مطالعه ترمودینامیکی جذب زیستی برای حذف نیکل با بیومس های میکروبی و مشتق شده از گیاهان

نژادنادری, مهدی; گوران اوریمی, حمید

کد مقاله : HE-2009-1893 (R2) بازدید : 97 صفحه: 187 - 204

نوع مقاله: پژوهشی

مطالعه ترمودینامیکی جذب زیستی برای حذف نیکل با بیومس های میکروبی و مشتق شده از گیاهان

محورهای موضوعی : آب و محیط زیست

1 - گروه مهندسی عمران، واحد تنکابن، دانشگاه آزاد اسلامی، تنکابن، ایران.
2 - دانشجوی دکترا، گروه مهندسی شیمی، دانشگاه فنی نوشیروانی بابل، بابل، ایران

تاریخ دریافت : 1399/06/27 تاریخ پذیرش : 1400/04/08 تاریخ انتشار : 1401/04/01

کلید واژه: نیکل, جاذب زیستی, ترمودینامیک, جذب زیستی, محلول های آبی,

چکیده مقاله :

زمینه هدف: تخلیه فلزات سنگین ناشی از صنایع مختلف اثرات منفی بر محیط زیست و ارگانیسم های زنده دارد. فن آوری های مرسوم حذف فلزات سنگین از محلول های آبی از نظر اقتصادی مقرون به صرفه نبوده و علاوه بر عدم اثر بخشی در غلظت های پائین یون فلزی به مقدار زیادی لجن شیمیائی تولید می نمایند. جذب زیستی نیکل بوسیله بیومس غیر زنده و غیر فعال میکروبی و یا مشتق شده از گیاهان یک فن آوری آلترناتیو و مبتکرانه برای حذف این آلودگی از محلول های آبی است که ضمن مرتفع کردن مشکلات روشهای مرسوم عنوان شده در این مقاله از قابلیت دسترسی فراوان جاذب توأم با تجدید پذیری و ظرفیت جذب بالا برخوردار می باشد. روش بررس : در این پژوهش، در مطالعه ای مروری با هدف معرفی انواع جاذب های زیستی میکروبی و مشتق شده از گیاهان به منظور حذف نیکل از محلول آبی و آشکارسازی ظرفیت جذب هر جاذب، از مقاله های یافت شده در بین سالهای 2001 تا 2020 استفاده شده است. یافته ها: تحقیقات صورت گرفته و نتایج حاصل از آن با توجه به مزایای بالقوه، استفاده از این بیومس ها به عنوان جاذب زیستی جهت حذف نیکل در محلول آبی را به عنوان چشم اندازی امیدوار کننده و دوستدار محیط زیست پیشنهاد می کند. بحثونتیجه گیری : براساس مطالعات ترمودینامیکی در اکثر فرآیندهای جذب زیستی نیکل با جاذب های مختلف ، مقدار منفی و مقدار مثبت گزارش گردیده است. مقدار منفی ناشی از خودبخودی بودن فرآیند و مقدار مثبت ناشی از افزایش برخوردهای تصادفی بین جامد و محلول در طول فرآیند دارد.

چکیده انگلیسی:

Objective field: The discharge of heavy metals from various industries has negative effects on the environment and living organisms. Conventional technologies for removing heavy metals from aqueous solutions are not economically viable and, in addition to not being effective at low concentrations of metal ions, produce large amounts of chemical sludge. Nickel's biological uptake by living, inactive, microbial or plant-derived biomass is an alternative and innovative technology to remove this contamination from aqueous solutions. It has high absorbency and reabsorption capacity. Investigation method: In this research, in a review study with the aim of introducing different types of microbial and plant-derived biological adsorbents in order to remove nickel from aqueous solution and reveal the adsorption capacity of each adsorbent, articles found between 2001 and 2020 have been used. Findings: Research has shown that the use of these biomass as a biological adsorbent for the removal of nickel in aqueous solution is a promising and environmentally friendly prospect. Discussion and conclusion Based on thermodynamic studies in most nickel biosorption processes with different adsorbents, the value of ∆G° is negative and the value of ∆S° is positive due to the increase of random collisions between solid and solution during the process.

