Sage Journals: Discover world-class research

Abstract

The need to eliminate heavy metal pollutants, particularly lead (Pb²⁺), has intensified due to industrialization and environmental contamination. This study synthesized a magnetic NiFe₂O₄@graphene oxide (GO) nanocomposite for efficient Pb²⁺ removal, characterized via Fourier transform Infrared (FT-IR), FESEM, X-ray diffraction (XRD), EDX, zeta potential, Vibrating sample magnetometry (VSM), Brunauer-Emmett-Teller (BET), TGA and DTG analysis. The nanocomposite demonstrated an exceptional experimental adsorption capacity of 137.86 mg/g at pH 6–8, achieving equilibrium within 5 min. Adsorption kinetics followed a pseudo-second-order model (R > o.999), and the equilibrium data were best described by the Freundlich isotherm (R² = 0.975). The material's industrial applicability is highlighted by: (1) Rapid treatment kinetics enabling high-throughput wastewater processing, (2) Magnetic separability allowing easy recovery and reuse in continuous flow systems, (3) Consistent performance (>90% efficiency after 5 cycles) reducing operational costs, and (4) High selectivity for Pb²⁺ in the presence of common interfering ions, as demonstrated by competitive adsorption studies. FT-IR confirmed the critical role of surface -OH groups in binding. This work presents a scalable, cost-effective solution for heavy metal remediation in electroplating, battery manufacturing, and mining wastewater treatment.

Keywords

heavy metals graphene nanocomposites nickel ferrite adsorption kinetics Langmuir-Freundlich models

Get full access to this article

View all access options for this article.

References

Taniguchi

. On the basic concept of'nano-technology. In: Proceedings of the international conference on production engineering, Tokyo, Part II, 1974, 1974: Japan Society of Precision Engineering.

Ishaq

Moussa

Kanwal

, et al. Facile synthesis of ternary graphene nanocomposites with doped metal oxide and conductive polymers as electrode materials for high performance supercapacitors. Sci Rep 2019; 9: 5974.

Hawezy

HJS

Qader

Omer

, et al. Magnetic nanoparticles for efficient heavy metal removal: synthesis, adsorption capacity, and key experimental parameters. Rev Inorg Chem 2025; 45: 587–596.

Schadler

. Polymer-based and polymer-filled nanocomposites. Nanocompos Sci Technol 2003: 77–153. DOI: 10.1002/3527602127.ch2.

Akl

Zaki

Elsaeed

. Green hydrogel-biochar composite for enhanced adsorption of uranium. ACS Omega 2021; 6: 34193–34205.

Braun

Schubert

Zsindely

. Nanoscience and nanotecnology on the balance. Scientometrics 1997; 38: 321–325.

Akkaya

. Uranium and thorium adsorption from aqueous solution using a novel polyhydroxyethylmethacrylate-pumice composite. J Environ Radioact 2013; 120: 58–63.

Gleiter

. Materials with ultrafine microstructures: retrospectives and perspectives. Nanostruct Mater 1992; 1: 1–19.

Pandey

Kumar

Misra

, et al. Recent advances in biodegradable nanocomposites. J Nanosci Nanotechnol 2005; 5: 497–526.

10.

Palmero

. Structural ceramic nanocomposites: a review of properties and powders’ synthesis methods. Nanomaterials 2015; 5: 656–696.

11.

Fischer

. Polymer nanocomposites: from fundamental research to specific applications. Mater Sci Eng: C 2003; 23: 763–772.

12.

Ray

Bousmina

. Biodegradable polymers and their layered silicate nanocomposites: in greening the 21st century materials world. Prog Mater Sci 2005; 50: 962–1079.

13.

Nayak

Mohanty

Nayak

, et al. A review on inkjet printing of nanoparticle inks for flexible electronics. J Mater Chem C 2019; 7: 8771–8795.

14.

Lalwani

Henslee

Farshid

, et al. Tungsten disulfide nanotubes reinforced biodegradable polymers for bone tissue engineering. Acta Biomater 2013; 9: 8365–8373.

15.

Lee

Goettler

. Structure-property relationships in polymer blend nanocomposites. Polymer Engineering & Science 2004; 44: 1103–1111.

16.

Shikaleska

Pavlovska

. Advanced materials based on polymer blends/polymer blend nanocomposites. In: IOP conference series: materials science and engineering, 2012, pp.012009: IOP Publishing.

17.

Liu

Boo

W-J

Clearfield

, et al. Intercalation and exfoliation: a review on morphology of polymer nanocomposites reinforced by inorganic layer structures. Mater Manuf Processes 2006; 21: 143–151.

18.

Wallace

. The band theory of graphite. Phys Rev 1947; 71: 622–634.

19.

Mermin

Wagner

. Absence of ferromagnetism or antiferromagnetism in one-or two-dimensional isotropic Heisenberg models. Phys Rev Lett 1966; 17: 1133–1136.

20.

Geim

. Graphene prehistory. Phys Scr 2012; T146: 014003.

21.

Geim

Novoselov

. The rise of graphene. Nat Mater 2007; 6: 183–191.

22.

MacDonald

Jung

Zhang

. Pseudospin order in monolayer, bilayer and double-layer graphene. Phys Scr 2012; T146: 014012.

23.

Viculis

Mack

Kaner

. A chemical route to carbon nanoscrolls. Science 2003; 299: 1361–1361.

24.

Geim

Kim

. Carbon wonderland. Sci Am 2008; 298: 90–97.

25.

Son

Y-W

Cohen

Louie

. Energy gaps in graphene nanoribbons. Phys Rev Lett 2006; 97: 216803.

