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1. Crafting Tunable Hollow Particles Using Antisolvent‐Driven Interlocking of Micron‐Sized Building Blocks

   https://doi.org/10.1002/adfm.202313025  

   Li, Peilong; Li, Jieying; Levin, Jacob; Kierulf, Arkaye; Smoot, James; Zarei, Amin; Abbaspourrad, Alireza (July 2024, Advanced Functional Materials)

   Abstract The contribution of a hollow structure on the rheological behavior of granular suspensions remains un‐investigated due to the challenge of water impermeability. Here starch is used to fabricate water‐permeable hollow particles, as a model for granular suspensions and investigated the resulting microstructures and rheological behavior. The hollow structure is fabricated based on a bottom‐up method by assembling micron‐sized building blocks into a superstructure. A Pickering emulsion is heated to fuse the starch interface, then, upon antisolvent precipitation, the polymer strands interlock to form a rigid shell around the oil template. When the template is removed a hollow particle remained. These particles exhibited a specific volume >5‐times higher than unmodified starch and consequently a higher viscosity. Larger particles showed higher viscosity but are also more fragile. The template structure can be manipulated to fine‐tune their functionality. These micro‐sized building blocks made from edible materials can be used as the next generation of texturizers. Additionally, these water‐permeable colloidosomes present an innovative approach to understanding how micro‐architectures impact the rheological behavior of granular suspensions. 

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2. Recent advances in starch‐based films toward food packaging applications: Physicochemical, mechanical, and functional properties

   https://doi.org/10.1111/1541-4337.12627  

   Lauer, Moira_K; Smith, Rhett_C (September 2020, Comprehensive Reviews in Food Science and Food Safety)

   Abstract Interest in starch‐based films has increased precipitously in response to a growing demand for more sustainable and environmentally sourced food packaging materials. Starch is an optimal candidate for these applications given its ability to form thermoplastic materials and films with affordable and often sustainably sourced plasticizers like those produced as waste byproducts by biodiesel and agricultural industries. Starch is also globally ubiquitous, affordable, and environmentally benign. Although the process of producing starch films is relatively straightforward, numerous factors, including starch source, extraction method, film formulation, processing methods, and curing procedures, drastically impact the ultimate material properties. The significant strides made from 2015 to early 2020 toward elucidating how these variables can be leveraged to improve mechanical and barrier properties as well as the implementation of various additives or procedural modifications are cataloged in this review. Advances toward the development of functional films containing antioxidant, antibacterial, or spoilage indicating components to prevent or signal the degradation of food products are also discussed. 

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3. Shell buckling for programmable metafluids

   https://doi.org/10.1038/s41586-024-07163-z  

   Djellouli, Adel; Van Raemdonck, Bert; Wang, Yang; Yang, Yi; Caillaud, Anthony; Weitz, David; Rubinstein, Shmuel; Gorissen, Benjamin; Bertoldi, Katia (April 2024, Nature)

   The pursuit of materials with enhanced functionality has led to the emergence of metamaterials—artificially engineered materials whose properties are determined by their structure rather than composition. Traditionally, the building blocks of metamaterials are arranged in fixed positions within a lattice structure. However, recent research has revealed the potential of mixing disconnected building blocks in a fluidic medium. Inspired by these recent advances, here we show that by mixing highly deformable spherical capsules into an incompressible fluid, we can realize a ‘metafluid’ with programmable compressibility, optical behaviour and viscosity. First, we experimentally and numerically demonstrate that the buckling of the shells endows the fluid with a highly nonlinear behaviour. Subsequently, we harness this behaviour to develop smart robotic systems, highly tunable logic gates and optical elements with switchable characteristics. Finally, we demonstrate that the collapse of the shells upon buckling leads to a large increase in the suspension viscosity in the laminar regime. As such, the proposed metafluid provides a promising platform for enhancing the functionality of existing fluidic devices by expanding the capabilities of the fluid itself. 

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4. Fuel‐Driven π‐Conjugated Superstructures to Form Transient Conductive Hydrogels

   https://doi.org/10.1002/ange.202417109  

   Tsironi, Ifigeneia; Maleszka, Jarek_A; Kriebisch, Brigitte_A_K; Wilson‐Kovacs, Robert_S; Acevedo, Orlando; O'Leary, Shamus_L; Watt, John; Boekhoven, Job; Olivier, Jean‐Hubert (December 2024, Angewandte Chemie)

   Abstract Despite advances in creating dissipative materials with transient properties, such as hydrogels and active droplets, their application remains confined to temporal changes in structural properties. Developing out‐of‐equilibrium materials whose electronic functions are parameterized by a chemical reaction cycle is challenging. Yet, this class of materials is required to construct biomimetic materials. In contrast to traditional chemical reaction cycles that exploit molecularly dissolved building blocks at thermodynamic equilibrium, we show that fiber structures derived from reactive naphthalene diimide (NDI) building blocks can be used as resting states to form far‐from‐equilibrium conductive hydrogels after the addition of chemical fuels. Upon fueling the NDI‐derived fibers, a dual‐component activation and deactivation pathway is deduced by kinetic analysis and is absent when using a molecularly dissolved resting state. Investigating the solid‐state morphologies of the structures formed throughout the fuel‐driven reaction cycle using cryo‐EM reveals that the resting thermodynamic fibers evolve to transient thicker fibrils and layered superstructures. We show that the transient redox‐active hydrogels exhibit a nearly threefold increase in electrical conductivity upon fuel consumption before reverting to their original value over hours. These far‐from‐equilibrium materials are potential candidates in applications such as programmable biorobotics and chemical computing. 

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5. How to reprogram the excitonic properties and solid-state morphologies of π-conjugated supramolecular polymers

   https://doi.org/10.1039/D0CP04819D  

   Liu, Kaixuan; Paulino, Victor; Mukhopadhyay, Arindam; Bernard, Brianna; Kumbhar, Amar; Liu, Chuan; Olivier, Jean-Hubert (January 2021, Physical Chemistry Chemical Physics)

   null (Ed.)

   The development of supramolecular tools to modulate the excitonic properties of non-covalent assemblies paves the way to engineer new classes of semicondcuting materials relevant to flexible electronics. While controlling the assembly pathways of organic chromophores enables the formation of J-like and H-like aggregates, strategies to tailor the excitonic properties of pre-assembled aggregates through post-modification are scarce. In the present contribution, we combine supramolecular chemistry with redox chemistry to modulate the excitonic properties and solid-state morphologies of aggregates built from stacks of water-soluble perylene diimide building blocks. The n-doping of initially formed aggregates in an aqueous medium is shown to produce π–anion stacks for which spectroscopic properties unveil a non-negligible degree of electron–electron interactions. Oxidation of the n-doped intermediates produces metastable aggregates where free exciton bandwidths (Ex BW ) increase as a function of time. Kinetic data analysis reveals that the dynamic increase of free exciton bandwidth is associated with the formation of superstructures constructed by means of a nucleation-growth mechanism. By designing different redox-assisted assembly pathways, we highlight that the sacrificial electron donor plays a non-innocent role in regulating the structure–function properties of the final superstructures. Furthermore, supramolecular architectures formed via a nucleation-growth mechanism evolve into ribbon-like and fiber-like materials in the solid-state, as characterized by SEM and HRTEM. Through a combination of ground-state electronic absorption spectroscopy, electrochemistry, spectroelectrochemistry, microscopy, and modeling, we show that redox-assisted assembly provides a means to reprogram the structure–function properties of pre-assembled aggregates. 

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