Top

Published in:

2022 | OriginalPaper | Chapter

Application of Core–Shell Nanohybrid Structures in Water Treatment

Authors : Hirakendu Basu, Shweta Singh, Suresh Kumar Kailasa, Rakesh Kumar Singhal

Published in: Nanohybrid Materials for Water Purification

Publisher: Springer Nature Singapore

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Core–shell nanoparticles have been the centre of attention of the researchers in various fields as the transition from bulk/micro particles to nanoparticles to core shell nanoparticles was seen to lead to enormous changes in the physical and chemical properties of the materials like increased surface to volume ratio, dominance of surface atoms over those in the core etc. Core–shell nanohybrid structures are nanocomposites which incorporates the advantages of both core–shell nanoparticles and other component of the hybrid material like polymer, ceramic, oxide structures. In recent times core–shell nanohybrid structures have gained wide attention in different energy and environment applications including sorption of pollutants from aquatic medium. Drinking water pollution is one of the major problems the world is facing today. Various technologies have been developed for removal of various contaminants from aquatic streams. Core–shell hybrid nanostructures can be tailored by chemical modification or by incorporation in the polymeric matrix. This not only makes them specific to some metal ions, radionuclides even nanoparticles but also enhances their sorption capacity. These materials can be synthesised by dispersion of building blocks in polymeric network, in situ polymerisation, sol–gel process, self-assembly of unit building blocks through layered structures or interpenetrating networks. In this book chapter, a series of core shell nanohybrid structures having application in water decontamination have been reviewed and discussedextensively. Synthesis strategies, sorptive properties of these core shell nanohybrid structures are summarised with emphasis on decontamination of conventional pollutants, radionuclides, dyes and organic pollutants.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

previous chapter Metal Oxide Nanoparticles for Water Decontamination

next chapter Future Challenges and Perspectives in Water Purification by Hybrid Materials

Roduner E (2006) Size matters: why nanomaterials are different. Chem Soc Rev 35(7):583–592CrossRef

Banerjee S, Dionysiou DD, Pillai SC (2015) Self-cleaning applications of TiO2 by photo-induced hydrophilicity and photocatalysis. Appl Catal B 176:396–428CrossRef

Kim J, Lee HC, Kim KH, Hwang MS, Park JS, Lee JM ... Park HG (2017) Photon-triggered nanowire transistors. Nat Nanotechnol 12(10):963–968

Liu Z, Lin CH, Hyun BR, Sher CW, Lv Z, Luo B ... He JH (2020) Micro-light-emitting diodes with quantum dots in display technology. Light: Sci Appl 9(1):1–23

Jassby D, Cath TY, Buisson H (2018) The role of nanotechnology in industrial water treatment. Nat Nanotechnol 13(8):670–672CrossRef

Gawande MB, Goswami A, Asefa T, Guo H, Biradar AV, Peng DL ... Varma RS (2015) Core–shell nanoparticles: synthesis and applications in catalysis and electrocatalysis. Chem Soc Rev 44(21):7540–7590

Ghosh Chaudhuri R, Paria S (2012) Core/shell nanoparticles: classes, properties, synthesis mechanisms, characterization, and applications. Chem Rev 112(4):2373–2433CrossRef

Kwizera EA, Chaffin E, Shen X, Chen J, Zou Q, Wu Z ... Huang X (2016) Size-and shape-controlled synthesis and properties of magnetic–plasmonic core–shell nanoparticles. J Phys Chem C 120(19):10530–10546

Radi A, Pradhan D, Sohn Y, Leung KT (2010) Nanoscale shape and size control of cubic, cuboctahedral, and octahedral Cu− Cu2O core− shell nanoparticles on Si (100) by one-step, templateless, capping-agent-free electrodeposition. ACS Nano 4(3):1553–1560CrossRef

10.

Guo P, Sikdar D, Huang X, Si KJ, Xiong W, Gong S, ... Cheng W (2015) Plasmonic core–shell nanoparticles for SERS detection of the pesticide thiram: size-and shape-dependent Raman enhancement. Nanoscale 7(7):2862–2868

11.

Basu H, Saha S, Kailasa SK, Singhal RK (2020) Present status of hybrid materials for potable water decontamination: a review. Environ Sci: Water Res Technol 6(12):3214–3248

12.

Singh R, Bhateria R (2021) Core–shell nanostructures: A simplest two-component system with enhanced properties and multiple applications. Environ Geochem Health 43(7):2459–2482CrossRef

13.

Leng Z, Li L, Zhang D, Li G (2018) Tunable green/red dual-mode luminescence via energy management in core-multishell nanoparticles. Mater Des 152:119–128CrossRef

14.

Lei L, Dai X, Cheng Y, Wang Y, Xiao Z, Xu S (2019) Dual-mode color tuning based on upconversion core/triple-shell nanostructure. J Mater Chem C 7(11):3342–3350CrossRef

15.

Dhanalakshimi T, Devi MS (2020) Water pollution. A primer on earth pollution: pollution types and disposal 97

16.

WHO (2006) Guidelines for drinking-water quality [Electronic Resource]: Incorporating First Addendum (vol. I) Recommendations, pp 375–377, 448–1456

17.

WHO (1993) Guidelines for drinking water quality recommendations. Geneva

18.

Yakamercan E, Ari A, Aygün A (2021) Land application of municipal sewage sludge: human health risk assessment of heavy metals. J Clean Prod 319:128568CrossRef

19.

Engwa GA, Ferdinand PU, Nwalo FN, Unachukwu MN (2019) Mechanism and health effects of heavy metal toxicity in humans. Poisoning in the modern world-new tricks for an old dog 10

20.

Crini G, Lichtfouse E (2019) Advantages and disadvantages of techniques used for wastewater treatment. Environ Chem Lett 17(1):145–155CrossRef

21.

Rathi BS, Kumar PS (2021) Application of adsorption process for effective removal of emerging contaminants from water and wastewater. Environ Pollut 280:116995CrossRef

22.

Suárez-Iglesias O, Collado S, Oulego P, Díaz M (2017) Graphene-family nanomaterials in wastewater treatment plants. Chem Eng J 313:121–135CrossRef

23.

Peng B, Yao Z, Wang X, Crombeen M, Sweeney DG, Tam KC (2020) Cellulose-based materials in wastewater treatment of petroleum industry. Green Energy Environ 5(1):37–49CrossRef

24.

