Samuel Pearce scite author profile

This Perspective outlines recent advances concerning the formation and potential uses of block copolymer micelles, a class of soft matter-based nanoparticles of growing importance. As a result of rapidly expanding interest since the mid 1990s, substantial advances have been reported in terms of the development of morphological diversity and complexity, control over micelle dimensions, scale up, and applications in a range of areas from nanocomposites to nanomedicine.

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Complex and Hierarchical 2D Assemblies via Crystallization-Driven Self-Assembly of Poly(l-lactide) Homopolymers with Charged Termini

Hsiao

et al. 2017

J. Am. Chem. Soc.

116

110

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Poly(l-lactide) (PLLA)-based nanoparticles have attracted much attention with respect to applications in drug delivery and nanomedicine as a result of their biocompatibility and biodegradability. Nevertheless, the ability to prepare PLLA assemblies with well-defined shape and dimensions is limited and represents a key challenge. Herein we report access to a series of monodisperse complex and hierarchical colloidally stable 2D structures based on PLLA cores using the seeded growth, "living-crystallization-driven self-assembly" method. Specifically, we describe the formation of diamond-shaped platelet micelles and concentric "patchy" block co-micelles by using seeds of the charge-terminated homopolymer PLLA[PPhMe]I to initiate the sequential growth of either additional PLLA[PPhMe]I or a crystallizable blend of the latter with the block copolymer PLLA-b-P2VP, respectively. The epitaxial nature of the growth processes used for the creation of the 2D block co-micelles was confirmed by selected area electron diffraction analysis. Cross-linking of the P2VP corona of the peripheral block in the 2D block co-micelles using Pt nanoparticles followed by dissolution of the interior region in good solvent for PLLA led to the formation of novel, hollow diamond-shaped assemblies. We also demonstrate that, in contrast to the aforementioned results, seeded growth of the unsymmetrical PLLA BCPs PLLA-b-P2VP or PLLA-b-PAGE alone from 2D platelets leads to the formation of diamond-fiber hybrid structures.

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Scalable Fiber-like Micelles and Block Co-micelles by Polymerization-Induced Crystallization-Driven Self-Assembly

et al. 2018

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Self-assembled 1D block copolymer nanoparticles (micelles) are of interest for a range of applications. However, morphologically pure samples are often challenging to access, and precise dimensional control is not possible. Moreover, the development of synthetic protocols that operate on a commercially viable scale has been a major challenge. Herein, we describe the preparation 1D fiber-like micelles with crystalline cores at high concentrations by a one-pot process termed polymerization-induced crystallization-driven self-assembly (PI-CDSA). We also demonstrate the formation of uniform fibers by living PI-CDSA, a process in which block copolymer synthesis, self-assembly, and seeded growth are combined. We have demonstrated that the method is successful for block copolymers that possess the same composition as that of the seed (homoepitaxial growth) and also where the coronal chemistries differ to give segmented 1D fibers known as block co-micelles. We have also shown that heteroepitaxial growth allows the formation of scaled-up block co-micelles where the composition of both the core and corona was varied. These proof-of-concept experiments indicate that PI-CDSA is a promising, scalable route to a variety of polydisperse or uniform 1D nanoparticles based on block copolymers with different crystalline core chemistries and, therefore, functions.

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Tailored self-assembled photocatalytic nanofibres for visible-light-driven hydrogen production

et al. 2020

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PISA: construction of self-organized and self-assembled functional vesicular structures

Pearce

Pérez–Mercader

2021

Polym. Chem.

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Samuel Pearce

50th Anniversary Perspective: Functional Nanoparticles from the Solution Self-Assembly of Block Copolymers

Complex and Hierarchical 2D Assemblies via Crystallization-Driven Self-Assembly of Poly(l-lactide) Homopolymers with Charged Termini

Scalable Fiber-like Micelles and Block Co-micelles by Polymerization-Induced Crystallization-Driven Self-Assembly

Tailored self-assembled photocatalytic nanofibres for visible-light-driven hydrogen production

PISA: construction of self-organized and self-assembled functional vesicular structures

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