اخبار و اعلانات
آمار
| تعداد نشریات | 19 |
| تعداد شمارهها | 380 |
| تعداد مقالات | 3,121 |
| تعداد مشاهده مقاله | 4,251,489 |
| تعداد دریافت فایل اصل مقاله | 2,845,934 |
حذف موثر کادمیوم از محیطهای آبی با کامپوزیتی از خاکستر سبک زغالسنگ و زیست سطح ساز رامنولیپیدی | ||
| نشریه مهندسی منابع معدنی | ||
| مقاله 7، دوره 5، شماره 3 - شماره پیاپی 17، مهر 1399، صفحه 107-126 اصل مقاله (1.64 M) | ||
| نوع مقاله: علمی-پژوهشی | ||
| شناسه دیجیتال (DOI): 10.30479/jmre.2020.11434.1309 | ||
| نویسندگان | ||
| مهلا پوربهاءالدینی زرندی1؛ حمید خوشدست* 2؛ اسماعیل دره زرشکی3؛ وحیده شجاعی2 | ||
| 1دانشجوی کارشناسی ارشد فرآوری مواد معدنی، بخش مهندسی معدن، مجتمع آموزش عالی زرند، زرند | ||
| 2استادیار، بخش مهندسی معدن، مجتمع آموزش عالی زرند، زرند | ||
| 3استادیار، آزمایشگاه تحقیقات و علوم کاربردی، دانشگاه شهید باهنر کرمان، کرمان | ||
| تاریخ دریافت: 26 مرداد 1398، تاریخ بازنگری: 04 تیر 1399، تاریخ پذیرش: 04 تیر 1399 | ||
| چکیده | ||
| در این پژوهش امکان حذف کادمیوم از محیطهای آب با استفاده از یک زیستکامپوزیت جدید که بر پایه خاکستر سبک زغالسنگ و بیوسورفکتانت رامنولیپیدی تولید شده، مورد بررسی قرار گرفته است. شرایط عملیاتی فرایند جذب، با در نظرگرفتن pH محلول و نسبت جاذب به فلز بهعنوان معیارهای عملیاتی و تأثیر آنها بر کارآیی حذف کادمیوم بهعنوان پاسخ فرایند، در قالب یک طرح آزمایشی مرکب مرکزی بررسی و بهینه شد. نتایج نشان داد که هر دو معیار بهطور مستقیم بر کارایی حذف، اثر مثبت دارند. بر اساس نتایج بهینهسازی، در مقدار pH برابر 10 و نسبت جاذب به فلز 40، بیش از 99درصد فلز از محلول حذف شد. مطالعه پیشرفت فرایند نسبت به زمان، نشان داد که جذب از سینتیک مرتبه اول با نرخ 57/548 بر دقیقه پیروی میکند. مقایسه مدلهای مختلف همدمای جذب نیز نشان داد که این فرایند به دلیل تطابق با معادله لانگمویر، از جذبی تکلایه با توزیع یکنواخت انرژی جذب بر سطح جاذب پیروی میکند. در این شرایط، بیشینه جذب برابر 11/67 میلیگرم فلز به ازای هر گرم زیستکامپوزیت حاصل شد. نتایج مطالعات گزینشپذیری نیز نشاندهنده قدرت جذب بسیار بالای جاذب بود و ضرایب گزینشپذیری برای فلزات کادمیوم، مس، سرب و روی تقریباً یکسان با یکدیگر و برابر واحد بهدست آمد. این نتایج نشان داد که کامپوزیتهای پایه خاکستر سبک و بیوسورفکتانتها را میتوان بهعنوان منبعی امیدبخش برای اهداف پالایش زیستمحیطی مورد استفاده قرار داد. | ||
| کلیدواژهها | ||
| خاکستر سبک؛ بیوسورفکتانت رامنولیپیدی؛ جذب سطحی؛ فلزات سنگین؛ پساب | ||
| عنوان مقاله [English] | ||
| Efficient Cadmium Removal from Aqueous Environments Using a Composite Produced by Coal Fly Ash and Rhamnolipid Biosurfactants | ||
| نویسندگان [English] | ||
| M. Poorbahaadini Zarandi1؛ H. Khoshdast2؛ E. Darezereshki3؛ V. Shojaei2 | ||
| 1M.Sc Student, Dept. of Mining Engineering, Higher Education Complex of Zarand, Zarand, Iran | ||
| 2Assistant Professor, Dept. of Mining Engineering, Higher Education Complex of Zarand, Zarand, Iran | ||
| 3Assistant Professor, Central Laboratory of Applied Research, Shahid Bahonar University of Kerman, Kerman, Iran | ||
| چکیده [English] | ||
| A novel bio-composite produced from coal fly ash accompanied by rhamnolipid biosurfactants was produced and used as an efficient adsorbent for the removal of cadmium from aqueous solution. Effects of initial solution pH (3-11) and absorbent to cadmium ratio (40-200) on cadmium removal, as process response, were studied and optimized using a central composite type response surface methodology. Results showed that both factors significantly affect the removal efficiency. Optimum adsorption conditions, resulting in over 99% cadmium removal, were achieved at pH 10 and absorbent to cadmium ratio of 40. Time-wise studies revealed that a maximum removal can be achieved following a classic first order model with a rate of 548.57 min-1. The cadmium adsorption on activated fly ash was also found to follow the Langmuir isotherm model with monolayer adsorption mechanism. Moreover, the bio-composite yielded a maximum adsorptive capacity of 67.11 mg/g. The selectivity study in bimetal aqueous systems using copper, lead and zinc metals also confirmed the high adsorption capacity of bio-composite. This study demonstrated that rhamnolipid-fly ash bio-composite could be considered as a promising efficient, low-cost resource material for the treatment of heavy metal polluted wastewaters. | ||