منابع و مأخذ:

Pahlavanzadeh, H., Keshtkar, A.R., Safdari, J., Abadi, Z., 2010, Biosorption of nickel(II) from aqueous solution by brown algae: Equilibrium, dynamic and thermodynamic studies. Journal of Hazardous Materials, vol. 175, 304–310.

Torab-Mostaedi, M. Asadollahzadeh, M., Hemmati, A.R., Khosravi, A., 2013, Equilibrium, kinetic, and thermodynamic studies for biosorption of cadmium and nickel on grapefruit peel. Journal of the Taiwan Institute of Chemical Engineers, vol. 44, 295–302.

Nuhoglu, Y., Malkoc, E., 2009, Thermodynamic and kinetic studies for environmentaly friendly Ni(II) biosorption using waste pomace of olive oil factory. Bioresource Technology, vol. 100, 2375–2380.

Serkan Yalcin, M., Özdemir, S., Kilinc, E., 2018, Preconcentration of Ni(II) and Co(II) by using immobilized thermophilic Geobacillus stearothermophilus SO-20 before ICP-OES determinations. Food Chemistry, 266,pp. 126-132.

Anitha, D., Ramadevi, A., Seetharaman, R., 2020, Biosorptive removal of Nickel(II) from aqueous solution by Mangosteen shell activated carbon, Materials Today: Proceedings, 1–5.

Amini, M., Younesi, H., Bahramifar, N., 2009, Biosorption of nickel(II) from aqueous solution by Aspergillus niger: Response surface methodology and isotherm study. Chemosphere, vol. 75, 1483–1491.

Long, J., Gao, X., Su, M., Li, H., Chen, D., Zhou, S., 2018, Performance and Mechanism of Biosorption of Nickel(II) from Aqueous Solution by Non-living Streptomyces roseorubens SY. Colloids and Surfaces A: Physicochem. Eng. Aspects, 548(5), pp. 125-133.

Noormohamadi, H.R., Fat'hi, R., Ghaedi, M., Ghezelbash, G.R., 2019, Potentiality of White-Rot Fungi in Biosorption of Nickel and Cadmium: Modeling Optimization and Kinetics Study. Chemosphere, vol. 216, pp. 124-130.

Villen-Guzman, M., Gutierrez-Pinilla, D., Gomez-Lahoz, C., Vereda-Alonso, C., Rodriguez-Maroto, J.M., Arhoun, B., 2019, Optimization of Ni (II) biosorption from aqueous solution on modified lemon peel. Environmental Research, 179. Part B, pp.1-22.

Aghababai Beni, A., Esmaeili, A., 2019, Biosorption, an efficient method for removing heavy metals from industrial effluents: A Review. Environmental Technology & Innovation, Vol. 53, 1-104.

Qin, H., Hu, T., Zhai, Y., Lu, N., Aliyeva, J., 2019, The improved methods of heavy metals removal by biosorbents: A review. Environmental Pollution, Vol. 258, 1-64.

Zafar, M.N., Nadeemb, R., Hanif, M.A., 2007, Biosorption of nickel from protonated rice bran. Journal of Hazardous Materials, vol. 143, 478–485.

Singh, S., Goyal, D., 2007, Microbial and Plant Derived Biomass for Removal of Heavy Metals from Wastewater. Bioresource Technology, Vol.98(12), 2243-57.

Wang, B., Xuan, J., Bai, Z., Luque, R., 2017, Chitosan biosorbents with designable performance for wastewater treatment. Chemical Engineering Journal, Vol. 325, 350-59.

Shi, L., Wei, D., Ngo, H.H., Guo, W., Du, B., Wei, Q., 2015, Application of anaerobic granular sludge for competitive biosorption of methylene blue and Pb (II): fluorescence and response surface methodology. Bioresource technology, Vol. 194, 297‐304.

