Evaluation of potentially toxic metal biosorption kinetics Mn (II) in acai pit residues (Euterpe Oleracea Mart.)
Avaliação da cinética de biossorção do íon Mn (II) em resíduos de caroço de açaí (Euterpe oleracea Mart.) in natura e na forma de carvão ativado em HCl
DOI:
https://doi.org/10.53660/CLM-1024-23C40Palavras-chave:
Resíduo de açaí; Carvão vegetal; Biossorção; Estudo cinético; PSO;Resumo
Contamination of ecosystems with industrial and population advances has caused numerous problems to the environment and human health, as inappropriate disposal of effluents contaminated by potentially toxic metals impairs soil and groundwater. A low-cost and efficient alternative for the removal of these metals is biosorption which can be performed through biosorbents such as the açai pit residue (Euterpe Oleracea Mart.). This work evaluates the reuse of acai pit waste in fresh form and as chemically activated charcoal with HCl in Mn (II) ions biosorption. The reuse of acai residue as Mn (II) ions biosorbent has shown good biosorption capabilities, and modified biomass performed better performance in a shorter contact time than fresh (186.72 mg kg-1 in 10 hours). The kinetic study according to PFO, PSO, ELOVICH, and intraparticle biomass diffusion models in fresh and chemically modified form has shown for both better adjustment to the pseudo-second-order model, indicating that the Mn (II) ion biosorption process occurs via chemiosorption.
Downloads
Referências
CORDEIRO, M. D. A.; ALMEIDA, O. DE; ROCHA DE CASTRO, D. A.; SILVA RIBEIRO, H. J. DA; MACHADO, N. T. HIDRÓLISE ENZIMÁTICA DO CAROÇO DE AÇAÍ (Euterpe oleracea Mart) PARA A PRODUÇÃO DE ETANOL. Revista Brasileira de Energias Renováveis, v. 8, n. 1, 2019.
ELOVICH, S.Y., LARINOV, O. . Theory of adsorption from solutions of non-electrolytes on solid (I) equation adsorption from solutions and the analysis of its simplest form, (II) verification of the equation of adsorption isotherm from solutions. Izv. Akad. Nauk. SSSR, v. 2, p. 209–216, 1962.
FARINAS, C. S.; SANTOS, R. R. M. DOS; NETO, V. B.; PESSOA, J. D. C. Aproveitamento do caroço do açai como substrato para produção de enzimas por fermentação em estado sólido. Boletim de Pesquisa e Desenvolvimento. 2009.
FAWZY, M. A. Biosorption of copper ions from aqueous solution by Codium vermilara: Optimization, kinetic, isotherm and thermodynamic studies. Advanced Powder Technology, v. 31, n. 9, p. 3724–3735, 2020.
GUO, X.; WANG, J. A general kinetic model for adsorption: Theoretical analysis and modeling. Journal of Molecular Liquids, v. 288, p. 111100, 2019.
HAMMO, M. M.; AKAR, T.; SAYIN, F.; CELIK, S.; AKAR, S. T. Efficacy of green waste-derived biochar for lead removal from aqueous systems: Characterization, equilibrium, kinetic and application. Journal of Environmental Management, v. 289, p. 112490, 1 jul. 2021.
HO, Y.S.; MCKAY, G. Pseudo-second order model for sorption processes. Process Biochemistry 34 (1999) 451–465, v. 43, n. 5, p. 451–465, 1999.
HO, Y. S.; MCKAY, G. Sorption of dye from aqueous solution by peat. Chemical Engineering Journal, v. 70, n. 2, p. 115–124, 1998.
LAGERGREN, S. About the theory of so-called adsorption of soluble substances. K. Svenska Vetenskapsakad. Handl, v. 24, p. 1–39, 1898.
MENEZES, C. J. M.; MARIA DA SILVA BENTO, A.; JOSÉ DE PAULA FILHO, F.; MARTINS DA COSTA, J. G.; MELO COUTINHO, H. D.; PEREIRA TEIXEIRA, R. N. Kinetic and thermodynamic study of copper (II) IONS biosorption by Caryocar Coriaceum Wittm bark. Sustainable Chemistry and Pharmacy, v. 19, p. 100364, 1 abr. 2021.
NASCIMENTO, J.M.; OLIVEIRA, J. D. .; LEITE, S. G. F. Chemical characterization of biomass flour of the babassu coconut mesocarp (Orbignya speciosa) during biosorption process of copper ions. Environmental Technology & Innovation, v. 16, p. 100440, nov. 2019.
NASCIMENTO, R.F.; LIMA, A.C.A., VIDAL, C.B.; MELO, D.Q.; RAULINO, G. S. C. ADSORÇÃO : aspectos teóricos e aplicações ambientais. 2014.
NASCIMENTO, J. M.; CRUZ, N. D.; OLIVEIRA, G. R. DE; SÁ, W. S.; OLIVEIRA, J. D. DE; RIBEIRO, P. R. S.; LEITE, S. G. F. Evaluation of the kinetics of gold biosorption processes and consequent biogenic synthesis of AuNPs mediated by the fungus Trichoderma harzianum. Environmental Technology and Innovation, v. 21, p. 101238, 2021.
