Your search keyword '"dynamic materials"' showing total 152 results

1. Mechanically robust and dynamic supramolecular polymer networks enabled by [an]daisy chain backbones.

Author

Wang, Yongming, Ding, Yi, Liu, Yuhang, Qu, Shaolei, Wang, Wenbin, Yu, Wei, Zhang, Zhaoming, Liu, Feng, and Yan, Xuzhou

Abstract

Supramolecular polymer networks (SPNs) have garnered significant research interest due to their dynamic properties. However, while current developments primarily focus on managing supramolecular crosslinks, the role of polymer backbones—equally crucial to SPN properties—has not yet been sufficiently explored. Herein, we utilize mechanically interlocked [an]daisy chain as backbone to prepare a class of SPNs, where the force-induced motion of successive mechanical bonds toughens and reinforces the networks. In specific, the [an]daisy chain backbones connect with polynorbornene chains through quadruple H-bonding in the SPN networks. Compared to the control with non-slidable backbone, The representative SPN-2 exhibits a robust feature in tensile tests with high maximum stress (14.7 vs. 7.89 MPa) and toughness (83.8 vs. 48.6 MJ/m3). Moreover, it also has superior performance in energy dissipation benefitting from the [an]daisy chain backbones as well as supramolecular crosslinks. Additionally, the SPN-2 displayed exceptional self-healing and reprocessing capabilities due to their dynamic quadrable H-bonding crosslinkers. These findings demonstrate the untapped potential of [an]daisy chain as a polymer skeleton to develop SPNs and open the door to design mechanically robust supramolecular materials with diverse smart functions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Advances in Additive Manufactured Scaffolds Mimicking the Osteochondral Interface.

Author

Beeren, Ivo A. O., Dijkstra, Pieter J., Mota, Carlos, Camarero‐Espinosa, Sandra, Baker, Matthew B., and Moroni, Lorenzo

Subjects

*REGENERATION (Biology), *DEGENERATION (Pathology), *BIOMIMICRY, *OSTEOARTHRITIS, *HYDROGELS

Abstract

Architectural, compositional, and mechanical gradients are present in many interfacial tissues in the body. Yet desired for regeneration, the recreation of these complex natural gradients in porous scaffolds remains a challenging task. Additive manufacturing (AM) has been highlighted as a technology to fabricate constructs to regenerate interfacial tissues. Integration of different types of gradients, which can be physical, mechanical, and/or biochemical, shows promise to control cell fate and the regeneration process in a spatial controlled manner. One of the most studied tissue interfaces is the osteochondral unit which connects cartilage to bone. This tissue is often damaged because of trauma or ageing, leading to osteoarthritis; a degenerative disease and a major cause of disability worldwide. Therefore, in view of osteochondral (OC) regeneration, a state‐of‐the‐art overview of current approaches is presented to manufacture gradient scaffolds prepared by AM techniques. The focus is on thermoplastic, hydrogel, and hybrid scaffolds comprising gradients that induce biomimicry by their physical and biological properties. The effect of these different systems on OC tissue formation in‐vitro and in‐vivo is addressed. Finally, an outlook on current trends of dynamic materials is provided, including proposals on how these materials could improve the mimicry of scaffolds applied for OC regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

3. Mechanically Interlocked Polyrotaxane Networks with Collective Motions of Multiple Main‐Chain Mechanical Bonds.

Author

Yang, Li, Wang, Yuanhao, Liu, Guoquan, Zhao, Jun, Cheng, Lin, Zhang, Zhaoming, Bai, Ruixue, Liu, Yuhang, Yang, Mengling, Yu, Wei, and Yan, Xuzhou

Subjects

*TENSILE tests, *POLYMERS, *MOLECULAR dynamics, *AXLES, *DEFORMATIONS (Mechanics), *THREAD (Textiles)

Abstract

Type I main‐chain polyrotaxanes (PRs) with multiple wheels threaded onto the axle are widely employed to design slide‐ring materials. However, Type II main‐chain PRs with axles threading into the macrocycles on the polymer backbones have rarely been studied, although they feature special topological structures and dynamic characteristics. Herein, we report the design and preparation of Type II main‐chain PR‐based mechanically interlocked networks (PRMINs), based on which the relationship between microscopic motion of mechanical bonds on the PRs and macroscopic mechanical performance of materials has been revealed. The representative PRMIN‐2 exhibits a robust feature in tensile tests with high stretchability (1680 %) and toughness (47.5 MJ/m3). Moreover, it also has good puncture performance with puncture energy of 22.0 mJ. Detailed rheological measurements and coarse‐grained molecular dynamics (CGMD) simulation reveal that the embedded multiple [2]rotaxane mechanical bonds on the PR backbones of PRMINs could undergo a synergistic long‐range sliding motion under external force, with the introduction of collective dangling chains into the network. As a result, the synchronized motions of coherent PR chains can be readily activated to accommodate network deformation and efficiently dissipate energy, thereby leading to enhanced mechanical performances of PRMINs. [ABSTRACT FROM AUTHOR]

Published

2024

4. Mechanically Interlocked [an]Daisy Chain Adhesives with Simultaneously Enhanced Interfacial Adhesion and Cohesion.

Author

Wang, Yongming, Liu, Guoquan, Zhao, Jun, Zhang, Zhaoming, Zhang, Hao, Ding, Yi, Zhang, Xinhai, Liu, Zhu, Yu, Wei, and Yan, Xuzhou

Subjects

*SUPRAMOLECULAR polymers, *INTERFACIAL bonding, *SUBSTRATES (Materials science), *DAISIES, *MOIETIES (Chemistry)

Abstract

Adhesives have been widely used to splice and repair materials to meet practical needs of humanity for thousands of years. However, developing robust adhesives with balanced adhesive and cohesive properties still remains a challenging task. Herein, we report the design and preparation of a robust mechanically interlocked [an]daisy chain network (DCMIN) adhesive by orthogonal integration of mechanical bonds and 2‐ureido‐4[1H]‐pyrimidone (UPy) H‐bonding in a single system. Specifically, the UPy moiety plays a dual role: it allows the formation of a cross‐linked network and engages in multivalent interactions with the substrate for strong interfacial bonding. The mechanically interlocked [an]daisy chain, serving as the polymeric backbone of the adhesive, is able to effectively alleviate applied stress and uphold network integrity through synergistic intramolecular motions, and thus significantly improves the cohesive performance. Comparative analysis with the control made of the same quadruple H‐bonding network but with non‐interlocked [an]daisy chain backbones demonstrates that our DCMIN possesses superior adhesion properties over a wide temperature range. These findings not only contribute to a deep understanding of the structure‐property relationship between microscopic mechanical bond motions and macroscopic adhesive properties but also provide a valuable guide for optimizing design principles of robust adhesives. [ABSTRACT FROM AUTHOR]

Published

2024

5. Bolstering the Mechanical Robustness of Supramolecular Polymer Network by Mechanical Bond.

Author

Wang, Yuan-Hao, Deng, Jing-Xi, Zhao, Jun, Ding, Yi, Yang, Li, Zhang, Zhao-Ming, and Yan, Xu-Zhou

Subjects

*SUPRAMOLECULAR polymers, *YOUNG'S modulus, *ENERGY dissipation, *TENSILE tests, *POLYMER networks, *ELASTICITY

Abstract

Supramolecular polymer networks (SPNs) are celebrated for their dynamic nature, yet they often exhibit inadequate mechanical properties. Thus far, the quest to bolster the mechanical resilience of SPNs while preserving their dynamic character presents a formidable challenge. Herein, we introduce [2]rotaxane into SPN to serve as another cross-link, which could effectively enhance the mechanical robustness of the polymer network without losing the dynamic properties. Compared with SPN, the dually cross-linked network (DPN) demonstrates superior breaking strength, Young's modulus, puncture force and toughness, underscoring its superior robustness. Furthermore, the cyclic tensile tests reveal that the energy dissipation capacity of DPN rivals, and in some cases surpasses, that of SPN, owing to the efficient energy dissipation pathway facilitated by [2]rotaxane. In addition, benefiting from stable topological structure of [2]rotaxane, DPN exhibits accelerated recovery from deformation, indicating superior elasticity compared to SPN. This strategy elevates the performance of SPNs across multiple metrics, presenting a promising avenue for the development of high-performance dynamic materials. [ABSTRACT FROM AUTHOR]

Published

2024

6. Strengthening and toughening styrene-butadiene rubber by mechanically interlocked cross-links.

Author

Wang, Yuanhao, Yang, Li, Cheng, Lin, Zhao, Jun, Bai, Ruixue, Wang, Wenbin, Qu, Shaolei, Zhang, Zhaoming, Yu, Wei, and Yan, Xuzhou