Yu S, Wang X, Pang H, Zhang R, Song W, Fu D ... Wang X (2018) Boron nitride-based materials for the removal of pollutants from aqueous solutions: a review. Chem Eng J 333, 343–360

25.

Wong S, Ngadi N, Inuwa IM, Hassan O (2018) Recent advances in applications of activated carbon from biowaste for wastewater treatment: a short review. J Clean Prod 175:361–375CrossRef

26.

Wan X, Zhan Y, Long Z, Zeng G, He Y (2017) Core@ double-shell structured magnetic halloysite nanotube nano-hybrid as efficient recyclable adsorbent for methylene blue removal. Chem Eng J 330:491–504CrossRef

27.

Alijani H, Shariatinia Z (2018) Synthesis of high growth rate SWCNTs and their magnetite cobalt sulfidenanohybrid as super-adsorbent for mercury removal. Chem Eng Res Des 129:132–149CrossRef

28.

Meaney SP, Follink B, Tabor RF (2018) Synthesis, characterization, and applications of polymer-silica core–shell microparticle capsules. ACS Appl Mater Interf 10(49):43068–43079CrossRef

29.

Guo X, Liu X, Xu B, Dou T (2009) Synthesis and characterization of carbon sphere-silica core–shell structure and hollow silica spheres. Colloids Surf, A 345(1–3):141–146CrossRef

30.

Tang F, Liu L, Alva G, Jia Y, Fang G (2017) Synthesis and properties of microencapsulated octadecane with silica shell as shape–stabilized thermal energy storage materials. Sol Energy Mater Sol Cells 160:1–6CrossRef

31.

Rao KS, El-Hami K, Kodaki T, Matsushige K, Makino K (2005) A novel method for synthesis of silica nanoparticles. J Colloid Interf Sci 289(1):125–131CrossRef

32.

Khanal A, Inoue Y, Yada M, Nakashima K (2007) Synthesis of silica hollow nanoparticles templated by polymeric micelle with core− shell− corona structure. J Am Chem Soc 129(6):1534–1535CrossRef

33.

Deng TS, Zhang QF, Zhang JY, Shen X, Zhu KT, Wu JL (2009) One-step synthesis of highly monodisperse hybrid silica spheres in aqueous solution. J Colloid Interf Sci 329(2):292–299CrossRef

34.

Basu H, Saha S, Mahadevan IA, Pimple MV, Singhal RK (2019) Humic acid coated cellulose derived from rice husk: a novel biosorbent for the removal of Ni and Cr. J Water Process Eng 32:100892

35.

Decker S, Klabunde KJ (1996) Enhancing effect of Fe2O3 on the ability of nanocrystalline calcium oxide to adsorb SO2. J Am Chem Soc 118(49):12465–12466CrossRef

36.

Basu H, Saha S, Pimple MV, Singhal RK (2019) Novel hybrid material humic acid impregnated magnetic chitosan nano particles for decontamination of uranium from aquatic environment. J Environ Chem Eng 7(3):103110CrossRef

37.

Basu H, Pimple MV, Saha S, Patel A, Dansena C, Singhal RK (2020) TiO2 microsphere impregnated alginate: a novel hybrid sorbent for uranium removal from aquatic bodies. New J Chem 44(10):3950–3960CrossRef

38.

Nayak MK, Singh J, Singh B, Soni S, Pandey VS, Tyagi S (2017) Introduction to semiconductor nanomaterial and its optical and electronics properties. In Metal semiconductor core-shell nanostructures for energy and environmental applications, pp 1–33. Elsevier

39.

Chiozzi V, Rossi F (2020) Inorganic–organic core/shell nanoparticles: progress and applications. Nanoscale Adv 2(11):5090–5105CrossRef

40.

Zhou Z, Liu R (2017) Fe₃O₄@ polydopamine and derived Fe₃O₄@ carbon core–shell nanoparticles: comparison in adsorption for cationic and anionic dyes. Colloids Surf, A 522:260–265CrossRef

41.

Gutierrez AM, Bhandari R, Weng J, Stromberg A, Dziubla TD, Hilt JZ (2019) Novel magnetic core-shell nanoparticles for the removal of polychlorinated biphenyls from contaminated water sources. Mater Chem Phys 223:68–74CrossRef

42.

Karsten S, Nan A, Turcu R, Liebscher J (2012) A new access to polypyrrole-based functionalized magnetic core-shell nanoparticles. J Polym Sci, Part A: Polym Chem 50(19):3986–3995CrossRef

43.

Xian Y, Hu Y, Liu F, Xian Y, Wang H, Jin L (2006) Glucose biosensor based on Au nanoparticles–conductive polyaniline nanocomposite. Biosens Bioelectron 21(10):1996–2000CrossRef

44.

Yan W, Feng X, Chen X, Li X, Zhu JJ (2008) A selective dopamine biosensor based on AgCl@ polyaniline core–shell nanocomposites. Bioelectrochemistry 72(1):21–27CrossRef

45.

Nakate UT, Ahmad R, Patil P, Bhat KS, Wang Y, Mahmoudi T, … Hahn YB (2019) High response and low concentration hydrogen gas sensing properties using hollow ZnO particles transformed from polystyrene@ ZnO core-shell structures. Int J Hydrogen Energy 44(29):15677–15688CrossRef

46.

Zhao Y, Chen Z, Zhu X, Möller M (2016) A facile one-step approach toward polymer@ SiO2 core–shell nanoparticles via a surfactant-free miniemulsion polymerization technique. Macromolecules 49(5):1552–1562CrossRef

47.

Basu H, Singhal RK, Pimple MV (2016) Highly efficient removal of TiO2 nanoparticles from aquatic bodies by silica microsphere impregnated Ca-alginate. New J Chem 40:3177–3186CrossRef

48.

Basu H, Singhal RK, Pimple MV, Reddy AVR (2015) Synthesis and characterization of silica microsphere and their application in removal of Uranium and Thorium from water. Int J Environ Sci Technol 12(6):1899–1906CrossRef

49.

Basu H, Singhal RK, Pimple MV, Saha S (2018) Graphene-prussian blue nanocomposite impregnated in alginate for efficient removal of cesium from aquatic environment. J Environ Chem Eng 6(4):4399-4407

50.

Silva DM, Liu R, Gonçalves AF, da Costa A, Gomes AC, Machado R ... Sencadas V (2021) Design of polymeric core-shell carriers for combination therapies. J Colloid Interf Sci 587:499–509

51.

