On the structure, morphology and transport through limitedly flexible chain sulfonated co-polyimide

Sapegin, Denis Andzheevich; Gubanova, G. N.; Kruchinina, E. V.; Volkov, A. Ya.; Попова, Е. Н.; Вылегжанина, М. Э.; Setničková, Kateřina; Кононова, С. В.

doi:10.1016/j.polymer.2020.123142

Cited by 7 publications

(23 citation statements)

References 37 publications

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“…The maximum rate of release of absorbed water is recorded at 101.4°C, and the thermal decomposition of sulfonic groups at 361.9°C, which coincides with the data presented in the literature. 32 That is, regardless of the chemical structure of the copolymers and the number of sulfonic groups, their decomposition (according to the maximum rate of this process) practically coincides. The maximum thermal decomposition rate of the main chain of the copolymer BDSA-SPI-2 (NEt 3 ) -1 is recorded at a high temperature of 590.3°C.…”

Section: Resultsmentioning

confidence: 97%

“…To study the possible conformational features of the macromolecular chain formed by DBTA and BDSA using the GAMESS software package, we optimized the structures of model dimers consisting of two BDSA units linked by DBTA. 32 Three different conformation of the dimer were studied: cis-1, cis-2 or trans with cis-1 and trans favouring a more linear chain conformation. The structures of the dimers were optimized with a 200 step run using N31 basis.…”

Section: Resultsmentioning

confidence: 99%

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New polyimide ionomers derived from 4,4^′-diamino-[1,1^′-biphenyl]-2,2^′-disulfonic acid for fuel cell applications

Кононова

Sapegin

Gubanova

et al. 2022

High Performance Polymers

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The set of important properties of polymers necessary for their use as fuel cell membranes, such as film-forming properties, stability in acidic aqueous media, thermal stability, proton conductivity, is determined by their chemical structure, which provides not only basic and fragmentary mobility of the polymer chain but also complex supramolecular structural features (in particular, phase separation). The effect of the chemical structure of aromatic polyimide sulfonic acids, containing a fragment of 4,4′-diamino[1,1′-biphenyl]-2,2′-disulfonic acid (BDSA), on their membrane-forming properties is discussed, as well as the membrane stability under the conditions of a hydrogen-air fuel cell. The research is aimed at investigating sulfonated polyimides based on the commercially available rigid monomer - BDSA and flexible dianhydrides with an electron donor in their structure. As a model for this study, two aromatic anhydrides with flexible -O- bonds were chosen for investigating the potential of corresponding polyimide films in application to proton exchange membranes. The synthesized sulfonic acid polyimide BDSA-SPI-4(H) is of interest as a proton-conducting membrane polymer for direct energy conversion electrochemical devices and has shown to be a promising material for this group of devices. It is suggested that the presence of the flexible electron donor bonds in the structure of dianhydride should increase the stability of the membranes prepared from BDSA. The properties of polyimide sulfonic acids from the aforementioned diamine and dianhydrides of different fragmentary flexibility implemented in this work could help the understanding of the connection between chemical structure and properties of the material in application to proton exchange membranes development.

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Section: Resultsmentioning

confidence: 97%

Section: Resultsmentioning

confidence: 99%

New polyimide ionomers derived from 4,4^′-diamino-[1,1^′-biphenyl]-2,2^′-disulfonic acid for fuel cell applications

Кононова

Sapegin

Gubanova

et al. 2022

High Performance Polymers

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“…It was previously reported that films from similar blockcopolyimide of BDSA, ODA, and DBTA (SPI-2) (Figure 7) showed lamellar-like microphase separated morphology. 5 Based on the previous data on the SPI-2-block-copolyimide having a similar structure, it was suggested that SPI-311 would demonstrate a similar tendency to form micro-phase separated morphologies as ODA and BAPB have similar reactivity. However, while leading to the blocks of close polycondensation degree, ODA and BAPB differ significantly in terms of the length of the introduced unit of the block and structural features of the DBTA chain they form.…”

Section: Morphological Features Of the Protonated Polyimidementioning

confidence: 99%

Introduction of a crystalline block as a strategy to increase swelling resistance and dimensional stability of sulfonated copolyimide

Sapegin

Gubanova

Vlasova

et al. 2022

J of Applied Polymer Sci

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The introduction of blocks inclined to form areas of high crystallinity into the sulfonated block co-polyimide is investigated as a prospective strategy to increase swelling resistance and dimensional stability of the polymer in application to the proton exchange membranes development. The novel copolymer with the highly crystalline block was obtained and characterized by the means of static and dynamic light scattering, IR spectroscopy, thermal gravimetric analysis and differential scanning calorimetry. The structural and morphological features of the obtained copolymer were investigated with X-ray diffraction analysis and atomic force microscopy. Transport properties of the co-polyimide are evaluated in terms of pervaporation, proton conductivity measurements and dielectric spectroscopy experiments. The article aims at the evaluation of the influence of the high-crystalline block introduction on morphological, transport and physical properties of the sulfonated copolymer. The properties of the obtained crystalline sulfonated copolymer are compared to the ones of the similar amorphous polyimide. The studied crystalline copolymer showed constancy of the proton conductivity values in the broad range of temperatures (20-120 C, RMSD of 0.23%) and relative humidity values.