Abstract

Styrene-butadiene rubber (SBR) is an indispensable material in modern society, and the necessity for enhanced mechanical properties in SBR persists, particularly to withstand the rigors of challenging environmental conditions. To surmount the limitations of conventional cross-linking modes, mechanical bonds stabilized by host-guest recognition are incorporated as the cross-linking points of SBR to form mechanically interlocked networks (MINs). Compared with covalently cross-linked network, the representative MIN exhibits superior mechanical performance in terms of elongation (1392%) and breaking strength (4.6 MPa), whose toughness has surged by 17 times. Dissociation of host-guest recognition and subsequent sliding motion provide an effective energy dissipation mechanism, and the release of hidden length is also beneficial to enhance toughness. Furthermore, the introduction of the rotaxane cross-links made the network more pliable and possess damping and elastic properties, which can return to initial state with one minute rest interval. We aspire that this direct introduction method can serve as a blueprint, offering valuable insights for the enhancement of mechanical properties in conventional commercial polymer materials. [ABSTRACT FROM AUTHOR]

Published

2024

7. Advances in Additive Manufactured Scaffolds Mimicking the Osteochondral Interface

Author

Ivo A. O. Beeren, Pieter J. Dijkstra, Carlos Mota, Sandra Camarero‐Espinosa, Matthew B. Baker, and Lorenzo Moroni

Subjects

additive manufacturing, dynamic materials, gradients, osteochondral regeneration, Biotechnology, TP248.13-248.65, Medical technology, R855-855.5

Abstract

Architectural, compositional, and mechanical gradients are present in many interfacial tissues in the body. Yet desired for regeneration, the recreation of these complex natural gradients in porous scaffolds remains a challenging task. Additive manufacturing (AM) has been highlighted as a technology to fabricate constructs to regenerate interfacial tissues. Integration of different types of gradients, which can be physical, mechanical, and/or biochemical, shows promise to control cell fate and the regeneration process in a spatial controlled manner. One of the most studied tissue interfaces is the osteochondral unit which connects cartilage to bone. This tissue is often damaged because of trauma or ageing, leading to osteoarthritis; a degenerative disease and a major cause of disability worldwide. Therefore, in view of osteochondral (OC) regeneration, a state‐of‐the‐art overview of current approaches is presented to manufacture gradient scaffolds prepared by AM techniques. The focus is on thermoplastic, hydrogel, and hybrid scaffolds comprising gradients that induce biomimicry by their physical and biological properties. The effect of these different systems on OC tissue formation in‐vitro and in‐vivo is addressed. Finally, an outlook on current trends of dynamic materials is provided, including proposals on how these materials could improve the mimicry of scaffolds applied for OC regeneration.

Published

2024

8. Stretchable poly[2]rotaxane elastomers

Author

Kai Liu, Xinhai Zhang, Dong Zhao, Ruixue Bai, Yongming Wang, Xue Yang, Jun Zhao, Hao Zhang, Wei Yu, and Xuzhou Yan

Subjects

Polyrotaxanes, Mechanically interlocked polymers, Mechanically interlocked molecules, Dynamic materials, Elastomers, Science (General), Q1-390

Abstract

ABSTRACT: Mechanically interlocked polymers (MIPs) are promising candidates for the construction of elastomeric materials with desirable mechanical performance on account of their abilities to undergo inherent rotational and translational mechanical movements at the molecular level. However, the investigations on their mechanical properties are lagging far behind their structural fabrication, especially for linear polyrotaxanes in bulk. Herein, we report stretchable poly[2]rotaxane elastomers (PREs) which integrate numerous mechanical bonds in the polymeric backbone to boost macroscopic mechanical properties. Specifically, we have synthesized a hydroxy-functionalized [2]rotaxane that subsequently participates in the condensation polymerization with diisocyanate to form PREs. Benefitting from the peculiar structural and dynamic characteristics of the poly[2]rotaxane, the representative PRE exhibits favorable mechanical performance in terms of stretchability (∼1200%), Young's modulus (24.6 MPa), and toughness (49.5 MJ/m3). Moreover, we present our poly[2]rotaxanes as model systems to understand the relationship between mechanical bonds and macroscopic mechanical properties. It is concluded that the mechanical properties of our PREs are mainly determined by the unique topological architectures which possess a consecutive energy dissipation pathway including the dissociation of host−guest interaction and consequential sliding motion of the wheel along the axle in the [2]rotaxane motif.

Published

2024

9. Insights into the Correlation of Cross‐linking Modes with Mechanical Properties for Dynamic Polymeric Networks.

Author

Deng, Jingxi, Bai, Ruixue, Zhao, Jun, Liu, Guoquan, Zhang, Zhaoming, You, Wei, Yu, Wei, and Yan, Xuzhou

Subjects

*ELASTOMERS, *CROSSLINKED polymers, *SUPRAMOLECULAR polymers, *POLYMER networks, *STRUCTURAL stability, *ELASTICITY

Abstract

Simultaneously introducing covalent and supramolecular cross‐links into one system to construct dually cross‐linked networks, has been proved an effective approach to prepare high‐performance materials. However, so far, features and advantages of dually cross‐linked networks compared with those possessing individual covalent or supramolecular cross‐linking points are rarely investigated. Herein, on the basis of comparison between supramolecular polymer network (SPN), covalent polymer network (CPN) and dually cross‐linked polymer network (DPN), we reveal that the dual cross‐linking strategy can endow the DPN with integrated advantages of CPN and SPN. Benefiting from the energy dissipative ability along with the dissociation of host–guest complexes, the DPN shows excellent toughness and ductility similar to the SPN. Meanwhile, the elasticity of covalent cross‐links in the DPN could rise the structural stability to a level comparable to the CPN, exhibiting quick deformation recovery capacity. Moreover, the DPN has the strongest breaking stress and puncture resistance among the three, proving the unique property advantages of dual cross‐linking method. These findings gained from our study further deepen the understanding of dynamic polymeric networks and facilitate the preparation of high‐performance elastomeric materials. [ABSTRACT FROM AUTHOR]

Published

2023

10. Mechanically Interlocked [2]Rotaxane Aerogels with Tunable Morphologies and Mechanical Properties.

Author

Luo, Zhen, Zhang, Xinhai, Zhao, Jun, Bai, Ruixue, Wang, Chunyu, Wang, Yuanhao, Zhao, Dong, and Yan, Xuzhou

Subjects

*AEROGELS, *CHEMICAL structure, *SMART materials, *HOST-guest chemistry, *MORPHOLOGY

Abstract

Mechanical bonds have been utilized as promising motifs to construct mechanically interlocked aerogels (MIAs) with mechanical adaptivity and multifunctionality. However, fabricating such aerogels with not only precise chemical structures but also dynamic features remains challenging. Herein, we present MIAs carrying dense [2]rotaxane units, which bestow both the stability and flexibility of the aerogel network. Owing to the stable chemical structure of a [2]rotaxane, MIAs possessing a precise and full‐scale mechanically interlocked network could be fabricated with the aid of diverse solvents. In addition, the dynamic nature of the [2]rotaxane resulted in morphologies and mechanical performances of the MIAs that can be dramatically modulated under chemical stimuli. We hope that the structure–property relationship in MIAs will facilitate the development of mechanically interlocked materials and provide novel opportunities toward constructing smart materials with multifunctionalities. [ABSTRACT FROM AUTHOR]

Published

2023

11. Highly Strong and Tough Supramolecular Polymer Networks Enabled by Cryptand‐Based Host‐Guest Recognition.

Author

Liu, Yuhang, Wan, Junjun, Zhao, Xinyang, Zhao, Jun, Guo, Yuchen, Bai, Ruixue, Zhang, Zhaoming, Yu, Wei, Gibson, Harry W., and Yan, Xuzhou

Subjects

*SUPRAMOLECULAR polymers, *POLYMER networks, *YOUNG'S modulus, *DEFORMATIONS (Mechanics), *CROWN ethers, *SMART materials, *BINDING constant

Abstract

Supramolecular polymer networks (SPNs) demonstrate great potential in the development of smart materials owing to their attractive dynamic properties. However, as they suffer from the inherent weak bonding of most noncovalent cross‐links, it remains a significant challenge to construct SPNs with outstanding mechanical performance. Herein, we exploit the cryptand/paraquat host‐guest recognition motifs as cross‐links to prepare a class of highly strong and tough SPNs. Unlike those supramolecular cross‐links with relatively weak binding abilities, the cryptand‐based host‐guest interactions have a high association constant and steady complexing structure, which effectively stabilizes the network and resists mechanical deformation under external force. Such favorable structural stability endows our SPNs with greatly enhanced mechanical performance, compared with the control‐1 cross‐linked by the weakly complexed crown ether/secondary ammonium salt motif (tensile strength: 21.1±0.5 vs 2.8±0.1 MPa; Young's modulus: 102.6±4.8 vs 2.1±0.3 MPa; toughness: 90.4±2.0 vs 10.8±0.6 MJ m−3). Moreover, our SPNs also retain abundant dynamic properties including good abilities in energy dissipation, reprocessability, and stimuli‐responsiveness. These findings provide novel insights into the preparation of SPNs with enhanced mechanical properties, and promote the development of high‐performance intelligent supramolecular materials. [ABSTRACT FROM AUTHOR]

Published

2023

12. Transient and Dissipative Host–Guest Hydrogels Regulated by Consumption of a Reactive Chemical Fuel.

Author

Su, Bo, Chi, Teng, Ye, Zhou, Xiang, Yuanhui, Dong, Ping, Liu, Dongping, Addonizio, Christopher J., and Webber, Matthew J.

