光谱学与光谱分析 |
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Study on Kinetic of Hg2+ from Wastewater Absorbed by Lemon Residues |
SHEN Wang-qing1, 2, WANG Miao1, YANG Ting1 |
1. College of Chemistry and Chemical Engineering, Neijiang Normal University, Neijiang 641100, China 2. Key Laboratory for Fruit Waste Treatment and Resource Recycling of Sichuan Provincial College, Neijiang 641100, China |
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Abstract With low price and its superior adsorption performance after modification, currently agricultural waste is used as adsorbent of heavy metals in wastewater, which has become a hot research topic. To study on Hg2+ from wastewater absorbed by lemon residues that has been modified by 15% concentration of sulphuric acid. The pore volume, pore size and other properties of the adsorbent were test. The samples were characterized by differential thermal analysis, IR, electron microscopy and spectroscopy. The result showed that the adsorption rate was controlled by membrane diffusion kinetics that was viewed as the first order kinetics equation of the Lagergren, which was physically absorbed. The adsorption properties of modified lemon residues were improved greatly, and the pore size distribution mainly was medium. There were three losses-weight process. There was a endothermic peak around 66 ℃ and two exotherm near 316 ℃ and 494 ℃. Basic framework of Lemon residues was not changed and structure of Lemon residues was amorphous; the surface of modified lemon residues loosen and many pores formed, and Hg2+ have been adsorbed effectively.
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Received: 2015-10-04
Accepted: 2016-01-25
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Corresponding Authors:
SHEN Wang-qing
E-mail: sqw7418@163.com
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[1] Liu C, Huang Y, Naismith N, et al. Environmental Science & Technology, 2003, 37(18): 4261. [2] GUO Xue-yi, LIANG Sha, XIAO Cai-mei, et al(郭学益, 梁 莎, 肖彩梅, 等). The Chinese Journal of Nonferrous Metals(中国有色金属学报), 2011, 21(9): 2270. [3] Zhan taoyang, Dudley K Strickland, Paul Bornstein. The Journalof Biological Chemistry, 2001, 276(11): 8403. [4] Hutchison A R, Atwood D A. Journal of Chemical Crystallography, 2003, 33(8): 631. [5] Palma G, Freer J, Baeza J. Water Research, 2003, 37(20): 4974. [6] Roundhill D M, Solangi I B, Memon S, et al. Partical Journal of Analytical Environmental Chemistry, 2009, 10(1/2): 1. [7] Esbrí J M, Bernaus A, Avila M, et al. Journal of Synchrotron Radiation, 2010, 17(2): 179. [8] LI Cen, ZHAN Dui, LENGBEN Cai-rang, et al(李 岑, 占 堆, 楞本才让, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2015, 35(4): 1072. [9] Acouea R A, Limaa E C,Diass L P, et al. Separation and Purification Technology, 2007, 57(1): 193. [10] Prasad R, Ghimire K N, Inoue K. Hydrometallurgy, 2005, 79(3/4): 182. [11] Ghimire K N, Inoue K, Yaimaguchi H, et al. Water Research, 2003, 37(20): 4945. [12] LIANG Sha, GUO Xue-yi, FENG Ning-chuan, et al. Journal of Hazardous Materials, 2009, 170(1): 425. [13] Brownp P, Jefcoat I A, Parrish D, et al. Advanced Environmental Resources, 2000, 4(1): 19. [14] Iqbal M, Saeed A, Iqbal Z S. Journal of Hazardous Materials, 2009, 164(1): 161. [15] Farinella N V, Matos G D, Arruda M A Z. Bioresource Technology, 2007, 98(10): 1940. [16] Annadurai A, Juang R S, Lee D J. Water Sci. Technol., 2002, 47(1): 185. [17] Adam J Janńczuk, David Agyemang, Neil C Da Costa, et al. Biochimica et Biophysica Acta, 2013, (1834):1484. [18] Tembhurkar A R,Radhika Deshpande. Journal of Hazardous, Toxic, and Radio Active Waste, 2012, 16:311. [19] Catia Giovanna Lopresto, Francesca Petrillo, Alessandro Alberto Casazza, et al. Separation and Purification Technology, 2014, 137(1):13. [20] María Boluda-Aguilar, Antonio López-Gómez. Industrial Crops and Products , 2013, 41(1):188. [21] SHEN Wang-qing, WEI Xi-jun, TANG Xue, et al(沈王庆, 魏锡均, 唐 雪, 等). Science and Technology of Food Industry(食品工业科技), 2015, 36(15): 224. [22] Noeline B F, Manohar D M, Anirudhan T S, et al. Sep. Purif. Technol.,2005, 45(1):131. [23] Zhan Honglei, Wu Shixiang, Bao Rima, et al. The Royal Society of Chemistry, 2015, 5:14389. [24] Vania Marilyn Marin-Rangel, Raul Cortes-Martinez, Ruth Alfaro Cuevas Villanueva, et al. Journal of Food Science, 2012, 71(1):10. [25] RAN Jing, HUANG Xiu-li, WANG Yang-ping, et al(冉 敬,黄秀丽,汪阳平,等). Hubei Agricultural Sciences(湖北农业科学),2015, 54(17): 4177. [26] SUN Xu-bing, ZHOU Wen-jun, ZHAI Hao-ying(孙绪兵,周文俊,翟好英). New Chemical Materials(化工新型材料),2015, 43(3): 176. [27] Lipponer M A, Dürr A. Chemical Physics Letters, 2015, (624): 69. [28] Xu Xiaojian, Deng Zichen. Multidiscipline Modeling in Materialsand Structures, 2013, 9(1):116. [29] Susanna Monti, Vincenzo Carravetta, Li Cui, et al. The Journal of Physical Chemistry C, 2014, 118, 3610. [30] Mingxin Liu, Dong Zhen, Lai Yanhua. Heat Transfer Research,2015, 46(4):369. [31] Pradip B Shelke, Limaye A V. Surface Science 2015, (1-4):637. [32] Layla A Al Juhaiman, Amal Abu Mustafa, Wafaa K Mekhamer. Anti-Corrosion Methods and Materials, 2013, 60(1):28. [33] Piotr Zarzycki, Sebastien Kerisit, Kevin M. The Journal of Physical Chemistry C, 2015, 119, 3111. |
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