Rodríguez-González B, Burrows A, Watanabe M, Kiely CJ, Marzán LML (2005) Multishell bimetallic AuAg nanoparticles: synthesis, structure and optical properties. J Mater Chem 15(17):1755–1759CrossRef

52.

Gerion D, Pinaud F, Williams SC, Parak WJ, Zanchet D, Weiss S, Alivisatos AP (2001) Synthesis and properties of biocompatible water-soluble silica-coated CdSe/ZnS semiconductor quantum dots. J Phys Chem B 105(37):8861–8871CrossRef

53.

Liu R, Qu F, Guo Y, Yao N, Priestley RD (2014) Au@ carbon yolk–shell nanostructures via one-step core–shell–shell template. Chem Commun 50(4):478–480CrossRef

54.

Arole VM, Munde SV (2014) Fabrication of nanomaterials by top-down and bottom-up approaches-an overview. J Mater Sci 1:89–93

55.

Indiarto R, Indriana LPA, Andoyo R, Subroto E, Nurhadi B (2021) Bottom–up nanoparticle synthesis: a review of techniques, polyphenol-based core materials, and their properties. Eur Food Res Technol 1–24

56.

Ealia SAM, Saravanakumar MP (2017, November). A review on the classification, characterisation, synthesis of nanoparticles and their application. In IOP conference series: materials science and engineering, Vol 263, No 3, p 032019. IOP Publishing

57.

Mehta VN, Desai ML, Basu H, Singhal RK, Kailasa SK (2021) Recent developments on fluorescent hybrid nanomaterials for metal ions sensing and bioimaging applications: a review. J Mol Liq 333:115950CrossRef

58.

Basu H, Singhal RK, Pimple MV, Saha S (2018) Graphene oxide encapsulated in alginate beads for enhanced sorption of uranium from different aquatic environments. J Environ Chem Eng 6(2):1625–1633

59.

Basu H, Singhal RK, Pimple MV, Kumar A, Reddy AVR (2014) Association and migration of uranium and thorium with silica colloidal particles in saturated subsurface zone. J Radio Anal Nucl Chem 303:2283–2290

60.

Malik MA, O’Brien P, Revaprasadu N (2002) A simple route to the synthesis of core/shell nanoparticles of chalcogenides. Chem Mater 14(5):2004–2010CrossRef

61.

Ban Z, Barnakov YA, Li F, Golub VO, O’Connor CJ (2005) The synthesis of core–shell iron@ gold nanoparticles and their characterization. J Mater Chem 15(43):4660–4662CrossRef

62.

Khatami M, Alijani HQ, Nejad MS, Varma RS (2018) Core@ shell nanoparticles: greener synthesis using natural plant products. Appl Sci 8(3):411CrossRef

63.

Khan A, Rashid A, Younas R, Chong R (2016) A chemical reduction approach to the synthesis of copper nanoparticles. Int Nano Lett 6(1):21–26CrossRef

64.

Guzmán MG, Dille J, Godet S (2009) Synthesis of silver nanoparticles by chemical reduction method and their antibacterial activity. Int J Chem Biomol Eng 2(3):104–111

65.

Jana NR, Gearheart L, Murphy CJ (2001) Evidence for seed-mediated nucleation in the chemical reduction of gold salts to gold nanoparticles. Chem Mater 13(7):2313–2322CrossRef

66.

Kailasa SK, Koduru JR, Desai ML, Park TJ, Singhal RK, Basu H (2018) Recent progress on surface chemistry of plasmonic metal nanoparticles for colorimetric assay of drugs in pharmaceutical and biological sample., Trends Anal Chem 105:106–120

67.

Basu H, Singhal RK, Pimple MV, Saha S (2017) Association and migration behavior of trace metals with humus colloidal particles in aquatic subsurface medium. J Radio Anal Nucl Chem 311(1): 503–551

68.

Lee WR, Kim MG, Choi JR, Park JI, Ko SJ, Oh SJ, Cheon J (2005) Redox− transmetalation process as a generalized synthetic strategy for core− shell magnetic nanoparticles. J Am Chem Soc 127(46):16090–16097CrossRef

69.

Chen D, Liu S, Li J, Zhao N, Shi C, Du X, Sheng J (2009) Nanometre Ni and core/shell Ni/Au nanoparticles with controllable dimensions synthesized in reverse microemulsion. J Alloy Compd 475(1–2):494–500CrossRef

70.

Park JI, Cheon J (2001) Synthesis of “solid solution” and “core-shell” type cobalt− platinum magnetic nanoparticles via transmetalation reactions. J Am Chem Soc 123(24):5743–5746CrossRef

71.

Ji Y, Yang S, Guo S, Song X, Ding B, Yang Z (2010) Bimetallic Ag/Au nanoparticles: a low temperature ripening strategy in aqueous solution. Colloids Surf, A 372(1–3):204–209CrossRef

72.

Lee CC, Chen DH (2006) Large-scale synthesis of Ni–Ag core–shell nanoparticles with magnetic, optical and anti-oxidation properties. Nanotechnology 17(13):3094CrossRef

73.

Singhal RK, Gangadhar B, Basu H, Venkatesh M, Naidu GRK, Reddy AVR (2012) Remediation of malathion contaminated soil using zero valent iron nano-particles. Am J Anal Chem 3:76–82

74.

Hess PH, Parker PH Jr (1966) Polymers for stabilization of colloidal cobalt particles. J Appl Polym Sci 10(12):1915–1927CrossRef

75.

Salavati-Niasari M, Davar F, Mazaheri M, Shaterian M (2008) Preparation of cobalt nanoparticles from [bis (salicylidene) cobalt (II)]–oleylamine complex by thermal decomposition. J Magn Magn Mater 320(3–4):575–578CrossRef

76.

Salavati-Niasari M, Davar F, Mir N (2008) Synthesis and characterization of metallic copper nanoparticles via thermal decomposition. Polyhedron 27(17):3514–3518CrossRef

77.

Wang L, Wang L, Luo J, Fan Q, Suzuki M, Suzuki IS ...Zhong CJ (2005) Monodispersed core− shell Fe₃O₄@ Au nanoparticles. J Phys Chem B 109(46):21593–21601

78.