Subjects

*HYDROGELS, *ENERGY consumption, *THERMODYNAMIC equilibrium

Abstract

The transient self‐assembly of molecules under the direction of a consumable fuel source is fundamental to biological processes such as cellular organization and motility. Such biomolecular assemblies exist in an out‐of‐equilibrium state, requiring continuous consumption of high energy molecules. At the same time, the creation of bioinspired supramolecular hydrogels has traditionally focused on associations occurring at the thermodynamic equilibrium state. Here, hydrogels are prepared from cucurbit[7]uril host–guest supramolecular interactions through transient physical crosslinking driven by the consumption of a reactive chemical fuel. Upon action from this fuel, the affinity and dynamics of CB[7]–guest recognition are altered. In this way, the lifetime of transient hydrogel formation and the dynamic modulus obtained are governed by fuel consumption, rather than being directed by equilibrium complex formation. [ABSTRACT FROM AUTHOR]

Published

2023

13. Robust and Dynamic Polymer Networks Enabled by Woven Crosslinks.

Author

Li, Guangfeng, Zhao, Jun, Zhang, Zhaoming, Zhao, Xinyang, Cheng, Lin, Liu, Yuhang, Guo, Zhewen, Yu, Wei, and Yan, Xuzhou

Subjects

*POLYMER networks, *SUPRAMOLECULAR polymers, *MECHANICAL behavior of materials, *COVALENT bonds

Abstract

Crosslinking plays a crucial role in determining mechanical properties of polymer materials. Although various crosslinks based on covalent or noncovalent bonds have been adopted, it remains an enormous challenge to develop a crosslink which could endow corresponding polymer network with robust yet dynamic properties. Herein, we report a crosslink simultaneously having dynamic property and woven geometry, and the polymer network with woven crosslinks (WPN) could integrate the merits of covalent polymer network (CPN) and supramolecular polymer network (SPN). In specific, the WPN not only exhibits comparable stiffness, strength, elastic recovery, and anti‐fatigue property to those of CPN, but also possesses decent mechanical adaptivity and ductility, similar to those of SPN. Particularly, its toughness and puncture resistance are much superior to those of the others. Besides, the dynamicity of woven crosslink also imparts good performances of self‐healing and processability to WPN. [ABSTRACT FROM AUTHOR]

Published

2022

14. Facile Physicochemical Reprogramming of PEG-Dithiolane Microgels.

Author

Nelson BR, Kirkpatrick BE, Skillin NP, Di Caprio N, Lee JS, Hibbard LP, Hach GK, Khang A, White TJ, Burdick JA, Bowman CN, and Anseth KS

Subjects

Mice, Animals, Hydrogels chemistry, Cell Line, Biocompatible Materials chemistry, Tissue Engineering methods, Myoblasts cytology, Polyethylene Glycols chemistry, Microgels chemistry

Abstract

Granular biomaterials have found widespread applications in tissue engineering, in part because of their inherent porosity, tunable properties, injectability, and 3D printability. However, the assembly of granular hydrogels typically relies on spherical microparticles and more complex particle geometries have been limited in scope, often requiring templating of individual microgels by microfluidics or in-mold polymerization. Here, we use dithiolane-functionalized synthetic macromolecules to fabricate photopolymerized microgels via batch emulsion, and then harness the dynamic disulfide crosslinks to rearrange the network. Through unconfined compression between parallel plates in the presence of photoinitiated radicals, we transform the isotropic microgels are transformed into disks. Characterizing this process, we find that the areas of the microgel surface in contact with the compressive plates are flattened while the curvature of the uncompressed microgel boundaries increases. When cultured with C2C12 myoblasts, cells localize to regions of higher curvature on the disk-shaped microgel surfaces. This altered localization affects cell-driven construction of large supraparticle scaffold assemblies, with spherical particles assembling without specific junction structure while disk microgels assemble preferentially on their curved surfaces. These results represent a unique spatiotemporal process for rapid reprocessing of microgels into anisotropic shapes, providing new opportunities to study shape-driven mechanobiological cues during and after granular hydrogel assembly., (© 2023 Wiley‐VCH GmbH.)

Published

2024

15. Thermo‐responsive topological metamorphosis in covalent‐and‐supramolecular polymer architectures

Author

Yongming Wang, Hao Zhang, Zhaoming Zhang, Jun Zhao, Ruixue Bai, Yuhang Liu, Xinhai Zhang, and Xuzhou Yan

Subjects

dynamic materials, host–guest chemistry, stimuli‐responsiveness, supramolecular polymers, topological metamorphosis, Chemistry, QD1-999, Biology (General), QH301-705.5

Abstract

Abstract Topological metamorphosis represents a powerful approach to modulate the properties of polymers. However, it still remains a major challenge to achieve the tunability of bulk mechanical properties via topological transformation in supramolecular polymer systems. Herein, we couple the covalent polymer and supramolecular polymer in a single system—referred to as covalent‐and‐supramolecular polymer (CSP)—to realize a thermo‐responsive macromolecular metamorphosis. The CSP is able to topologically switch from grafted polymer to cross‐linked network by taking advantage of synergistic dynamic covalent interactions and host–guest interactions. Benefiting from the topologically structural transformation, brittleness intrinsically evolves into toughness in our CSP architectures with minimum change of their molecular compositions from furan–maleimide to anthracene–maleimide linkers. Our work demonstrates that supramolecular polymers are a promising platform to design smart materials not only due to their inherent stimuli‐responsive properties but also because of their abilities in determining bulk mechanical properties of polymers with alterable topological structures.

Published

2022

16. Complementary Dynamic Chemistries for Multifunctional Polymeric Materials.

Author

Zhang, Borui, De Alwis Watuthanthrige, Nethmi, Wanasinghe, Shiwanka V., Averick, Saadyah, and Konkolewicz, Dominik

Subjects

*MATERIALS science, *FUNCTIONAL groups, *DYNAMIC stability, *MECHANICAL properties of condensed matter, *SUPRAMOLECULAR chemistry

Abstract

Dynamic materials (DMs) or dynamers have potential applications across a broad range of material science challenges. These applications include sustainable materials as a part of the circular plastics economy, advanced materials with tailored high stress properties and biomedical agents. DMs are comprised of polymers that crosslinked through reversible covalent and noncovalent linking groups. This group provides reversible bonds, which impart properties such as (re)healing, adaptability, toughness into a material. The nature of the linker dictates the dynamer's stability and dynamic properties, although for many applications one linker alone cannot give materials with complex multiresponsive functions. The combination of multiple dynamic linkers can introduce complementary functionalities into a single material. This combination of linkers enhances the collective material properties by matching their strengths and offsetting the weaknesses, or by selecting linkers for specific functions, such as one linker for rapid exchange and the other to respond to external stimuli. This contribution highlights the possibilities and unique features of materials containing multiple dynamic linkers, reviewing both fundamental discoveries of materials possessing multiple dynamic bonds and applications facilitated by the presence of multiple linking group chemistry. [ABSTRACT FROM AUTHOR]

Published

2022

17. Dynamic Gas-Bridged Bond: An Opportunity of Fabricating Dynamic Assembled Materials with Gas.

Author

Yang N, Wang Y, and Yan Q

Abstract

Gas molecules, as a family of unique polyatomic building blocks, have long been considered hard to involve in molecular assembly or construct assembled materials due to their structural simplicity yet paucity of defined interacting sites. To solve this non-trivial challenge, a core idea is to break the limit of current ways of bonding gas molecules, endowing them with new modes of interactions that match the basic requirements of molecular assembly. In recent years, a new concept, named the dynamic gas-bridged bond (DGB), has emerged, which allows for gas molecules to constitute a dynamic bridging structure between other building blocks with the aid of frustrated Lewis pairs. This makes it possible to harness gas in a supramolecular or dynamic manner. Herein, this perspective discusses distinct dynamic natures of DGBs and manifests their particular functions in various fields, including the control of molecular/polymeric self-assembly nanostructures, creation of multidimensional assembled materials, and recyclable catalysts. The future research direction and challenges of dynamic gas-bridged chemistry toward gas-programmed self-assembly and gas-constructed adaptive materials are highlighted.