Xin, S., Zeng, Z., Zhou, X., Luo, W., Shi, X., Wang, Q., Deng, H., Du, Y., 2017, Recyclable Saccharomyces cerevisiae loaded nanofibrous mats with sandwich structure constructing via bio‐electrospraying for heavy metal removal. Journal of hazardous materials. Vol. 324, 365‐372.

Wang, Z., Shen, D., Shen, F., Wu, C., Gu, S., 2017, Kinetics, equilibrium and thermodynamics studies on biosorption of Rhodamine B from aqueous solution by earthworm manure derived biochar. International Biodeterioration & Biodegradation, vol. 120, 104‐114.

Du, Z., Zheng, T., Wang, P., Hao, L., Wang, Y., 2016, Fast microwave‐assisted preparation of a low‐cost and recyclable carboxyl modified lignocellulose‐biomass jute fiber for enhanced heavy metal removal from water. Bioresource technology, Vol. 201, 41-49.

Saha, G.C., Hoque, M.I.U., Miah, M.A.M.., Holze, R.., Chowdhury, D.A., Khandaker, S., Chowdhury, S., 2017, Biosorptive removal of lead from aqueous solutions onto Taro (Colocasiaesculenta (L.) Schott) as a low cost bioadsorbent: Characterization, equilibria, kinetics and biosorption‐mechanism studies. Journal of environmental chemical engineering, vol. 5(3), 2151‐2162.

Basu, H. Saha, S., Mahadevan, I.A., Pimple, M.V., Singhal, R.K., 2019, Humic acid coated cellulose derived from rice husk: A novel biosorbent for the removal of Ni and Cr. Journal of Water Process Engineering, vol. 32, 1-8.

Barquilha, C.E.R., Cossich, E.S., Tavares, C.R.G., Silva, E.A., 2018, Biosorption of nickel(II) and copper(II) ions by Sargassum sp. In nature and alginate extraction products. Bioresource Technology Reports, vol. 5, 43-50.

Sadat Hosseini, S., Asm Hosseini, M., Khezri, S., Qanbari Talouki, F. and Khosravi, A., (2015), Removal of nickel ion from aqueous solutions using natural zeolite along with a case study, Journal of Applied Chemistry, (41)11, 48-39. (In Persian).

Gholami, Z., Houshmand, A., Naseri, A., Pourreza, N., (2013), Removal of nickel and cadmium from polluted water using bagasse nanoparticles, Journal of Irrigation Engineering Sciences (Agricultural Scientific Journal), (2) 36, 107-97. (In Persian).

Asadeki, Z., Ansari, R. and Stewar, F., (2018). Removal of nickel (II) ion using iron (III) oxide nanoparticles from aqueous solutions: study of kinetic, isotherm and thermodynamic models. Journal of Health and Environment, (3)12, 396-383. (In Persian).

Ahmadi Asb Chin, S. and Jafari, N., (2014). Investigation of kinetics and isotherm of nickel ion removal from aqueous solution by Cystoseira indica (Thivy & Doshi) brown algae extracted from Oman Sea, Iranian Journal of Plant Biology, (21) 6, 8-1. (In Persian).

Abdelfattah, I., Ismail, A.A., Sayed, F. Al., Almedolab, A., Aboelghait, K., 2016, Biosorption of heavy metals ions in real industrial wastewater using peanut husk as efficient and cost effective adsorbent. Environmental Nanotechnology, Monitoring & Management, vol (6). 176‐183.

Malik, R., Dahiya, S., 2017, An experimental and quantum chemical study of removal of utmostly quantified heavy metals in wastewater using coconut husk: A novel approach to mechanism. International journal of biological macromolecules, vol. 98, 139‐149.

Masoumi, F., Khadivinia, E., Alidoust, L., Mansourinejad, Z., Shahryari, S., Safaei, M., Mousavi, A., Salmanian, A.‐, Zahiri, H.S., Vali, H., 2016, Nickel and lead biosorption by Curtobacterium sp. FM01, an indigenous bacterium isolated from farmland soils of northeast Iran. Journal of environmental chemical engineering, Vol. 4(1), pp. 950‐957.

