بررسی آزمایشگاهی و ارزیابی مدل‌های سینتیک واجذب کادمیم از بار رسوبی بستر در یک کانال دایره‌ای

نوع مقاله : مقاله پژوهشی

نویسندگان

1 گروه علوم و مهندسی آب، دانشکده کشاورزی و محیط زیست، دانشگاه اراک، اراک، ایران

2 گروه مهندسی آبیاری و آبادانی، دانشکدگان کشاورزی و منابع طبیعی، دانشگاه تهران، کرج، ایران.

چکیده

در سراسر دنیا، بیشتر منابع آب‌های سطحی و رودخانه‌ها با آلودگی‌های مختلفی در تماس هستند. یکی از آلودگی‌های صنعتی، ورود فلزات سنگین به رودخانه‌ها و جذب آنها توسط رسوبات است. از سوی دیگر، فلزات سنگین در برخی شرایط محیطی ممکن است از رسوبات آزاد شوند. در این تحقیق، به‌منظور بررسی پدیدة واجذب کادمیم توسط رسوبات، ابتدا رسوبات با قطر متوسط 54/0 میلی‌متر به‌طورمصنوعی با کادمیم با غلظت‌های مختلف آلوده شدند. سپس اثر غلظت کادمیم و همچنین سرعت جریان بر نرخ واجذب از رسوبات آلوده به‌صورت آزمایشگاهی در یک فلوم دایره‌ای با قطر 6/1 متر و عرض 2/0 متر در سرعت‌های 18/0 و 35/0 متربرثانیه بررسی شد. نتایج آزمایش‌های واجذب نشان داد که بیشتر کادمیم قابل واجذب در حدود 5/0 ساعت از رسوبات دفع می‌شوند. با افزایش غلظت کادمیم، نرخ واجذب نیز افزایش یافت به‌طوری که با افزایش غلظت ازmg/kg  7 تاmg/kg  49/5، نرخ واجذب از 7/10 تا 30 درصد افزایش یافت. همچنین افزایش سرعت جریان تاثیر ناچیزی بر نرخ واجذب داشت؛ به‌طوری‌که در حداکثر غلظت نرخ‌واجذب به‌ازای سرعت‌های 18/0 و 35/0 متربرثانیه به‌ترتیب 25 و 30 درصد مشاهده شد. پس از بررسی مدل‌های سینتیک واجذب مشخص شد که معادله‌های پخشیدگی سهموی دوگانه با خطای متوسط نسبی 02/7 درصد و 99/0 = R2، 77/5 = SSE، 85/0 = KGE دقت بیشتری نسبت به معادله‌های دیگر دارند. نتایج آزمایش‌های این تحقیق نشان داد که بیشتر ذرات رسوب و کادمیم پیوند قوی از نوع شیمیایی با هم ‏برقرار کرده‌اند و فرایندهای جذب و واجذب فلزهای سنگین توسط رسوبات ‏برگشت‌ناپذیر هستند.‏

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Experimental Study and evaluation of kinetic models of cadmium desorption from bed sediment load in a circular Flume

نویسندگان [English]

  • Mohsen Nasrabadi 1
  • Mohammad Hosein Omid 2
1 Department of Water Science and Engineering, Faculty of Agriculture and Environment,, Arak University, Arak, Iran.
2 Department of Irrigation and Reclamation Engineering,, Faculties of Agricultural and Natural Resources, University of Tehran, Karaj, Iran.
چکیده [English]

Most surface water sources and rivers are exposed to various pollutants in all around the world. One of the industrial pollutants is the entry of heavy metals into rivers and their absorption by sediments. On the other hand, heavy metals may be released from sediments under various environmental conditions. In this study, in order to investigate the cadmium desorption from sediments, the sediments with an average diameter of 0.54 mm were first artificially contaminated with cadmium at different concentrations. Then, the effect of cadmium concentration and flow velocity on the desorption rate from contaminated sediments was investigated experimentally in a circular flume with a diameter of 1.6 m and a width of 0.2 m at velocities of 0.18 and 0.35 m/s. Desorption experiments revealed that nearly all of the desorbable cadmium was extracted from the sediments in about 30 min. With increasing cadmium concentration, the desorption rate also increased, so that with increasing concentration from 7 mg/kg to 49.5 mg/kg, the desorption rate increased from 10.7 to 30%. Also, increasing the flow rate had a negligible effect on the desorption rate; so that at the maximum concentration, the desorption rate was observed to be 25 and 30% for velocities of 0.18 and 0.35 m/s, respectively. After examining the desorption kinetic models, it was found that the double parabolic diffusion equations with R2 = 0.99, SSE = 5.77, KGE = 0.85, and mean relative error of 7.02% are more accurate than the other equations. The results of the experiments in this study showed that most sediment particles and cadmium have formed strong chemical bonds and that the processes of adsorption and desorption of heavy metals by sediments are irreversible. 