| کلیدواژهها [English] | ||
| Fly Ash, Rhamnolipid Biosurfactant, Adsorption, Heavy Metal, Wastewater | ||
| مراجع | ||
|
[1] Mushtaq, F., Zahid, M., Bhatti, I. A., Nasir, S., and Hussain, T. (2019). “Possible applications of coal fly ash in wastewater treatment”. Journal of Environmental Management, 240: 27-46. [2] Matzenbacher, C. A., Garcia, A. L. H., dos Santos, M. S., Nicolau, C. C., Premoli, S., Correa, D. S., de Souza, C. T., Niekraszewicz, L., Dias, J. F., and Delgado, T. V. (2017). “DNA damage induced by coal dust, fly and bottom ash from coal combustion evaluated using the micronucleus test and comet assay in vitro”. Journal of Hazardous Materials, 324: 781-788. [3] Aljerf, L. (2018). “High-efficiency extraction of bromocresol purple dye and heavy metals as chromium from industrial effluent by adsorption onto a modified surface of zeolite: kinetics and equilibrium study”. Journal of Environmental Management, 225: 120-132. [4] Visa, M., Isac, L., and Duta, A. (2012). “Fly ash adsorbents for multi-cation wastewater treatment”. Applied Surface Science, 258: 6345-6352. [5] Munoz, M., Aller, A., and Littlejohn, D. (2014). “The bonding of heavy metals on nitric acidetched coal fly ashes functionalized with 2-mercaptoethanol or thioglycolic acid”. Materials Chemistry and Physics, 143: 1469-1480. [6] Visa, M. (2016). “Synthesis and characterization of new zeolite materials obtained from fly ash for heavy metals removal in advanced wastewater treatment”. Powder Technology, 294: 338-347. [7] Pizarro, J., Castillo, X., Jara, S., Ortiz, C., Navarro, P., Cid, H., Rioseco, H., Barros, D., and Belzile, N. (2015). “Adsorption of Cu 2+ on coal fly ash modified with functionalized mesoporous silica”. Fuel, 156: 96-102. [8] Li, G., Wang, B., Sun, Q., Xu, W., and Han, Y. (2017). “Adsorption of lead ion on amino-functionalized fly-ash-based SBA-15 mesoporous molecular sieves prepared via two-step hydrothermal method”. Microporous Mesoporous Materials, 252: 105-115. [9] Adamczuk, A., and Kołodyńska, D. (2015). “Equilibrium, thermodynamic and kinetic studies on removal of chromium, copper, zinc and arsenic from aqueous solutions onto fly ash coated by chitosan”. Chemical Engineering Journal, 274: 200-212. [10] Karanac, M., Đolić, M., Veljović, Đ., Rajaković-Ognjanović, V., Veličković, Z., Pavićević, V., and Marinković, A. (2018). “The removal of Zn2+, Pb2+, and as (V) ions by lime activated fly ash and valorization of the exhausted adsorbent”. Waste Management, 78: 366-378. [11] Xiyili, H., Cetintaş, S., and Bingol, D. (2017). “Removal of some heavy metals onto mechanically activated fly ash: modeling approach for optimization, isotherms, kinetics and thermodynamics”. Process Safety and Environmental Protection, 109: 288-300. [12] Deng, X., Qi, L., and Zhang, Y. (2018). “Experimental study on adsorption of hexavalent chromium with microwave-assisted alkali modified fly ash”. Water, Air, & Soil Pollution, 229: 18. [13] Visa, M., and Duta, A. (2013). “TiO2/fly ash novel substrate for simultaneous removal of heavy metals and surfactants”. Chemical Engineering Journal, 223: 860-868. [14] Okte, A., Karamanis, D., and Tuncel, D. (2014). “Dual functionality