Published

2024

18. Synergistic Covalent and Supramolecular Polymers for Mechanically Robust but Dynamic Materials.

Author

Zhang, Zhaoming, Cheng, Lin, Zhao, Jun, Wang, Lei, Liu, Kai, Yu, Wei, and Yan, Xuzhou

Subjects

*SUPRAMOLECULAR polymers, *MUSCLE contraction, *SYSTEM integration, *MATERIALS, *POLYMERS

Abstract

Nature has engineered delicate synergistic covalent and supramolecular polymers (CSPs) to achieve advanced life functions, such as the thin filaments that assist in muscle contraction. Constructing artificial synergistic CSP materials with bioinspired mechanically adaptive features, however, represents a challenging goal. Here, we report an artificial CSP system to illustrate the integration of a covalent polymer (CP) and a supramolecular polymer (SP) in a synergistic fashion, along with the emergence of notable mechanical and dynamic properties which are unattainable when the two polymers are formed individually. The synergistic effect relies on the peculiar network structures of the SP and CPs, which endow the resultant CSPs with overall improved mechanical performance in terms of the stiffness, strength, stretchability, toughness, and elastic recovery. Moreover, the dynamic properties of the SP, including self‐healing, stimuli‐responsiveness, and reprocessing, are also retained in the CSPs, thus leading to their application as programmable and tunable materials. [ABSTRACT FROM AUTHOR]

Published

2020

19. Orthogonal dynamic covalent boroxine-crosslinked poly(disulfide) networks for chemically recyclable encryption materials.

Author

Shi, Mingyu, Shi, Chen-Yu, Zhang, Qi, and Qu, Da-Hui

Subjects

*RECYCLABLE material, *SHAPE memory polymers, *DISULFIDES, *CHEMICAL bonds, *WASTE recycling, *COVALENT bonds, *CHEMICAL recycling

Abstract

[Display omitted] • Simple building blocks enable orthogonal solvent-free coupling of DCBs. • Poly(TABA) shows relatively high mechanical robustness (E = 1.1 GPa, σ t = 30 MPa). • Rheological kinetic analysis reveals intrinsic temperature range of bond exchange. • A fluorescent and shape-memorable dual-encryption material is constructed by design. • Multi-ways (decrosslinking and depolymerization) employed to recycle this material. Replacing the "inert" chemical bonds in traditional materials with dynamic bonds brings opportunities in designing renewable materials that repair, reprocess and recycle. Despite the many efforts made in covalent adaptable networks by elaborating a single type of dynamic covalent chemistry, the fabrication of double dynamic covalent polymeric networks, especially using simple small-molecule building blocks, still remains challenging. Here we report the solvent-free construction of a thermosetting material by combining 1,2-dithiolane-based reversible polymerization and dynamic covalent boroxine chemistry as crosslinkers. The resulting materials exhibit tunable mechanical properties, mechanical reprocessability, shape memory ability and closed-loop chemical recyclability. Quantitative kinetic analysis reveals the temperature-dependent apparent activation energy for the bond exchange of the resulting network as a result of the simultaneous integration of the two dynamic covalent bonds. Meanwhile, the boroxine units also act as a luminescent center to enable an emissive "organic glass" that can be used as a dual encryption material taking advantage of the reprogrammable shape-memory behavior of the dynamic network. Benefitting from the simple design, tunable variables and multi-functions, we envision that this double dynamic chemistry offers a robust scaffold and great chemical spaces for the design of dynamic polymeric materials. [ABSTRACT FROM AUTHOR]

Published

2024

20. Dynamic interactions between adsorbates and catalyst surfaces over long-term OER stability testing in acidic media.

Author

Li, Ruihan, Lu, Bingzhang, Edgington, Jane, and Seitz, Linsey C.

Subjects

*ADSORBATES, *CHRONOAMPEROMETRY, *CATALYSTS, *X-ray absorption, *OXIDATION of water, *X-ray spectroscopy, *OXYGEN in water

Abstract

[Display omitted] • Dynamic Ir electronic and geometric structural change with surface adsorption. • pH-dependent oxygenate adsorption and Ir dissolution pathway. • Unfavorable adsorption coincides with distorted Ir linkage and decreased Ir valence state. The interaction between catalyst surfaces and adsorbed oxygen intermediates is critical to catalytic performance for electrochemical water oxidation to oxygen. However, the relationship between adsorption energetics and electrocatalytic activity is primarily assessed for pristine catalyst materials, which leaves much unknown about the dynamics of these properties in relationship to catalyst performance during long-term operation. In this work, we experimentally assess OH and O adsorption on Ca 2 IrO 4 nanoparticles and monitor their evolution during extensive chronoamperometry tests at highly oxidizing potentials in a range of low pH electrolytes. In situ x-ray absorption spectroscopy reveals changes for surface adsorbate energetics and local iridium structures with applied potentials. Increasingly unfavorable adsorption of OH and formation of O intermediates after long-term operation is correlated with severe metal dissolution, distorted [IrO 6 ] octahedral linkages, and a decreased average Ir valence. This work establishes connections between surface adsorption energetics, Ir structure, OER kinetics, and material stability outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

21. A Visible‐Light‐Induced Dynamic Mechanical Bond as a Linkage for Dynamic Materials.

Author

Yin, Yong‐Fei, Yun, Meng‐Yan, Wu, Lin, Duan, Hong‐Ying, Jiang, Xia‐Min, Zhan, Tian‐Guang, Cui, Jiecheng, Liu, Li‐Juan, and Zhang, Kang‐Da

Subjects

*CHEMICAL bonds, *VISIBLE spectra, *MATERIALS

Abstract

Exploring dynamic bonds and their applications in fabricating dynamic materials has received great attention. A photoinduced [2]rotaxane‐based dynamic mechanical bond (DMB) features visible‐light‐triggered dynamic bonding behavior that is essentially distinguished from conventional dynamic chemical bonds. In this DMB, a photoisomerizable ortho‐fluoroazobenzene unit is introduced as a steric‐controllable stopper, the visible‐light‐induced dynamic wagging movement of which enables the photoregulated threading of the macrocycle. This allows reversible in situ de‐/reforming of the mechanical bond without involving dynamic chemical linkage. The DMB‐cross‐linked polymeric gel shows interesting photoinduced degradation behavior upon visible light irradiation. Benefiting from the distinctive dual dynamic nature of reversible bonding behavior and mechanical interlocked structure, this DMB is expected to serve as a new type of dynamic bond that can be applied in designing dynamic soft materials. [ABSTRACT FROM AUTHOR]

Published

2019

22. Tunable Orthogonal Reversible Covalent (TORC) Bonds: Dynamic Chemical Control over Molecular Assembly.

Author

Reuther, James F., Dahlhauser, Samuel D., and Anslyn, Eric V.

Subjects

*COVALENT bonds, *MOLECULAR self-assembly, *MACROMOLECULES, *BIOLOGICAL systems, *MOLECULAR machinery (Technology), *NUCLEIC acids

Abstract

Dynamic assembly of macromolecules in biological systems is one of the fundamental processes that facilitates life. Although such assembly most commonly uses noncovalent interactions, a set of dynamic reactions involving reversible covalent bonding is actively being exploited for the design of functional materials, bottom‐up assembly, and molecular machines. This Minireview highlights recent implementations and advancements in the area of tunable orthogonal reversible covalent (TORC) bonds for these purposes, and provides an outlook for their expansion, including the development of synthetically encoded polynucleotide mimics. TORC about: The utilization of tunable orthogonal reversible covalent (TORC) bonds is highlighted in this Minireview. The focus lies in the variety of different applications that are possible, including controlling molecular assembly, operating complex molecular machines, and designing dynamic, self‐healable polymer networks. [ABSTRACT FROM AUTHOR]

Published

2019

23. Mesoporous chitosan nanofibers loaded with norfloxacin and coated with phenylboronic acid perform as bioabsorbable active dressings to accelerate the healing of burn wounds.

