Abstract
Development and application of low-cost and effective adsorbents to remove polycyclic aromatic hydrocarbons from effluents has become a research focus in recent years. We selected reed stem, ginkgo nut shell and hazelnut shell as adsorbents, and used acid hydrolysis as a simple modification technology. The adsorption isotherms of naphthalene to raw and modified adsorbents were controlled by partitioning. The adsorption capability of the hydrolysed hazelnut shell was notably enhanced at a higher level compared with that of other adsorbents. Results showed that the adsorption capacity (17250.42 μg/g) of modified hazelnut shell was observed for an initial naphthalene concentration of 25mg/L, with a contact time of 72 h, adsorbent dosage of 1 g/L and initial pH of 7.0. Furthermore, the regeneration capability of hydrolyzed hazelnut shell indicated that it was a promising adsorbent for naphthalene removal in wastewater treatment.
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References
V. Kavitha, A. B. Mandal and A. Gnanamani, Int. Biodeter. Biodegr., 94, 24 (2014).
M. Kim, S. H. Hong, J. Won, U. H. Yim, J. H. Jung, S. Y. Ha, J. G. An, C. Joo, E. Kim, G. M. Han, S. Baek, H. W. Choi and W. J. Shim, Water Res., 47(2), 758 (2013).
W. Yang, Y. H. Lang, J. Bai and Z. Y. Li, Ecol. Eng., 74, 117 (2015).
J. Lee, S. W. Chun, H. J. Kang and F. Talke, Macromol. Res., 19(6), 582 (2011).
Q. Shi, A. Li, Z. Zhu and B. Liu, J. Environ. Sci., 25(1), 188 (2013).
M. Anbia and S. E. Moradi, Chem. Eng. J., 148(2–3), 452 (2009).
S. Changchaivong and S. Khaodhiar, Appl. Clay Sci., 43(3–4), 317 (2009).
R. J. Krupadam, M. S. Khan and S. R. Wate, Water Res., 44(3), 681 (2010).
A. Rubio-Clemente, R. A. Torres-Palma and G. A. Peñuela, Sci. Total Environ., 478, 201 (2014).
X. Xia, G. Li, Z. Yang, Y. Chen and G. H. Huang, Environ. Pollut., 157(4), 1352 (2009).
C. Sakulthaew, S. Comfort, C. Chokejaroenrat, C. Harris and X. Li, Chemosphere, 117, 1 (2014).
Z. C. Zeledón-Toruño, C. Lao-Luque, F. X. C. de las Heras and M. Sole-Sardans, Chemosphere, 67(3), 505 (2007).
Y. Zhou, P. Lu and J. Lu, Carbohyd. Polym., 88(2), 502 (2012).
M. À. Olivella, P. Jové, A. Bianchi, C. Bazzicalupi and L. Cano, Chemosphere, 90(6), 1939 (2013).
B. Cabal, T. Budinova, C. O. Ania, B. Tsyntsarski, J. B. Parra and B. Petrova, J. Hazard. Mater., 161(2–3), 1150 (2009).
Z. Xi and B. Chen, J. Environ. Sci., 26(4), 737 (2014).
S. Valili, G. Siavalas, H. K. Karapanagioti, I. D. Manariotis and K. Christanis, J. Environ. Manage., 128, 252 (2013).
S. Rangabhashiyam, E. Nakkeeran, N. Anu and N. Selvaraju, Res. Chem. Intermed., 41, 8405 (2015).
S. Rangabhashiyam and N. Selvaraju, J. Mol. Liq., 207, 39 (2015).
L. Huang, T. B. Boving and B. Xing, Environ. Sci. Technol., 40(10), 3279 (2006).
B. Chen, M. Yuan and H. Liu, J. Hazard. Mater., 188(1–3), 436 (2011).
B. Chen and M. Yuan, J. Soils Sediment., 11(1), 62 (2011).
R. Crisafully, M. A. L. Milhome, R. M. Cavalcante, E. R. Silveira, D. De Keukeleire and R. F. Nascimento, Bioresour. Technol., 99(10), 4515 (2008).
