Issue 25, 2021

Towards scalable, low dispersity, and dimensionally tunable 2D platelets using living crystallization-driven self-assembly

Abstract

Nanoscale two-dimensional (2D) rectangular platelets based on polymeric precursors are of interest as a result of their potentially useful properties and applications. Low dispersity 2D platelets can be prepared from crystallizable polymeric amphiphiles via the seeded growth method known as living crystallization-driven self-assembly (CDSA) but only at very low solution concentrations of ca. 0.002–0.01 wt%. This severely limits the ability to explore their properties in detail and to investigate new applications. In this proof-of-concept work we report significant improvements in the scalability of low dispersity 2D nanoparticles prepared via living CDSA of phosphonium-capped poly(ferrocenyldimethylsilane) (PFS) homopolymers, PFS23[PPh2Me]X, with surfactant counteranions (X) at concentrations up to 0.2 wt%, 20 times higher than previously reported. At higher concentrations, platelets are still formed but at the cost of a loss in fidelity. The effects of different counteranions, temperature and concentration on platelet dimensions, structure fidelity, and aggregation behaviour were also explored. Moreover, increasing the temperature at which self-assembly was performed was found to improve the platelet fidelity and yield lower aspect ratio structures at high concentrations.

Graphical abstract: Towards scalable, low dispersity, and dimensionally tunable 2D platelets using living crystallization-driven self-assembly

Supplementary files

Article information

Article type
Paper
Submitted
26 Apr 2021
Accepted
26 May 2021
First published
27 May 2021

Polym. Chem., 2021,12, 3650-3660

Towards scalable, low dispersity, and dimensionally tunable 2D platelets using living crystallization-driven self-assembly

C. E. Ellis, T. Fukui, C. Cordoba, A. Blackburn and I. Manners, Polym. Chem., 2021, 12, 3650 DOI: 10.1039/D1PY00571E

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