Surface Modification of Matrimid® 5218 Polyimide Membrane with Fluorine-Containing Diamines for Efficient Gas Separation

Lee, Tae Hoon; Lee, Byung Kwan; Park, Jin-Sung; Park, Jinmo; Kang, Jun Hyeok; Yoo, Seung Yeon; Kim, Yo-Han; Park, Ho Bum

doi:10.3390/membranes12030256

Cited by 17 publications

(2 citation statements)

References 58 publications

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“…The thermal decomposition had two steps in the Matrimid ® film, whereas it became multistep in the nanocomposite films ( Figure 4 , Figure 5 and Figure 6 ). The high thermal stability of Matrimid ® is indicated by a T onset at 503 °C, a main degradation peak ( T d1) at 530 °C and a second decomposition one ( T d2) at around 609 °C, which is related to the thermal decomposition of the imide group and carbonization [ 28 ]. Nevertheless, at 800 °C, a residue of 56% was registered, indicating that higher temperatures are required for a complete degradation of the polyimide.…”

Section: Resultsmentioning

confidence: 99%

Molecularly Mixed Composite Membranes for Gas Separation Based on Macrocycles Embedded in a Polyimide

Vuono,

Clarizia,

Ferreri

et al. 2024

Polymers

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Polyimides are a polymer class that has been extensively investigated as a membrane material for gas separation owing to its interesting permselective properties in a wide range of operation temperatures and pressures. In order to improve their properties, the addition of different filler types is currently studied. p-tert-Butylcalix[n]arene macrocycles (PTBCs) with different cavity sizes (PTBC4, PTBC6, PTBC8) were used as fillers in a commercial thermoplastic polyimide, with a concentration in the range 1–9 wt%, to develop nanocomposite membranes for gas separation. The selected macrocycles are attractive organic compounds owing to their porous structure and affinity with organic polymers. The nanocomposite membranes were prepared in the form of films in which the polymeric matrix is a continuous phase incorporating the dispersed additives. The preparation was carried out according to a pre-mixing approach in a mutual solvent, and the solution casting was followed by a controlled solvent evaporation. The films were characterized by investigating their miscibility, morphology, thermal and spectral properties. The gas transport through these films was examined as a function of the temperature and also time. The results evidenced that the incorporation of the chosen nanoporous fillers can be exploited to enhance molecular transport, offering additional pathways and promoting rearrangements of the polymeric chains.

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Section: Resultsmentioning

confidence: 99%

Molecularly Mixed Composite Membranes for Gas Separation Based on Macrocycles Embedded in a Polyimide

Vuono,

Clarizia,

Ferreri

et al. 2024

Polymers

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“…Sobresalen las polimidas por sus elevadas propiedades térmicas, mecánicas y la facilidad para mezclarse con otros polímeros (Han & Ho, 2021;Indira & Abhitha, 2021). Al respecto, Lee et al, (2022) realizaron modificaciones en la polimida comercial Matrimida® mezclándola con otros polímeros, lo que mejoró considerablemente la selectividad de las MCMM. Rungta et al (2017) estudiaron las diferencias entre un polímero comercial Matrimid® y 6FDA:BDPA para su aplicación en membranas CMM.…”

Section: Introductionunclassified

Modificación estructural de polímeros bifenilen-isatina y su aplicación en membranas CMM: Efecto en las propiedades de transporte

Ortiz-Espinoza,

Aguilar-Vega

2023

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Las membranas de Carbón de Malla Molecular (MCMM) presentan excelentes propiedades químicas y térmicas, superan fácilmente la típica compensación entre permeabilidad y selectividad en procesos de separación de gases. Sin embargo, el rendimiento y los mecanismos de transporte involucrados en la separación no están muy claros. Los principales polímeros precursores para la síntesis de MCMM están limitados a resinas fenólicas, poliimidas y estructuras altamente aromáticas. Lo anterior, abre la oportunidad para explorar nuevos materiales poliméricos como precursores. Por ejemplo, las diferentes variantes de los poli(oxindoliliden arileno)s, POXINARs. Esta investigación se enfoca en evaluar el rendimiento de separación de las MCMM modificadas estructuralmente con grupos para-fluorofenilo. Se sintetizaron MCMM a partir de los precursores poli(2-oxo-3-bifenilen)indol [POBI-H], y poli(2-oxo-3-bifenilen-1-(4-fluoro)fenilindol [POBI-FPh]. La caracterización se realizó mediante microscopia de infrarrojo y análisis termogravimétrico y, finalmente, se evaluaron las propiedades de transporte de gases puros a temperaturas de 30, 40 y 45 °C y una diferencia de presión de 2 atm.

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Fabrication of new proton conducting membrane for fuel cell applications based on porous polyimide Matrimid® and hydrophobic protic ionic liquid

Rogalsky

Tarasyuk

Babkina

et al. 2023

J of Applied Polymer Sci

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A new proton conducting membrane has been developed by impregnation of porous polyimide Matrimid® (PI) with hydrophobic protic ionic liquid triethylammonium bis(trifluoromethylsulfonyl)imide (TEA‐TFSI). According to the results of dynamic mechanical analysis (DMA), PI/TEA‐TFSI membrane has satisfactory viscoelastic properties in the temperature range 25–100°C. However, the sharp drop in storage modulus (E') occurs at higher temperatures that is probably caused by the plasticizing effect of ionic liquid. To improve the mechanical properties of PI matrix, it was impregnated with the solution of polyetheramine Jeffamine® D‐400 in the TEA‐TFSI. This approach allowed to obtain a partially cross‐linked PI which is more resistant to deformation at elevated temperatures. Thus, DMA study revealed a storage modulus around 400 MPa for PI/Jeffamine/TEA‐TFSI membrane up to 150°C, like neat porous Matrimid®. Thermogravimetric analysis results indicate high thermal stability of PI/Jeffamine/TEA‐TFSI composite with thermal degradation point of 343°C. The ionic conductivity of the composite membrane is 4·10−3 S/cm at room temperature and reaches the level of 10−2 S/cm above 100°C. Overall, the results of this study indicate that partially cross‐linked porous PI impregnated with hydrophobic protic ionic liquid is a promising polymer electrolyte membrane for fuel cells operating at elevated temperatures in water‐free conditions.

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Surface Modification of Matrimid® 5218 Polyimide Membrane with Fluorine-Containing Diamines for Efficient Gas Separation

Cited by 17 publications

References 58 publications

Molecularly Mixed Composite Membranes for Gas Separation Based on Macrocycles Embedded in a Polyimide

Molecularly Mixed Composite Membranes for Gas Separation Based on Macrocycles Embedded in a Polyimide

Modificación estructural de polímeros bifenilen-isatina y su aplicación en membranas CMM: Efecto en las propiedades de transporte

Fabrication of new proton conducting membrane for fuel cell applications based on porous polyimide Matrimid® and hydrophobic protic ionic liquid

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