C. O. Ania, B. Cabal, C. Pevida, A. Arenillas, J. B. Parra, F. Rubiera and J. J. Pis, Appl. Surf. Sci., 253(13), 5741 (2007).
C. F. Chang, C. Y. Chang, K. H. Chen, W. T. Tsai, J. L. Shie and Y. H. Chen, J. Colloid Interf. Sci., 277(1), 29 (2004).
S. Baidas, B. Gao and X. Meng, J. Hazard. Mater., 189(1–2), 54 (2011).
M. Miao, H. Jiang, B. Jiang, S. W. Cui, Z. Jin and T. Zhang, Food Res. Int., 49(1), 303 (2012).
J. Liu, Y. Cheng, C. Liu, C. Zhang and Z. Wang, Sci. Hortic-Amsterdam, 150, 348 (2013).
J. Liu, Y. Cheng, K. Yan, Q. Liu and Z. Wang, Sci. Hortic-Amsterdam, 136, 128 (2012).
I. Langmuir, J. Am. Chem. Soc., 40, 1361 (1918).
H. Freundlich, Methuen, London, UK (1926).
S. Lagergren, Handlingar, 24, 1 (1898).
Y. S. Ho and G. Mckay, Process Biochem., 34, 451 (1999).
J. S. Cao, J. X. Lin, F. Fang, M. T. Zhang and Z. R. Hu, Bioresour. Technol., 163, 199 (2014).
C. K. Jain and M. K. Sharma, Water Air Soil Pollut., 137(1–4), 1 (2002).
M. YalÇin, A. GÜrses, Ç. Doğar and M. SÖZbİLİr, Adsorption, 10(4), 339 (2005).
S. S. Banerjee, M. V. Joshi and R. V. Jayaram, Chemosphere, 64(6), 1026 (2006).
Y. Li, B. Chen and L. Zhu, Bioresour. Technol., 101(19), 7307 (2010).
L. Xu, M. Zhang and L. Zhu, Appl. Clay Sci., 100, 29 (2014).
M. Novoszad, M. H. Gerzabek, G. Haberhauer, M. Jakusch, H. Lischka, D. Tunega and H. Kirchmann, Chemosphere, 59(5), 639 (2005).
B. E. Whitman, J. R. Mihelcic and D. R. Lueking, Appl. Microbiol. Biot., 43(3), 539 (1995).
W. Yang, D. Lampert, N. Zhao, D. Reible and W. Chen, J. Soils Sediment., 12(5), 713 (2012).
M. G. R. Vianna, J. Dweck, F. Quina, F. S. Carvalho and C. O. Nascimento, J. Therm. Anal. Calorim., 100(3), 889 (2010).
X. Shen, X. Wang, S. Tao and B. Xing, Environ. Sci. Pollut. Res., 21(20), 11979 (2014).
X. Cheng, A. Kan and M. Tomson, J. Nanopart. Res., 7(4–5), 555 (2005).
S. Y. Lee and S. J. Kim, Appl. Clay Sci., 22(1–2), 55 (2002).
X. Ruan, P. Sun, X. Ouyang and G. Qian, Chinese Sci. Bull., 56(32), 3431 (2011).
S. Ibrahim, S. Wang and H. M. Ang, Biochem. Eng. J., 49(1), 78 (2010).
S. Şener and A. Özyılmaz, Ultrason. Sonochem., 17(5), 932 (2010).
X. Yang, J. Li, T. Wen, X. Ren, Y. Huang and X. Wang, Colloids Surf., A: Physicochemical and Engineering Aspects, 422, 118 (2013).
M. K. Chung, M. T. K. Tsui, K. C. Cheung, N. F. Y. Tam and M. H. Wong, Sep. Purif. Technol., 54(3), 355 (2007).
G. Liu, J. Ma, X. Li and Q. Qin, J. Hazard. Mater., 164(2), 1275 (2009).
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Zhu, M., Tian, W., Chai, H. et al. Acid-hydrolyzed agricultural residue: A potential adsorbent for the decontamination of naphthalene from water bodies. Korean J. Chem. Eng. 34, 1073–1080 (2017). https://doi.org/10.1007/s11814-016-0348-3
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DOI: https://doi.org/10.1007/s11814-016-0348-3