The Use of Pre-heated Black Cumin Seeds (Nigella sativa) for Sorption Basic Dyes from Aqueous Solutions

Hassan, Afrah Abood; Al-Isawi, Rawaa; Saleh, Zahra Abd

doi:10.12911/22998993/141586

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Tytuł artykułu

The Use of Pre-heated Black Cumin Seeds (Nigella sativa) for Sorption Basic Dyes from Aqueous Solutions

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Hassan Afrah Abood , Al-Isawi Rawaa , Saleh Zahra Abd

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DOI

10.12911/22998993/141586

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Abstrakty

The discharge of industrial effluents containing dyes such as methylene blue (MB) and safranine T (ST) into water resources has caused serious problems for humans and organisms which live in water. On the other hand, the seeds of nigella sativa have been known to be effective and economical materials that present an excellent performance of dye removal from various types of wastewater. In this study, a different method from the existing literature was used, where the black cumin seeds (HBCS) were heated for a twenty-four hour period at 85 °C and ground to 300 µm particle size to obtain new adsorbents for (MB) and (ST) dye adsorption from aqueous solutions. Four operating variables, which show a strong impact on adsorption, were tested by conducting a batch mode adsorption experiment and these were: the dye solution’s initial pH (pH), the contact time (t), the initial concentration of the dye (C_o), and the mass of the adsorbent (m_a). The sorption capacity of the adsorbent (q) and the dye removal efficiency (% Rem) were utilized as indicators of the impacts of selected operating variables on adsorption processes. It was found that the adsorption of MB and ST dyes increased when the initial concentration of the solution is higher. The adsorption of MB and ST dyes onto HBCS with initial concentration of 50 mg/L was 3.39 mg/g and 4.36 mg/g, respectively. The equilibrium values for the MB and ST dyes corresponded with the Freundlich isotherm model onto HBCS highlighting the multi-layer adsorption process occurring which describes the interactions between the modified HBCS and the two dyes. The findings demonstrate that the optimum adsorption processes of the MB and ST dyes accrued in the 120 minutes and obtained at pH 10.7 and 11 for MB and ST, respectively. These conditions provide a negative charge for the surface of HBCS, causing its attraction to the positive charge of the MB and ST dyes. Kinetic studies elucidated that the MB and ST dyes adsorption onto HBCS most corresponded with pseudo-second order. The findings of this study could be implemented functionally in the industrial wastewater treatment sector.

Słowa kluczowe

basic dye kinetics sorption black cumin equilibrium Nigella sativa isotherm model

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2021

Tom

Vol. 22, nr 9

Strony

149--158

Opis fizyczny

Bibliogr. 30 poz., rys., tab.

Twórcy

autor

Hassan Afrah Abood

Environmental Engineering Department, College of Engineering, University of Babylon, Babel, Iraq

autor

Al-Isawi Rawaa

eng.rawaa.alisawi@uobabylon.edu.iq

Environmental Engineering Department, College of Engineering, University of Babylon, Babel, Iraq

https://orcid.org/0000-0003-3662-8716

autor

Saleh Zahra Abd

Civil Engineering Department, College of Engineering, University of Babylon, Babel, Iraq

