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1. Self‐Healable Fluorinated Copolymers Governed by Dipolar Interactions

   https://doi.org/10.1002/advs.202101399  

   Wang, Siyang; Urban, Marek_W (July 2021, Advanced Science)

   Abstract Although dipolar forces between copolymer chains are relatively weak, they result in ubiquitous inter‐ and/or intramolecular interactions which are particularly critical in achieving the mechanical integrity of polymeric materials. In this study, a route is developed to obtain self‐healable properties in thermoplastic copolymers that rely on noncovalent dipolar interactions present in essentially all macromolecules and particularly fluorine‐containing copolymers. The combination of dipolar interactions between C─F and C═O bonds as well as CH₂/CH₃entities facilitates self‐healing without external intervention. The presence of dipole‐dipole, dipole‐induced dipole, and induced‐dipole induced dipole interactions leads to a viscoelastic response that controls macroscopic autonomous multicycle self‐healing of fluorinated copolymers under ambient conditions. Energetically favorable dipolar forces attributed to monomer sequence and monomer molar ratios induces desirable copolymer tacticities, enabling entropic energy recovery stored during mechanical damage. The use of dipolar forces instead of chemical or physical modifications not only eliminates additional alternations enabling multiple damage‐repair cycles but also provides further opportunity for designing self‐healable commodity thermoplastics. These materials may offer numerous applications, ranging from the use in electronics, ion batteries, H₂fuel dispense hoses to self‐healable pet toys, packaging, paints and coatings, and many others. 

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2. Self‐Healable Poly(ionic liquid) Copolymers Driven by Polar and Dipolar Forces

   https://doi.org/10.1002/anie.202510066  

   Gaikwad, Samruddhi; Liu, Jiahui; Mashkow, Nyx; Urban, Marek W (August 2025, Angewandte Chemie International Edition)

   Abstract Commodity aliphatic and aromatic acrylic‐based copolymers self‐heal due to ubiquitouskey‐and‐lock,ring‐and‐lock, andfluorophilic‐σ‐lockvan der Waals (vdW) interactions. However, the role of these interactions in the presence of covalently copolymerized ionic liquid (IL) is not known. This study is driven by the hypothesis that covalently incorporated cation–anion pairs to form poly(ionic liquid) copolymers (PILCs) can perturb inter‐ or intra‐chain vdW interactions reflected in mechanical and electrical responses. To test this hypothesis, we synthesized a series of PILCs comprising of pentafluorostyrene (PFS) and imidazolium‐based IL monomers with variable‐length aliphatic tails (methyl and butyl). Using a combination of 2D¹H‐¹H and¹⁹F ‐¹⁹F NOESY NMR and FTIR measurements supplemented by molecular dynamic (MD) simulations, these studies demonstrate that preferentially alternating/random PILCs topologies facilitate self‐healing. The introduction of cation–anion moieties modifies thefluorophilic‐σ‐lockinteractions and, along with longer aliphatic tails ─(CH₂)₃CH₃covalently attached to the imidazolium cation, enhances cation‐anion mobility, thus faster recovery from mechanical damage occurs. These findings underline how precise control over dipolar and ionic interactions through copolymer composition enables self‐healing in PILCs. These insights may open pathways for designing sustainable, mechanically resilient materials for applications in energy storage and energy harvesting. 

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3. Self‐Healing of Polymers via Supramolecular Chemistry

   https://doi.org/10.1002/admi.201800384  

   Yang, Ying; Urban, Marek_W (June 2018, Advanced Materials Interfaces)

   Abstract Recent advances of supramolecular chemistry utilized in the development of self‐healing polymers have revealed that the rate and equilibrium constants of bond dissociation/re‐association, bonding directionality, chain relaxation time, decay rate of chain relaxation after damage, and cluster formation may impact the healing efficiency in a given environment. This review provides an assessment of supramolecular chemistries responsible for self‐healing using H‐bonding, metal–ligand, host–guest, ionic, π–π, and hydrophobic interactions. The impact of these chemistries on self‐healing is examined for various polymeric systems with multifunctional applications which are unique to supramolecular networks. This review also discusses the driving forces leading to physical damage closure in the context of supramolecular bond dynamics, providing insights into the design principles to achieve efficient recovery. 

