Hierarchically Structured Nanocomposites via a “Systems Materials Science” Approach

Li, Rebecca L.; Thrasher, Carl J.; Hueckel, Theodore; Macfarlane, Robert J.

doi:10.1021/accountsmr.2c00153

Cited by 9 publications

(6 citation statements)

References 67 publications

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“…Specifically, substantial endeavors are currently being dedicated to understanding through which mechanisms and features chiral information can be transmitted across multi‐length scales [10,11] . The synthesis of these materials requires a systems‐level approach based on how structural changes across multiple length scales influence one another during all steps of their preparation [12] . Gaining insight into interactions that occur hierarchically across various length scales is crucial, as they are closely related to the mechanical functional properties of many such materials [13] …”

Section: Introductionmentioning

confidence: 99%

“…[10,11] The synthesis of these materials requires a systems-level approach based on how structural changes across multiple length scales influence one another during all steps of their preparation. [12] Gaining insight into interactions that occur hierarchically across various length scales is crucial, as they are closely related to the mechanical functional properties of many such materials. [13] Finally, another area of current active research is the design of catalytic systems for smart application purposes based on their control using external stimuli.…”

Section: Introductionmentioning

confidence: 99%

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Multi‐Length Scale Communication Effects in Catalysis: Thinking Big and Acting Small

Moyano,

Crusats

2024

Adv Synth Catal

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The use of hierarchically structured materials as catalysts has been finding increasing application in the past years. For these catalytic systems, not only the nano‐scale matters: a high degree of order across multiple length scales, along with its control and analytical assessment, is of paramount importance to obtain innovative properties that can find application in catalysis. Most reviews dealing with hierarchically structured materials are concerned with the “bottom‐up” transfer of structural information along the different length scales, with special emphasis on the transmission of chirality. Due to their mesoscale size together with their complex behaviour, these systems are susceptible to feel the effects of macroscopic forces, that can exert a “top‐down” control of their catalytic properties, so that an external stimulus, acting at the level of the supramolecular architecture of the catalyst, can ultimately determine the outcome of the catalyzed reaction at the molecular level. We review in this paper some recent reports that deal with the experimental implementation of this concept, either by using a mechanical force in a full range direct transmission to the reaction coordinate, or by means of a stepwise relay transmission from the macroscopic level (purely supramolecular chirality) to the nanoscopic one. We focus in this review on these multi‐length scale communication control effects, identifying the different mechanisms that are affecting the catalytic activity.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multi‐Length Scale Communication Effects in Catalysis: Thinking Big and Acting Small

Moyano,

Crusats

2024

Adv Synth Catal

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“…18,30−33 These examples demonstrate the importance of considering supramolecular chemistry from a hierarchical, "systems" approach where both the molecular and nanoscale geometries become interdependent factors affecting structure−property relationships. 34 Despite the importance of nanoscale geometry in dictating multivalent thermodynamics, this design parameter is challenging to analyze, as the emergent behaviors it induces in supramolecular systems cannot be fully understood simply by summing the effects of multiple individual molecular contributions. Therefore, better understanding and control of thermodynamic behaviors within these massively multivalent systems promises exciting opportunities for materials design but requires efforts to develop fundamental principles that apply to a range of polymer and nanoparticle systems.…”

Section: ■ Introductionmentioning

confidence: 99%

Rationally Designing the Supramolecular Interfaces of Nanoparticle Superlattices with Multivalent Polymers