Author

Ailincai, Daniela, Cibotaru, Sandu, Anisiei, Alexandru, Coman, Corneliu G., Pasca, Aurelian Sorin, Rosca, Irina, Sandu, Andreea-Isabela, Mititelu-Tartau, Liliana, and Marin, Luminita

Subjects

*WOUND healing, *NORFLOXACIN, *NANOFIBERS, *CHITOSAN, *GRAM-negative bacteria, *ETHYLENE oxide

Abstract

The paper reports new chitosan-based nanofibers, designed to address the healing of burn wounds. To this aim, mesoporous chitosan fiber mats were prepared by electrospinning using poly(ethylene oxide) as sacrificial additive, followed by loading with norfloxacin and coating with an antifungal agent via dynamic imine bonds. Dynamic vapor sorption experiment proved intra-fiber mesopores around 2.7 nm, and UV–vis, FTIR, and NMR spectroscopy confirmed the norfloxacin embedding and the imination reaction. SEM, AFM and POM techniques displayed semicrystalline nanofibers with average diameter around 170 nm entangled into a non-woven mat. Their mesoporous nature favored a rapid adsorption of fluids up to 17 g/g, and a biodegradation rate fitting the wound healing rate, i.e. up to 30 % mass loss in media of pH characteristic to wound exudate and total degradation in that characteristic to normal dermis. The composite fibers released the NFX and 2FPBA in a controlled manner, and showed antimicrobial activity against gram positive, gram negative and fungal strains. They had no cytotoxic effect on normal human dermal fibroblasts, and showed biocompatibility on experimental rats. The investigation of wound healing ability on second/third-degree burn model in rats revealed wound closure and total restoration of the fully functional dermis and epidermis. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

24. Reprocessable Polyurethane Foams Using Acetoacetyl-Formed Amides.

Author

Kassem H, Imbernon L, Stricker L, Jonckheere L, and Du Prez FE

Abstract

Like any other thermosetting material, polyurethane foams (PUFs) contain permanent cross-links that hinder their reprocessability and make their recyclability a tedious and environmentally unfriendly process. Herein, we introduce acetoacetyl-formed amides, formed by the reaction of isocyanates with acetoacetate groups, as dynamic units in the backbone of PUFs. By extensive variation of the foam composition, optimum parameters have been found to produce malleable foams above temperatures of 130 °C, without the requirement of any solvent during the foaming process. The PU cross-linked material can be compression-molded at least three times, giving rise to PU elastomers and thus maintaining a cross-linked network structure. Characterization of the original foams shows comparable properties to standard PUFs, for example, having a density of 32 kg/m 3 , while they show similar chemical and thermal properties upon reprocessing to strong PU elastomers, exhibiting T g ranging from -42 to -48 °C. This research provides a straightforward method to produce thermally reprocessable PUFs as a promising pathway to address the recycling issues of end-of-life foams.

Published

2023

25. Bioorthogonal Strategies for Engineering Extracellular Matrices.

Author

Madl, Christopher M. and Heilshorn, Sarah C.

Subjects

*HYDROGELS, *EXTRACELLULAR matrix, *TISSUE engineering, *CROSSLINKING (Polymerization), *BIOMOLECULES

Abstract

Abstract: Hydrogels are commonly used as engineered extracellular matrix (ECM) mimics in applications ranging from tissue engineering to in vitro disease models. Ideal mechanisms used to crosslink ECM‐mimicking hydrogels do not interfere with the biology of the system. However, most common hydrogel crosslinking chemistries exhibit some form of crossreactivity. The field of bioorthogonal chemistry has arisen to address the need for highly specific and robust reactions in biological contexts. Accordingly, bioorthogonal crosslinking strategies are incorporated into hydrogel design, allowing for gentle and efficient encapsulation of cells in various hydrogel materials. Furthermore, the selective nature of bioorthogonal chemistries can permit dynamic modification of hydrogel materials in the presence of live cells and other biomolecules to alter matrix mechanical properties and biochemistry on demand. This review provides an overview of bioorthogonal strategies used to prepare cell‐encapsulating hydrogels and highlights the potential applications of bioorthogonal chemistries in the design of dynamic engineered ECMs. [ABSTRACT FROM AUTHOR]

Published

2018

26. Homogenization of kinetic laminates in linearized elasticity.

Author

Serrano, Hélia

Subjects

*LAMINATED materials, *ELASTICITY, *ASYMPTOTIC homogenization, *VARIATIONAL approach (Mathematics), *STOCHASTIC convergence

Abstract

The homogenization of kinetic laminates in the framework of time-dependent linearized elasticity is studied from a variational point of view through the Γ-convergence of the associated energies. The characterization of the effective coefficients is achieved by means of a finite dimensional minimization problem. [ABSTRACT FROM AUTHOR]

Published

2018

27. Tuneable Transient Thermogels Mediated by a pH- and Redox-Regulated Supramolecular Polymerization.

Author

Spitzer, Daniel, Rodrigues, Leona Lucas, Straßburger, David, Mezger, Markus, and Besenius, Pol

Subjects

*OXIDATION-reduction reaction, *SUPRAMOLECULAR polymers, *POLYMERIZATION, *DENDRIMERS, *PEPTIDE amphiphiles

Abstract

A multistimuli-responsive transient supramolecular polymerization of β-sheet-encoded dendritic peptide monomers in water is presented. The amphiphiles, which contain glutamic acid and methionine, undergo a glucose oxidase catalyzed, glucose-fueled transient hydrogelation in response to an interplay of pH and oxidation stimuli, promoted by the production of reactive oxygen species (ROS). Adjusting the enzyme and glucose concentration allows tuning of the assembly and the disassembly rates of the supramolecular polymers, which dictate the stiffness and transient stability of the hydrogels. The incorporation of triethylene glycol chains introduces thermoresponsive properties to the materials. We further show that repair enzymes are able to reverse the oxidative damage in the methionine-based thioether side chains. Since ROS play an important role in signal transduction cascades, our strategy offers great potential for applications of these dynamic biomaterials in redox microenvironments. [ABSTRACT FROM AUTHOR]

Published

2017

28. Inside Back Cover: Transient and Dissipative Host–Guest Hydrogels Regulated by Consumption of a Reactive Chemical Fuel (Angew. Chem. Int. Ed. 11/2023).

Author

Su, Bo, Chi, Teng, Ye, Zhou, Xiang, Yuanhui, Dong, Ping, Liu, Dongping, Addonizio, Christopher J., and Webber, Matthew J.

Subjects

*ENERGY consumption

Abstract

The temporary nature of this fuel-directed change in the interacting molecules causes the gels that are formed from this fuel to have a limited lifetime, autonomously converting back to their original pre-gel state over time without additional user input. Inside Back Cover: Transient and Dissipative Host-Guest Hydrogels Regulated by Consumption of a Reactive Chemical Fuel (Angew. Keywords: Chemical Fuel; Dynamic Materials; Non-Equilibrium; Rheology; Soft Matter EN Chemical Fuel Dynamic Materials Non-Equilibrium Rheology Soft Matter 1 1 1 03/02/23 20230306 NES 230306 B A new route to prepare hydrogels b relies on consumption of a chemical fuel to transiently drive network crosslinking by host-guest motifs, thereby prompting hydrogelation. [Extracted from the article]

Published

2023

29. Innenrücktitelbild: Transient and Dissipative Host–Guest Hydrogels Regulated by Consumption of a Reactive Chemical Fuel (Angew. Chem. 11/2023).

Author

Su, Bo, Chi, Teng, Ye, Zhou, Xiang, Yuanhui, Dong, Ping, Liu, Dongping, Addonizio, Christopher J., and Webber, Matthew J.