De Jesus JC, González I, Quevedo A, Puerta T (2005) Thermal decomposition of nickel acetate tetrahydrate: an integrated study by TGA, QMS and XPS techniques. J Mol Catal A: Chem 228(1–2):283–291CrossRef

79.

Fu Y, Shearwood C (2004) Characterization of nanocrystallineTiNi powder. Scripta Mater 50(3):319–323CrossRef

80.

Wang Q, Yang H, Shi J, Zou G (2001) Preparation and characterization of nanocrystalline powders of Cu–Zn alloy by wire electrical explosion method. Mater Sci Eng, A 307(1–2):190–194CrossRef

81.

Basu H, Singh S, Venkatesh M, Pimple MV, Singhal RK (2021) Graphene oxide-MnO2-goethite microsphere impregnated alginate: a novel hybrid nanosorbent for As (III) and As (V) removal from groundwater. J Water Process Eng 42:102129CrossRef

82.

Basu H, Singhal RK, Pimple MV, Manisha V, Bassan MKT, Reddy AVR, Mukherjee T (2011) Development of naturally occurring siliceous material for the preferential removal of thorium from U-Th from aquatic environment. J Radio Anal Nucl Chem 289:231–237CrossRef

83.

Parashar M, Shukla VK, Singh R (2020) Metal oxides nanoparticles via sol–gel method: a review on synthesis, characterization and applications. J Mater Sci: Mater Electron 31(5):3729–3749

84.

Petcharoen K, Sirivat A (2012) Synthesis and characterization of magnetite nanoparticles via the chemical co-precipitation method. Mater Sci Eng, B 177(5):421–427CrossRef

85.

Kim YI, Kim D, Lee CS (2003) Synthesis and characterization of CoFe2O4 magnetic nanoparticles prepared by temperature-controlled coprecipitation method. Physica B 337(1–4):42–51CrossRef

86.

He Q, Zhang Z, Xiong J, Xiong Y, Xiao H (2008) A novel biomaterial—Fe₃O₄: TiO₂ core-shell nano particle with magnetic performance and high visible light photocatalytic activity. Opt Mater 31(2):380–384CrossRef

87.

Palacios-Hernández T, Hirata-Flores GA, Contreras-López OE, Mendoza-Sánchez ME, Valeriano-Arreola I, González-Vergara E, Méndez-Rojas MA (2012) Synthesis of Cu and Co metal oxide nanoparticles from thermal decomposition of tartrate complexes. Inorganica Chimica Acta 392:277–282CrossRef

88.

Sun S, Zeng H (2002) Size-controlled synthesis of magnetite nanoparticles. J Am Chem Soc 124(28):8204–8205CrossRef

89.

Salavati-Niasari M, Davar F, Mazaheri M (2008) Preparation of ZnO nanoparticles from [bis (acetylacetonato) zinc (II)]–oleylamine complex by thermal decomposition. Mater Lett 62(12–13):1890–1892CrossRef

90.

Tian Y, Newton T, Kotov NA, Guldi DM, Fendler JH (1996) Coupled composite CdS− CdSe and core− shell types of (CdS) CdSe and (CdSe) CdS nanoparticles. J Phys Chem 100(21):8927–8939CrossRef

91.

Korgel BA, Monbouquette HG (2000) Controlled synthesis of mixed core and layered (Zn, Cd) S and (Hg, Cd) S nanocrystals within phosphatidylcholine vesicles. Langmuir 16(8):3588–3594CrossRef

92.

Zhou HS, Honma I, Komiyama H, Haus JW (1993) Coated semiconductor nanoparticles; the cadmium sulfide/lead sulfide system’s synthesis and properties. J Phys Chem 97(4):895–901CrossRef

93.

Kortan AR, Hull R, Opila RL, Bawendi MG, Steigerwald ML, Carroll PJ, Brus LE (1990) Nucleation and growth of CdSe on ZnS quantum crystallite seeds, and vice versa, in inverse micelle media. J Am Chem Soc 112(4):1327–1332CrossRef

94.

Xie XL, Li RKY, Liu QX, Mai YW (2004) Structure-property relationships of in-situ PMMA modified nano-sized antimony trioxide filled poly (vinyl chloride) nanocomposites. Polymer 45(8):2793–2802CrossRef

95.

Ballauff M, Lu Y (2007) “Smart” nanoparticles: preparation, characterization and applications. Polymer 48(7):1815–1823CrossRef

96.

Singh S, Basu H, Bassan MKT, Singhal RK (2022) Thiol functionalised silica microsphere loaded polymeric hydrogel: development of a novel hybrid sorbent for removal of lead and cadmium. Chemosphere 286:131659CrossRef

97.

Wang C, Yan J, Cui X, Cong D, Wang H (2010) Preparation and characterization of magnetic hollow PMMA nanospheres via in situ emulsion polymerization. Colloids Surf, A 363(1–3):71–77CrossRef

98.

Mohod CV, Dhote J (2013) Review of heavy metals in drinking water and their effect on human health. Int J Innov Res Sci, Eng Technol 2(7):2992–2996

99.

Fu Z, Xi S (2020) The effects of heavy metals on human metabolism. Toxicol Mech Methods 30(3):167–176CrossRef

100.

Saad AHA, Azzam AM, El-Wakeel ST, Mostafa BB, Abd El-latif MB (2018) Removal of toxic metal ions from wastewater using ZnO@ Chitosan core-shell nanocomposite. Environ Nanotechnol Monitor Manag 9:67–75CrossRef

101.

Mehta VN, Desai ML, Basu H, Singhal RK, Kailasa SK (2021) Recent developments on fluorescent hybrid nanomaterials for metal ions sensing and bioimaging applications: a review. J Mol Liq 333:115950

102.

Basu H, Singhal RK, Pimple MV, Reddy AVR (2015) Arsenic removal from ground water by goethite impregnated calcium alginate beads. Water, Air, Soil Pollut 226:22

103.

Zhang M, Song W, Chen Q, Miao B, He W (2015) One-pot synthesis of magnetic Ni@ Mg (OH) 2 core–shell nanocomposites as a recyclable removal agent for heavy metals. ACS Appl Mater Interf 7(3):1533–1540CrossRef

104.

Zhu K, Chen C, Xu H, Gao Y, Tan X, Alsaedi A, Hayat T (2017) Cr (VI) reduction and immobilization by core-double-shell structured magnetic polydopamine@ zeoliticidazolate frameworks-8 microspheres. ACS Sustain Chem Eng 5(8):6795–6802CrossRef

105.

