پیوندهای مفید
اخبار و اعلانات
آمار
| تعداد نشریات | 158 |
| تعداد شمارهها | 6,226 |
| تعداد مقالات | 67,700 |
| تعداد مشاهده مقاله | 115,008,831 |
| تعداد دریافت فایل اصل مقاله | 89,690,849 |
ارزیابی عملکرد جاذب طبیعی ریشۀ زرشک در حذف کروم از محیط آبی (مطالعۀ موردی: منابع آب زیرزمینی بیرجند) | ||
| محیط شناسی | ||
| مقاله 8، دوره 41، شماره 4، اسفند 1394، صفحه 827-840 اصل مقاله (1.01 M) | ||
| نوع مقاله: مقاله پژوهشی | ||
| شناسه دیجیتال (DOI): 10.22059/jes.2016.57137 | ||
| نویسندگان | ||
| علی شهیدی1؛ عباس خاشعی سیوکی2؛ زهرا زراعتکار* 3 | ||
| 1دانشیار گروه مهندسی آب، دانشگاه بیرجند | ||
| 2استادیار گروه مهندسی آب، دانشگاه بیرجند | ||
| 3کارشناس ارشد مهندسی منابع آب، دانشگاه بیرجند | ||
| چکیده | ||
| از مهمترین نگرانیهای اخیر در خصوص فاضلابهای صنعتی، ورود فلزات سنگین به منابع آب و محیطزیست است. با توجه به خصوصیات سمی و خطرناک کروم ششظرفیتی، حذف آن از طریق روش کارآمد و اقتصادی، امری ضروری به نظر میرسد. هدف از این مطالعه بررسی کاربرد پودر ریشۀ زرشک در حذف کروم ششظرفیتی از پساب است. پس از آمادهسازی جاذب، اثر متغیرهای مختلفی از قبیل pH اولیۀ محلول، زمان واکنش، وزن جاذب، غلظت اولیۀ کروم و دما بررسی شد. نتایج نشان داد که کارایی حذف کروم ششظرفیتی با افزایش pH و غلظت اولیۀ کروم کاهش، در صورتی که با افزایش مقدار جاذب و مدت زمان تماس ذرات جاذب با محلول حاوی یون کروم، درصد حذف افزایش یافته است که در مدت زمان 90 دقیقه به حالت تعادل میرسد. حداکثر میزان ظرفیت جذب پودر ریشۀ زرشک برابر 92/23 میلیگرم بر گرم و بیشترین بازده جذب برای ریشۀ زرشک در دمای 50 درجه برابر 85/97 درصد به دست آمد. نتایج مطالعات تعادلی مشخص کرد که فرایند جذب از مدل سینتیکی شبه درجۀ اول اصلاحشده و مدل ایزوترمی لانگمیر (R2=0.99) پیروی میکند. بنابراین، میتوان نتیجه گرفت که ریشۀ زرشک بهمنزلۀ یک جاذب زیستی تجزیهپذیر و ارزانقیمت، عملکرد مناسبی برای حذف کروم از محلولهای آبی دارد. | ||
| کلیدواژهها | ||
| پساب؛ حذف؛ ریشۀ زرشک؛ کروم؛ فلزات سنگین | ||
| عنوان مقاله [English] | ||
| Performance Assessment of natural adsorbent using Barberry Root in the removal of Chromium from aqueous environment (Case study: Groundwater resource of Birjand) | ||
| نویسندگان [English] | ||
| Ali Shahidi1؛ Abbas Khashei-Siuki2؛ Zahra Zeraatkar3 | ||
| 1Associate professor, Department of Water Engineering, University of Birjand, Birjand, Iran | ||
| 2Assistant professor, Department of Water Engineering, University of Birjand, Birjand, Iran | ||
| 3MSc Water Resources Engineering, Department of Water Engineering, University of Birjand, Birjand, Iran | ||
| چکیده [English] | ||
| The potential sources of Cr (VI) are various effluents from metallurgy, electroplating, leather tanning, textile dyeing, paint, ink, and aluminum manufacturing industries. These industrial effluents can contain Cr (VI), in the concentration range of 10 to 100 mg/L (Nakano et al 2000), which is much higher than the standard limit; 0.5 mg/L in industrial wastewater (EPA). In aqueous systems, chromium usually exists in both trivalent [Cr (III)] and Cr (VI) forms. Although Cr (III) is considered an essential trace element, Cr (VI) is toxic, carcinogenic, mutagenic and teratogenic (Wittbrodt & Palmer 1995). Therefore, the removal of Cr (VI) from industrial wastewater is of particular concern. Advances in water and wastewater treatment technology need spur for the development of technologies that may be more effective and less costly. Nowadays, the contamination of water by toxic heavy metals through