کلیدواژه‌ها [English]

  • Desorption rate
  • cadmium
  • river sediments
  • desorption kinetic models

Introduction

The importance of the adsorption and desorption of chemicals between sediment particles and dissolved materials can be examined from different points of view. First, a significant number of pollutants, especially heavy metals, are adsorbed by suspended sediments or bed sediments after entering the waterway. Second, resuspension of sediments due to dredging, tides, floods, or washing of sedimentation basins may cause pollutants to re-enter the waterway. Also, contaminated sediment particles may release heavy metals under some environmental conditions and become a source of secondary pollution (Huang, 2003a, b). Therefore, it is necessary to understand the mechanism of adsorption/desorption of heavy metals by sediments and the parameters affecting it. However, in general, the results have shown that the same factors affect adsorption and desorption, and the desorption capacity of cadmium is controlled by the cadmium adsorption capacity (Loganathan et al., 2012).

Although many studies have been conducted on the adsorption/desorption of heavy metals, there are still gaps in the literature to be filled. For example, it is still unclear how the flow velocity of a stream can control the desorption rates of cadmium at different concentrations. Therefore, compared to the numerous studies on the desorption of heavy metals from sediments, relatively few studies have investigated the cadmium desorption kinetics from river sediments (especially the Karaj River as a case study) and even fewer have determined the effect of flow turbulence, a common phenomenon in natural rivers, on the desorption rate. Also, almost all studies so far have investigated the adsorption and desorption phenomena under reactor conditions, and no study has been conducted in an open channel, where the flow conditions are similar to those in a river. In addition, in this study, the desorption kinetics were evaluated using eight models developed in the literature. The findings of this study may be useful for predicting the efficiency of heavy metal pollution cleanup methods in rivers. Therefore, the overall objectives of the present study are: 1. To investigate the factors affecting cadmium desorption (pollution concentration and flow velocity) in an open channel and 2. To evaluate different kinetic models in describing cadmium desorption.

Methodology

In this study, a circular flume with an average diameter of 1.6 m, a width of 0.2 m, and a depth of 0.15 m was used (Figure 1). This flume was placed on a fixed platform with dimensions of 2 × 2 m2. Sediments were artificially contaminated with cadmium in the circular flume. For this purpose, cadmium solutions with concentrations of 0.15, 0.46, 0.77, and 1 ppm were added to the flow with a sediment concentration of 20 g/L. Circular flume flow was maintained at two constant speeds of 6 and 10 rpm. After the sediments were exposed to different concentrations of cadmium for 12 hours to determine the amount of cadmium absorbed, a sample of the supernatant was taken and the remaining solution was separated from the sediments. After adjusting the temperature, pH and EC, the experiment began by taking samples at specific time intervals from a specific point in the center of the flume.

The flume was then completely filled with distilled water to a depth of 0.13 m. Before the desorption experiments began, a 0.01 M solution of calcium chloride CaCl2 was used to adjust the electrical conductivity and a dilute solution of HNO3 was used to adjust the pH. After adjusting the electrical conductivity and pH, to create a concentration of 20 g/L, 2600 g of cadmium-contaminated sediment samples were poured into a circular flume with a water volume of 130 L. The flow in the circular flume was maintained for 12 h until equilibrium was reached. The cadmium ion concentration was measured by taking 50 mL samples at specific time intervals (0, 5, 15, 30, 60, 120, 180, 240, 480, and 720 min) from a specific point in the center of the flume. These samples were immediately transported to the laboratory for analysis by ICP-OES.

Results and Discussion

The results if adsorption experiments showed that as the cadmium concentration in the solution increases, the adsorption rate per unit mass of sediment increases. Meanwhile, the percentage of cadmium removed from the solution also increased with increasing concentration. It can be said that this time is the time to reach equilibrium, which is independent of the cadmium concentration and the sediment concentration. The time for the cadmium desorption process to reach equilibrium is about 2 hours, and from then the desorption rate reaches a constant value. The negligible amount of cadmium desorption indicates a strong and strong bond between cadmium ions and sediment particles. The predictable result in studies where sediments are artificially contaminated is that cadmium adsorption and desorption are reversible processes (physical bonding). However, the results of the experiments in this study showed that most sediment particles and cadmium have established a strong chemical bond. The results of the experiments show that the adsorption and desorption processes of heavy metals by Karaj River sediments are irreversible.