NASCIMENTO, J. M.; OLIVEIRA, J. D. Characterizing the pequi bark (caryocar brasiliense camb.) and teak sawdust (tectona grandis) biomasses in natura, or modified with citric acid, according to boehm’s methodology . Revista Virtual de Quimica, 2017.
NASCIMENTO, J. M.; SANTOS, J. J. S.; NASCIMENTO, R. M.; OLIVEIRA, J. D. Comparison of the biossorption potential of highly toxic metals Cd(II) and Pb(II) in in natura biomasses from the peel of pequi (Caryocar brasiliense Camb), sawdust Teca wood (Tectona grandis) and wooden ear (Pycnoporus sanguineus). Revista de Química Industrial, v. 748, p. 25, 2015.
OTHMANI, A.; MAGDOULI, S.; SENTHIL KUMAR, P.; KAPOOR, A.; CHELLAM, P. V.; GÖKKUŞ, Ö. Agricultural waste materials for adsorptive removal of phenols, chromium (VI) and cadmium (II) from wastewater: A review. Environmental Research, v. 204, n. May 2021, 2022.
RAMBABU, K.; BHARATH, G.; BANAT, F.; SHOW, P. L. Biosorption performance of date palm empty fruit bunch wastes for toxic hexavalent chromium removal. Environmental Research, v. 187, n. March, p. 109694, 2020.
RWIZA, M. J.; OH, S. Y.; KIM, K. W.; KIM, S. D. Comparative sorption isotherms and removal studies for Pb(II) by physical and thermochemical modification of low-cost agro-wastes from Tanzania. Chemosphere, v. 195, p. 135–145, 2018.
SILVA, M. P.; CUNHA, V. M. B.; SOUSA, S. H. B.; MENEZES, E. G. O.; BEZERRA, P. D. N.; FARIAS NETO, J. T. DE; FILHO, G. N. R.; ARAÚJO, M. E.; CARVALHO, R. N. DE. Supercritical CO2 extraction of lyophilized Açaí (Euterpe oleracea Mart.) pulp oil from three municipalities in the state of Pará, Brazil. Journal of CO2 Utilization, v. 31, p. 226–234, 1 maio 2019.
SOUZA, J. I. DE; SCHOENLEIN-CRUSIUS, I. H.; PIRES-ZOTTARELLI, C. L. A.; SCHOENLEIN, N. C. Biossorção de cobre, manganês e cádmio por biomassas de Saprolegnia subterranea (Dissmann) R.L. Seym. e Pythium torulosum Coker & P. Patt. (Oomycetes). Acta Botanica Brasilica, v. 22, n. 1, p. 217–223, 2008.
SPAIN, O.; PLÖHN, M.; FUNK, C. The cell wall of green microalgae and its role in heavy metal removal. Physiologia Plantarum, v. 173, n. 2, p. 526–535, 2021.
SYEDA, H. I.; SULTAN, I.; RAZAVI, K. S.; YAP, P. S. Biosorption of heavy metals from aqueous solution by various chemically modified agricultural wastes: A review. Journal of Water Process Engineering, v. 46, p. 102446, 1 abr. 2022.
TALUKDAR, D.; JASROTIA, T.; SHARMA, R.; JAGLAN, S.; KUMAR, RAJEEV; VATS, R.; KUMAR, RAMAN; MAHNASHI, M. H.; UMAR, A. Evaluation of novel indigenous fungal consortium for enhanced bioremediation of heavy metals from contaminated sites. Environmental Technology and Innovation, v. 20, p. 101050, 2020.
VILLEN-GUZMAN, M.; GUTIERREZ-PINILLA, D.; GOMEZ-LAHOZ, C.; VEREDA-ALONSO, C.; RODRIGUEZ-MAROTO, J. M.; ARHOUN, B. Optimization of Ni (II) biosorption from aqueous solution on modified lemon peel. Environmental Research, v. 179, p. 108849, 1 dez. 2019.
WEBER, W.J.; MORRIS, J. C. Advances in water pollution research: removal of biologically resistant pollutants from wastewaters by adsorptionProceedings of International Conference on Water Pollution Symposium. Anais...Oxford: Pergamon Press, 1962.
XU, S.; XING, Y.; LIU, S.; HAO, X.; CHEN, W.; HUANG, Q. Characterization of Cd2+ biosorption by Pseudomonas sp. strain 375, a novel biosorbent isolated from soil polluted with heavy metals in Southern China. Chemosphere, v. 240, p. 124893, 2020.
ZHANG, J. WEI; BI, F. ZHI; WANG, Q. JIA; WANG, W. LIN; LIU, B.; LUTTS, S.; WEI, W.; ZHAO, Y. PING; WANG, G. XIANG; HAN, R. MING. Characteristics and influencing factors of cadmium biosorption by the stem powder of the invasive plant species Solidago canadensis. Ecological Engineering, v. 121, n. February 2017, p. 12–18, 2018.