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1. Divalent cation effects in the glass transition of poly(diallyldimethylammonium)–poly(styrene sulfonate) polyelectrolyte complexes

   https://doi.org/10.1039/d4sm00856a  

   Braide, Tamunoemi; Manoj_Lalwani, Suvesh; Eneh, Chikaodinaka I; Lutkenhaus, Jodie L (December 2024, Soft Matter)

   The assembly and dynamics of polyelectrolyte complexes (PECs) and polyelectrolyte multilayers (PEMs) are influenced by water content, pH, and salt concentration. However, the influence of divalent salts on the assembly of polyelectrolyte complexes remains unclear. This work showcases that divalent chloride salts directly impact the glass transition temperature and the ion–ion interactions within PECs. Here, poly(diallyldimethylammonium)–poly(styrene sulfonate) (PDADMA–PSS) PECs are assembled in solutions containing MgCl2 and CaCl2 (following the Hofmeister series). These PECs are studied for the cations’ influence on physicochemical properties (glass transition, polymer composition, ion pairing) at varying salt concentrations (0.03 M, 0.10 M, 0.15 M, and 0.20 M). Modulated differential scanning calorimetry (MDSC) experiments demonstrate that PECs assembled with CaCl2 have a significantly higher glass transition temperature when compared to PECs assembled with MgCl2. Neutron activation analysis (NAA) and nuclear magnetic resonance (NMR) spectroscopy demonstrate that this difference is due to strong ion-specific effects influencing the ratio of intrinsic and extrinsic ion pairings in the system. Furthermore, this study demonstrates a universal linear relationship between the thermal transition and the number of water molecules surrounding oppositely charged polyelectrolyte–polyelectrolyte intrinsic ion pairs, even when the salt contains divalent cations. Ion-specific trends have implications on the glass transition and composition of PDADMA–PSS PECs. Divalent salts not only follow the trend of the Hofmeister series but also introduce bridging into the polyelectrolyte complex; however, the structural relaxation of the PEC remains the same. This study offers a bridge between divalent cation behavior on polymer assembly properties and its transition to industrial applications such as controlled drug delivery, sensors, and water purification. 

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2. Segregative phase separation of strong polyelectrolyte complexes at high salt and high polymer concentrations

   https://doi.org/10.1039/D4SM00994K  

   Chee, Conner H; Benharush, Rotem; Knight, Lexi R; Laaser, Jennifer E (October 2024, Soft Matter)

   The phase behavior of polyelectrolyte complexes and coacervates (PECs) at low salt concentrations has been well characterized, but their behavior at concentrations well above the binodal is not well understood. Here, we investigate the phase behavior of stoichiometric poly(styrene sulfonate)/poly(diallyldimethylammonium) mixtures at high salt and high polymer concentrations. Samples were prepared by direct mixing of PSS/PDADMA PECs, water, and salt (KBr). Phase separation was observed at salt concentrations approximately 1 M above the binodal. Characterization by thermogravimetric analysis, FTIR, and NMR revealed that both phases contained significant amounts of polymer, and that the polymer-rich phase was enriched in PSS, while the polymer-poor phase was enriched in PDADMA. These results suggest that high salt concentrations drive salting out of the more hydrophobic polyelectrolyte (PSS), consistent with behavior observed in weak polyelectrolyte systems. Interestingly, at the highest salt and polymer concentrations studied, the polymer-rich phase contained both PSS and PDADMA, suggesting that high salt concentrations can drive salting out of partially-neutralized complexes as well. Characterization of the behavior of PECs in the high concentration limit appears to be a fruitful avenue for deepening fundamental understanding of the molecular-scale factors driving phase separation in these systems. 

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3. Formamide as a Robust Alternative to Water for Plasticizing Polyelectrolyte Complexes

   https://doi.org/10.1021/acs.macromol.4c01691  

   Hassoun, Sarriah; Digby, Zachary A; Abou_Hamad, Nagham; Schlenoff, Joseph B (October 2024, Macromolecules)

   Polyelectrolyte complexes, PECs, are glassy and brittle when dry but may be plasticized with water. Though hydrated PECs contain a high proportion of water, many still exhibit a glass transition in the 0 to 100 oC range. The apparently unique effectiveness of water as a plasticizer of PECs has been an obstacle to further developments in applications and in fundamental studies of PEC properties. In this work it is shown that formamide is an excellent and even superior solvent for plasticizing PECs, substantially decreasing glass transition temperatures relative to those of hydrated PECs when formamide is used as a solvent instead. The affinities of PECs for water and formamide, indicated by the (exothermic) enthalpies of solvent swelling of dry PECs, are comparable. Ion transport dynamics revealed similar lifetimes, about 1 ns, of charge pairs within a PEC solvated with water compared to formamide, despite the differences in their dielectric constants. Ion transport dynamics, which depend on the mobility of pendant groups, have lower cooperativity than those of the polymer backbone. The use of formamide is a significant experimental variable for reducing the glass transition temperature/viscosity of complexed polyelectrolytes and can turn a solidlike hydrated complex into a fluidlike coacervate. 