26.

Riedl

Zakharov

Starke

. Precise in situ thickness analysis of epitaxial graphene layers on SiC (0001) using low-energy electron diffraction and angle resolved ultraviolet photoelectron spectroscopy. Appl Phys Lett 2008; 93. DOI: 10.1063/1.2960341.

27.

Lemme

Echtermeyer

Baus

, et al. A graphene field-effect device. IEEE Electron Device Lett 2007; 28: 282–284.

28.

Staudenmaier

. Verfahren zur darstellung der graphitsäure. Ber Dtsch Chem Ges 1898; 31: 1481–1487.

29.

Ciszewski

Mianowski

. Badania nad procesem utleniania grafitu mieszaninami utleniającymi w kwasach nieorganicznych. Chemik 2013; 67: 267–274.

30.

Santos

LMGD

Vicentini Neto

Barata-Silva

, et al. Inorganic element profile of medicinal Cannabis extracts consumed by pediatric patients. Braz J Pharm Sci 2022; 58. DOI: 10.1590/s2175-97902022e20176.

31.

Kubier

Wilkin

Pichler

. Cadmium in soils and groundwater: a review. Appl Geochem 2019; 108: 104388.

32.

Gworek

Dmuchowski

Baczewska-Dąbrowska

. Mercury in the terrestrial environment: a review. Environ Sci Eur 2020; 32: 1–19.

33.

Faisal

Hasnain

. Hazardous impact of chromium on environment and its appropriate remediation. J Pharmacol Toxicol 2006; 1: 248–258.

34.

Yusuf

ASA

. Potential effects of arsenic on urinary extracellular vesicle in rat . Doctoral dissertation, King Abdulaziz University Jeddah, 2021.

35.

Khosravi-Darani

Rehman

Katsoyiannis

, et al. Arsenic exposure via contaminated water and food sources. Water (Basel) 2022; 14: 1884.

36.

Nogueira

Melão

Lombardi

, et al. Natural DOM affects copper speciation and bioavailability to bacteria and ciliate. Arch Environ Contam Toxicol 2009; 57: 274–281.

37.

Eide

. Zinc transporters and the cellular trafficking of zinc. Biochim Biophys Acta Mol Cell Res 2006; 1763: 711–722.

38.

Genchi

Carocci

Lauria

, et al. Nickel: human health and environmental toxicology. Int J Environ Res Public Health 2020; 17: 679.

39.

Guo

. Spectroscopic and statistical physics elucidation for Cu(II) remediation using magnetic bio adsorbent based on Fe3O4-chitosan-graphene oxide. Int J Biol Macromol 2024; 276: 133895–133095.

40.

Nandhini

Vignesh

Shobana

. Structural and optical integrity of pure and NiFe2O4-GO nanoferrite: a combined experimental and first principles approach. Inorg Chem Commun 2023; 158: 111662–111704.

41.

Tamilselvi

Lekshmi

Padma Nathan

, et al. Nife2o4 / rGO nanocomposites produced by soft bubble assembly for energy storage and environmental remediation. Renewable Energy 2022; 181: 1386–1401.

42.

Agarwal

Rani

Shanker

. Green biosynthesized NiFe2O4 coated with rGO for efficient photocatalytic degradation of plastic additives: synthesis, mechanism, and kinetics. Diamond Relat Mater 2025; 153: 112115–112125.

43.

Phani

Acharyulu

Sohan

, et al. Effect of the graphene- Ni/NiFe2O4 composite on bacterial inhibition mediated by protein degradation. ACS Omega 2022; 25: 30794–30800.

44.

Jiang

L-L

H-T

Pei

L-F

, et al. The effect of temperatures on the synergistic effect between a magnetic field and functionalized graphene oxide-carbon nanotube composite for Pb2+ and phenol adsorption. J Nanomater 2018; 2018: 1–13.

45.

Lingamdinne

Koduru

Chang

Y-Y

, et al. Process optimization and adsorption modeling of Pb (II) on nickel ferrite-reduced graphene oxide nano-composite. J Mol Liq 2018; 250: 202–211.

46.

Donga1

Mishra

Ndlovu

, et al. Magnetic magnetite-graphene oxide (Fe3O4-GO) nanocomposites for removal of dyes from aqueous solution, vol:.(1234567890). J Inorg Organomet Polym Mater 2024; 34: 4192–4202.

47.

Cheng

Zhao

Guo

, et al. High-efficiency removal of lead/cadmium from wastewater by MgO modified biochar derived from crofton weed: adsorption behavior and quantitative analysis adsorption mechanism. Bioresour Technol 2022; 343: 126081–126890.

48.

imra

Imran

Ramzan

, et al. Functionalized graphene oxide-zinc oxide hybrid material and its deployment for adsorptive removal of levofloxacin from aqueous media. Environ Res 2023; 217: 114958–114965.

49.

Vedenyapinaa

Kurmyshevaa

Kulaishina

, et al. Adsorption of heavy metals on activated carbons (a review). Solid Fuel Chem 2021; 55: 83–104.

50.

Zorainy

Gar Alalm

Kaliaguine

, et al. Revisiting the MIL-101 metal–organic framework: design, synthesis, modifications, advances, and recent applications. J Mater Chem A 2021; 9: 22159–22217.

51.

Zhao

, et al. Preparation of graphene oxide/chitosan complex and its adsorption properties for heavy metal ions. Green Process Synth 2020; 9: 294–303.

Synthesis of a magnetic NiFe 2 O 4 @graphene oxide nanocomposite for efficient and rapid lead(II) ion removal from water

Abstract

Keywords

Get full access to this article

References