Nawaz T, Zulfiqar S, Sarwar MI, Iqbal M (2020) Synthesis of diglycolic acid functionalized core-shell silica coated Fe 3 O 4 nanomaterials for magnetic extraction of Pb (II) and Cr (VI) ions. Sci Rep 10(1):1–13CrossRef

106.

Liu L, Liu S, Zhao L, Su G, Liu X, Peng H, ... Tang A (2020) Fabrication of novel magnetic core-shell chelating adsorbent for rapid and highly efficient adsorption of heavy metal ions from aqueous solution. J Mol Liq 313:113593

107.

Ma Z, Zhao D, Chang Y, Xing S, Wu Y, Gao Y (2013) Synthesis of MnFe₂O₄@ Mn–Co oxide core–shell nanoparticles and their excellent performance for heavy metal removal. Dalton Trans 42(39):14261–14267CrossRef

108.

Amiri O, Hosseinpour-Mashkani SM, Rad MM, Abdvali F (2014) Sonochemical synthesis and characterization of CdS/ZnS core–shell nanoparticles and application in removal of heavy metals from aqueous solution. Superlattices Microstruct 66:67–75CrossRef

109.

Yang W, Wang Y, Wang Q, Wu J, Duan G, Xu W, Jian S (2021) Magnetically separable and recyclable Fe₃O₄@ PDA covalent grafted by l-cysteine core-shell nanoparticles toward efficient removal of Pb²⁺. Vacuum 189:110229CrossRef

110.

Jahanbakhsh Z, Hosseinzadeh H, Masoumi B (2021) Synthesis of carboxymethyl β-cyclodextrin bonded Fe₃O₄@ SiO₂–NH₂ core-shell magnetic nanocomposite adsorbent for effective removal of Pb (II) from wastewater. J Sol-Gel Sci Technol 1–13

111.

Jiang X, Su S, Rao J, Li S, Lei T, Bai H, ... Yang X (2021) Magnetic metal-organic framework (Fe₃O₄@ ZIF-8) core-shell composite for the efficient removal of Pb (II) and Cu (II) from water. J Environ Chem Eng 9(5):105959

112.

Bhardwaj S, Sarkar T (2020) Core–shell type magnetic Ni/NiO nanoparticles as recyclable adsorbent for Pb (II) and Cd (II) ions: one-pot synthesis, adsorption performance, and mechanism. J Taiwan Inst Chem Eng 113:223–230CrossRef

113.

Patiño-Ruiz D, Rehmann L, Mehrvar M, Quiñones-Bolaños E, Herrera A (2020) Synthesis of FeO@ SiO 2–DNA core–shell engineered nanostructures for rapid adsorption of heavy metals in aqueous solutions. RSC Adv 10(64):39284–39294CrossRef

114.

Zhao Z, Zhang X, Zhou H, Liu G, Kong M, Wang G (2017) Microwave-assisted synthesis of magnetic Fe₃O₄-mesoporous magnesium silicate core-shell composites for the removal of heavy metal ions. Microporous Mesoporous Mater 242:50–58CrossRef

115.

Ji S, Miao C, Liu H, Feng L, Yang X, Guo H (2018) A hydrothermal synthesis of Fe 3 O 4@ C hybrid nanoparticle and magnetic adsorptive performance to remove heavy metal ions in aqueous solution. Nanoscale Res Lett 13(1):1–10CrossRef

116.

Chen J, Liu K, Jiang M, Han J, Liu M, Wang C, Li C (2019) Controllable preparation of porous hollow carbon sphere@ ZIF-8: Novel core-shell nanomaterial for Pb²⁺ adsorption. Colloids Surf, A 568:461–469CrossRef

117.

Fathy M, Zayed MA, Moustafa YM (2019) Synthesis and applications of CaCO3/HPC core–shell composite subject to heavy metals adsorption processes. Heliyon 5(8):e02215CrossRef

118.

Venkateswarlu S, Yoon M (2015) Core–shell ferromagnetic nanorod based on amine polymer composite (Fe₃O₄@ DAPF) for fast removal of Pb (II) from aqueous solutions. ACS Appl Mater Interf 7(45):25362–25372CrossRef

119.

Luo H, Zhang S, Li X, Liu X, Xu Q, Liu J, Wang Z (2017) Tannic acid modified Fe₃O₄ core–shell nanoparticles for adsorption of Pb²⁺ and Hg²⁺. J Taiwan Inst Chem Eng 72:163–170CrossRef

120.

Ren C, Ding X, Fu H, Li W, Wu H, Yang H (2017) Core–shell superparamagnetic monodisperse nanospheres based on amino-functionalized CoFe₂O₄@ SiO₂ for removal of heavy metals from aqueous solutions. RSC Adv 7(12):6911–6921CrossRef

121.

Ashrafi A, Rahbar-Kelishami A, Shayesteh H (2017) Highly efficient simultaneous ultrasonic assisted adsorption of Pb (II) by Fe₃O₄@ MnO₂ core-shell magnetic nanoparticles: synthesis and characterization, kinetic, equilibrium, and thermodynamic studies. J Mol Struct 1147:40–47CrossRef

122.

Gui CX, Li QJ, Lv LL, Qu J, Wang QQ, Hao SM, Yu ZZ (2015) Core–shell structured MgO@ mesoporous silica spheres for enhanced adsorption of methylene blue and lead ions. RSC Adv 5(26):20440–20445CrossRef

123.

Xiong T, Yuan X, Cao X, Wang H, Jiang L, Wu Z, Liu Y (2020) Mechanistic insights into heavy metals affinity in magnetic MnO₂@ Fe₃O₄/poly (m-phenylenediamine) core− shell adsorbent. Ecotoxicol Environ Saf 192:110326CrossRef

124.

Wang S, Wang K, Dai C, Shi H, Li J (2015) Adsorption of Pb²⁺ on amino-functionalized core–shell magnetic mesoporous SBA-15 silica composite. Chem Eng J 262:897–903CrossRef

125.

Wan S, Yu C, Li Y, Lu Z, Wang Y, Wang Y, He F (2021) Highly selective and ultrafast removal of cadmium and copper from water by magnetic core-shell microsphere. Chem Eng J 405:126576CrossRef

126.