of TiO2-flyash nanocomposites: water vapor adsorption and photocatalysis”. Catalysis Today, 230: 205-213. [15] Yang, L., Wang, F., Hakki, A., Macphee, D. E., Liu, P., and Hu, S. (2017). “The influence of zeolites fly ash bead/TiO2 composite material surface morphologies on their adsorption and photocatalytic performance”. Applied Surface Science, 392: 687-696. [16] Joshi, M. K., Pant, H. R., Liao, N., Kim, J. H., Kim, H. J., Park, C. H., and Kim, C. S. (2015). “In-situ deposition of silver− iron oxide nanoparticles on the surface of fly ash for water purification”. Journal of Colloid and Interface Science, 453: 159-168. [17] Karanac, M., Đolić, M., Veličković, Z., Kapidžić, A., Ivanovski, V., Mitrić, M., and Marinković, A. (2018). “Efficient multistep arsenate removal onto magnetite modified fly ash”. Journal of Environmental Management, 224: 263-276. [18] Okte, A. N., and Karamanis, D. (2013). “A novel photoresponsive ZnO-flyash nanocomposite for environmental and energy applications”. Applied Catalysis B: Environmental, 142: 538-552. [19] Zhang, Y., and Liu, L. (2013). “Fly ash-based geopolymer as a novel photocatalyst for degradation of dye from wastewater”. Particuology, 11: 353-358. [20] Zhang, Y. J., He, P. Y., Zhang, Y. X., and Chen, H. (2018). “A novel electroconductive graphene/fly ash-based geopolymer composite and its photocatalytic performance”. Chemical Engineering Journal, 334: 2459-2466. [21] Duan, P., Yan, C., Zhou, W., and Ren, D. (2016). “Development of fly ash and iron ore tailing based porous geopolymer for removal of Cu (II) from wastewater”. Ceramics International, 42: 13507-13518. [22] Rekadwa, B., Maske, V., Khobragade, C. N., and Kasbe, P. S. (2019). “Production and evaluation of mono- and di-rhamnolipids produced by Pseudomonas aeruginosa VM011”. Data in Brief, 24: 103890. [23] Goswami, M., and Phukan, P. (2017). “Enhanced adsorption of cationic dyes using sulfonic acid modified activated carbon”. Journal of Environmental Chemical Engineering, 5(4): 3508. [24] Mudyawabikwa, B., Mungondori, H. H., Tichagwa, L., and Katwire, D. M. (2017). “Methylene blue removal using a low-cost activated carbon adsorbent from tobacco stems: kinetic and equilibrium studies”. Water Science & Technology, 75(10): 2390-2402. [25] Tahiruddin, N. S. M., and Ab Rahman, S. Z. (2013). “Adsorption of lead in aqueous solution by a mixture of activated charcoal and peanut shell”. World Journal of Science and Technology Research, 1: 102. [26] Subramonian, W., Wu, T. Y., and Chai, S.-P. (2015). “An application of response surface methodology for optimizing coagulation process of raw industrial effluent using Cassia obtusifolia seed gum together with alum”. Industrial Crops and Products, 70: 107-115. [27] Boveiri Shami, R., Shojaei, V., and Khoshdast, H. (2019). “Efficient cadmium removal from aqueous solutions using a sample coal waste activated by rhamnolipid biosurfactant”. Journal of Environmental Management, 231: 1182-1192. [28] Rikalović, M. J., Gojgić-Cvijović, G., Vrvić, M. M., and Karadžić, I. (2012). “Production and characterization of rhamnolipids from Pseudomonas aeruginosa san ai”. Journal of the Serbian Chemical Society, 77(1): 27-42. [29] Rahman, P. K. S. M., Pasirayi, G., Auger, V., and Ali, Z. (2010). “Production of rhamnolipid biosurfactants by Pseudomonas aeruginosa DS10-129 in a microfluidic bioreactor”. Biotechnology and Applied Biochemistry, 55(1): 45-52. [30] Lan, G., Fan, Q., Liu, Y., Chen, C., Li, G., Liu, Y., and Yin, X. (2015). “Rhamnolipid production from waste cooking oil using Pseudomonas SWP-4”. Biochemical Engineering Journal, 101: 44-54. [31] Sounthararajah, D. P., Loganathan, P., Kandasamy, J., and