SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4386290421> ?p ?o ?g. }

Showing items 1 to 100 of ±149 with 100 items per page.

W4386290421 abstract "Abstract Gasoline vapour emission is hazardous to both human health and the ecosystem and also results in capital loss, altogether revealing the necessity of its recovery. Some ZIF‐8–Pebax flat nanocomposite membranes were fabricated by the method of solution casting and used for gasoline vapour recovery as represented by n ‐hexane vapour/nitrogen separation. Microporous ZIF‐8 nanoparticles were synthesized and characterized by Fourier transform infrared (FTIR) and Brunauer–Emmett–Teller (BET) analysis. BET results revealed specific surface area, total volume, and average pore diameter of 940.8 m 2 · g −1 , 0.36 cm 3 · g −1 , and 1.54 nm, respectively. Pure nitrogen and n ‐hexane vapour/nitrogen gas mixture permeabilities were measured through the membranes. There was a decline in both permeation rate and selectivity up to 5.0 wt.% of ZIF‐8 loading and the next increment at their higher loadings to considerably more values that the pristine membrane. The maximum n ‐hexane vapour permeability and selectivity at 10.0 wt.% loading of ZIF‐8 nanoparticles, the feed flow rate of 173 mL · min −1 , and permeate side pressure of −200 mbar were observed as 280.1 Barrer and 106.7, respectively, revealing 60.0% and 36.9% improvements compared with those of the pristine Pebax membrane. Observed 86%–92% n ‐hexane vapour recovery approves the successful application of the ZIF‐8–Pebax nanocomposite membranes for n ‐hexane/nitrogen separation. The long‐term separation performance of 5.0 wt.% ZIF‐8 loaded nanocomposite membrane was improved by 76.5% compared with that of the pristine Pebax membrane." @default.
W4386290421 created "2023-08-31" @default.
W4386290421 creator A5063909419 @default.
W4386290421 creator A5092718220 @default.
W4386290421 date "2023-08-30" @default.
W4386290421 modified "2023-09-27" @default.
W4386290421 title "Preparation of <scp>ZIF</scp>‐8—Pebax 1657 nanocomposite membranes for <i>n</i>‐hexane/nitrogen separation as a representative of gasoline vapour recovery" @default.
W4386290421 cites W1969726698 @default.
W4386290421 cites W1970252296 @default.
W4386290421 cites W1971320238 @default.
W4386290421 cites W1978180304 @default.
W4386290421 cites W1983228638 @default.
W4386290421 cites W1989893374 @default.
W4386290421 cites W1990985622 @default.
W4386290421 cites W2005147646 @default.
W4386290421 cites W2009887774 @default.
W4386290421 cites W2011366910 @default.
W4386290421 cites W2016456209 @default.
W4386290421 cites W2017677627 @default.
W4386290421 cites W2018274772 @default.
W4386290421 cites W2025127307 @default.
W4386290421 cites W2041555678 @default.
W4386290421 cites W2047843246 @default.
W4386290421 cites W2053587888 @default.
W4386290421 cites W2061016515 @default.
W4386290421 cites W2068484826 @default.
W4386290421 cites W2068538071 @default.
W4386290421 cites W2075717509 @default.
W4386290421 cites W2076714182 @default.
W4386290421 cites W2082098449 @default.
W4386290421 cites W2084712194 @default.
W4386290421 cites W2086284626 @default.
W4386290421 cites W2100643813 @default.
W4386290421 cites W2114117293 @default.
W4386290421 cites W2120332187 @default.
W4386290421 cites W2121750568 @default.
W4386290421 cites W2122840059 @default.
W4386290421 cites W2127822838 @default.
W4386290421 cites W2141668000 @default.
W4386290421 cites W2150349451 @default.
W4386290421 cites W2274698111 @default.
W4386290421 cites W2276443194 @default.
W4386290421 cites W2283580751 @default.
W4386290421 cites W2309082800 @default.
W4386290421 cites W2316187436 @default.
W4386290421 cites W2320043925 @default.
W4386290421 cites W2325528214 @default.
W4386290421 cites W2342003110 @default.
W4386290421 cites W2532653172 @default.
W4386290421 cites W2556003345 @default.
W4386290421 cites W2573392584 @default.
W4386290421 cites W2604173572 @default.
W4386290421 cites W2604446067 @default.
W4386290421 cites W2626821740 @default.
W4386290421 cites W2658837914 @default.
W4386290421 cites W2754786437 @default.
W4386290421 cites W2762210305 @default.
W4386290421 cites W2764116673 @default.
W4386290421 cites W2768336046 @default.
W4386290421 cites W2791716863 @default.
W4386290421 cites W2810254782 @default.
W4386290421 cites W2887511526 @default.
W4386290421 cites W2888471268 @default.
W4386290421 cites W2902325629 @default.
W4386290421 cites W2943409900 @default.
W4386290421 cites W2949762523 @default.
W4386290421 cites W2969904616 @default.
W4386290421 cites W2977922058 @default.
W4386290421 cites W2995665571 @default.
W4386290421 cites W2999733159 @default.
W4386290421 cites W3003005337 @default.
W4386290421 cites W3043294396 @default.
W4386290421 cites W3107522893 @default.
W4386290421 cites W3108953369 @default.
W4386290421 cites W3124297814 @default.
W4386290421 cites W3133991041 @default.
W4386290421 cites W3153023467 @default.
W4386290421 cites W3156090979 @default.
W4386290421 cites W3165730388 @default.
W4386290421 cites W3179413602 @default.
W4386290421 cites W4200513461 @default.
W4386290421 cites W4207029542 @default.
W4386290421 cites W4220654380 @default.
W4386290421 cites W4294676017 @default.
W4386290421 cites W775458866 @default.
W4386290421 cites W88429384 @default.
W4386290421 doi "https://doi.org/10.1002/cjce.25074" @default.
W4386290421 hasPublicationYear "2023" @default.
W4386290421 type Work @default.
W4386290421 citedByCount "0" @default.
W4386290421 crossrefType "journal-article" @default.
W4386290421 hasAuthorship W4386290421A5063909419 @default.
W4386290421 hasAuthorship W4386290421A5092718220 @default.
W4386290421 hasConcept C113196181 @default.
W4386290421 hasConcept C118792377 @default.
W4386290421 hasConcept C127413603 @default.
W4386290421 hasConcept C13253532 @default.
W4386290421 hasConcept C150394285 @default.
W4386290421 hasConcept C159985019 @default.
W4386290421 hasConcept C160892712 @default.