With increasing flow velocity, the amount of cadmium desorption also increased slightly. Also, at low concentrations, the difference in cadmium desorption at both flow velocities is very small and negligible. One of the main differences in sediment movement at 0.18 and 0.35 m/s was that at 0.18 m/s, the sediments had not reached the threshold of movement and were almost stationary at the bottom of the flume. This is while at 0.35 m/s, the sediments were completely moving in the bed and had a lot of rolling and sliding. As a result, increasing the flow velocity and consequently increasing the turbulence causes an increase in the collision of sediment particles with each other, and as a result, a greater amount of cadmium will be released from the sediments. These results show that in seasonal rivers that always have flood currents flowing in them, the turbulence caused by floods can cause the release of heavy metals from the sediments into the flow. This phenomenon is also significant for contaminated sediments accumulated upstream of dam reservoirs.

Conclusions

The results of experiments showed that the initial desorption of cadmium from sediments is a rapid process. Most of the desorbable cadmium is removed from the sediments in about 0.5 hours, although some of the desorption process is still in progress by the end of the experiment.

The results of the experiments in this study showed that most of the sediment and cadmium particles have established a strong chemical bond. The results of the experiments also show that the processes of adsorption and desorption of heavy metals by the sediments of the Karaj River are irreversible.

With increasing cadmium concentration, the rate of its desorption from the sediments has also increased. So that the percentage of cadmium desorption (R) for low concentrations is up to about 10.7 percent, and with increasing cadmium contamination, the percentage of cadmium release reaches 30 percent.

With increasing average flow velocity, the rate of cadmium desorption has also increased. Although the increase in the rate of increase in turbulence has been very small. Also, at high concentrations, the difference in cadmium desorption at both flow rates is very small and about 5%.

The results of the desorption kinetics models showed that the double parabolic diffusion models (with R2 = 0.896 and SSE = 1.26), the two-constant rate (with R2 = 0.737 and SSE = 1.72) and the parabolic diffusion (with R2 = 0.99 and SSE = 5.76) are suitable models for estimating the desorption rate, but after calculating the mean relative error (MAE), it was observed that the double parabolic diffusion model with an average error of 7.02 percent is better than the two constant rate models (with an average error of 10 percent) and the parabolic diffusion (with an average error of 57 percent).

Author Contributions

“Conceptualization, M.N.and M.H.O.; methodology and validation, M.N. and M.H.O.; formal analysis, M.N.; investigation, M.N.; resources, M.H.O.; data curation, M.N.; writing—original draft preparation, M.N.; writing—review and editing, M.H.O.; visualization, M.N.; supervision, M.H.O.;

All authors have read and agreed to the published version of the manuscript.”

Data Availability Statement

Not applicable

Acknowledgements

The authors would like to thank all participants of the present study.

Ethical considerations

The study was approved by the Ethics Committee of the Arak University. The authors avoided data fabrication, falsification, plagiarism, and misconduct.

Conflict of interest

The author declares no conflict of interest.