Milojković, J., Pezo, L., Stojanović, M., Mihajlović, M., Lopičić, Z., Petrović, J., Stanojević, M., Kragović, M., 2016, Selected heavy metal biosorption by compost of Myriophyllum spicatum—a chemometric approach. Ecological Engineering, vol. 93, 112‐119.

Yu, H., Pang, J., Ai, T., Liu, L., 2016, Biosorption of Cu2+, Co2+ and Ni2+ from aqueous solution by modified corn silk: Equilibrium, kinetics, and thermodynamic studies. Journal of the Taiwan Institute of Chemical Engineers, Vol. 62, 21‐30.

Jones, B.O., John, O.O., Luke, C., Ochieng, A., Bassey, B.J., 2016, Application of mucilage from Dicerocaryum eriocarpum plant as biosorption medium in the removal of selected heavy metal ions. Journal of environmental management, Vol. 177, 365‐372.

Nongmaithem, N., Roy, A., Bhattacharya, P.M., 2016, Screening of Trichoderma isolates for their potential of biosorption of nickel and cadmium. brazilian journal of microbiology, Vol. 47(2). 305‐313.

Giovanella, P., Cabral, L., Costa, A.P., de Oliveira Camargo, F.A., Gianello, C., Bento, F.M., 2017, Metal resistance mechanisms in Gram‐negative bacteria and their potential to remove Hg in the presence of other metals. Ecotoxicology and environmental safety, vol. 140, 162‐169.

Suzaki, P.Y.R.., Munaro, M.T., Triques, C.C., Kleinübing, S.J., Klen, M.R.F., de Matos Jorge, L.M.., Bergamasco, R., 2017, Biosorption of binary heavy metal systems: Phenomenological mathematical modeling. Chemical Engineering Journal, vol. 313, 364‐373.

El‐Gendy, M.M.A.A., El‐Bondkly, A.M.A., 2016, Evaluation and enhancement of heavy metals bioremediation in aqueous solutions by Nocardiopsis sp. MORSY1948, and Nocardia sp. MORSY2014. brazilian journal of microbiology, vol. 47(3), 571‐586.

Mahmoud, M.E., Abdou, A.E., Mohamed, S.M., Osman, M.M., 2016, Engineered staphylococcus aureus via immobilization on magnetic Fe3O4‐phthalate nanoparticles for biosorption of divalent ions from aqueous solutions. Journal of Environmental Chemical Engineering, vol. 4(4), 3810‐3824.

Barquilha, C., Cossich, E., Tavares, C., Silva, E., 2017, Biosorption of nickel (II) and copper (II) ions in batch and fixed‐bed columns by free and immobilized marine algae Sargassum sp. Journal of Cleaner Production, vol. 150, 58‐64.

Wu, S.P., Dai, X..Z., Kan, J.R., Shilong, F.D., Zhu, M..Y., 2017, Fabrication of carboxymethyl chitosan–hemicellulose resin for adsorptive removal of heavy metals from wastewater. Chinese Chemical Letters, vol. 28(3), 625-632.

Aksu, Z., 2002, Determination of the equilibrium, kinetic and thermodynamic parameters of the batch biosorption of nickel(II) ions onto Chlorella vulgaris. Process Biochemistry. Vol. 38, 89-99.

Padmavathy, V., Vasudevan, P., and, Dhingra, S.C., 2002, Biosorption of nickel(II) ions on Baker’s yeast. Process Biochemistry, vol. 38, 1389-1395.

Aloma, I., Martı´n-Lara, M.A., Rodrı´guez, I.L., Bla´zquez, G., Calero, M., 2012, Removal of nickel (II) ions from aqueous solutions by biosorption on sugarcane bagasse. Journal of the Taiwan Institute of Chemical Engineers, Vol. 43, 275–281.