Abolhasani J, Khanmiri RH, Ghorbani-Kalhor E, Hassanpour A, Asgharinezhad AA, Shekari N, Fathi A (2015) An Fe₃O₄@ SiO₂@ polypyrrole magnetic nanocomposite for the extraction and preconcentration of Cd (II) and Ni (II). Anal Methods 7(1):313–320CrossRef

127.

Sun L, Li Y, Sun M, Wang H, Xu S, Zhang C, Yang Q (2011) Porphyrin-functionalized Fe₃O₄@ SiO₂ core/shell magnetic colorimetric material for detection, adsorption and removal of Hg²⁺ in aqueous solution. New J Chem 35(11):2697–2704CrossRef

128.

Zhu H, Shen Y, Wang Q, Chen K, Wang X, Zhang G ... Bai R (2017) Highly promoted removal of Hg (II) with magnetic CoFe₂O₄@ SiO₂ core–shell nanoparticles modified by thiol groups. RSC Adv 7(62):39204–39215

129.

Xia K, Guo Y, Shao Q, Zan Q, Bai R (2019) Removal of mercury (II) by EDTA-functionalized magnetic CoFe₂O₄@ SiO₂ nanomaterial with core-shell structure. Nanomaterials 9(11):1532CrossRef

130.

Removal of Hg(II) by poly(1-vinylimidazole)-grafted Fe₃O₄@SiO₂ magnetic nanoparticles Water Res 69C:252–260 (2014) https://doi.org/10.1016/j.watres.2014.11.030

131.

Afraz A, Hajian A, Niknam Z, Mosayebi E, Yusefi A, Sillanpää M (2017) Amin-functionalized magnetic-silica core-shell nanoparticles for removal of Hg²⁺ from aqueous solution. J Dispers Sci Technol 38(5):750–756CrossRef

132.

Wu A, Jia J, Luan S (2011) Amphiphilic PMMA/PEI core–shell nanoparticles as polymeric adsorbents to remove heavy metal pollutants. Colloids Surf, A 384(1–3):180–185CrossRef

133.

Chang L, Pu Y, Jing P, Cui Y, Zhang G, Xu S ... Qiao C (2021). Magnetic core-shell MnFe2O4@ TiO2 nanoparticles decorated on reduced graphene oxide as a novel adsorbent for the removal of ciprofloxacin and Cu (II) from water. Appl Surf Sci 541:148400

134.

Xiong Z, Zheng H, Hu Y, Hu X, Ding W, Ma J, Li Y (2021) Selective adsorption of Congo red and Cu (II) from complex wastewater by core-shell structured magnetic carbon@ zeoliticimidazolate frameworks‑8 nanocomposites. Separ Purif Technol 119053

135.

Zuo B, Deng Q, Shao H, Cao B, Fan Y, Li W, Huang M (2021) Fe₃O₄@ Mesoporous-SiO₂@ Chitosan@ polyaniline core-shell nanoparticles as recyclable adsorbents and reductants for hexavalent chromium. ACS Appl Nano Mater 4(2):1831–1840CrossRef

136.

Ekka B, Dhar G, Sahu S, Mishra M, Dash P, Patel RK (2021) Removal of Cr (VI) by silica-titania core-shell nanocomposites: in vivo toxicity assessment of the adsorbent by Drosophila melanogaster. Ceram Int 47(13):19079–19089CrossRef

137.

Zhang Y, Xu S, Zhou H, Qi H, Wang H (2021) Adsorption of organic pollutants and heavy metal by Co-doped core-shell MoO2/Mo2C adsorbent. J Solid State Chem 293:121801CrossRef

138.

Yang Q, Wang H, Li F, Dang Z, Zhang L (2021) Rapid and efficient removal of Cr (vi) by a core–shell magnetic mesoporous polydopamine nanocomposite: roles of the mesoporous structure and redox-active functional groups. J Mater Chem A 9(22):13306–13319CrossRef

139.

Wang T, Zhang L, Li C, Yang W, Song T, Tang C ... Luo J (2015) Synthesis of core–shell magnetic Fe₃O₄@ poly (m-phenylenediamine) particles for chromium reduction and adsorption. Environ Sci Technol 49(9):5654–5662

140.

Facile synthesis of layered core-shell structure Fe₃O₄ magnetic composites and its application for the Co²⁺ removal. J Mol Liq 325:114517 (2020). https://doi.org/10.1016/j.molliq.2020.114517

141.

Zhang X, Wang Y, Yang S (2014) Simultaneous removal of Co (II) and 1-naphthol by core–shell structured Fe₃O₄@ cyclodextrin magnetic nanoparticles. Carbohyd Polym 114:521–529CrossRef

142.

Huo JB, Xu L, Yang JCE, Cui HJ, Yuan B, Fu ML (2018) Magnetic responsive Fe₃O₄-ZIF-8 core-shell composites for efficient removal of As (III) from water. Colloids Surf, A 539:59–68CrossRef

143.

Wu J, Zhu H, Liu G, Tan L, Hu X, Chen C ... Tan X (2017) Fabrication of core–shell CMNP@ PmPD nanocomposite for efficient As (V) adsorption and reduction. ACS Sustain Chem Eng 5(5):4399–4407

144.

Singhal RK, Basu H, Manisha V, Reddy AVR, Mukherjee T (2011) Removal of low level americium-241 from potable water originated from different geochemical environments by calcium alginate. Desalination 280:313–318

145.

Wang Z, Wang J, Zhu L, He Y, Duan T (2020) Scalable Fe@ FeO core-shell nanoparticle-embedded porous wood for high-efficiency uranium (VI) adsorption. Appl Surf Sci 508:144709CrossRef

146.

Dai Z, Zhang H, Sui Y, Ding D, Hu N, Li L, Wang Y (2018) Synthesis and characterization of a novel core–shell magnetic nanocomposite via surface-initiated RAFT polymerization for highly efficient and selective adsorption of uranium (VI). J Radio Anal Nucl Chem 316(1):369–382CrossRef

147.

Tan L, Zhang X, Liu Q, Wang J, Sun Y, Jing X ... Liu L (2015) Preparation of magnetic core–shell iron oxide@ silica@ nickel-ethylene glycol microspheres for highly efficient sorption of uranium (VI). Dalton Trans 44(15):6909–6917

148.

Liu Q, Li W, Zhao W, Tan L, Jing X, Liu J ... Wang J (2016) Synthesis of ketoxime-functionalized Fe 3 O 4@ C core–shell magnetic microspheres for enhanced uranium (vi) removal. RSC Adv 6(26):22179–22186

149.