Subjects

*ENERGY consumption, *RHEOLOGY, *MOLECULES

Abstract

The temporary nature of this fuel-directed change in the interacting molecules causes the gels that are formed from this fuel to have a limited lifetime, autonomously converting back to their original pre-gel state over time without additional user input. Keywords: Chemical Fuel; Dynamic Materials; Non-Equilibrium; Rheology; Soft Matter EN Chemical Fuel Dynamic Materials Non-Equilibrium Rheology Soft Matter 1 1 1 03/02/23 20230306 NES 230306 B A new route to prepare hydrogels b relies on consumption of a chemical fuel to transiently drive network crosslinking by host-guest motifs, thereby prompting hydrogelation. Chemical Fuel, Dynamic Materials, Non-Equilibrium, Rheology, Soft Matter. [Extracted from the article]

Published

2023

30. Controlling the Localization of Liquid Droplets in Polymer Matrices by Evaporative Lithography.

Author

Zhao, Huaixia, Xu, Jiajia, Jing, Guangyin, Prieto-López, Lizbeth Ofelia, Deng, Xu, and Cui, Jiaxi

Subjects

*MATRICES (Mathematics), *DROPLETS, *LIQUIDS, *LITHOGRAPHY, *EVAPORATION (Chemistry)

Abstract

Localized inclusions of liquids provide solid materials with many functions, such as self-healing, secretion, and tunable mechanical properties, in a spatially controlled mode. However, a strategy to control the distribution of liquid droplets in solid matrices directly obtained from a homogeneous solution has not been reported thus far. Herein, we describe an approach to selectively localize liquid droplets in a supramolecular gel directly obtained from its solution by using evaporative lithography. In this process, the formation of droplet-embedded domains occurs in regions of free evaporation where the non-volatile liquid is concentrated and undergoes a phase separation to create liquid droplets prior to gelation, while a homogeneous gel matrix is formed in the regions of hindered evaporation. The different regions of a coating with droplet embedment patterns display different secretion abilities, enabling the control of the directional movement of water droplets. [ABSTRACT FROM AUTHOR]

Published

2016

31. Temporal Control of Gelation and Polymerization Fronts Driven by an Autocatalytic Enzyme Reaction.

Author

Jee, Elizabeth, Bánsági, Tamás, Taylor, Annette F., and Pojman, John A.

Subjects

*POLYMERIZATION, *CATALYTIC hydrolysis, *GELATION, *MICHAEL reaction, *AUTOCATALYSIS

Abstract

Chemical systems that remain kinetically dormant until activated have numerous applications in materials science. Herein we present a method for the control of gelation that exploits an inbuilt switch: the increase in pH after an induction period in the urease-catalyzed hydrolysis of urea was used to trigger the base-catalyzed Michael addition of a water-soluble trithiol to a polyethylene glycol diacrylate. The time to gelation (minutes to hours) was either preset through the initial concentrations or the reaction was initiated locally by a base, thus resulting in polymerization fronts that converted the mixture from a liquid into a gel (ca. 0.1 mm min−1). The rate of hydrolytic degradation of the hydrogel depended on the initial concentrations, thus resulting in a gel lifetime of hours to months. In this way, temporal programming of gelation was possible under mild conditions by using the output of an autocatalytic enzyme reaction to drive both the polymerization and subsequent degradation of a hydrogel. [ABSTRACT FROM AUTHOR]

Published

2016

32. New Developments in Proton Radiography at the Los Alamos Neutron Science Center (LANSCE).

Author

Morris, C., Brown, E., Agee, C., Bernert, T., Bourke, M., Burkett, M., Buttler, W., Byler, D., Chen, C., Clarke, A., Cooley, J., Gibbs, P., Imhoff, S., Jones, R., Kwiatkowski, K., Mariam, F., Merrill, F., Murray, M., Olinger, C., and Oro, D.

Subjects

*PROTONS, *RADIOGRAPHS, *FLASH radiography, *RADIOGRAPHY, *CHEMICAL reactions

Abstract

An application of nuclear physics, a facility for using protons for flash radiography, has been developed at the Los Alamos Neutron Science Center (LANSCE). Protons have proven far superior to high energy x-rays for flash radiography because of their long mean free path, good position resolution, and low scatter background. Although this facility is primarily used for studying very fast phenomena such as high explosive driven experiments, it is finding increasing application to other fields, such as tomography of static objects, phase changes in materials and the dynamics of chemical reactions. The advantages of protons are discussed, data from some recent experiments will be reviewed and concepts for new techniques are introduced. [ABSTRACT FROM AUTHOR]

Published

2016

33. Biocatalytic Feedback-Driven Temporal Programming of Self-Regulating Peptide Hydrogels.

Author

Heuser, Thomas, Weyandt, Elisabeth, and Walther, Andreas

Subjects

*PEPTIDES, *BIOCATALYSIS, *ENZYMES, *HYDROGELS, *PROTEINS

Abstract

Switchable self-assemblies respond to external stimuli with a transition between near-equilibrium states. Although being a key to present-day advanced materials, these systems respond rather passively, and do not display autonomous dynamics. For autonomous behavior, approaches must be found to orchestrate the time domain of self-assemblies, which would lead to new generations of dynamic and self-regulating materials. Herein, we demonstrate catalytic control of the time domain of pH-responsive peptide hydrogelators in a closed system. We program transient acidic pH states by combining a fast acidic activator with the slow, enzymatic, feedback-driven generation of a base (dormant deactivator). This transient state can be programmed over orders of magnitude in time. It is coupled to dipeptides to create autonomously self-regulating, dynamic gels with programmed lifetimes, which are used for fluidic guidance, burst release, and self-erasing rapid prototyping. [ABSTRACT FROM AUTHOR]

Published

2015

34. On Material Optimization in Continuum Dynamics.

Author

Lurie, Konstantin

Subjects

*RELAXATION methods (Mathematics), *MATHEMATICAL continuum, *METRIC spaces, *NUMERICAL analysis, *MATHEMATICAL optimization

Abstract

Special features of the general statements of material optimization problems in space-time are discussed in the paper. The main focus is put on the extension of problems that are ill-posed. [ABSTRACT FROM AUTHOR]

Published

2015

35. Molecular Encryption and Reconfiguration for Remodeling of Dynamic Hydrogels.

Author

Shihui Li, Gaddes, Erin R., Niancao Chen, and Yong Wang

Subjects

*CELL adhesion, *BIOMEDICAL materials, *HYDROGELS, *POLYMER colloids, *COLLOIDAL gels

Abstract

Dynamic materials have been widely studied for regulation of cell adhesion that is important to a variety of biological and biomedical applications. These materials can undergo changes mainly through one of the two mechanisms: ligand release in response to chemical, physical, or biological stimuli, and ligand burial in response to mechanical stretching or the change of electrical potential. This study demonstrates an encrypted ligand and anew hydrogel that are capable of inducing and inhibiting cell adhesion, which is controlled by molecular reconfiguration. The ligand initially exhibits an inert state; it can be reconfigured into active and inert states by using unblocking and recovering molecules in physiological conditions. Since molecular reconfiguration does not require the release of the ligand from the hydrogels, inhibiting and inducing cell adhesion on the hydrogels can be repeated for multiple cycles. [ABSTRACT FROM AUTHOR]

Published

2015

36. Perspectives in Chemistry-Aspects of Adaptive Chemistry and Materials.

Author

Lehn, Jean‐Marie

Subjects

*CHEMISTRY, *SMART materials, *DYNAMICAL systems, *EQUILIBRIUM, *TWO-dimensional models, *THREE-dimensional imaging, *MATERIALS science

Abstract

Chemistry, pure and applied, is a science and an industry. By its power over the expressions of matter, it also displays the creativity of art. It has expanded from molecular to supramolecular chemistry and then, by way of constitutional dynamic chemistry, towards adaptive chemistry. Constitutional dynamics allow for adaptation, through component exchange and selection in response to physical stimuli (e.g. light, photoselection), to chemical effectors (e.g. metal ions, metalloselection) or to environmental effects (e.g. phase change) in equilibrium or out-of-equilibrium conditions, towards the generation of the best-adapted/fittest constituent(s) in a dynamic set. Such dynamic systems can be represented by two-dimensional or three-dimensional dynamic networks that define the agonistic and antagonistic relationships between the different constituents linked through component exchange. The introduction of constitutional dynamics into materials science opens perspectives towards adaptive materials and technologies, presenting attractive behavioral features (such as self-healing). In particular, dynamic polymers may undergo modification of their properties (mechanical, optical, etc.) through component exchange and recombination in response to physical or chemical agents. Constitutional adaptive materials open towards a systems materials science and offer numerous opportunities for soft-matter technologies. [ABSTRACT FROM AUTHOR]

Published

2015

37. Emerging functional materials based on chemically designed molecular recognition

Author

Chen, Wei, Tian, Xiaohua, He, Wenbo, Li, Jianwei, Feng, Yonghai, and Pan, Guoqing