مراجع

Abbaszadeh, H., Daneshfaraz, R., Sume, V., & Abraham, J. 2024. Experimental investigation and application of soft computing models for predicting flow energy loss in arc-shaped constrictions. AQUA—Water Infrastructure, Ecosystems and Society, 73(3), 637-661.‏
Abbaszadeh, H., Norouzi, R., Sume, V., Kuriqi, A., Daneshfaraz, R., & Abraham, J. 2023. Sill role effect on the flow characteristics experimental and regression model analytical. Fluids, 8(8), p. 235.‏
Ahmaruzzaman, M. 2011. Industrial wastes as low-cost potential adsorbents for the treatment of wastewater laden with heavy metals. Adv. Colloid Interface Sci 166: 36–59.
Ali, R.M., Hamad, H.A., Hussein, M.M., Malash, G.F. 2016. Potential of using green adsorbent of heavy metal removal from aqueous solutions: Adsorption kinetics, isotherm, thermodynamic, mechanism and economic analysis. Ecol Eng 91: 317–332.
Allen, H.E., Chen, Y.T., Li, Y.M., Huang, C.P. 1995. Soil partition coefficients for Cadmium by column desorption and comparison to batch adsorption measurements. Envir Sci Technol 29(8): 1887-1891.
Amela, K., Hassen, M.A., Kerroum, D. 2012. Isotherm and kinetics study of biosorption of cationic dye onto banana Peel. Energy Procedia 19: 286–295.
Cheng, H., Hu, E., Hu, Y. 2012. Impact of mineral micropores on transport and fate of organic contaminants: A review. J Contam Hydrol 129–130: 80–90.
Esfandbod, M., Adhami, E., Rezaei Rashti, C.M., Esfandbod, M. 2010. Kinetics of cadmium desorption from some soils of Iran. 19th World Congress of Soil Science, Soil Solutions for a Changing World. 1–6 August, Brisbane, Australia, 154-157.
Fornster, U. and Gottfried, T. W. 1981. Metal pollution in the aquatic environment, 2nd Ed., Berlin: Springer-Verlag.
Franchi, A., Davis, A.P. 1997. Desorption of cadmium (ii) from artificially contaminated sediments. Water, Air, and Soil Pollution 100: 181–196.
Fu, L., Xu, X., Fu, G., Zhang, R., Liu, H. 2020. Adsorption and desorption characteristics of cadmium ion by ash-free biochars, Journal of Renewable Materials 8(7): 801–818, doi:10.32604/jrm.2020.09369.
Gardiner, J. 1974. The chemistry of cadmium in natural waters. The adsorption of cadmium in river muds and naturally occurring soils. Water Res 8: 157-164.
Ghasemi Fasaei, R., Maftoun, M., Ronaghi, A., Karimian, N., Yasrebi, J., Assad, M.T., Ippolito, J.A. 2006. Kinetics of copper desorption from highly calcareous soils. Commun Soil Sci Plant Analysis 37: 797-809.
Ghoveisi, H., Farhoudi, J., Omid, M.H., Mahdavi Mazdeh, A. 2013. Comparison of Different Methods for Linear Regression of Pseudo Second Order Adsorption Kinetics of Cadmium. J. Civil Eng. Urban, 3 (2): 73-76.
Hart, B.T. 1986. Water Quality Management - The role of particulate matter in the transport and fate of pollutants, Water Studies Center, Chisholm Institute of Technology, Melbourne.
Hassanzadeh, Y. & Abbaszadeh, H. 2023. Investigating Discharge Coefficient of Slide Gate-Sill Combination Using Expert Soft Computing Models. Journal of Hydraulic Structures, 9(1), pp.63-80.
Hassanzadeh, Y. & Abbaszadeh, H. 2023. Investigating Discharge Coefficient of Slide Gate-Sill Combination Using Expert Soft Computing Models. Journal of Hydraulic Structures, 9(1), pp.63-80.
Hassanzadeh, Y., Abbaszadeh, H., Abedi, A., & Abraham, J. 2024. Numerical simulation of the effect of downstream material on scouring-sediment profile of combined spillway-gate. AQUA—Water Infrastructure, Ecosystems and Society, jws2024360.
Huang, S. L. 2003a. Adsorption of cadmium ions onto the Yellow River sediments. Water Qual. Res. J. Can. 38 (2), 413–‎‎432.‎
Huang, S. L. 2003b. Investigation of cadmium desorption from different sized sediments. J. Environ. Eng. ASCE 129 (3), ‎‎241–247.‎
Huang, S. L. and Wan, Z. H. 1995. Present state of experimental research on heavy metal pollutant adsorption-desorption by sediment, International Journal of Sediment Research, 10(3), 69–81.
Huang, S.L., Onyx Wai, W.H., Sheung, Li, Y. 1999. Determination of cadmium ion desorption from non-uniform sediment particles, Toxicological & Environmental Chemistry 72(3-4): 195-213.
Huang, Y., Fu, C., Li, Z., Fang, F., Ouyang, W., Guo, J. 2019. Effect of dissolved organic matters on adsorption and desorption behavior of heavy metals in a water-level-fluctuation zone of the Three Gorges Reservoir, China. Ecotoxicology and Environmental Safety 185: 109695. doi:10.1016/j.ecoenv.2019.109695.
Jain, C. K. and Ram, D. 1997b. Adsorption of metal ions on bed sediments, Hydrol. Sci. J., Vol.42, No.5, 713–723.
