Self-Assembly of Biofunctional Polymer on Graphene Nanoribbons
Abstract
Graphene’s adhesive properties owing to inherent van der Waals interactions become increasingly relevant in the nanoscale regime. Polymer self-assembly <i>via</i> graphene-mediated noncovalent interactions offers a powerful tool for the creation of anisotropic nanopatterned systems. Here, we report the supramolecular self-assembly of biofunctional-modified poly(2-methoxystyrene) on graphene nanoribbons prepared by unzipping multiwalled carbon nanotubes. This approach promotes the glycol-modified polymer to self-assemble into structured nanopatterns with preserved bioactivity. The self-assembly is attributed to enhanced van der Waals interactions and the associated charge transfer from polymer to graphene. These findings demonstrate that the assembly yields a prospective route to novel nanomaterial systems- Text
- Journal contribution
- Medicine
- Pharmacology
- Biotechnology
- Immunology
- Virology
- Chemical Sciences not elsewhere classified
- Physical Sciences not elsewhere classified
- Information Systems not elsewhere classified
- van der Waals interactions
- polymer
- unzipping multiwalled carbon nanotubes
- nanoscale regime
- novel nanomaterial systems
- anisotropic nanopatterned systems
- charge transfer
- Biofunctional Polymer
- graphene nanoribbons
- assembly yields
Similar works
Full text
Last time updated on 16/03/2018
This paper was published in The Francis Crick Institute.
Having an issue?
Is data on this page outdated, violates copyrights or anything else? Report the problem now and we will take corresponding actions after reviewing your request.