Yang Y, Wang J, Wu F, Ye G, Yi R, Lu Y, Chen J (2016) Surface-initiated SET-LRP mediated by mussel-inspired polydopamine chemistry for controlled building of novel core–shell magnetic nanoparticles for highly-efficient uranium enrichment. Polym Chem 7(13):2427–2435CrossRef

150.

Liu Y, Yang P, Li Q, Liu Y, Yin J (2019) Preparation of FeS@ Fe₃O₄ core–shell magnetic nanoparticles and their application in uranyl ions removal from aqueous solution. J Radio Anal Nucl Chem 321(2):499–510CrossRef

151.

Li P, Wang J, Wang X, He B, Pan D, Liang J ... Fan Q (2018) Arsenazo-functionalized magnetic carbon composite for uranium (VI) removal from aqueous solution. J Mol Liq 269:441–449

152.

Zhao Y, Li J, Zhao L, Zhang S, Huang Y, Wu X, Wang X (2014) Synthesis of amidoxime-functionalized Fe₃O₄@ SiO₂ core–shell magnetic microspheres for highly efficient sorption of U (VI). Chem Eng J 235:275–283CrossRef

153.

Hu S, Lin X, Zhang Y, Huang R, Qu Y, Luo X, Zhou J (2017) Preparation and application of alginate-Ca/attapulgite clay core/shell particle for the removal of uranium from aqueous solution. J Radio Anal Nucl Chem 314(1):307–319CrossRef

154.

Feng J, Cai Y, Wang X, Wang X, Zhu M, Fang M ... Tan X (2021) Designed Core–Shell Fe 3 O 4@ polydopamine for effectively removing uranium (VI) from aqueous solution. Bull Environ Contamin Toxicol 106:165–174

155.

Li L, Lu W, Ding D, Dai Z, Cao C, Liu L, Chen T (2019) Adsorption properties of pyrene-functionalized nano-Fe₃O₄ mesoporous materials for uranium. J Solid State Chem 270:666–673CrossRef

156.

Zhu K, Lu S, Gao Y, Zhang R, Tan X, Chen C (2017) Fabrication of hierarchical core-shell polydopamine@ MgAl-LDHs composites for the efficient enrichment of radionuclides. Appl Surf Sci 396:1726–1735CrossRef

157.

Tan X, Fang M, Tan L, Liu H, Ye X, Hayate T, Wang X (2018) Core–shell hierarchical C@Na2Ti3O7·9H2O nanostructures for the efficient removal of radionuclides. Environ Sci: Nano 5:1140–1149

158.

Zhao M, Cui Z, Pan D, Fan F, Tang J, Hu Y ... Wu W (2021) An efficient uranium adsorption magnetic platform based on amidoxime-functionalized flower-like Fe₃O₄@ TiO₂ Core–Shell microspheres. ACS Appl Mater Interf 13(15):17931–17939

159.

Xu S, Yingguo Z, Yingguo Z, Zheng F, Zheng F, Zhan Y (2016) Hollow Fe₃O₄@mesoporous carbon core–shell microspheres for efficient sorption of radionuclides, Springer. J Mater Sci 51(5). https://doi.org/10.1007/s10853-015-9567-y

160.

Wu Y, Li B, Wang X, Yu S, Pang H, Liu Y ... Wang X (2019) Magnetic metal-organic frameworks (Fe₃O₄@ ZIF-8) composites for U (VI) and Eu (III) elimination: simultaneously achieve favorable stability and functionality. Chem Eng J 378:122105

161.

Tan L, Zhang X, Liu Q, Jing X, Liu J, Song D ... Wang J (2015) Synthesis of Fe₃O₄@ TiO2 core–shell magnetic composites for highly efficient sorption of uranium (VI). Colloids Surf A: Physicochem Eng Aspects 469:279–286

162.

Yang S, Yang S, Zong P, Zong P, Ren X, Ren X, Wang X, Wang X (2012) Rapid and highly efficient preconcentration of Eu(III) by Core–Shell structured Fe₃O₄@Humic acid magnetic nanoparticles, ACS Appl Mater Interf 4(12):6891–6900

163.

Zhang Y, Lin X, Hu S, Zhang X, Luo X (2016) Core–shell zeolite@ Alg–Ca particles for removal of strontium from aqueous solutions. RSC Adv 6(78):73959–73973CrossRef

164.

Fakhri H, Mahjoub AR, Aghayan H (2019) Effective adsorption of Co²⁺ and Sr²⁺ ions by 10-tungsten-2-molybdophosphoric acid supported amine modified magnetic SBA-15. J Radio Anal Nucl Chem 321(2):449–461CrossRef

165.

Mou W, Du S, Yu Q, Li X, Wei H, Yang Y (2018) Efficient capture of radioactive strontium from water using magnetic WO3 assembled on grapheme oxide nanocomposite. Chem Select 3(24):6992–6997

166.

Wang G, Liu Q, Chang M, Jang J, Sui W, Si C, Ni Y (2019) Novel Fe₃O₄@ lignosulfonate/phenolic core-shell microspheres for highly efficient removal of cationic dyes from aqueous solution. Ind Crops Prod 127:110–118CrossRef

167.

Didehban A, Zabihi M, Faghihi M, Akbarbandari F, Akhtarivand H (2021) Design and fabrication of core-shell magnetic and non-magnetic supported carbonaceous metal organic framework nanocomposites for adsorption of dye. J Phys Chem Solids 152:109930CrossRef

168.

Review on nickel-based adsorption materials for Congo red. J Hazardous Mater 403:123559 (August 2020). https://doi.org/10.1016/j.jhazmat.2020.123559

169.

Yang S, Zong P, Ren S, Wang X (2014) Highly regenerable mussel-inspired Fe₃O₄@polydopamine-Ag core-shell microspheres as catalyst and adsorbent for methylene blue removal. ACS Appl Mater Interf 6(11):8845–8852, Jun 11. https://doi.org/10.1021/am501632f

170.

Huang W, Xu J, Lu D, Deng J, Shi G, Zhou T (2018) Rational design of magnetic infinite coordination polymer core-shell nanoparticles as recyclable adsorbents for selective removal of anionic dyes from colored wastewater. Appl Surf Sci 2018–12–01. https://doi.org/10.1016/j.apsusc.2018.08.122

171.