Published

2020

38. Process design for 5-axis ball end milling using a real-time capable dynamic material removal simulation

Author

O. Pape, Alexander Krödel, Lars Ellersiek, Volker Böß, A. Mücke, and Berend Denkena

Subjects

0209 industrial biotechnology, Topography, Flexible materials, Design, Turbine blade, Computer science, Dewey Decimal Classification::600 | Technik::620 | Ingenieurwissenschaften und Maschinenbau, Mechanical engineering, Process design, 02 engineering and technology, Shape deviations, medicine.disease_cause, Industrial and Manufacturing Engineering, Dexel, Nickel alloys, law.invention, Ball milling, 020901 industrial engineering & automation, 0203 mechanical engineering, law, Mold, medicine, Titanium alloys, Unstable process, Running-in process, Ball mill, Milling, Mechanical Engineering, Titanium alloy, Turbomachine blades, Hard to cut material, Process stability, 3D printers, Vibration, 020303 mechanical engineering & transports, Dynamic materials, Additive manufacturing process, Ball (bearing), ddc:620, Milling (machining), Simulation

Abstract

For repairing turbine blades or die and mold forms, additive manufacturing processes are commonly used to build-up new material to damaged sections. Afterwards, a subsequent re-contouring process such as 5-axis ball end milling is required to remove the excess material restoring the often complex original geometries. The process design of the re-contouring operation has to be done virtually, because the individuality of the repair cases prevents actual running-in processes. Hard-to-cut materials e.g. titanium or nickel alloys, parts prone to vibration and long tool holders complicate the repair even further. Thus, a fast and flexible material removal simulation is needed. The simulation has to predict suitable processes focusing shape deviations under consideration of process stability for arbitrary complex engagement conditions. In this paper, a dynamic multi-dexel based material removal simulation is presented, which is able to predict high-resolution surface topography and stable parameters for arbitrary processes such as 5-axis ball end milling. In contrast to other works, the simulation is able to simulate an unstable process using discrete cutting edges in real-time.

Published

2021

39. Photoinduced transformations of stiff-stilbene-based discrete metallacycles to metallosupramolecular polymers.

Author

Xuzhou Yan, Jiang-Fei Xu, Cook, Timothy R., Feihe Huang, Qing-Zheng Yang, Chen-Ho Tung, and Stang, Peter J.

Subjects

*METALLACYCLES, *POLYMERS, *BIPYRIDINE, *ORGANOPLATINUM compounds, *IRRADIATION, *PHOTOISOMERIZATION

Abstract

Control over structural transformations in supramolecular entities by external stimuli is critical for the development of adaptable and functional soft materials. Herein, we have designed and synthesized a dipyridyl donor containing a central Z-configured stiff-stilbene unit that self-assembles in the presence of two 180° di-Pt(ll) acceptors to produce size-controllable discrete organoplatinum(ll) metallacycles with high efficiency by means of the directional-bonding approach. These discrete metallacycles undergo transformation into extended metallosupramolecular polymers upon the conformational switching of the dipyridyl ligand from Z-config-ured (0°) to E-configured (180°) when photoirradiated. This transformation is accompanied by interesting morphological changes at nanoscopic length scales. The discrete metallacycles aggregate to spherical nanoparticles that evolve into long nanofibers upon polymer formation. These fibers can be reversibly converted to cyclic oligomers by changing the wavelength of irradiation, which reintroduces Z-configured building blocks owing to the reversible nature of stiff-stilbene photoisomerization. The design strategy defined here represents a novel self-assembly pathway to deliver advanced supramolecular assemblies by means of photocontrol. [ABSTRACT FROM AUTHOR]

Published

2014

40. Mechanics of network materials with responsive crosslinks.

Author

Wang, Chao, Gao, Enlai, Wang, Lifeng, and Xu, Zhiping

Subjects

*MECHANICAL behavior of materials, *CROSSLINKED polymers, *MOLECULAR dynamics, *SIMULATION methods & models, *VISCOELASTICITY, *MICROSTRUCTURE

Abstract

Abstract: The mechanics of responsive fiber-network materials have been explored here by performing coarse-grained molecular dynamics simulations. Theoretical analysis based on a simple viscoelastic model is used to characterize the relationship between their microstructures and overall mechanical behaviors. The dynamic responses in stress and strain induced by externally tuned interfiber crosslinks are discussed. Our results here indicate the possibility of optimizing the dynamic performance of macroscopic network materials by tuning the crosslinks at the molecular level, and lay the groundwork for dynamic material design for structural and mechanical applications. [Copyright &y& Elsevier]

Published

2014

41. Dynamers: From Supramolecular Polymers to Adaptive Dynamic Polymers.

Author

Lehn, Jean-Marie

Abstract

Dynamers may be defined as constitutional dynamic polymers of either supramolecular or molecular nature, i.e., polymeric entities whose monomeric components are linked through reversible connections, which can be either non-covalent interactions or reversible covalent bonds. They may for example implement hydrogen bonding, resulting in supramolecular hydrogen-bonded polymers. Alternatively, covalent dynamic polymers may be derived from the formation of imine-type bonds. Dynamers thus present the capacity to modify their constitution by exchange and reshuffling of their components. These constitutional dynamic features confer on dynamers the ability to modulate their properties in response to external chemical or physical triggers such as heat, light, medium, chemical additives, etc. They thus give access to higher levels of behavior such as self- healing and adaptation. The exchange of monomeric components defines constitutional dynamic networks of interconverting polymeric entities of different constitutions, presenting agonistic and antagonistic relationships between their constituents, and responding to chemical or physical stimulations by upregulating or downregulating specific linked entities. Such arrays represent adaptive constitutional networks that may be implemented for the development of tunable adaptive materials and technologies, towards the advent of a systems polymer/materials science in line with the emergence of systems chemistry. [ABSTRACT FROM AUTHOR]

Published

2013

42. PROLEGOMENA TO STUDIES ON DYNAMIC MATERIALS AND THEIR SPACE-TIME HOMOGENIZATION.

Author

MAUGIN, GERARD A. and ROUSSEAU, MARTINE

Subjects

SPACETIME, METAPHYSICS, ASYMPTOTIC homogenization, PARTIAL differential equations, CONSERVATION laws (Mathematics)

Abstract

This short contribution aims at introducing the notion of dynamic materials (as initiated by Blekhman and Lurie) and the corresponding allied techniques of homogenization and asymptotic analysis. Main role is played by the canonical conservation laws of energy and wave momentum - the latter most often ignored in the field of continuum mechanics - as follows from an application of the celebrated theorem of E. Noether. [ABSTRACT FROM AUTHOR]

Published

2013

43. Self-Healing Dynamic Polymeric Systems.

Author

Tyagi, Prashant, Deratani, André, and Quemener, Damien

Subjects

*SELF-healing materials, *POLYMERS, *MOLECULAR dynamics, *CHEMICAL bonds, *MATERIALS science, *MOLECULAR self-assembly

Abstract

The concept of self-healing has created a paradigm shift in the development of a new kind of responsive polymeric materials, which have traditionally been used in a passive role. Inspired by nature, the advancements made in this nascent field of research have given materials the ability of not only sensing damage but also responding and mending themselves in an appropriate manner. Self-healing in polymers can be autonomous, without the need for human intervention, or nonautonomous, requiring some form of external stimulus. The latter type involves the incorporation of dynamic bonds within the polymeric system, giving the ability to heal multiple times. This minireview discusses some of the prominent self-healing polymeric systems that harness different dynamic bond chemistries, with the aim of highlighting the potential of dynamic bonds to prepare such advanced materials. [ABSTRACT FROM AUTHOR]

Published

2013

44. FRACTAL SELF-ORGANIZATION OF BACTERIA-INSPIRED AGENTS.

Author

HUANG, YUFENG, KRUMANOCKER, IAN, and COPPENS, MARC-OLIVIER

Subjects

*FRACTALS, *MULTIAGENT systems, *REACTION-diffusion equations, *COMPUTER simulation, *MICHAELIS-Menten equation, *BIOSYNTHESIS, *BACTERIAL growth

Abstract

We develop an agent-based model as a preliminary theoretical basis to guide the synthesis of a new class of materials with dynamic properties similar to bacterial colonies. Each agent in the model is representative of an individual bacterium capable of: the uptake of chemicals (nutrients), which are metabolized; active movement (part viscous, part diffusive), consuming metabolic energy; and cellular division, when agents have doubled in size. The agents grow in number and self-organize into fractal structures, depending on the rules that define the actions of the agents and the parameter values. The environment of the agents includes chemicals responsible for their growth and is described by a diffusion-reaction equation with Michaelis-Menten kinetics. These rules are modeled mathematically by a set of equations with five dimensionless groups that are functions of physical parameters. Simulations are performed for different parameter values. The resulting structures are characterized by their fractal scaling regime, box-counting and mass-radius dimensions, and lacunarity. Each parameter influences the overall structure in a unique way, generating a wide spectrum of structures. For certain combinations of parameter values, the model converges to a steady state, with a finite population of agents that no longer divide. [ABSTRACT FROM AUTHOR]

Published

2012

45. Chemoresponsive alternating supramolecular copolymers created from heterocomplementary calix[4]pyrroles.

Author

Jung Su Park, Ki Youl Yoon, Dong Sub Kim, Lynch, Vincent M., Bielawski, Christopher W., Johnston, Keith P., and Sessler, Jonathan L.

