Construction of effective transmission channels by anchoring metal‐organic framework on side‐chain sulfonated poly(arylene ether ketone sulfone) for fuel cells

Ju, Mengchi; Shi, Qingyuan; Xu, Jingmei; Chen, Xuan; Ren, Jiahui; Lei, Jinxuan; Meng, L.; Zhao, Pengyun; Wang, Zhe

doi:10.1002/er.7914

Cited by 14 publications

(9 citation statements)

References 54 publications

(147 reference statements)

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“…18 For instance, Liu et al studied a sulfonated N-heterocyclic containing poly(aryl ether ketone)s with suspended phenyl moities for PEMFCs, which showed a swelling rate of 5.6%, and proton conductivity of 9.8-103 mS cm À1 at 75 C. 19 Ju et al constructed an effective proton transport channel by introducing metal-organic framework on the linked of sulfonated poly(arylene ether ketone sulfone). The MOFpolymer membrane showed a proton conductivities of 0.054-0.069 S cm À1 at 30 C, 0.088-0.116 S cm À1 at 80 C. 20 Traizole pendant sulfonated poly(arylene ether ketone sulfone) was reported to have a proton conductivity of 0.166 S cm À1 at 120 C, which was more significant than that of Nafion 117. 21 Itoh et al synthesized a phosphoric acid doped hyperbranched polymer for PEMFC and obtained a proton conductivity of 1.2 Â 10 À5 and 2.6 Â 10 À6 S cm À1 due to the hyperbranched structure providing better water permeability.…”

Section: Introductionmentioning

confidence: 94%

“…Ju et al constructed an effective proton transport channel by introducing metal–organic framework on the linked of sulfonated poly(arylene ether ketone sulfone). The MOF‐polymer membrane showed a proton conductivities of 0.054–0.069 S cm −1 at 30°C, 0.088–0.116 S cm −1 at 80°C 20 . Traizole pendant sulfonated poly(arylene ether ketone sulfone) was reported to have a proton conductivity of 0.166 S cm −1 at 120°C, which was more significant than that of Nafion 117 21 .…”

Section: Introductionmentioning

confidence: 94%

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TiO₂ nanoparticle enhanced high temperature proton conductivity in hyperbranched sulfonated polyarylene aliphatic ketones for proton exchange membrane fuel cell applications

Theerthagiri

Prabukanthan²,

Deivanayagam

et al. 2023

J of Applied Polymer Sci

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A new hyperbranched sulfonated poly(arylene aliphatic ketones) (HB‐SPAAK) has been synthesized and loaded with titania nanoparticles to obtain HB‐SPAAK/TiO2 nanocomposites for thermally stable proton‐conducting electrolyte membrane fuel cell (PEMFC) applications. The synthesis of HB‐SPAAKs was carried out through the polycondensation reaction of different aliphatic and aromatic acids with simultaneous loss of H2O, trifluromethane sulfonic acid used as catalyst. The long chain hyperbranched polymers and TiO2‐loaded nanocomposites were characterized by FT‐IR, 1H‐NMR, SEM and HR‐TEM. Proton conductivity (PC), swelling ratio, water uptake and oxidative stability. The SEM image of TiO2 NPs and HB‐SPAAKs/TiO2 nanocomposites membrane clearly showed the spherical of TiO2 and porous structure of HB‐SPAAKs with a pore diameter of 2–50 μm. TEM image reveals the uniform particle size distribution of TiO2 nanoparticles having a nanosize of 100 nm. TiO2 loaded polymer nanocomposites showed lower values of W/U and S/R when compared to the unmodified HB‐SPAAK, while 3% TiO2 loaded HB‐SPAAKs exhibited a threefold increment of proton conductivity of 1.439 × 10−2 S cm−1 compared to HB‐SPAAKs (0.41 x 10−2 S cm−1) and lower than that of Nafion 117 (0.1003 S cm−1 at 80°C). The 5% TiO2 NPs‐embedded with HB‐SPAAKs nanocomposites membranes also presented admirable oxidative stability with a degradation value of 13.8% during immersion in Fenton reagent for 8 h at 70°C.

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Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 94%

TiO₂ nanoparticle enhanced high temperature proton conductivity in hyperbranched sulfonated polyarylene aliphatic ketones for proton exchange membrane fuel cell applications

Theerthagiri

Prabukanthan²,

Deivanayagam

et al. 2023

J of Applied Polymer Sci

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“…Numerous polymers have been explored as the AEMs' backbones, including poly(arylene ether ketone) (PEK), 9,10 poly(arylene ether sulfone) (PES), 11,12 poly(phenylene oxide) (PPO), 13,14 polybenzimidazole (PBI), 15,16 poly(crown ether) (PCE) 17,18 and several heteroatom-free polymers like poly(arylene alkylene), [19][20][21] polyfluorenes 22 and polyalkenes. 23 In addition, various functional cationic groups, such as quaternary ammonium, 10,20-22 imidazolium, 9,11 guanidinium, 24 phosphonium, 25 pyrrolidinium, 26 piperidinium 27,28 and some metal-based cations, 29 have been studied and utilized for AEMs. In particular, recent research demonstrated the cationic groups carrying alkyl chains or bulky groups showed better alkaline stability, which could be attributed to the steric hindrance effect.…”

Section: Introductionmentioning

confidence: 99%

Comb‐shaped block poly(arylene ether sulfone ketone)s for anion exchange membranes

Lai,

Li,

Zheng

et al. 2023

J of Applied Polymer Sci

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A well‐designed architecture is presented here to construct high‐performance anion exchange membranes (AEMs). A series of quaternized fluorene‐containing block poly(arylene ether sulfone ketone)s (QFPESK‐m‐n) is synthesized as the main chains, and grafted with comb‐shaped C8 long alkyl chains for the AEMs. By varying the hydrophilic segment’ length, there has been a significant change in the microstructure as well as phase separation morphology of the membranes, as confirmed by atomic force microscopy. Hence the as‐prepared AEMs with moderate ion exchange capacities (IECs) show enhanced hydroxide conductivities in the range of 28.8―94.7 mS⋅cm−1 from 30 to 80°C. Furthermore, based on the block backbones and hydrophobic comb‐shaped alkyl chains, the AEMs show low‐level swelling ratios of 4.3% to 9.2% at 30°C and from 6.2% to 13.2% at 80°C, and superior ratios of conductivity to swelling. In addition, the QFPESK‐m‐n AEMs also depict acceptable mechanical properties, good thermal stability and an optimizable alkaline stability.

