SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4292103452> ?p ?o ?g. }

Showing items 1 to 100 of ±159 with 100 items per page.

W4292103452 endingPage "126580" @default.
W4292103452 startingPage "126580" @default.
W4292103452 abstract "The environmental pollution by chemical pollutants has expanded. Today, the use of biopolymer composites as adsorbent has attracted a lot of attention due to biopolymers presence in plant tissue also their hybridization with magnetic nanoparticles will increase the removal of contaminants from aqueous solutions. Inulin biopolymer from Jerusalem artichoke plant by using ultrasonic wave simply in presence of Eco-Friendly precursors was extracted and the inulin-Fe3O4 nanocomposite for the first time was synthesized then DLS analysis the pH which maximum adsorption occurs, XRD and FTIR obvious peaks, TGA stability of nanocomposites at high temperatures, EDX elements FESEM and TEM morphology identified VSM showed magnetic saturation of 46.1 emu g−1 which can be separate easily from environment BET the specific surface area of nanocomposite was calculated 25.6 m2/g synthesis of inulin-Fe3O4 nanocomposite is very cost-effective and impressive. The effect of parameters, including dosage of adsorbent and pH on the adsorption capacity, studied which 136.4 mg/g at pH of 7 for methylene blue and 152.5, 167.7, 198 mg/g for Co2+, Cu2+, and Hg2+ respectively on 0.01g adsorbent for pH 5.5 obtained. Competitive adsorption of metal ions was also studied, which 93.1% of Hg2+ can adsorb which is more than the other two ions which indicates its effect on these ions. The Langmuir isotherm and pseudo-second-order kinetic provided a better description of the behavior of this system, the adsorption process is endothermic for methylene blue and exothermic for metals also, the reusability of this nanocomposite for repeated cycles, can be seen." @default.
W4292103452 created "2022-08-17" @default.
W4292103452 creator A5013674849 @default.
W4292103452 creator A5018105299 @default.
W4292103452 creator A5056016772 @default.
W4292103452 creator A5058719195 @default.
W4292103452 date "2022-11-01" @default.
W4292103452 modified "2023-10-18" @default.
W4292103452 title "Preparation of magnetic inulin nanocomposite and its application in the removal of methylene blue and heavy metals from aqueous solution" @default.
W4292103452 cites W1568914582 @default.
W4292103452 cites W1965842963 @default.
W4292103452 cites W1977188915 @default.
W4292103452 cites W1979583864 @default.
W4292103452 cites W1981972278 @default.
W4292103452 cites W1983830768 @default.
W4292103452 cites W1990705176 @default.
W4292103452 cites W1992262649 @default.
W4292103452 cites W1992791901 @default.
W4292103452 cites W1995718743 @default.
W4292103452 cites W1996193209 @default.
W4292103452 cites W2000141214 @default.
W4292103452 cites W2002617779 @default.
W4292103452 cites W2007032996 @default.
W4292103452 cites W2009789896 @default.
W4292103452 cites W2012843745 @default.
W4292103452 cites W2016334396 @default.
W4292103452 cites W2017993997 @default.
W4292103452 cites W2018370207 @default.
W4292103452 cites W2019603031 @default.
W4292103452 cites W2021873455 @default.
W4292103452 cites W2022384190 @default.
W4292103452 cites W2026816247 @default.
W4292103452 cites W2028150718 @default.
W4292103452 cites W2028499970 @default.
W4292103452 cites W2028610148 @default.
W4292103452 cites W2029299505 @default.
W4292103452 cites W2030095799 @default.
W4292103452 cites W2037199500 @default.
W4292103452 cites W2038505512 @default.
W4292103452 cites W2040750114 @default.
W4292103452 cites W2042710291 @default.
W4292103452 cites W2051945196 @default.
W4292103452 cites W2053797687 @default.
W4292103452 cites W2062993033 @default.
W4292103452 cites W2065326526 @default.
W4292103452 cites W2066413302 @default.
W4292103452 cites W2071271391 @default.
W4292103452 cites W2079033040 @default.
W4292103452 cites W2083605379 @default.
W4292103452 cites W2086221794 @default.
W4292103452 cites W2086883304 @default.
W4292103452 cites W2090573656 @default.
W4292103452 cites W2094186398 @default.
W4292103452 cites W2095844870 @default.
W4292103452 cites W2106984250 @default.
W4292103452 cites W2107725151 @default.
W4292103452 cites W2134529045 @default.
W4292103452 cites W2142066322 @default.
W4292103452 cites W2293570006 @default.
W4292103452 cites W2311502662 @default.
W4292103452 cites W2514532124 @default.
W4292103452 cites W2524085447 @default.
W4292103452 cites W2620819580 @default.
W4292103452 cites W2761205616 @default.
W4292103452 cites W2770047020 @default.
W4292103452 cites W2791240048 @default.
W4292103452 cites W2795901427 @default.
W4292103452 cites W2809441373 @default.
W4292103452 cites W2902225809 @default.
W4292103452 cites W2925190098 @default.
W4292103452 cites W2939073419 @default.
W4292103452 cites W2980212693 @default.
W4292103452 cites W2983097750 @default.
W4292103452 cites W3033466864 @default.
W4292103452 cites W3048590097 @default.
W4292103452 cites W3096158893 @default.
W4292103452 cites W3101948395 @default.
W4292103452 cites W4239033501 @default.
W4292103452 cites W865735089 @default.
W4292103452 doi "https://doi.org/10.1016/j.matchemphys.2022.126580" @default.
W4292103452 hasPublicationYear "2022" @default.
W4292103452 type Work @default.
W4292103452 citedByCount "3" @default.
W4292103452 countsByYear W42921034522023 @default.
W4292103452 crossrefType "journal-article" @default.
W4292103452 hasAuthorship W4292103452A5013674849 @default.
W4292103452 hasAuthorship W4292103452A5018105299 @default.
W4292103452 hasAuthorship W4292103452A5056016772 @default.
W4292103452 hasAuthorship W4292103452A5058719195 @default.
W4292103452 hasConcept C12143843 @default.
W4292103452 hasConcept C127413603 @default.
W4292103452 hasConcept C13965031 @default.
W4292103452 hasConcept C150394285 @default.
W4292103452 hasConcept C155672457 @default.
W4292103452 hasConcept C160892712 @default.
W4292103452 hasConcept C161790260 @default.
W4292103452 hasConcept C171250308 @default.
W4292103452 hasConcept C178790620 @default.