Crosslinking of Pressure-Sensitive Adhesives with Polymer-Grafted Nanoparticles

Desroches, Griffen; Wang, Yuping; Kubiak, Joshua M.; Macfarlane, Robert J.

doi:10.1021/acsami.1c22997

Cited by 14 publications

(26 citation statements)

References 34 publications

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“…To circumvent this limitation, we have developed polymer grafted nanoparticles (PGNPs) that possess short brushes that can be cross-linked postprocessing (Figure B). − , The use of cross-links instead of chain entanglement to impart mechanical strength enables filler loadings as high as 57 vol % without sacrificing mechanical properties . These PGNPs can use different types of cross-linking moieties (for example, anhydrides and amides), and can be processed into conformal films and arbitrarily shaped 3D objects through hot pressing, compression molding, extrusion, or vacuum forming. ,, Nevertheless, while these cross-linked PGNPs possess homogeneously distributed fillers, they lack long-range organization.…”

Section: Building Blocks For Self-assemblymentioning

confidence: 99%

“…One of the first steps toward a systems materials design concept for hierarchical composites is therefore to elucidate appropriate building blocks that have structural features that can be intentionally programmed at these different length scales. Our group has tackled this challenge by developing a suite of polymer-grafted nanoparticles that are inherently composite architectures, containing both rigid inorganic cores and soft polymeric brushes. − These designs provide a major advantage in the investigation of “systems” approaches to materials synthesis by using molecular and nanoscale handles to manipulate assembly during the formation of higher-order structures, and also allowing nanoscale design features to alter supramolecular behavior. By exploiting biomolecular recognition, supramolecular chemistry, nanoparticle synthesis, and processing methods, we have begun to outline a potential pathway toward a “systems materials science” approach to developing new polymer composites.…”

Section: Introductionmentioning

confidence: 99%

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Hierarchically Structured Nanocomposites via a “Systems Materials Science” Approach

Thrasher

Hueckel

et al. 2022

Acc. Mater. Res.

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Conspectus Nanocomposite materials can achieve desirable characteristics otherwise unavailable to single component systems, making them attractive platforms to precisely modulate a material’s mechanical, electromagnetic, thermal, and optical properties. Because these properties are often dependent on the organization of constituent materials just as much as their relative composition, intentionally programming composite properties requires hierarchical structural control across many length scales. However, the fundamental forces governing the atomic, molecular, nanoscale, microscale, and macroscale composition and structure of a material are all interlinked, and thus must be manipulated simultaneously to properly create ideal designer materials. This fundamental interdependency indicates the need for a “systems materials science” approach to rational nanocomposite design. Much like the fields of “systems biology” and “systems chemistry”, a “systems materials science” approach would emphasize emergent connections arising from complex networks of interactions between individual components. In the context of materials synthesis, a systems-level approach would need to consider how structural changes across multiple length scales (chemical bonding, nano- and microstructural evolution, macroscopic geometry) influence one another during all steps of material synthesis and processing. In this account, we highlight our recent work exploring pathways to “systems materials science” inspired design via the development of versatile, programmable, and scalable nanocomposite building blocks. Our group has established a suite of polymer-grafted nanoparticle designs that are inherently composite architectures, containing rigid inorganic cores with dynamic polymer ligand brushes. These building blocks provide molecular and nanoscale handles to dictate particle assembly into higher-order structures by exploiting biomolecular recognition, supramolecular chemistry, nanoparticle synthesis, and an array of different processing conditions. Moreover, they also enable systems-level approaches to material design, as they provide a means of using nano- to macroscale modifications to material structure as a means of altering molecular to nanoscale behaviors. We outline the advancements that have guided our thinking about composite synthesis, underscore key design motifs, and detail how feedback and feedforward mechanisms can govern structure formation at multiple length scales. The contents of this account are organized by length scale, starting with an examination of molecular interactions capable of guiding assembly. This section considers the trade-offs between precision and scalability, culminating in a discussion of strategies which provide a balance of programmability, compositional versatility, and accessibility. We proceed to describe the thermodynamic principles of building block assembly, showing how the resulting nanostructures can be dictated via both composition and assembly environment. Further, we connect molecular and nanosca...

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Section: Building Blocks For Self-assemblymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Hierarchically Structured Nanocomposites via a “Systems Materials Science” Approach

Thrasher

Hueckel

et al. 2022

Acc. Mater. Res.

