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1. Functionalized Nanochannels from Self‐Assembled and Photomodified Poly(Styrene‐ b ‐Butadiene‐ b ‐Styrene)

   https://doi.org/10.1002/smll.201701885  

   Sutisna, Burhannudin ; Polymeropoulos, George ; Musteata, Valentina ; Sougrat, Rachid ; Smilgies, Detlef‐M. ; Peinemann, Klaus‐Viktor ; Hadjichristidis, Nikolaos ; Nunes, Suzana P. ( October 2017 , Small)

   Membranes are prepared by self‐assembly and casting of 5 and 13 wt% poly(styrene‐b‐butadiene‐b‐styrene) (PS‐b‐PB‐b‐PS) copolymers solutions in different solvents, followed by immersion in water or ethanol. By controlling the solution‐casting gap, porous films of 50 and 1 µm thickness are obtained. A gradient of increasing pore size is generated as the distance from the surface increased. An ordered porous surface layer with continuous nanochannels can be observed. Its formation is investigated, by using time‐resolved grazing incident small angle X‐ray scattering, electron microscopy, and rheology, suggesting a strong effect of the air–solution interface on the morphology formation. The thin PS‐b‐PB‐b‐PS ordered films are modified, by promoting the photolytic addition of thioglycolic acid to the polybutadiene groups, adding chemical functionality and specific transport characteristics on the preformed nanochannels, without sacrificing the membrane morphology. Photomodification increases fivefold the water permeance to around 2 L m⁻²h⁻¹bar⁻¹, compared to that of the unmodified one. A rejection of 74% is measured for methyl orange in water. The membranes fabrication with tailored nanochannels and chemical functionalities can be demonstrated using relatively lower cost block copolymers. Casting on porous polyacrylonitrile supports makes the membranes even more scalable and competitive in large scale.

    

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2. Influence of carboxylated and phosphonated single‐walled carbon nanotubes on the transport properties of sulfonated poly(styrene‐isobutylene‐styrene) membranes

   https://doi.org/10.1002/pola.29222  

   Ruiz‐Colón, Eduardo ; Pérez‐Pérez, Maritza ; Suleiman, David ( October 2018 , Journal of Polymer Science Part A: Polymer Chemistry)

   This study discusses the effect of carboxylated (COOH) and phosphonated (PO₃H₂) single‐walled carbon nanotubes (SWCNTs) on the transport properties of sulfonated poly(styrene‐isobutylene‐styrene) (SO₃H SIBS) as polymer nanocomposite membranes (PNMs) for direct methanol fuel cell (DMFC) and chemical and biological protective clothing (CBPC) applications. The properties were determined as a function of sulfonation level of SIBS, SWCNTs functionalization and loading. A comprehensive materials characterization study was performed to understand the interactions between the nanofillers and the functionalized polymer matrix, and to determine the effect of their incorporation on the resulting nanostructure of the PNMs. Results indicate that the sulfonation level is the variable that dictates nanofiller dispersion, mechanical properties, water absorption capabilities, morphology, and oxidative stability of SO₃H SIBS. Meanwhile, the nanofiller loading and functionalization influenced the transport properties. The nanofillers reduced methanol permeation. PO₃H₂SWCNTs increased the proton conductivity but at a high sulfonation level (i.e.,90 mol %), the ionic interconnectivity caused a more complex morphology decreasing the transport of protons. Optimal selectivity in transport properties were found with a sulfonation level of 61 mol % and a PO₃H₂SWCNTs loading of 1.0 wt. % for DMFC and 0.5 wt. % for CBPC due to changes in morphology and the unique transport mechanism of permeants through the PNMs. © 2018 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem.2018,56, 2475–2495

    

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3. Transport properties of blended sulfonated poly(styrene‐isobutylene‐styrene) and isopropyl phosphate membranes

   https://doi.org/10.1002/app.47009  

   Ruiz‐Colón, Eduardo ; Pérez‐Pérez, Maritza ; Suleiman, David ( August 2018 , Journal of Applied Polymer Science)