the discharge of industrial wastewater is a worldwide environmental problem that this pollution can also have a source of groundwater with the geological formation. There are various methods for removing heavy metals including chemical precipitation, membrane filtration, ion exchange, liquid extraction or electro-dialysis (Park 2007). However, these methods are not widely used due to their high cost and low feasibility for small-scale industries (Elangovan 2008). The widespread industrial use of low cost adsorbents for wastewater treatment is strongly recommended at present, due to their local availability, technical feasibility, engineering applicability and cost effectiveness (Girgis 2002; Serrano 2004). Most agriculture wastes or by products are considered to be low value products. As an alternative, a variety of inexpensive biomasses have been studied for their ability to remove Cr (VI) from aqueous solutions. Among these low cost adsorbents are microorganisms, seaweed, clay minerals, agricultural wastes, industrial wastes and various other low-cost materials (Bailay et al 1999; Dokken et al 1999; Park et al 2001; Selvi et al 2001; Rao et al 2002; Babel & Kurniawan 2003; Lakatos et al 2003; Yu et al 2003; Kobya 2004; Bishnoi et al 2004; Gupta & Ali 2004; Chun et al 2004; Grag et al 2004; Sheng et al 2004; Kobya et al 2005; Khezami & Capart 2005; Prasenjit & Sumathi, 2005; Sen et al 2005; Khosravi et al 2005 ; Verma et al 2006; Potgieter et al 2006; Wang & Qin 2006; Zulkali et al 2006; Yasemin et al 2007; Sciban et al 2007; Gerente et al 2007; Igwe et al 2007; Cetin et al 2007; Benhima et al 2008; Rocha et al 2009; Jaman et al 2009; Miralles et al 2010; Boudrahem et al 2011; Anwar et al 2010; Revathi et al 2012 ; Bai et al 2011; Ramalingam et al 2012). The dynamics is an essential aspect of the adsorption process especially for practical applications. Therefore, the present investigation has been undertaken for studying the dynamic behavior of adsorption through batch experiments performed under different conditions of contact time, pH, adsorbent, initial concentration, particle size and temperature. A well-fitted kinetic equation was used to evaluate the suitable operational conditions for the removal process, and a Langmuir-type isotherm was modeled using kinetic data and experimental results. Matherials & Methods Preparation of the soluble metal The stock solutions of Cr (VI) (1000 mg/l) were prepared by dissolving K2Cr2O7 (analytical reagent grade) in distilled water. The desired Cr (VI) concentrations were prepared from the stock solution by making fresh dilutions for each sorption experiment. The initial pH of the solution was adjusted by using a solution of HNO3 or NaOH. Preparation of adsorbent Barberry roots were collected from South Khorasan, Birjand areas and soaked in distilled water for 24 hr before putting in an oven at 70°C for 24 hours. Barberry roots using Mill Were powdered. Powders were sieved through a 100 mesh and were stored in a container away from moisture. Batch adsorption experiments Adsorption experiments were carried out in batch mode. In order to investigate the nature of Cr (VI), initially the effect of pH on percentage removal was carried out and then further experiments on the effect of contact time, adsorption weight, initial concentration and temperature