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“…Although at first glance these areas are not related, they all use the possibilities inherent in chemical structure of amphiphilic polymers. The most evident potential of such polymers is the possibility of formation of films with heterogeneous morphologies, which demonstrate microphase separation 1,5,6 . Due to considerable difference in affinities of various domains in these films to certain solvents, it is possible to use them in preparation of efficient membranes for selective transport of substances in liquid media.…”

Section: Introductionmentioning

confidence: 99%

“…The important features include ability of a polymer for intramolecular and intermolecular interactions (due to the presence of electron donor and electron acceptor atoms) and free volume of a polymer. The prominent examples of polymers capable of microphase separation are sulfated fluoroolefins 7–11 or polysaccharides, 12 sulfated polyimides intended for various purposes 6 . Another promising approach is the introduction of hydrophilic fragments with active hydroxyl groups into aromatic polyimides containing extended rigid hydrophobic domains, as well as heat treatment of hydroxyl‐containing polyimide materials at high temperatures, which leads to unique structural and chemical changes in the polymer backbone and side groups.…”

Section: Introductionmentioning

confidence: 99%

Novel hydroxyl‐containing and thermo‐dehydrocyclizable polycondensation polymers for multifunctional materials: Synthesis, properties, application

Lebedeva

Кононова

Kruchinina

et al. 2021

J of Applied Polymer Sci

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Novel poly(amide‐imide)s and poly(amide‐o‐hydroxy‐imide)s were synthesized in the process of low‐temperature polycondensation of diacid chloride of 2‐(4‐carboxyphenyl)‐1,3‐dioxoisoindoline‐5‐carboxylic acid with a single diamine of 5,5′‐methylenebis(2‐aminophenol (DADHyDPhM) or of 4,4′‐methylenebis(benzeneamine) (DADPhМ), and also with a mixture of named diamines (molar ratios of DADHyDPhM to DADPhМ being equal to 7:3, 1:1, and 3:7). The influence of hydroxy‐imide modifying units (fragments) introduced into the basic poly(amide‐imide) on its thermal stability (the processes of polymers destruction proceed intensively in the temperature range from 400 to 600°C and has a complex character); parameters of pervaporation through heat‐resistant films prepared from polymer solutions were analyzed. Polymer films are rigid materials (modulus of elasticity–3 to 4 GPa) with a strength above 100 MPa. Heating up to 300°C leads for all three compositions to a noticeable increase in the elastic modulus and to a pronounced tendency to increase the strength characteristics.

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On the structure, morphology and transport through limitedly flexible chain sulfonated co-polyimide

Cited by 7 publications

References 37 publications

New polyimide ionomers derived from 4,4^′-diamino-[1,1^′-biphenyl]-2,2^′-disulfonic acid for fuel cell applications

New polyimide ionomers derived from 4,4^′-diamino-[1,1^′-biphenyl]-2,2^′-disulfonic acid for fuel cell applications

Introduction of a crystalline block as a strategy to increase swelling resistance and dimensional stability of sulfonated copolyimide

Novel hydroxyl‐containing and thermo‐dehydrocyclizable polycondensation polymers for multifunctional materials: Synthesis, properties, application

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On the structure, morphology and transport through limitedly flexible chain sulfonated co-polyimide

Cited by 7 publications

References 37 publications

New polyimide ionomers derived from 4,4′-diamino-[1,1′-biphenyl]-2,2′-disulfonic acid for fuel cell applications

New polyimide ionomers derived from 4,4′-diamino-[1,1′-biphenyl]-2,2′-disulfonic acid for fuel cell applications

Introduction of a crystalline block as a strategy to increase swelling resistance and dimensional stability of sulfonated copolyimide

Novel hydroxyl‐containing and thermo‐dehydrocyclizable polycondensation polymers for multifunctional materials: Synthesis, properties, application

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Product

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New polyimide ionomers derived from 4,4^′-diamino-[1,1^′-biphenyl]-2,2^′-disulfonic acid for fuel cell applications

New polyimide ionomers derived from 4,4^′-diamino-[1,1^′-biphenyl]-2,2^′-disulfonic acid for fuel cell applications