Subjects

*X-ray diffraction, *COPOLYMERS, *PYRROLES, *MACROCYCLIC compounds, *TETRATHIAFULVALENE

Abstract

The importance of noncovalent interactions in the realm of biological materials continues to inspire efforts to create artificial supramolecular polymeric architectures. These types of self-assembled materials hold great promise as environmentally stimuli-responsive materials because they are capable of adjusting their various structural parameters, such as chain length, architecture, conformation, and dynamics, to new surrounding environments upon exposure to appropriate external stimuli. Nevertheless, in spite of considerable advances in the area of responsive materials, it has proved challenging to create synthetic self-assembled materials that respond to highly disparate analytes and whose environmentally induced changes in structure can be followed directly through both various spectroscopic and X-ray diffraction analyses. Herein, we report a new set of artificial self-assembled materials obtained by simply mixing two appropriately chosen, heterocomplementary macrocyclic receptors, namely a tetrathiafulvalene-functionalized calix[4]pyrrole and a bis(dinitrophenyl)-meso-substituted calix[4]pyrrole. The resulting polymeric materials, stabilized by combination of donor-acceptor and hydrogen bonding interactions, undergo dynamic, reversible dual guest-dependent structural transformations upon exposure to two very different types of external chemical inputs, namely chloride anion and trinitrobenzene. The structure and dynamics of the copolymers and their analyte-dependent responsive behavior was established via single crystal X-ray crystallography, SEM, heterocomplementary isodesmic analysis, 1- and 2D NMR, and dynamic light scattering spectroscopies. Our results demonstrate the benefit of using designed heterocomplementary interactions of two functional macrocyclic receptors to create synthetic, self-assembled materials for the development of "smart" sensory materials that mimic the key biological attributes of multianalyte recognition and substrate-dependent multisignaling. [ABSTRACT FROM AUTHOR]

Published

2011

46. Elements of study on dynamic materials.

Author

Rousseau, Martine, Maugin, Gérard, and Berezovski, Mihhail

Subjects

*ELASTIC waves, *SPATIAL analysis (Statistics), *INTERFACES (Physical sciences), *DOPPLER effect, *ELASTICITY, *DENSITY, *MECHANICAL behavior of materials, *LINEAR statistical models

Abstract

a preliminary study to more complex situations of interest in small-scale technology, this paper envisages the elementary propagation properties of elastic waves in one-spatial dimension when some of the properties (mass density, elasticity) may vary suddenly in space or in time, the second case being of course more original. Combination of the two may be of even greater interest. Toward this goal, a critical examination of what happens to solutions at the crossing of pure space-like and time-like material discontinuities is given together with simple solutions for smooth transitions and numerical simulations in the discontinuous case. The effects on amplitude, speed of propagation, frequency changes and the appearance of a Doppler-like effect are demonstrated although the whole physical system remains linear. [ABSTRACT FROM AUTHOR]

Published

2011

47. Dynamic materials with formation of clots: optimal mass transport in one spatial dimension without takeover.

Author

Lurie, K. A.

Subjects

FLUID dynamics, COLLISIONS (Physics), MASS (Physics), MOMENTUM (Mechanics), EQUATIONS

Abstract

The concept of dynamic materials (DM) was introduced in the earlier work [1, 2, 9] and developed there for the case of non-colliding characteristics. The present paper extends this concept toward the case when the characteristics collide. The extension is formulated for a linear continuity equation in 1D with a no takeover condition applied to the moving masses. This implies the formation of clots with the preservation of both mass and momentum, which makes the approach resemble the method of “sticky particles” known in pressureless gas dynamics. The extension introduces non-linearity into the transportation problem that was originally missing, thus placing it closer to a non-linear conservation law. [ABSTRACT FROM AUTHOR]

Published

2010

48. Mathematical analysis of the waves propagation through a rectangular material structure in space–time

Author

Lurie, K.A., Onofrei, D., and Weekes, S.L.

Subjects

*MATHEMATICAL analysis, *SPATIAL analysis (Statistics), *WAVE equation, *MICROSTRUCTURE, *MATHEMATICAL variables, *SPACETIME

Abstract

Abstract: We consider propagation of waves through a spatio-temporal doubly periodic material structure with rectangular microgeometry in one spatial dimension and time. Both spatial and temporal periods in this dynamic material are assumed to be the same order of magnitude. Mathematically the problem is governed by a standard wave equation with variable coefficients. We consider a checkerboard microgeometry where variables cannot be separated. The rectangles in a space–time checkerboard are assumed filled with materials differing in the values of phase velocities but having equal wave impedance . The difference between dynamic materials and classical static composites is that in the former case the design variables will also be time dependent. Within certain parameter ranges, the formation of distinct and stable limiting characteristic paths, i.e., limit cycles, was observed in [K.A. Lurie, S.L. Weekes, Wave propagation and energy exchange in a spatio-temporal material composite with rectangular microstructure, J. Math. Anal. Appl. 314 (2006) 286–310]; such paths attract neighboring characteristics after a few time periods. The average speed of propagation along the limit cycles remains the same throughout certain ranges of structural parameters, and this was called in [K.A. Lurie, S.L. Weekes, Wave propagation and energy exchange in a spatio-temporal material composite with rectangular microstructure, J. Math. Anal. Appl. 314 (2006) 286–310] a plateau effect. Based on numerical evidence, it was conjectured in [K.A. Lurie, S.L. Weekes, Wave propagation and energy exchange in a spatio-temporal material composite with rectangular microstructure, J. Math. Anal. Appl. 314 (2006) 286–310] that a checkerboard structure is on a plateau if and only if it yields stable limit cycles and that there may be energy concentrations over certain time intervals depending on material parameters. In the present work we give a more detailed analytic characterization of these phenomena and provide a set of sufficient conditions for the energy concentration that was predicted numerically in [K.A. Lurie, S.L. Weekes, Wave propagation and energy exchange in a spatio-temporal material composite with rectangular microstructure, J. Math. Anal. Appl. 314 (2006) 286–310]. [Copyright &y& Elsevier]

Published

2009

49. Space–time topology optimization for one-dimensional wave propagation

Author

Jensen, Jakob S.

Subjects

*WAVE mechanics, *MECHANICAL loads, *ELASTICITY, *ELASTIC rods & wires, *MATHEMATICAL optimization, *TOPOLOGY

Abstract

Abstract: A space–time extension of the topology optimization method is presented. The formulation, with design variables in both the spatial and temporal domains, is used to create structures with an optimized distribution of material properties that can vary in time. The method is outlined for one-dimensional transient wave propagation in an elastic rod with time dependent Young’s modulus. By two simulation examples it is demonstrated how dynamic structures can display rich dynamic behavior such as wavenumber/frequency shifts and lack of energy conservation. The optimization method’s potential for creating structures with novel dynamic behavior is illustrated by a simple example; it is shown that an elastic rod in which the optimized stiffness distribution is allowed to vary in time can be much more efficient in prohibiting wave propagation compared to a static bandgap structure. Optimized designs in form of spatio-temporal laminates and checkerboards are generated and discussed. The example lays the foundation for creating designs with more advanced functionalities in future work. [Copyright &y& Elsevier]

Published

2009

50. Dynamers: dynamic molecular and supramolecular polymers

Author

Lehn, Jean-Marie

Subjects

*POLYMERS, *SUPRAMOLECULAR chemistry, *POLYCONDENSATION, *HYDROGEN bonding, *CHEMISTRY

Abstract

Abstract: Dynamers may be defined as constitutional dynamic polymers, i.e. polymeric entities whose monomeric components are linked through reversible connections and have therefore the capacity to modify their constitution by exchange and reshuffling of their components. They may be either of molecular or supramolecular nature depending on whether the connections are reversible covalent bonds or non-covalent interactions. They are formed, respectively, either by polycondensation with functional recognition or by polyassociation with interactional recognition between the connecting subunits. Both types are illustrated by specific examples implementing hydrogen bonding on one hand and acylhydrazone formation on the other. The dynamic properties confer to dynamers the ability to undergo adaptation and driven evolution under the effect of external chemical or physical triggers. Dynamers thus are constitutional dynamic materials resulting from the application of the principles of constitutional dynamic chemistry to polymer science. [Copyright &y& Elsevier]

Published

2005