Vigneswaran, S. (2015). “Adsorptive removal of heavy metals from water using sodium titanate nanofibres loaded onto GAC in fixed-bed columns”. Journal of Hazardous Materials, 287: 306. [32] Khoshdast, H., Abbasi, H., Sam, A., and Akbari Noghabi, K. (2012). “Frothability and surface behavior of a rhamnolipid biosurfactant produced by Pseudomonas aeruginosa MA01”. Biochemical Engineering Journal, 64: 127-134. [33] Khoshdast, H., and Sam, A. (2012). “An efficiency evaluation of iron concentrates flotation using rhamnolipid biosurfactant as a frothing reagent”. Environmental Engineering Research, 17(1): 9-15. [34] Montgomery D. C. (2008). “Design and Analysis of Experiments”. John Wiley & Sons, New York. [35] Champion, J. T., Gilkey, J. C., Lamparski, H., Retterer, J., and Miller, R. M. (1995). “Electron microscopy of rhamnolipid (biosurfactant) morphology: effects of pH, cadmium and octane”. Journal of Colloid and Interface Science, 170: 569-574. [36] Benincasa, M., Marque’s, A., Pinazo, A., and Manresa, A. (2010). “Rhamnolipid surfactants: alternative substrates, new Strategies”. In Sen, R. (Ed.), Biosurfactants. Springer, New York, 170-184. [37] Luo, J., Hein, C., Müucklich, F., and Solioz, M. (2017). “Killing of bacteria by copper, cadmium, and silver surfaces reveals relevant physicochemical parameters”. Biointerphases, 12(2): 1-6. [38] Liu, H. L., and Chiou, Y. R. (2005). “Optimal decolorization efficiency of reactive red 239 by UV/TiO2 photocatalytic process coupled with response surface methodology”. Chemical Engineering Journal, 112(1-3): 173-179. [39] Aljeboree, A. M., Alshirifi, A. N., and Alkaim, A. F. (2017). “Kinetics and equilibrium study for the adsorption of textile dyes on coconut shell activated carbon”. Arabian Journal of Chemistry, 10(2): S3381-S3393. [40] Wang, L., Zhang, J., and Wang, A. (2011). “Fast removal of methylene blue from aqueous solution by adsorption onto chitosan-g-poly (acrylic acid)/attapulgite composite”. Desalination, 266: 33-39. [41] Bodagh, A., Khoshdast, H., Sharafi, H., Zahiri, H. S., and Akbari Noghabi, K. (2013). “Removal of cadmium(II) from aqueous solution by ion flotation using rhamnolipid biosurfactant as ion collector”. Industrial & Engineering Chemistry Research, 52(10): 3910-3917. [42] El Nemr, A. (2009). “Potential of pomegranate husk carbon for Cr(VI) removal from wastewater: kinetic and isotherm studies”. Journal of Hazardous Materials, 161(1): 132-141. [43] Sreejalekshmi, K. G., Anoopkrishnan, K., and Anirudhan, T. S. (2009). “Adsorption of Pb(II) and Pb(II)-citric acid on sawdust activated carbon: kinetic and equilibrium isotherm studies”. Journal of Hazardous Materials, 161(2-3): 1506-1513. [44] Jalayeri, H., Salarirad, M. M., and Ziaii, M. (2016). “Kinetics and isotherm modelling of Zn(II) ions adsorption onto mine soils”. Physicochemical Problems of Mineral Processing, 52(2): 767-779. [45] Irannajad, M., Haghighi, H. K., and Soleimanipour, M. (2016). “Adsorption of Zn2+, Cd2+ and Cu2+ on zeolites coated by manganese and iron oxides”. Physicochemical Problems of Mineral Processing, 52(2): 894-908. [46] Ghosh, R. K., and Reddy, D. D. (2013). “Tobacco stem ash as an adsorbent for removal of methylene blue from aqueous solution: equilibrium, kinetics, and mechanism of adsorption”. Water, Air, & Soil Pollution, 224: 1-12. [47] Yuan, X. Z., Meng, Y. T., Zeng, G. M., Fang, Y. Y., and Shi, J. G. (2008). “Evaluation of tea-derived biosurfactant on removing heavy metal ions from dilute wastewater by ion flotation”. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 317(1-3): 256-261. | ||
|
آمار تعداد مشاهده مقاله: 465 تعداد دریافت فایل اصل مقاله: 420 |
||