic Coatings, Год журнала: 2024, Номер 189, С. 108276 - 108276

Опубликована: Фев. 6, 2024

Язык: Английский

Процитировано

41

Synthesis of Hybrid/Superhydrophobic Coupling Agent Grafted Nano SiO2 and Its Use in Fabrication of Rubber Nanocomposite with Outstanding Oil/Water Separation Capability DOI Creative Commons
Reza Ghamarpoor, Masoud Jamshidi,

Zainab Allawi Kadhim Alhaeehm

и другие.

Results in Engineering, Год журнала: 2024, Номер 22, С. 102270 - 102270

Опубликована: Май 15, 2024

Design and synthesis of a new sorbent with high performances oil-water separation is one the challenges to world community. Herein, superhydrophobic/novel coupling agent (NCA) containing several vinyl groups was synthesized. Also, isocyanate (VI) tetraethoxysilane (TEOS) reacted synergetic strategy crosslinked networks through click reaction under N2 gas atmosphere. 1H-NMR FTIR analyses confirmed formation NCA SiC10H18O6N2 chemical formula. Then, grafted on nanoparticles at different amounts by sol-gel method. It found that surface modification enhanced water contact angle (WCA) from 60° 163°. In following, without were applied contents tire rubber compound. The uniform dispersion/distribution nano fillers in polymer matrix strong filler-polymer interactions crosslink density improved mechanical sample. prepared nanocomposites tested against absorption oils. results showed superior nanocomposite modified (i.e. TR-TNS5) had efficiency over 90% compared pure TR-NS5) which less than 30%. cycle 95% after addition (from 240 440 cycles). illustrated angles 153.22° 13.34° oil droplets, respectively. rubbery performances.

Язык: Английский

Процитировано

34

Ultralight Three‐Layer Gradient‐Structured MXene/ Reduced Graphene Oxide Composite Aerogels with Broadband Microwave Absorption and Dynamic Infrared Camouflage DOI
Chi Yu,

Dexuan Lin,

Jianhua Guo

и другие.

Small, Год журнала: 2024, Номер unknown

Опубликована: Май 2, 2024

Abstract Infrared and radar detectors posed substantial challenges to weapon equipment personnel due their continuous surveillance reconnaissance capabilities. Traditional single‐band stealth devices are insufficient for dual‐band detection in both infrared microwave bands. To overcome this limitation, a gradient‐structured MXene/reduced graphene oxide (rGO) composite aerogel (GMXrGA) is fabricated through two‐step bidirectional freeze casting process, followed by freeze‐drying thermal annealing. GMXrGA exhibits distinct three‐layered structure, with each layer playing crucial role absorption. This deliberate design amplifies the efficiency of absorption material's effectiveness dynamic camouflage. displays an ultralow density 5.2 mg∙cm −3 demonstrates exceptional resistance compression, enduring 200 cycles at maximum strain 80%. Moreover, it shows superior performance, minimum reflection loss ( RL min ) –60.1 dB broad effective bandwidth EAB 14.1 GHz (3.9–18.0 GHz). Additionally, low conductivity (≈26 mW∙m −1 ∙K camouflage capabilities within temperature range 50–120 °C, achieving rapid concealment 30 s. Consequently, they hold great potential diverse applications, including intelligent buildings, wearable electronics, equipment.

Язык: Английский

Процитировано

26