were conducted by using optimized pH. Only one parameter was changed at a time while others were maintained constant. In the first set of experiment, percentage adsorption was studied at various pH of (1.5–9) at constant adsorbent weight of 0.1 g/100 ml, initial Cr (VI) of 50 ppm and the predetermined time (10min) in a rotary shaker at a speed of 200rpm using series of 100 mL Erlenmeyer flasks. Next second set of experiments were conducted with various contact time, initial Cr (VI) concentration (50ppm) at constant adsorbent weight (0.1 g/100 ml) and at optimized pH 1.5. In the third set of experiment adsorption weight was varied (0.05–1 g/100 ml) while other parameters such as initial Cr (VI) concentration (50 mg/l), optimum time (90min) and optimum solution pH kept constant. In the fourth set of experiment Cr (VI) concentration was varied (25–200 ppm) and in the last set of experiment, temperature was varied at six different temperatures viz., 22, 25, 35, 40, 45 and 50°C in a thermostat attached with a shaker. The constancy of the temperature was maintained with an accuracy of ± 0.5 ºC.22-50), and other optimum parameters kept constant. After completion of every set of experiments the supernatant was separated by filtration using Whatman filter paper and only 10ml of each sample was stored for residual chromium analysis. The pH of each solution was adjusted using required quantity of HNO3 or NaOH before mixing the adsorbent. Three replicates per sample were done and the average results are taken for calculation. The filtrate was analyzed using Atomic Absorption Spectrophotometry (AAS) (Shimadzu AA-6300; 228.63 nm). All the experiments were performed in. | ||
| کلیدواژهها [English] | ||
| Barberry Root, Cr (VI), Heavy metals, Removal, Wastewater | ||
| مراجع | ||
|
پرویزی مساعد، ح.، سبحان اردکانی، س.، حمیدیان، ا. م. 1391. «حذف فلزات سنگین Cr(VІ) و Zn(ІІ) از پساب توسط پوستۀ برنج»، نشریۀ محیطزیست طبیعی، مجلۀ منابع طبیعی ایران، دورۀ 65، شمارۀ 3، 315-327. تقیزاده، ع.ا.، خدادادی، م.، شهریاری، ط.، دری، ح.، زعفرانیه، م.، خسروی، ر. 1391. مجلۀ علمی دانشگاه علوم پزشکی بیرجند، شمارۀ 2، صص 173 تا 180. سمرقندی، م. ر.، عزیزیان، س.، شیرزاد سیبنی، م.، 1388. «حذف کروم ششظرفیتی از محیطهای آبی با استفاده از خاک ارۀ اصلاحشدۀ درخت راجی»، مطالعۀ تعادلی و سینتیکی، مجلۀ علمی دانشگاه علوم پزشکی و خدمات بهداشتی درمانی همدان، دورۀ شانزدهم، شمارۀ 4، صص 61- 67. شهریاری، ط.، معاشری، ن.، شریفزاده، غ. 1389. «غلظت کروم و مس در آبهای زیرزمینی و شبکۀ توزیع آب آشامیدنی شهر بیرجند در سال 1388-1389»، مجلۀ علمی دانشگاه علوم پزشکی بیرجند، صص 62- 67. غنیزاده، ق.، قانعیان، م. ت.، عسگری، ق. 1392. «کاربرد جاذب خاکستر استخوان در تصفیۀ آبهای آلوده با کروم ششظرفیتی»، مجلۀ دانشگاه علوم پزشکی قم، شمارۀ 2، صص 7- 16. فدایی، ا.، پورخباز، ع. ر.، نبی بیدهندی، غ. ر.، امیری، م. ج.، جمشیدی، ا.، و الهی، ه. 1390. «حذف کروم ششظرفیتی از محلولهای آبی به وسیلۀ کربن هستۀ سنجد و عناب و مقایسۀ آن با کربن فعال گرانولی»، فصلنامۀ محیطشناسی، شمارۀ 67: 49- 54. قانعیان، م. ت.، احرامپوش م. ح.، دهواری، م.، جمشیدی، ب.، امراللهی، م. 1391. فصلنامۀ علمی پژوهشی دانشکدۀ بهداشت یزد، شمارۀ 2، صص 19- 28. Agarwal, GS., Bhuptawat, HK. and Chaudhari, S. 2006. Biosorption of aqueous chromium(VI) by Tamarindus indica seeds, Bioresource Technology, 97: 949-56.
Azizian, S. 2004. Kinetics models of sorption: a theoretical study, Journal of Colloid and Interface Science, 276: 47-52.
