Recent trends in MXene polymeric Hydrogel bionanoarchitectures and applications
Clicks: 40
ID: 280676
2022
Article Quality & Performance Metrics
Overall Quality
Improving Quality
0.0
/100
Combines engagement data with AI-assessed academic quality
Reader Engagement
Emerging Content
3.9
/100
13 views
13 readers
Trending
AI Quality Assessment
Not analyzed
Abstract
Recently, hydrogels (HYD) have garnered tremendous interest because of their potential uses in sensors, flexible energy storing gadgets, human@machine-interfacial systems, soft electronics and actuating machines. As a result of their inherent exhibition of hydrophilicity, metallically inclined conductivity, elevated aspect ratio, architectural disposition along with tune-able attributes, when 2-D transitionally inclined metallic carbides/nitrides or M−X are embedded within HYD systems, they give enchanting and wide settings for the fabrication of M−X oriented soft materials with tunable applicability and multifunctional properties. M−X@HYD bionanoarchitectures exceptional properties are propelled by intricate gel architectures along with gelation strategies, requiring versatile studies and engineering at the nanoscale. Nevertheless, M−X embedment within HYD can notably increment M−X stability, which regularly is an inhibiting parameter for varying M−X oriented uses. Nevertheless, through simplified modifications, M−X@HYD derivatives like aerogels, are liable to be garnered, thereby broadening their horizon. Therefore, this elucidation presents recently emerging trends in M−X@HYD architectures, multifunctional applications and enhancement of the performance of M−X−oriented gadgets. Herein, the prevailing architectures of varying M−X@HYD constructions as well as inherent gelation mechanisms along with their interlinkage propelling forces are elucidated. Their unique properties and multifunctional applications (electromagnetic interference shielding, biomedicals, energy storage/harvesting, sensing and catalysis), emanating from embedment of M−X within HYD are comprehensively and elaborately elucidated in this review paper.
| Reference Key |
idumah2022recentcleaner
Use this key to autocite in the manuscript while using
SciMatic Manuscript Manager or Thesis Manager
|
|---|---|
| Authors | Idumah, Christopher Igwe; |
| Journal | Cleaner Materials |
| Year | 2022 |
| DOI |
DOI not found
|
| URL | |
| Keywords |
chemistry
microscopy
Materials of engineering and construction. Mechanics of materials
Chemical technology
Engineering (General). Civil engineering (General)
Technology
Electrical engineering. Electronics. Nuclear engineering
Descriptive and experimental mechanics
Science (General)
physics
social sciences (general)
|
Citations
No citations found. To add a citation, contact the admin at info@scimatic.org
Comments
No comments yet. Be the first to comment on this article.