Molecular Engineering of Colloidal Atoms

Cui, Yan; Wang, Jingchun; Liang, Juncong; Qiu, Huibin

doi:10.1002/smll.202207609

Cited by 15 publications

(13 citation statements)

References 211 publications

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“…The amount of DNA on a particle determines its coordination number, which is analogous to the valence of an atom in a molecule system. [34][35][36][37][38] Since then, a variety of DNA-mediated regioselective surface encoding approaches have been developed to explore novel assembled structures both in experiment and simulation (Fig. 1).…”

Section: Wenhementioning

confidence: 99%

DNA-mediated regioselective encoding of colloids for programmable self-assembly

Ding

Chen

et al. 2023

Chem. Soc. Rev.

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Section: Wenhementioning

confidence: 99%

DNA-mediated regioselective encoding of colloids for programmable self-assembly

Ding

Chen

et al. 2023

Chem. Soc. Rev.

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“…[30] Compared to atoms and molecules, the interactions between colloids are usually spherically symmetric. Various techniques, such as template-assisted assembly, ligand-mediated assembly, and anisotropy-regulated assembly, [31][32][33] have been developed to break the interaction symmetry for desired structures. For instance, templated assembly involves using prefabricated microwells to create spatial confinement, where various geometric colloidal molecules can be created by using differently shaped microwells (Figure 3a).…”

Section: Colloidal Molecules From Equilibrium Self-assemblymentioning

confidence: 99%

Colloidal Self‐Assembly: From Passive to Active Systems

Huang,

Wu,

Chen

et al. 2023

Angew Chem Int Ed

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Self‐assembly fundamentally implies the organization of small sub‐units into large structures or patterns without the intervention of specific local interactions. This process is commonly observed in nature, occurring at various scales ranging from atomic/molecular assembly to the formation of complex biological structures. Colloidal particles may serve as micrometer‐scale surrogates for studying assembly, particularly for the poorly understood kinetic and dynamic processes at the atomic scale. Recent advances in colloidal self‐assembly have enabled the programmable creation of novel materials with tailored properties. We here provide an overview and comparison of both passive and active colloidal self‐assembly, with a discussion on the energy landscape and interactions governing both types. In the realm of passive colloidal assembly, many impressive and important structures have been realized, including colloidal molecules, one‐dimensional chains, two‐dimensional lattices, and three‐dimensional crystals. In contrast, active colloidal self‐assembly, driven by optical, electric, chemical, or other fields, involves more intricate dynamic processes, offering more flexibility and potential new applications. A comparative analysis underscores the critical distinctions between passive and active colloidal assemblies, highlighting the unique collective behaviors emerging in active systems. These behaviors encompass collective motion, motility‐induced phase segregation, and exotic properties arising from out‐of‐equilibrium thermodynamics. Through this comparison, we aim to identify the future opportunities in active assembly research, which may suggest new application domains.

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“…Nanoparticle (NP) assemblies have been considered as a prototype for artificial molecules/atoms; − however, the level of their structural complexity and hierarchy is far less than those in molecular or atomic systems. , Unlike molecules with asymmetric shapes and bond polarization, colloidal synthesis favors high symmetry, , often leading to isotropic interparticle interactions and the formation of close-packing assemblies. , As pointed out by Glotzer and others, , the key structural feature to create directional interaction, but not yet included in those colloidal building blocks, is anisotropy. Despite notable progress in the controlled synthesis of colloidal NPs in terms of their size, , shape, − and chemical composition, precise control of interparticle interactions (direction and strength), ,− even for anisotropic NP building blocks, remains at its early stage in comparison with their covalent counterparts such as atomic or molecular bonding.…”

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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Molecular Engineering of Colloidal Atoms

Cited by 15 publications

References 211 publications

DNA-mediated regioselective encoding of colloids for programmable self-assembly

DNA-mediated regioselective encoding of colloids for programmable self-assembly

Colloidal Self‐Assembly: From Passive to Active Systems

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

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