Alvarez, P., Blanco, C. and Granda, M. 2006. The adsorption of Chromium (VI) from industrial wastewater by acid and base-activated lignocellulosic residues, Journal of Hazardous Materials, 144: 400-405.
Argun, M.E., Dursun, S., Ozdemir, C. and Karatas, M. 2006. Heavy metal adsorption by modified oak sawdust:Thermodynamics and kinetics, Journal of Hazardous Materials, 141:77-85.
Bansal, M., Singh, D. and Garg, VK. 2009. A comparative study for the removal of hexavalent chromium from aqueous solution by agriculture wastes carbons, Journal of Hazardous Materials,171: 83-92.
Babel, S., and Agustiono Kurniawan, T., 2004. Cr(VI) removal from Synthetic Waste Water using coconut shell Charcoal and commercial activated carbon modifiled. Chemosphere. 54: 951-967.
Choi, HD., Cho, JM., Baek, K., Yang, JS. and Lee, JY. 2009. Influence of Cationic Surfactant on Adsorption of Cr (VI) Onto Activated Carbon. Journal of Hazardous Materials,161(2-3):1565-1568.
Dakiky, M., Khamis, M., Manassra, A. and Mer'eb, M. 2002. Selective adsorption of chromium (VI) in industrial wastewater using low-cost abundantly available adsorbents, Advances in Environmental Research, 6: 533-40.
Di Natale, F., Lancia, A., Molino, A. and Musmarra, D. 2007. Removal of chromium ions form aqueous solutions by adsorption on activated carbon and char, Journal of Hazardous Materials,145: 381-90.
Dubey, SP., and Gopal, K. 2007. Adsorption of chromium (VI) on low cost adsorbents derived from agricultural waste material: A comparative study, Journal of Hazardous Materials,145: 465-70.
Gao, H., Liu, Y., Zeng, G., Xu, W., Xia, W., 2008. Characterization of Cr (VI) removal from aqueous solutions by a surplus agricultural waste-Rice straw, Journal of Hazardous Materials, 150:446–452.
Guo. Y., Qi, J., Yang, Sh, K.,Wang, Z., and Xu, H., 2002. Adsorption of Cr (VI) on micro- and mesoporous rice husk-based active carbon, Materials Chemistry and Physics, 78: 132-137
Gupta, VK., Rastogi, A. and Nayak, A. 2010. Adsorption studies on the removal of hexavalent chromium from aqueous solution using a low cost fertilizer industry waste material, Journal of Colloid and Interface Science, 342:135-41.
Gupta, R., and Mohapatra, H. 2003. Microbial biomass: An economical alternative for removal of heavy metals from waste water, Indian Journal of Experimental Biology, 41: 945-966.
Gupta, S. & Babu, BV. 2008. Removal of toxic metal Cr (VI) from aqueous solutions using sawdust as adsorbent: equilibrium, kinetics and regeneration studies. Chemical Engineering Journal, 150:352- 365.
Granados-Correa, F., and Jimenez-Becerril, J. 2009. Chromium (VI) adsorption on boehmite, Journal of Hazardous Materials, 162:1178-84.
Karthikeyan, T., Rajgopal, S. and Miranda, LR. 2005. Chromium (VI) adsorption from aqueous solution by Hevea Brasilinesis sawdust activated carbon, Journal of Hazardous Materials, 124: 192-9.
Klimaviciute, R., Bendoraitiene, J., Rutkaite, R. and Zemaitaitis, A. 2010. Adsorption of hexavalent chromium on cationic cross-linked starches of different botanic origins, Journal of Hazardous Materials, 181: 624-32.
Levankumar, L., Muthukumaran, V. and Gobinath, MB. 2009. Batch adsorption and kinetics of chromium (VI) removal from aqueous solutions by Ocimum americanum L, seed pods, Journal of Hazardous Materials, 161: 709-13.
Liu, Y.-g., Fan, T., Zeng, G.-m., Li, X., Tong, Q., Ye, F., Zhou, M., Xu, W.-h. and Huang, Y.-e. 2006. Removal of Cadmium and Zinc ions from aqueous solution by living Aspergillus niger. Transactions of Nonferrous Metals Society of China, 16(3): 681-686.