Bibliografia

1. Abdel-Ghani N.T., El-Chaghaby G.A., Rawash E.S.A., Lima E.C. 2019. Magnetic activated carbon nanocomposite from Nigella sativa L. waste (MNSA) for the removal of Coomassie brilliant blue dye from aqueous solution: Statistical design of experiments for optimization of the adsorption conditions. J Adv Res, 17, 55–63.
2. Abukhadra M.R., Mohamed A.S. 2019. Adsorption Removal of Safranin Dye Contaminants from Water Using Various Types of Natural Zeolite. Silicon, 11(3), 1635–1647.
3. Al-Ghouti M.A., Al-Absi R.S. 2020. Mechanistic understanding of the adsorption and thermodynamic aspects of cationic methylene blue dye onto cellulosic olive stones biomass from wastewater. Sci Rep, 10(1), 1–18.
4. Bayomie O.S., Kandeel H., Shoeib T., Yang H., Youssef N., El-Sayed M.M.H. 2020. Novel approach for effective removal of methylene blue dye from water using fava bean peel waste. Sci Rep, 10(1), 1–10.
5. Benjelloun M., Miyah Y., Akdemir Evrendilek G., Zerrouq F., Lairini S. 2021. Recent Advances in Adsorption Kinetic Models: Their Application to Dye Types. Arab J Chem, 14(4), 103031.
6. Freundlich H.M.F. 1906. Over the Adsorption in Solution. J Phys Chem, 57, 385–471.
7. Gisi S.D., Lofrano G., Grassi M., Notarnicola M. 2016. Characteristics and adsorption capacities of low-cost sorbents for wastewater treatment: A review. Sustain Mater Technol, 9, 10–40.
8. Ho Y., McKay G. 1999. Pseudo-second order model for sorption processes. Process Biochem, 34(5), 451–465.
9. Hynes N.R.J., Kumar J.S., Kamyab H., Sujana J.A.J., Al-Khashman O.A., Kuslu Y., Ene A., Suresh Kumar B. 2020. Modern enabling techniques and adsorbents based dye removal with sustainability concerns in textile industrial sector -A comprehensive review. J Clean Prod, 272, 122636.
10. Katheresan V., Kansedo J., Lau S.Y. 2018. Efficiency of various recent wastewater dye removal methods: A review. J Environ Chem Eng, 6(4), 4676–4697.
11. Kocaman S. 2020. Removal of methylene blue dye from aqueous solutions by adsorption on levulinic acid-modified natural shells. Int J Phytoremediation, 22(8), 885–895.
12. Lagergren S. 1898. About the theory of so-called adsorption of soluble substances, Zur theorie der sogenannten adsorption gelster stoffe. K Sven Vetenskapsakademiens, Handl Band, 24, 1–39.
13. Langmuir I. 1918. The adsorption of gases on plane surfaces of glass, mica and platinum. J Am Chem Soc, 40(9), 1361–1403.
14. Lellis B., Fávaro-Polonio C.Z., Pamphile J.A., Polonio J.C. 2019. Effects of textile dyes on health and the environment and bioremediation potential of living organisms. Biotechnol Res Innov, 3(2), 275–290.
15. Maia L.S., Duizit L.D., Pinhatio F.R., Mulinari D.R. 2021. Valuation of banana peel waste for producing activated carbon via NaOH and pyrolysis for methylene blue removal. Carbon Lett, 31(4), 749–762.
16. Paredes-Quevedo L.C., González-Caicedo C., Torres-Luna J.A., Carriazo J.G. 2021. Removal of a Textile Azo-Dye (Basic Red 46) in Water by Efficient Adsorption on a Natural Clay. Water, Air, Soil Pollut, 232(1), 4.
17. Qurratulane B., Bhardwaj N. 2014. Role of BioSorbents in The Decolorization of Some Commonly Used Dyes. J Sci, 4(10), 637–642.
18. Rahman H.H.A., Moustafa A.H.E., Kassem M.G. 2015. Black cumin (Nigella sativa) as Low Cost Biosorbent For the Removal of Toxic Cu (II) and Pb (II) From Aqueous Solutions. Int J Eng Technol, 15(2), 46–66.
19. Rakass S., Mohmoud A., Hassani H.O., Abboudi M., Kooli F., Wadaani F.A. 2018. Modified nigella sativa seeds as a novel efficient natural adsorbent for removal of methylene blue dye. Molecules, 23(8).
20. Senthil Kumar P., Palaniyappan M., Priyadharshini M., Vignesh A.M., Thanjiappan A., Sebastina Anne Fernando P., Tanvir Ahmed R., Srinath R. 2014. Adsorption of basic dye onto raw and surface-modified agricultural waste. Environ Prog Sustain Energy, 33(1), 87–98.
21. Shindhal T., Rakholiya P., Varjani S., Pandey A., Ngo H.H., Guo W., Ng H.Y., Taherzadeh M.J. 2021. A critical review on advances in the practices and perspectives for the treatment of dye industry wastewater. Bioengineered, 12(1),70–87.
22. Siddiqui S.I., Rathi G., Chaudhry S.A. 2018. Qualitative analysis of acid washed black cumin seeds for decolorization of water through removal of highly intense dye methylene blue. Data Br, 20,1044–1047.
23. Siddiqui S.I., Zohra F., Chaudhry S.A. 2019. Nigella sativa seed based nanohybrid composite-Fe2O3–SnO2/BC: A novel material for enhanced adsorptive removal of methylene blue from water. Environ Res, 178, 108667.
24. Soleimani H., Mahvi A.H., Yaghmaeian K., Abbasnia A., Sharafi K., Alimohammadi M., Zamanzadeh M. 2019. Effect of modification by five different acids on pumice stone as natural and low-cost adsorbent for removal of humic acid from aqueous solutions ‐ Application of response surface methodology. J Mol Liq, 290, 111181.
25. Srinivasan K. 2018. Cumin (Cuminum cyminum) and black cumin (Nigella sativa) seeds: traditional uses, chemical constituents, and nutraceutical effects. Food Qual Saf, 2(1), 1–16.
26. Tara N., Siddiqui S.I., Rathi G., Chaudhry S.A., Inamuddin, Asiri A.M. 2020. Nano-engineered Adsorbent for the Removal of Dyes from Water: A Review. Curr Anal Chem, 16(1), 14–40.
27. Thabede P.M., Shooto N.D., Naidoo E.B. 2020. Removal of methylene blue dye and lead ions from aqueous solution using activated carbon from black cumin seeds. South African J Chem Eng, 33(April), 39–50.
28. Wong S., Ghafar N.A., Ngadi N., Razmi F.A., Inuwa I.M., Mat R., Amin N.A.S. 2020. Effective removal of anionic textile dyes using adsorbent synthesized from coffee waste. Sci Rep, 10(1), 1–13.
29. Wu J., Xia A., Chen C., Feng L., Su X., Wang X. 2019. Adsorption Thermodynamics and Dynamics of Three Typical Dyes onto Bio-adsorbent Spent Substrate of Pleurotus eryngii. Int J Environ Res Public Health, 16(5), 679.
30. Xia X., Zhou Z., Wu S., Wang D., Zheng S., Wang G. 2018. Adsorption removal of multiple dyes using biogenic selenium nanoparticles from an escherichia coli strain overexpressed selenite reductase CsrF. Nanomaterials, 8(4), 1–15.

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Bibliografia

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