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4. Aqueous Processing of Stoichiometric and Nonstoichiometric Materials from Complex Coacervates

   https://doi.org/10.1021/accountsmr.5c00173  

   Hung, Shao-Hsiang Joe; Schiffman, Jessica D (October 2025, Accounts of Materials Research)

   With the rise of green engineering, there is an increasing need to manufacture materials without relying on organic solvents. Using all-aqueous approaches mitigates the industrial safety and environmental concerns that are associated with volatile organic compounds, while enabling scalable and sustainable fabrication processes. Water-insoluble polyelectrolyte complexes (PECs) arise due to the electrostatic attraction between oppositely charged polyelectrolytes in solution. Notably, when salt is present, these rigid or glassy PECs can be transformed into malleable and liquid states, enabling researchers to process solid materials from the previously deemed unprocessable. The liquid PEC phase, also known as a polyelectrolyte complex coacervate, arises through liquid–liquid phase separation and offers a tunable viscosity to match the needs of the processing method. These coacervates exhibit adjustable rheological properties by varying parameters, including temperature, salt type, ionic strength, polymer ratio, and molecular weight. This tunability makes them attractive for applications ranging from coatings and adhesives to biomedical delivery systems. Notably, the transition between liquid and solid PECs is reversible, as removing salt ions restores the physical cross-links. Additionally, PECs exhibit exceptional stability in various organic solvents and solutions with extreme pH values, without requiring chemical cross-linking. However, the aqueous processing strategies and reversibility of PECs have yet to be fully explored. In this Account, we primarily focus on the well-studied PEC system composed of the strong polyelectrolytes poly(sodium 4-styrenesulfonate) and poly(diallyldimethylammonium chloride). First, we describe how salt concentration is a crucial parameter that enables the aqueous processing of coacervates via electrospinning, spin coating, bar casting, and 3D printing into fibers, coatings, membranes, and 3D structures. We also discuss the impact that processing conditions, like drying and quenching, have on the properties of solid materials, such as their porosity and mechanical strength. Next, we highlight reports that explore how the solubility mismatch between polyelectrolyte pairs and salt ions result in solid and liquid PECs that are nonstoichiometric, thereby exhibiting an overcompensation phenomenon or nonstoichiometry. How the mechanical behavior of a material changes as a function of temperature, i.e., their thermomechanical properties, as well as membrane separation performance are notably influenced by nonstoichiometry, even when the degree of nonstoichiometry is minimal. Interestingly, we are starting to see research reports in the literature on how post-treatment methods, including salt and heat annealing, previously applied to polyelectrolyte multilayer films, offer some transferability to bar-casted separation membranes, which warrants further research. We conclude with a forward-looking discussion that highlights the potential opportunities and challenges related to the future implementation of PEC-based materials. 

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5. Optimization of Polyelectrolyte Coacervate Membranes via Aqueous Phase Separation

   https://doi.org/10.1021/acsami.4c18989  

   Hung, Shao-Hsiang Joe; Chiang, Meng-Chen; Schiffman, Jessica D (December 2024, ACS Applied Materials & Interfaces)

   Polymeric membranes fabricated via the nonsolvent-induced phase separation process rely heavily on toxic aprotic organic solvents, like N-methyl-pyrrolidine (NMP) and dimethylformamide. We suggest that the “saloplastic” nature of polyelectrolyte complexes (PECs) makes them an excellent candidate for fabricating next-generation water purification membranes that use a more sustainable aqueous phase separation process. In this study, we investigate how the properties of PECs and their interactions with salt can form pore-containing membranes from the strong polyelectrolytes poly(sodium 4-styrenesulfonate) (PSS) and poly(diallyldimethylammonium chloride) (PDADMAC) in the presence of potassium bromide (KBr). How the single-phase polymer-rich (coacervate) dope solution and coagulation bath impacted the formation, morphology, and pure water permeance (PWP) of the membranes was systematically evaluated by using scanning electron microscopy and dead-end filtration tests. The impact of a salt annealing post-treatment process was also tested; these treated PEC membranes exhibited a PWP of 6.2 L m–2 h–1 bar–1 and a dye removal of 91.7% and 80.5% for methyl orange and methylene blue, respectively, which are on par with commercial poly(ether sulfone) nanofiltration membranes. For the first time, we have demonstrated the ability of the PEC membranes to repel Escherichia coli bacteria under static conditions. Our fundamental study of polyelectrolyte membrane pore-forming mechanisms and separation performance could help drive the future development of sustainable materials for membrane-based separations. 

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