Gabr, R.M., Hassan, S.H.A., Shoreit, A.A.M., 2008, Biosorption of lead and nickel by living and non-living cells of Pseudomonas aeruginosa ASU 6a. International Biodeterioration & Biodegradation, Vol.62, 195–203.

Rajeswari, M., Kulkarni, K., Vidya Shetty, K., Srinikethan, G., 2013, Cadmium (II) and nickel (II) biosorption by Bacillus laterosporus (MTCC 1628), Journal of the Taiwan Institute of Chemical Engineers, Vol. 45(4), 1628-1635.

Vijayaraghavan, K., Rangabhashiyam, S., Ashokkumar, T., Arockiaraj, J., 2017, Assessment of samarium biosorption from aqueous solution by brown macroalga Turbinaria conoides. Journal of the Taiwan Institute of Chemical Engineers, Vol. 74, 113‐120.

Thevannan, A., Mungroo, R., Niu, C.H. 2010, Biosorption of nickel with barley straw. Bioresource Technology, Vol. 101, 1776–1780.

Montazer-Rahmati, M.M., Rabbani, P., Abdolali, A., Keshtkar, A.R., 2011, Kinetics and equilibrium studies on biosorption of cadmium, lead, and nickel ions from aqueous solutions by intact and chemically modified brown algae, Journal of Hazardous Materials, vol. 185, 401–407.

Gupta, V., Rastogi, A., Nayak, A., 2010, Biosorption of nickel onto treated alga (Oedogonium hatei): Application of isotherm and kinetic models. Journal of Colloid and Interface Science, vol 342, pp. 533–539.

Ozer, A., Gurbuz, G., Calimli, A., Korbahti, BK., 2007, Investigation of nickel(II) biosorption on Enteromorpha prolifera: Optimization using response surface analysis. Journal of Hazardous Materials, vol 152, 778–788.

Rangabhashiyam, S., Selvaraju, N., 2015, Evaluation of the biosorption potential of a novel Caryota urens inflorescence waste biomass for the removal of hexavalent chromium from aqueous solutions. Journal of the Taiwan Institute of Chemical Engineers, (47), pp. 59-70.

Zhou, K., Yang, Z., Liu, Y., Kong, X., 2015, Kinetics and equilibrium studies on biosorption of Pb (II) from aqueous solution by a novel biosorbent: Cyclosorus interruptus. Journal of Environmental Chemical Engineering, Vol. 3(3), 2219-2228.

Fathy, N.A., El‐Wakeel, S.T., El‐Latif, R.R.A., 2015, Biosorption and desorption studies on chromium (VI) by novel biosorbents of raw rutin and rutin resin. Journal of Environmental Chemical Engineering, Vol. 3(2), 1137‐1145.

Zhao, C., Liu, J., Tu, H., Li, F., Li, X., Yang, J., Liao, J., Yang, Y., Liu, N., Sun, Q., 2016, Characteristics of uranium biosorption from aqueous solutions on fungus Pleurotus ostreatus. Environmental Science and Pollution Research, Vol. 23(24), 24846‐24856.

Deniz, F., Karabulut, A., 2017, Biosorption of heavy metal ions by chemically modified biomass of coastal seaweed community: studies on phycoremediation system modeling and design. Ecological Engineering, Vol. 106, 101‐108.

Nakkeeran, E., Rangabhashiyam, S., Giri Nandagopal, M., Selvaraju, N., 2016, Removal of Cr (VI) from aqueous solution using Strychnos nux‐vomica shell as an adsorbent. Desalination and Water Treatment, 57(50), pp. 23951‐23964.

Nadeem, R., Manzoor, Q., Iqbal, M., Nisar, J., 2016, Biosorption of Pb (II) onto immobilized and native Mangifera indica waste biomass. Journal of Industrial and Engineering Chemistry, vol. 35, 185‐194.

Ogunsile, B., Bamgboye, M., 2017, Biosorption of Lead (II) onto soda lignin gels extracted from Nypa fruiticans. Journal of environmental chemical engineering, vol. 5(3), 2708‐2717.

_||_