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Polymers
Feb 08, 2023;15 (4):

Application of Molecular Imprinting for Creation of Highly Selective Sorbents for Extraction and Separation of Rare-Earth Elements.

Ruslan Kondaurov, Yevgeniy Melnikov, Laura Agibayeva
Author Information
  1. Ruslan Kondaurov: Department of Biochemical Engineering, International Engineering and Technological University, Al-Farabi ave. 93a, Almaty 050060, Kazakhstan. ORCID
  2. Yevgeniy Melnikov: Department of Biochemical Engineering, International Engineering and Technological University, Al-Farabi ave. 93a, Almaty 050060, Kazakhstan.
  3. Laura Agibayeva: Faculty of Chemistry and Chemical Technology, Al-Farabi Kazakh National University, Al-Farabi ave. 71, Almaty 050040, Kazakhstan.
PMID: 36850129 DOI: 10.3390/polym15040846

Abstract

The aim of the work is to study the effectiveness of a molecular imprinting technique application for the creation of highly selective macromolecular sorbents for selective sorption of light and heavy rare-earth metals (for example, samarium and gadolinium, respectively) with subsequent separation from each other. These sorbents seem to be promising due to the fact that only the target rare-earth metal will be sorbed owing to the fact that complementary cavities are formed during the synthesis of molecularly imprinted polymers. In other words, the advantage of the proposed macromolecules is the absence of accompanying sorption of metals with close chemical properties. Two types of molecularly imprinted polymers (MIP) were synthetized based on methacrylic acid (MAA) and 4-vinylpyridine (4VP) functional monomers. The sorption properties (extraction degree, exchange capacity) of the MIPs were studied. The impact of template removal cycle count (from 20 to 35) on the sorption effectivity was studied. Laboratory experiments on selective sorption and separation of samarium and gadolinium from a model solution were carried out.

Keywords

functional macromolecular structures light and heavy rare-earth metals molecular imprinting technique molecularly imprinted polymers selective sorption separation of rare-earth metals

References

  1. Sensors (Basel). 2017 Apr 19;17(4): [PMID: 28422082]
  2. Adv Drug Deliv Rev. 2002 Jan 17;54(1):149-61 [PMID: 11755710]
  3. Macromol Rapid Commun. 2019 Sep;40(17):e1900096 [PMID: 31111979]
  4. RSC Adv. 2020 Apr 6;10(23):13783-13798 [PMID: 35493016]
  5. PLoS One. 2021 Apr 22;16(4):e0250407 [PMID: 33886661]
  6. Comput Intell Neurosci. 2022 Jul 4;2022:9900219 [PMID: 35832250]
  7. Sensors (Basel). 2017 Feb 04;17(2): [PMID: 28165419]
  8. Anal Chim Acta. 2007 May 15;591(1):17-21 [PMID: 17456419]
  9. Int J Pharm. 2000 Feb 15;195(1-2):39-43 [PMID: 10675681]
  10. Polymers (Basel). 2022 Mar 04;14(5): [PMID: 35267850]
  11. Polymers (Basel). 2022 Feb 08;14(3): [PMID: 35160628]
  12. J Chromatogr B Analyt Technol Biomed Life Sci. 2004 May 5;804(1):173-82 [PMID: 15093171]
  13. Top Curr Chem. 2012;325:1-28 [PMID: 22183146]

Grants

  1. AP13067631/Ministry of science and higher education of the Republic of Kazakhstan
Journal Article

Word Cloud

Created with Highcharts 10.0.0sorptionselectiverare-earthmetalsseparationmolecularlyimprintedpolymersmolecularimprintingtechniquemacromolecularsorbentslightheavysamariumgadoliniumfactpropertiesfunctionalstudiedaimworkstudyeffectivenessapplicationcreationhighlyexamplerespectivelysubsequentseempromisingduetargetmetalwillsorbedowingcomplementarycavitiesformedsynthesiswordsadvantageproposedmacromoleculesabsenceaccompanyingclosechemicalTwotypesMIPsynthetizedbasedmethacrylicacidMAA4-vinylpyridine4VPmonomersextractiondegreeexchangecapacityMIPsimpacttemplateremovalcyclecount2035effectivityLaboratoryexperimentsmodelsolutioncarriedoutApplicationMolecularImprintingCreationHighlySelectiveSorbentsExtractionSeparationRare-EarthElementsstructures

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