Self-healing nanocomposites via N-doped GO promoted "click chemistry".
R V Siva Prasanna SankaSravendra RanaPoonam SinghAbhishek K MishraPankaj KumarManjeet SinghNanda Gopal SahooWolfgang Hubertus BinderGun Jin YunChanwook ParkPublished in: Soft matter (2022)
N-doped graphene stabilized Cu(I)-catalyzed self-healing nanocomposites are developed. This study found the use of N-doped graphene as both a nanostructured material for enhancing mechanical and conductive properties and a catalyst promoter (a scaffold for catalytic copper(I) particles), helpful to trigger self-healing via "click chemistry". Due to an increase in electron density on nitrogen atom doping, including the coordination of N-doped rGO with Cu + ions, nitrogen-doped graphene-supported copper particles demonstrate a higher reaction yield at room temperature without adding any external ligand/base. In this study, only one component (an azide moiety containing a healing agent) was encapsulated, whereas another component (an alkyne moiety containing a healing agent) was as such (without encapsulation) homogeneously dispersed in a matrix. Triggered capsule rupture then induces the contact of the healing agents with the N-doped graphene-based catalyst and the alkyne molecules dispersed in the matrix, inducing a "click"-reaction, allowing onsite damage to be repaired as determined by mechanical measurements entirely. Tensile measurements were also performed using molecular dynamics (MD) simulations to support the findings. Given the enormous importance of autonomic repair of materials damage, this concept here reports a trustworthy and reliable chemical system with a high level of robustness.
Keyphrases
- room temperature
- molecular dynamics
- quantum dots
- visible light
- metal organic framework
- highly efficient
- ionic liquid
- reduced graphene oxide
- density functional theory
- carbon nanotubes
- gene expression
- blood pressure
- emergency department
- heart rate variability
- electron transfer
- walled carbon nanotubes
- aqueous solution
- amino acid
- carbon dioxide
- oxide nanoparticles
- monte carlo
- tissue engineering