0000000000286328

AUTHOR

Jonas Heckel

showing 3 related works from this author

Spinodal decomposition of chemically fueled polymer solutions

2021

Out-of-equilibrium phase transitions driven by dissipation of chemical energy are a common mechanism for morphological organization and temporal programming in biology. Inspired by this, dissipative self-assembly utilizes chemical reaction networks (CRNs) that consume high-energy molecules (chemical fuels) to generate transient structures and functionality. While a wide range of chemical fuels and building blocks are now available for chemically fueled systems, so far little attention has been paid to the phase-separation process itself. Herein, we investigate the chemically fueled spinodal decomposition of poly(norbornene dicarboxylic acid) (PNDAc) solution, which is driven by a cyclic che…

chemistry.chemical_classificationPhase transitionMaterials scienceSpinodal decomposition02 engineering and technologyGeneral ChemistryPolymerDissipation010402 general chemistry021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciencesChemical reaction0104 chemical sciencesChemical energychemistryChemical engineeringDissipative systemMolecule0210 nano-technologySoft Matter
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Chemically Fueled Block Copolymer Self‐Assembly into Transient Nanoreactors**

2021

In chemically fueled supramolecular materials, molecular self-assembly is coupled to a fuel-driven chemical reaction cycle. The fuel-dependence makes the material dynamic and endows it with exciting properties like adaptivity and autonomy. In contrast to the large work on the self-assembly of small molecules, we herein designed a diblock copolymer, which self assembles into transient micelles when coupled to a fuel-driven chemical reaction cycle. Moreover, we used these transient block copolymer micelles to locally increase the concentration of hydrophobic reagents and thereby function as a transient nanoreactor.

Materials science010405 organic chemistryMechanical EngineeringSupramolecular chemistryEnergy Engineering and Power TechnologyNanoreactorManagement Science and Operations Research010402 general chemistry01 natural sciencesSmall moleculeChemical reactionMicelle0104 chemical sciencesChemical engineeringReagentCopolymerSelf-assemblyChemSystemsChem
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Chemically Fueled Volume Phase Transition of Polyacid Microgels

2021

Abstract Microgels are soft colloids that show responsive behavior and are easy to functionalize for applications. They are considered key components for future smart colloidal material systems. However, so far microgel systems have almost exclusively been studied in classical responsive switching settings using external triggers, while internally organized, autonomous control mechanisms as found in supramolecular chemistry and DNA nanotechnology relying on fuel‐driven out‐of‐equilibrium concepts have not been implemented into microgel systems. Here, we introduce chemically fueled transient volume phase transitions (VPTs) for poly(methacrylic acid) (PMAA) microgels, where the collapsed hydr…

Phase transition540 Chemistry and allied sciencesMaterials scienceSupramolecular chemistry010402 general chemistrydissipative self-assembly01 natural sciencesnonequilibrium processesCatalysismicrogelschemistry.chemical_compoundColloidMicrogels | Hot PaperDNA nanotechnologyfuelsAutonomous controlResearch Articlespolymerschemistry.chemical_classification010405 organic chemistryMaterial systemGeneral ChemistryPolymerGeneral Medicine0104 chemical sciencesChemical engineeringMethacrylic acidchemistry540 ChemieResearch ArticleAngewandte Chemie
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