Polymer-Tethered Nanoparticles: From Surface Engineering to Directional Self-Assembly

Shen, Xiaoxue; Liu, Kun; Nie, Zhihong; Kumacheva, Eugenia

doi:10.1021/acs.accounts.2c00066

Cited by 37 publications

(21 citation statements)

References 78 publications

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“…Several excellent reviews have been published on the selfassembly of colloidal particles, covering topics such as the principles that govern self-assembly, [42][43][44] the types of colloidal particles that can self-assemble, [45][46][47] and the characterisation, properties and applications of the resultant self-assembled superstructures. [48][49][50] We encourage interested readers to consult these references.…”

Section: Introductionmentioning

confidence: 99%

Self-assembly of colloidal metal–organic framework (MOF) particles

et al. 2023

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Section: Introductionmentioning

confidence: 99%

Self-assembly of colloidal metal–organic framework (MOF) particles

et al. 2023

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“…Adding surface ligands to colloidal building blocks provides a meaningful postsynthetic way to design anisotropic metal NPs and potentially guide their self-assembly in a specific pathway. ,− A number of methods in the literature have been reported to introduce surface ligands on metal NPs with regioselectivity: e.g., surface facet recognition, − templated surface grafting, , and phase segregation of mixed ligands . Together with anisotropic NP topologies, site-specific ligand grafting can provide, or sometimes amplify, the directional interparticle interactions to drive NP assembly in a desired manner. ,− For example, gold nanorods (AuNRs) are a classic type of anisotropic building blocks having distinct LSPR bands along their transverse and longitudinal directions. , Without regioselective ligand coverage, AuNRs can pack as clusters with a local preferential direction along their sides; , however, with site-specific modification with ligands, AuNRs can be organized in an end-to-end fashion that allows their longitudinal LSPR coupling. − An early example from Kumacheva and co-workers demonstrated that thiol-terminated polystyrene (PS-SH) could preferentially bind with Au (111) facets located at the two ends in tetrahydrofuran (THF), because the grafting density of cetyltrimethylammonium bromide (CTAB) on convex (111) facets was considerably lower as compared to that on flat (110) and (100) facets as the sides of AuNRs.…”

Section: Introductionmentioning

confidence: 99%

Site-Specific Chemistry on Gold Nanorods: Curvature-Guided Surface Dewetting and Supracolloidal Polymerization

et al. 2023

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Control of interparticle interactions in terms of their direction and strength highly relies on the use of anisotropic ligand grafting on nanoparticle (NP) building blocks. We report a ligand deficiency exchange strategy to achieve site-specific polymer grafting of gold nanorods (AuNRs). Patchy AuNRs with controllable surface coverage can be obtained during ligand exchange with a hydrophobic polystyrene ligand and an amphiphilic surfactant while adjusting the ligand concentration (C PS ) and solvent condition (C water in dimethylformamide). At a low grafting density of ≤0.08 chains/nm 2 , dumbbell-like AuNRs with two polymer domains capped at the two ends can be synthesized through surface dewetting with a high purity of >94%. These site-specificallymodified AuNRs exhibit great colloidal stability in aqueous solution. Dumbbell-like AuNRs can further undergo supracolloidal polymerization upon thermal annealing to form one-dimensional plasmon chains of AuNRs. Such supracolloidal polymerization follows the temperature−solvent superposition principle as revealed by kinetic studies. Using the copolymerization of two AuNRs with different aspect ratios, we demonstrate the design of chain architectures by varying the reactivity of nanorod building blocks. Our results provide insights into the postsynthetic design of anisotropic NPs that potentially serve as units for polymer-guided supracolloidal self-assembly.

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“…These hybrid nanomaterials are usually with a soft/soft or hard/soft interface which demonstrates extraordinary properties especially in their assembled structures that are not seen in their bulk due to the confinement effect. Representative examples include, when grafted to a hard material, polymer grafted nanoparticle or spherical brushes, 14‐16 polymer grafted nanorods, 17,18 and polymer grafted nanopores 19,20 . One typical example is poly(ethylene oxide) (PEO) grafted to gold crystal used in biomedical engineering due to its superior biocompatible, optical and nontoxic properties 21,22 .…”

Section: Introductionmentioning

confidence: 99%

polyGraft 1.0: A program for molecular structure and topology generation of polymer‐grafted hybrid nanostructures

Chen

2023

J Comput Chem

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Polymer‐grafted hybrid materials have been ubiquitously employed in various engineering applications. The design of these hybrid materials with superior performances requires a molecularly detailed understanding of the structure and dynamics of the polymer brushes and their interactions with the grafting substrate. Molecular dynamics (MD) simulations are very well suited for the study of these materials which can provide molecular insights into the effects of polymer composition and length, grafting density, substrate composition and curvatures, and nanoconfinement. However, few existing tools are available to generate such systems, which would otherwise reduce the barrier of preparation for such systems to enable high throughput simulations. Here polyGraft, a general, flexible, and easy to use Python program, is introduced for automated generation of molecular structure and topology of polymer grafted hybrid materials for MD simulations purposes, ranging from polymer brushes grafted to hard substrates, to densely grafted bottlebrush polymers. polyGraft is openly accessible on GitHub (https://github.com/nanogchen/polyGraft).

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Polymer-Tethered Nanoparticles: From Surface Engineering to Directional Self-Assembly

Cited by 37 publications

References 78 publications

Self-assembly of colloidal metal–organic framework (MOF) particles

Self-assembly of colloidal metal–organic framework (MOF) particles

Site-Specific Chemistry on Gold Nanorods: Curvature-Guided Surface Dewetting and Supracolloidal Polymerization

polyGraft 1.0: A program for molecular structure and topology generation of polymer‐grafted hybrid nanostructures

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