Malkoc, E., Nuhoglu, Y. and Dundar, M. 2006. Adsorption of chromium (VI) on pomace-An olive oil industry waste: Batch and column studies, Journal of Hazardous Materials,138: 142-51.
Mohan, D., and Pittman, Jr CU. 2006. Activated carbons and low cost adsorbents for remediation of tri- and hexavalent chromium from water, Journal of Hazardous Materials,137: 762-811.
Mohan, D., Rajput, S., Singh, VK., Steele, PH. and Pittman, Jr CU. 2011. Modeling and evaluation of chromium remediation from water using low cost bio-char, a green adsorbent, Journal of Hazardous Materials,188: 319-33.
Moussavi, G., and Khosravi, R. 2010 Removal of cyanide from wastewater by adsorption onto pistachio hull wastes: parametric experiments, kinetics and equilibrium analysis, Journal of Hazardous Materials, 183:724–730.
Pehlivan, E., Altun, T., 2008. Biosorption of chromium ion from aqueous solutions using Walnutm Hzalnut and Almond shell. Journal or Hazardous Materials, 155:378-384.
Park, D., Yun, Y.S. and Park, J.M. 2005. Studies on hexavalent chromium biosorption by chemically treated biomass of Ecklonia sp., Chemosphere, 60:1356–1364.
Pillay, K., Cukrowska, EM. and Coville, NJ. 2009. Multi-walled carbon nanotubes as adsorbents for the removal of parts per billion levels of hexavalent chromium from aqueous solution, Journal of Hazardous Materials, 166:1067-75.
Raji, C., Manju, G.N. and Anirudhan, T.S. 1997. Removal of heavy metals ions from water saw dust based activated carbon, Indian Journal of Engineering and Material Sciences, 4:254-260.
Rao, M., Pavwate, A.V. and Bhole, A.G. 2002. Removal of Cr and Ni from aqueous solution using bagasse and fly ash. Waste Management, 22:821-830.
Rodrigues, LA., Maschio, LJ., da Silva, RE. and da Silva, ML. 2010. Adsorption of Cr (VI) from Aqueous Solution by Hydrous Zirconium Oxide. Journal or Hazardous Materials, 173(1-3):630-636.
Schneider, RM., Cavalin, CF., Barros, MASD. and Tavares, CRG. 2007. Adsorption of chromium ions in activated carbon, Chemical Engineering, 132:355-62.
Sharma, DC., and Forster, CF. 1994. A preliminary examination into the adsorption of hexavalent chromium using low-cost adsorbents, Bioresource Technology,47: 257-64.
Sumathi, KMS., Mahimairaja, S. and Naidu, R. 2005. Use of low-cost biological wastes and vermiculite for removal of chromium from tannery effluent, Bioresource Technology, 96: 309-16.
Selvi, K., Pattabhi, S. and Kadirvelu, K. 2001. Removal of Cr(VI) from Aqueous Solution by Adsorption onto Activated Carbon. Bioresource Technology, 80(1):87-89.
Umpuch, C., Bunmanan, N., Kueasing, U. and Kaewsan, P. 2011. Adsorption of Lead from synthetic solution using Luffa Charcoal. World Academy of Science, Engineering and Technology, 5(9): 11-15.
Vivek Narayanan, N., and Ganesan, M. 2009. Use of adsorption using granular activated carbon (GAC) for the enhancement of removal of chromium from synthetic wastewater by electrocoagulation, Journal of Hazardous Materials, 161: 575-80.
Weber, W.J. 1972. Physicochemical Processes for Water Quality control, John Wiley and Sons Inc., New York.
Yu, LJ., Shukla, SS., Dorris, KL., Shukla, A. and Margrave, JL. 2003. Adsorption of chromium from aqueous solutions by maple sawdust., Journal of Hazardous Materials, 100: 53-63.
Zimmermann, AC., Mecabô, A. and Fagundes, T. 2010. Rodrigues CA. Adsorption of Cr(VI) Using Fe-Crosslinked Chitosan Complex (Ch-Fe). Journal of Hazardous Materials,179(1-3):192-196. | ||
|
آمار تعداد مشاهده مقاله: 3,114 تعداد دریافت فایل اصل مقاله: 834 |
||