Self Cite

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“…Strong adhesives with high load-bearing capabilities can provide both adhesive bonding to substrate surfaces and cohesive bonding throughout the bulk material. As a result, they are able to withstand static loads and frequent loading–unloading conditions, which is beneficial for enhancing safety and extending service life in the wood glue, cement nails, electronic devices, and automotive industries. − From the perspective of adhesive applications, strong adhesives required to transfer force between adhered substrates usually have several characteristics: (1) a low elastic modulus, which allows for solid contact and strong bonding with the substrates; (2) an elastic character at a low frequency, which can resist flow during debonding; and (3) a notable degree of viscoelasticity, which provides enough energy dissipation during debonding when external stress is applied. , …”

Section: Introductionmentioning

confidence: 99%

Topology and Dynamic Regulations of Comb-like Polymers as Strong Adhesives

et al. 2023

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Strong adhesives as structural load-bearing materials can provide both adhesive bonding to substrate surfaces and cohesive bonding throughout the bulk material, which are widely used in the cement nail, electronic device, and automotive industries. By a molecular topological regulation, in this work, we developed a series of strong adhesives based on comb-like polymers. By systematically regulating the topological parameters including the side chain length, the spacer between side chains, and the degree of polymerization of the overall backbone, comprehensive studies on linear rheology (the terminal relaxation time and zero viscosity) and non-linear debonding adhesion (the work of adhesion) are performed on these comb-like polymers. It was found that the rheological behaviors depend not only on the structure parameters but also on whether or not the samples exhibit phase separation. Moreover, regardless of the topological structure of comb-like polymers with strong and weak phase separation, the universal work of adhesion is observed to be dependent on the multiplication of terminal relaxation time and the debonding rate, indicating dynamic control over the nonlinear work of adhesion. Furthermore, comb-like polymers are feasible to bind with diverse substrates, including glass, polypropylene and polyethylene terephthalate, wood, and metal. In comparison to existing works using dynamic physical or chemical bonds, molecular topology regulation is more easily fulfilled in strong adhesives without the use of additives and complicated chemical and physical modifications, lowering the barrier for practical applications.

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“…It is important to note that the resistance of this type of adhesives not only depends on their nature but also on the degree of crosslinking of the polymer chains [ 10 ]. Non-crosslinked polymers are also widely used as PSAs, the resistance of which is improved by the introduction of fillers whose particles form a three-dimensional network [ 15 , 16 ]. Likewise, the use of nanotubes as filler particles in the adhesive matrix provides this three-dimensional network, which improves the mechanical properties of PSAs [ 15 , 16 ].…”

Section: Introductionmentioning

confidence: 99%

“…Non-crosslinked polymers are also widely used as PSAs, the resistance of which is improved by the introduction of fillers whose particles form a three-dimensional network [ 15 , 16 ]. Likewise, the use of nanotubes as filler particles in the adhesive matrix provides this three-dimensional network, which improves the mechanical properties of PSAs [ 15 , 16 ]. Among the groups of PSAs mentioned above, the most employed in the industrial sector are acrylic-based materials, with numerous families differing in the polymerization process (emulsion, solution, hot melt, or radiation curing) [ 17 , 18 , 19 ].…”

Section: Introductionmentioning

confidence: 99%

Comparative Mechanical Study of Pressure Sensitive Adhesives over Aluminium Substrates for Industrial Applications

2022

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The use of adhesives for fixing low-weight elements is showing increasing interest in the industry, as it would reduce the weight of the assembly, costs, and production time. Specifically, the application of pressure-sensitive adhesives (PSAs) to join non-structural naval components to aluminium substrates has not yet been reported. In the present work, a study of the mechanical behaviour of different double-sided PSAs applied on bare aluminium alloy substrates is performed. The influence of surface roughness, surface chemical treatments, and the matrix of the adhesives is studied through different mechanical tests, such as shear, T-peel, and creep. The application of an adhesion promoter improved the mechanical behaviour. Low roughness substrates provided better performance than ground samples. Acrylic foam adhesives were subjected to creep tests, whose results were fitted to a simple mathematical model, predicting the fracture time as a function of the applied load.

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Crosslinking of Pressure-Sensitive Adhesives with Polymer-Grafted Nanoparticles

Cited by 14 publications

References 34 publications

Hierarchically Structured Nanocomposites via a “Systems Materials Science” Approach

Hierarchically Structured Nanocomposites via a “Systems Materials Science” Approach

Topology and Dynamic Regulations of Comb-like Polymers as Strong Adhesives

Comparative Mechanical Study of Pressure Sensitive Adhesives over Aluminium Substrates for Industrial Applications

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