Thrasher,

Jia,

Yee

et al. 2024

J. Am. Chem. Soc.

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In supramolecular materials, multiple weak binding groups can act as a single collective unit when confined to a localized volume, thereby producing strong but dynamic bonds between material building blocks. This principle of multivalency provides a versatile means of controlling material assembly, as both the number and the type of supramolecular moieties become design handles to modulate the strength of intermolecular interactions. However, in materials with building blocks significantly larger than individual supramolecular moieties (e.g., polymer or nanoparticle scaffolds), the degree of multivalency is difficult to predict or control, as sufficiently large scaffolds inherently preclude separated supramolecular moieties from interacting. Because molecular models commonly used to examine supramolecular interactions are intrinsically unable to examine any trends or emergent behaviors that arise due to nanoscale scaffold geometry, our understanding of the thermodynamics of these massively multivalent systems remains limited. Here we address this challenge via the coassembly of polymer-grafted nanoparticles and multivalent polymers, systematically examining how multivalent scaffold size, shape, and spacing affect their collective thermodynamics. Investigating the interplay of polymer structure and supramolecular group stoichiometry reveals complicated but rationally describable trends that demonstrate how the supramolecular scaffold design can modulate the strength of multivalent interactions. This approach to self-assembled supramolecular materials thus allows for the manipulation of polymer–nanoparticle composites with controlled thermal stability, nanoparticle organization, and tailored meso- to microscopic structures. The sophisticated control of multivalent thermodynamics through precise modulation of the nanoscale scaffold geometry represents a significant advance in the ability to rationally design complex hierarchically structured materials via self-assembly.

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“…Nanomaterials are of interest in multiple technological applications and scientific fields, as sub-100 nm features can enable unique properties or behaviors not observed in a macroscopic material. − These beneficial properties require control over multiple aspects of nanomaterial designcomposition, feature size and shape, and the local chemical environment. Colloidal synthesis and assembly of nanoparticles is therefore an attractive means of materials development, as judicious ligand selection can both control the particle synthetic protocol and the final particles’ interactions with the surrounding environment and each other. − …”

Section: Introductionmentioning

confidence: 99%

Nanoparticle Brushes: Macromolecular Ligands for Materials Synthesis

et al. 2023

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Conspectus Colloidal nanoparticles have unique attributes that can be used to synthesize materials with exotic properties, but leveraging these properties requires fine control over the particles’ interactions with one another and their surrounding environment. Small molecules adsorbed on a nanoparticle’s surface have traditionally served as ligands to govern these interactions, providing a means of ensuring colloidal stability and dictating the particles’ assembly behavior. Alternatively, nanoscience is increasingly interested in instead using macromolecular ligands that form well-defined polymer brushes, as these brushes provide a much more tailorable surface ligand with significantly greater versatility in both composition and ligand size. While initial research in this area is promising, synthesizing macromolecules that can appropriately form brush architectures remains a barrier to their more widespread use and limits understanding of the fundamental chemical and physical principles that influence brush-grafted particles’ ability to form functional materials. Therefore, enhancing the capabilities of polymer-grafted nanoparticles as tools for materials synthesis requires a multidisciplinary effort, with specific focus on both developing new synthetic routes to polymer-brush-coated nanoparticles and investigating the structure–property relationships the brush enables. In this Account, we describe our recent work in developing polymer brush coatings for nanoparticles, which we use to modulate particle behavior on demand, select specific nanoscopic architectures to form, and bolster traditional bulk polymers to form stronger materials by design. Distinguished by the polymer type and capabilities, three classes of nanoparticles are discussed here: nanocomposite tectons (NCTs), which use synthetic polymers end-functionalized with supramolecular recognition groups capable of directing their assembly; programmable atom equivalents (PAEs) containing brushes of synthetic DNA that employ Watson–Crick base pairing to encode particle binding interactions; and cross-linkable nanoparticles (XNPs) that can both stabilize nanoparticles in solution and polymer matrices and subsequently form multivalent cross-links to strengthen polymer composites. We describe the formation of these brushes through “grafting-from” and “grafting-to” strategies and illustrate aspects that are important for future advancement. We also examine the new capabilities brushes provide, looking closely at dynamic polymer processes that provide control over the assembly state of particles. Finally, we provide a brief overview of the technological applications of nanoparticles with polymer brushes, focusing on the integration of nanoparticles into traditional materials and the processing of nanoparticles into bulk solids.

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Hierarchically Structured Nanocomposites via a “Systems Materials Science” Approach

Cited by 9 publications

References 67 publications

Multi‐Length Scale Communication Effects in Catalysis: Thinking Big and Acting Small

Multi‐Length Scale Communication Effects in Catalysis: Thinking Big and Acting Small

Rationally Designing the Supramolecular Interfaces of Nanoparticle Superlattices with Multivalent Polymers

Nanoparticle Brushes: Macromolecular Ligands for Materials Synthesis

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