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4. Electrically Accelerated Self‐Healable Polyionic Liquid Copolymers

   https://doi.org/10.1002/smll.202201952  

   Liu, Qianhui; Wang, Siyang; Zhao, Zeyu; Tong, Jianhua; Urban, Marek W. (May 2022, Small)

   Abstract Electrically accelerated self‐healable poly(ionic liquids) copolymers that exhibit resistor‐capacitor (RC) circuit properties are developed. At low alternating current (AC) frequencies these materials behave as a resistor (R), whereas at higher frequencies as a capacitor (C). These properties are attributed to a combination of dipolar and electrostatic interactions in (1‐[(2‐methacryloyloxy)ethyl]‐3‐butylimidazolium bis(trifluoromethyl‐sulfonyl)imide) copolymerized with methyl methacrylate (MMA) monomers to form p(MEBIm‐TSFI/MMA)] copolymers. When the monomer molar ratio (MEBIm‐TSFI:MMA) is 40/60, these copolymers are capable of undergoing multiple damage‐repair cycles and self‐healing is accelerated by the application of alternating 1.0–4.0 V electric field (EF). Self‐healing in the absence of EFs is facilitated by van der Waals (vdW) interactions, but the application of AC EF induces back and forth movement of charges against the opposing force that result in dithering of electrostatic dipoles giving rise to interchain physical crosslinks. Electrostatic inter‐ and intrachain interactions facilitated by copolymerization of ionic liquid monomers with typically dielectric acrylic‐based monomers result in enhanced cohesive energy densities that accelerate the recovery of vdW forces facilitating self‐healing. Incorporating ionic liquids into commodity polymers offers promising uses as green conducting solid polyelectrolytes in self‐healable energy storage, energy‐harvesting devices, and many other applications. 

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5. UV-induced vesicle to micelle transition: a mechanistic study

   https://doi.org/10.1039/c9py01259a  

   Machado, Craig A.; Tran, Roger; Jenkins, Taylor A.; Pritzlaff, Amanda M.; Sims, Michael B.; Sumerlin, Brent S.; Savin, Daniel A. (November 2019, Polymer Chemistry)

   The morphology of self-assembled block copolymer aggregates is highly dependent on the relative volume fraction of the hydrophobic block. Thus, a dramatic change in the volume fraction of the hydrophobic block can elicit on-demand morphological transitions. Herein, a novel hydrophobic monomer containing a photolabile nitrobenzyl (Nb) protecting group was synthesized and incorporated into a block copolymer with poly(ethylene glycol) methacrylate. This motif allows for the hydrophobic volume fraction of the amphiphilic block copolymer to be dramatically reduced in situ to induce a morphological transition upon irradiation with UV light. Two amphiphilic block copolymers, Nb 94 and Nb 176, with hydrophobic weight fractions of 80% and 86%, respectively, were synthesized and their self-assembly in water studied. Nb 94 assembled into vesicles with R h = 235 nm and underwent a morphological transition after 21 minutes of UV irradiation to spherical micelles with R h = 27 nm, determined by dynamic light scattering and confirmed by transmission electron microscopy. At intermediate irradiation times (14–20 min), Nb 94 vesicles swelled to a larger size, but underwent a morphological transition over the course of hours or days, depending on the exact irradiation time. Nb 176 assembled into large compound vesicles with a hydrodynamic radius ( R h ) of 973 nm, as determined by dynamic light scattering (DLS), which decreased to ca. 700 nm after 300 minutes of UV irradiation with no apparent morphological transition. This study elucidates the mechanism and kinetics of the morphological transitions of block copolymer assemblies induced by a change in the hydrophobic volume fraction of the polymer. 

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