   This work discusses the effect of isopropyl phosphate (IP) on the transport properties of sulfonated poly(styrene‐isobutylene‐styrene) (SO₃H SIBS) as membranes for direct methanol fuel cell (DMFC) and chemical and biological protective clothing (CBPC) applications. The properties were determined as a function of SIBS sulfonation level (i.e., 24, 34, 49, and 84 mol %) and IP loading (i.e., 1, 3, 5, 11, and 15 wt %). A comprehensive material characterization study (e.g.,FTIR, TGA, AFM, and SAXS) was performed to confirm the presence of the phosphate groups in the polymer matrix, assess the thermal stability of the proton‐exchange membranes (PEMs), and understand how the unique interactions between the phosphate and sulfonic groups influenced the nanostructure of SO₃H SIBS. The transport properties, water absorption capabilities (i.e.,swelling ratio, water uptake, etc.), oxidative stability, and ion‐exchange capacity (IEC) were performed to evaluate the impact of IP on the properties of the resulting solvent‐casted membranes. Results suggest that the morphology, thermal stability, and vapor permeability are governed by the sulfonation level, whereas the IEC, oxidative stability, water absorption capabilities, and the rest of the transport properties are dominated by the ionic content (i.e.,sulfonic and phosphate groups) and their synergistic effects. © 2018 Wiley Periodicals, Inc. J. Appl. Polym. Sci.2019,136, 47009.

    

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4. Dielectric behavior of sulfonated poly(styrene–isobutylene–styrene) triblock copolymer thin films

   https://doi.org/10.1002/app.45662  

   Rozo‐Medina, Martha L. ; Padovani, Agnes M. ( August 2017 , Journal of Applied Polymer Science)

   Sulfonated, block copolymers have traditionally been studied for applications in fuel cells and chemical protective clothing, among others. As such, most investigations have focused on the evaluation of transport properties and the selectivity and permeability of the polymer membranes. This work, however, focuses on the electrical characterization of sulfonated poly(styrene–isobutylene–styrene) (SIBS) triblock copolymer thin films. More specifically, the dielectric properties of SIBS are evaluated as a function of critical parameters such as frequency, sulfonation percent, and the polymer concentration. The results show that the dielectric constant increases with sulfonation percent and polymer concentration to values as high as 13,600. This work also provides insights into the correlation of SIBS electrical properties with its chemical structure and morphology. The structure–property relationship is derived through a combination of techniques including: elemental analysis, Fourier transform infrared spectroscopy, thermogravimetric analysis, and atomic force microscopy. © 2017 Wiley Periodicals, Inc. J. Appl. Polym. Sci.2018,135, 45662.

    

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5. Revealing Deformation Mechanisms in Polymer-Grafted Thermoplastic Elastomers via In Situ Small-Angle X-ray Scattering

   https://doi.org/10.1021/acsami.3c09445  

   Torres, Vincent M. ; Furton, Erik ; Sevening, Jensen N. ; Lloyd, Elisabeth C. ; Fukuto, Masafumi ; Li, Ruipeng ; Pagan, Darren C. ; Beese, Allison M. ; Vogt, Bryan D. ; Hickey, Robert J. ( December 2023 , ACS Applied Materials & Interfaces)

   The tunable properties of thermoplastic elastomers (TPEs), through polymer chemistry manipulations, enable these technologically critical materials to be employed in a broad range of applications. The need to “dial-in” the mechanical properties and responses of TPEs generally requires the design and synthesis of new macromolecules. In these designs, TPEs with nonlinear macromolecular architectures outperform the mechanical properties of their linear copolymer counterparts, but the differences in deformation mechanism providing enhanced performance are unknown. Here, in situ small-angle X-ray scattering (SAXS) measurements during uniaxial extension reveal distinct deformation mechanisms between a commercially available linear poly(styrene)-poly(butadiene)-poly(styrene) (SBS) triblock copolymer and the grafted SBS version containing grafted poly(styrene) (PS) chains from the poly(butadiene) (PBD) mid-block. The neat SBS (φSBS = 100%) sample deforms congruently with the macroscopic dimensions with the domain spacing between spheres increasing and decreasing along and traverse to the stretch direction, respectively. At high extensions, end segment pullout from the PS-rich domains is detected, which is indicated by a disordering of SBS. Conversely, the PS-grafted SBS that is 30 vol% SBS and 70% styrene (φSBS = 30%) exhibits a lamellar morphology and in situ SAXS measurements reveal an unexpected deformation mechanism. During deformation there are two simultaneous processes: significant lamellar domain rearrangement to preferentially orient the lamellae planes parallel to the stretch direction and crazing. The samples whiten at high strains as expected for crazing, which corresponds with the emergence of features in the two-dimensional SAXS pattern during stretching consistent with fibril-like structures that bridge the voids in crazes. The significant domain rearrangement in the grafted copolymers is attributed to the new junctions formed across multiple PS domains by the grafts of a single chain. The in situ SAXS measurements provide insights into the enhanced mechanical properties of grafted copolymers that arise through improved physical crosslinking that leads to nanostructured domain reorientation for self-reinforcement and craze formation where fibrils help to strengthen the polymer. 

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