Huo Y, Wu H, Wang Z, Wang F, Liu Y, Feng Y, Zhao Y (2018) Preparation of core/shell nanocomposite adsorbents based on amine polymer-modified magnetic materials for the efficient adsorption of anionic dyes, Author links open overlay panel. Colloids Surf A: Physicochem Eng Aspects 549, 20 July 2018:174–183

172.

Zhang Z, Kong J (2011) Novel magnetic Fe₃O₄@C nanoparticles as adsorbents for removal of organic dyes from aqueous solution, Author links open overlay panel. J Hazardous Mater 193:325–329, 15 October

173.

Konickia W, Hełminiakb A, Arabczykb W, Mijowska E (2018) Adsorption of cationic dyes onto Fe@graphite core–shell magnetic nanocomposite: equilibrium, kinetics and thermodynamics, Author links open overlay panel. Chem Eng Res Design 129:259–270, Jan 2018

174.

Huang B, Liu Y, Li B, Wang H, Zeng G (2019) Adsorption mechanism of polyethyleneimine modified magnetic core–shell Fe₃O₄@SiO₂ nanoparticles for anionic dye removal. RSC Adv 9:32462–32471

175.

Wang W, Jiao T, Zhang Q, Luo X, Hu J, Chen Y, Peng Q, Yan X, Li B (2015) Hydrothermal synthesis of hierarchical core–shell manganese oxide nanocomposites as efficient dye adsorbents for wastewater treatment. RSC Adv 5:56279–56285

176.

Konickia W, Hełminiak A, Arabczyk W, Mijowska E (2017) Removal of anionic dyes using magnetic Fe@graphite core-shell nanocomposite as an adsorbent from aqueous solutions, Author links open overlay panel. J Colloid Interf Sci 497:155–164, 1 July

177.

Zheng Y, Liub J, Cheng B, You W, Ho W, Tang H (2019) Hierarchical porous Al2O3@ZnO core-shell microfibres with excellent adsorption affinity for Congo red moleculeAuthor links open overlay panel. Appl Surf Sci 473:251–260, 15 April

178.

Shaoa Y, Zhou L, Bao C, Ma J, Liu M, Wang F (2016) Magnetic responsive metal–organic frameworks nanosphere with core–shell structure for highly efficient removal of methylene blue, This paper is dedicated to the memory of Professor Yanfeng Li.Author links open overlay panel. Chem Eng J 283:1127–1136, 1 Jan

179.

Wo R, Li Q-L, Zhu C, Zhang Y, Qiao G-f, Lei K-y, Du P, Jiang W (2019) Preparation and characterization of functionalized metal–organic frameworks with core/shell magnetic particles (Fe₃O₄@SiO₂@MOFs) for removal of congo red and methylene blue from water solution. J Chem Eng Data 64(6):2455–2463

180.

Kollarahithlu SC, Balakrishnan RM (2021) Adsorption of pharmaceuticals pollutants, Ibuprofen, Acetaminophen, and Streptomycin from the aqueous phase using amine functionalized superparamagnetic silica nanocomposite. Author links open overlay panel. J Clean Prod 294:12615, 20 April

181.

Guo J, Yu M, Wei X, Huang L (2018) Preparation of core–shell magnetic molecularly imprinted polymer with uniform thin polymer layer for adsorption of dichlorophen. J Chem Eng Data 63(8):3068–3073

182.

Wang Z, Tang H, Li W, Li J, Xu R, Zhang K, He G, Shearing PR, Brett DJL (2019) Core–shell TiO₂@C ultralong nanotubes with enhanced adsorption of antibiotics. J Mater Chem A 7:19081–19086

183.

Soares SF, Fernandes T, Sacramento M, Trindade T, Daniel-da-Silva AL (2019) Magnetic quaternary chitosan hybrid nanoparticles for the efficient uptake of diclofenac from waterAuthor links open overlay panel. Carbohydr Polym 203:35–44, 1 Jan

184.

Du ZD, Cui YY, Yang CX, Yan X-P (2019) Core–Shell magnetic amino-functionalized microporous organic network nanospheres for the removal of tetrabromobisphenol A from aqueous solution. ACS Appl Nano Mater 2(3):1232–1241

185.

Zhoua Q, Wang Y, Xiao J, Fan H (2016) Adsorption and removal of bisphenol A, α-naphthol and β-naphthol from aqueous solution by Fe₃O₄@polyaniline core–shell nanomaterialsAuthor links open overlay panel. Synthetic Metals 212:113–122, Feb

186.

Zhou L, Pan S, Chen X, Zhao Y, Zou B, Jin M (2014) Kinetics and thermodynamics studies of pentachlorophenol adsorption on covalently functionalized Fe₃O₄@SiO₂–MWCNTs core–shell magnetic microspheres. Chem Eng J 257:10–19, 1 Dec

187.

Zhang X, Wang Y, Yang S (2014) Simultaneous removal of Co(II) and 1-naphthol by core–shell structured Fe₃O₄@cyclodextrin magnetic nanoparticles. Carbohydrate Polymers 114:521–529, 19 Dec

188.

Gao M, Deng L, Kang X, Fua Q, Zhang K, Wang M, Xia Z, Gao D (2020) Core-shell structured magnetic covalent organic frameworks for magnetic solid-phase extraction of diphenylamine and its analogs, J Chromatogr A 1629:461476, 11 Oct 2020

189.

Li Y, Zhang H, Chen Y, Huang L, Lin Z, Cai Z (2019) Core–Shell structured magnetic covalent organic framework nanocomposites for Triclosan and Triclocarban adsorption. ACS Appl Mater Interf 11(25):22492–22500

190.

Zhou Q, Wang Y, Xiao J, Fan H (2017) Fabrication and characterisation of magnetic graphene oxide incorporated Fe₃O₄@polyaniline for the removal of bisphenol A, t-octyl-phenol, and α-naphthol from water. Sci Rep 7. Article number: 11316

Title: Application of Core–Shell Nanohybrid Structures in Water Treatment
Authors: Hirakendu Basu
Shweta Singh
Suresh Kumar Kailasa
Rakesh Kumar Singhal
Publisher: Springer Nature Singapore
Book: Nanohybrid Materials for Water Purification
Print ISBN: 978-981-19-2331-9

Electronic ISBN: 978-981-19-2332-6

Copyright Year: 2022
DOI: https://doi.org/10.1007/978-981-19-2332-6_12

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Premium Partners