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“…The commercial PEMs of Nafion membranes produced by DuPont exhibit good stability and high proton conductivity 8,9 . However, the disadvantages, such as excessively expensive price, high fuel permeability, strong dependence on water, and rapid performance degradation at elevated temperatures, limit the large‐scale use of Nafion membranes 10,11 . Sulfonated aromatic polymers with excellent mechanical properties and chemical stability are considered to be possible to replace Nafion membranes 12,13 .…”

Section: Introductionmentioning

confidence: 99%

“…dependence on water, and rapid performance degradation at elevated temperatures, limit the large-scale use of Nafion membranes. 10,11 Sulfonated aromatic polymers with excellent mechanical properties and chemical stability are considered to be possible to replace Nafion membranes. 12,13 Wang et al prepared sulfonated poly(ether ether ketone) (SPEEK) membranes with different sulfonation degrees, and the proton conductivities of SPEEK membranes with degrees of sulfonation (DS) of 39% and 47% were close to that of Nafion115 membranes.…”

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confidence: 99%

Enhancing proton conductivity of proton exchange membranes via anchoring imidazole‐loaded MIL‐101‐NH ₂ onto sulfonated poly (arylene ether ketone sulfone) by chemical bonding

Meng

Zhang

et al. 2022

Intl J of Energy Research

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Summary Organic‐inorganic modification by incorporating metal‐organic frameworks to copolymers is one strategy to advance the properties of membranes. Here, the imidazole‐loaded MIL‐101‐NH2 (Im@MIL‐101‐NH2) was prepared and chemically anchored onto sulfonated poly (arylene ether ketone sulfone) containing carboxyl groups (C‐SPAEKS). The chemical stabilities, mechanical properties, and dimensional stabilities of compound membranes were increased. The highest tensile strength of C‐SPAEKS‐IM6 reach to 105.36 MPa. The weight retention rate of hybrid membranes was still higher than 90% after the oxidation stability test at 80°C. Furthermore, the introducing Im@MIL‐101‐NH2 could construct new proton transport paths, and the amphiphilic imidazole molecules embedded inside Im@MIL‐101‐NH2 could act as proton carriers. The C‐SPAEKS‐IM6 showed a maximum proton conductivity of 0.082 S cm−1 at 90°C. Additionally, the peak power density of C‐SPAEKS‐IM6 was 171.52 mW cm−2. To sum up, this series of membranes have latent capacity in the application of fuel cells. Im@MIL‐101‐NH2 was anchored on polymer backbones via the Hinsberg reaction. Chemical bonds between MOFs and polymer chains improved compatibility of two phases. Cross‐linking structure enhanced the mechanical property and oxidative stability. The sulfonamide groups could devote protons and transport it to MOFs.

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Construction of effective transmission channels by anchoring metal‐organic framework on side‐chain sulfonated poly(arylene ether ketone sulfone) for fuel cells

Cited by 14 publications

References 54 publications

TiO₂ nanoparticle enhanced high temperature proton conductivity in hyperbranched sulfonated polyarylene aliphatic ketones for proton exchange membrane fuel cell applications

TiO₂ nanoparticle enhanced high temperature proton conductivity in hyperbranched sulfonated polyarylene aliphatic ketones for proton exchange membrane fuel cell applications

Comb‐shaped block poly(arylene ether sulfone ketone)s for anion exchange membranes

Enhancing proton conductivity of proton exchange membranes via anchoring imidazole‐loaded MIL‐101‐NH ₂ onto sulfonated poly (arylene ether ketone sulfone) by chemical bonding

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Construction of effective transmission channels by anchoring metal‐organic framework on side‐chain sulfonated poly(arylene ether ketone sulfone) for fuel cells

Cited by 14 publications

References 54 publications

TiO2 nanoparticle enhanced high temperature proton conductivity in hyperbranched sulfonated polyarylene aliphatic ketones for proton exchange membrane fuel cell applications

TiO2 nanoparticle enhanced high temperature proton conductivity in hyperbranched sulfonated polyarylene aliphatic ketones for proton exchange membrane fuel cell applications

Comb‐shaped block poly(arylene ether sulfone ketone)s for anion exchange membranes

Enhancing proton conductivity of proton exchange membranes via anchoring imidazole‐loaded MIL‐101‐NH 2 onto sulfonated poly (arylene ether ketone sulfone) by chemical bonding

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TiO₂ nanoparticle enhanced high temperature proton conductivity in hyperbranched sulfonated polyarylene aliphatic ketones for proton exchange membrane fuel cell applications

TiO₂ nanoparticle enhanced high temperature proton conductivity in hyperbranched sulfonated polyarylene aliphatic ketones for proton exchange membrane fuel cell applications

Enhancing proton conductivity of proton exchange membranes via anchoring imidazole‐loaded MIL‐101‐NH ₂ onto sulfonated poly (arylene ether ketone sulfone) by chemical bonding