Jain, C.K. and Sharma, M. K. 2002. Adsorption of cadmium on bed sediment of river Hindon: adsorption models and kinetics, Water, Air, and soil pollution, Vol.137, 1-19.
Khater, A.H., Zaghloul, A.M. 2002. Copper and zink desorption kinetics from soil: Effect of pH, paper presented in 17th World Conference on Soil science, 14-21 August, Thailand, 47: 1-9.
Krishnamurti, G.S.R., Cieslinski, G., Huang, P.M., Van Rees, K.C.J. 1999. Kinetics of cadmium release from soils as influenced by organic acids: Implication in cadmium availability. J Environ Qual 26: 271–277.
Landrum P.F., Lee H., Lydy M.J. 1992. Toxicokinetics in aquatic systems: model comparisons and use in hazard assessment. Environ. Toxicol. Chem. 11: 1709-1725.
Li, P., Lang, M., Wang, X.X., Zhang, T.L. 2016. Sorption and desorption of copper and cadmium in a contaminated soil affected by soil amendments. CLEAN-Soil, Air, 44(11): 1547-1556. doi:10.1002/clen.201500555.
Li, Z., Man, N., Wang, S., Liang, D. 2015. Selenite adsorption and desorption in main Chinese soils with their characteristics and physicochemical properties. J Soils Sediments 15(5): 1150–1158.
Liu, J., Liu, Y.J., Liu, Y., Liu, Z., Ning Zhang, A. 2018. Quantitative contributions of the major sources of heavy metals in soils to ecosystem and human health risks: A case study of Yulin, China. Ecotoxicol Environ Saf 164: 261–269. doi: 10.1016/j.ecoenv.2018.08.030.
Loganathan, P., Vigneswaran, S., Kandasamy, J., Naidu, R. 2012. Cadmium sorption and desorption in soils: a review. Critical Reviews in Environmental Science and Technology 42(5): 489–533. doi:10.1080/10643389.2010.520234.
Mahdavi Mazdeh, A. 2009. Modeling the absorption and transport of heavy metal pollution by sediment loads. PhD thesis. Department of Irrigation and Reclamation Engineering, University of Tehran. (in Persian)
‎Mahdavi, A., Kashefipour, S. M. and Omid, M. H. 2013. Proc. ICE-Water Management. 166(3) (2013) 152.‎
Mahdavi, A., Omid, M.H. and Ganjali, M.R. 2008. Effect of bed load transport on kinetic sorption in a circular flume. Proceedings of International Conference on Fluvial Hydraulics, RiverFlow2008, Cesme-Izmir, Turkey. Kubaba Congress Department and Travel Services, Ankara, Turkey, pp. 2485–2491.
Marashi, A., Kouchakzadeh, S. & Yonesi, H.A. 2023. Rotary gate discharge determination for inclusive data from free to submerged flow conditions using ENN, ENN–GA, and SVM–SA. Journal of Hydroinformatics. 25(4), 1312-1328.
Mcbride, M. B., Richards, B. K., Steenhuis, T., Russo, J. J., Sauve, S. 1997. Mobility and solubility of toxic metals and nutrients in soil fifteen years after sludge application. Soil Science, 162(7): 487–500.
Mehri, Y., Soltani, J. & Khashehchi, M. 2019. Predicting the coefficient of discharge for piano key side weirs using GMDH and DGMDH techniques. Flow Measurement and Instrumentation, 65, pp. 1-6.
Mohammadi, A., Saeedi, M., Mollahoseini, A. 2018. Simultaneous desorption and desorption kinetics of phenanthrene, anthracene, and heavy metals from kaolinite with different organic matter content. Soil and Sediment Contamination: An International Journal 27(3): 200-220. doi: 10.1080/15320383.2017.1339666.
Nasrabadi, M., Omid, M. H., Mahdavi Mazdeh, A. 2022. Experimental Study of Flow Turbulence Effect on Cadmium Desorption Kinetics from Riverbed Sands, Environmental Process, (2022) 9:10. https://doi.org/10.1007/s40710-022-00558-y
Nasrabadi, M., Omid, M.H., Mahdavi Mazdeh, A. 2017. Cadmium adsorption characteristics for Karaj Riverbed Sands. Journal of Materials and Environmental Sciences 8(5): 1729-1736.
Nasrabadi, M., Omid, M.H., Mahdavi Mazdeh, A. 2021. Effect of cadmium sorption by river sediments on longitudinal dispersion, Water Science & Technology-Water Supply, doi: 10.2166/ws.2021.368.
Nasrabadi, M., Omid, M.H., Mazdeh, A., Shahriari, T. 2018. Cadmium adsorption by natural zeolite in a circular flume. International Journal of Environmental Technology and Management 21(3-4): 174-189.
Nasrabadi. M. 2016. Experimental, analytical and numerical study of the role of river sediments on the transport and dispersion processes of heavy metals. PhD thesis. Department of Irrigation and Landscaping Engineering, University of Tehran. (in Persian).
Neely, B.W., Branson, D.R. and Blau, G.E. 1974. Partition Coefficient to Measure Bioconcentration Potential or Organic Chemicals in Fish. Environ. Sci. Technol. 8: 1113-1115.
Polyzopoulos, N.A., Keramidas, V.Z., Kiosse, H. 1986. Phosphate sorption by some alfisols of Greece as Described by Commonly Used isotherms. J Soil Sci 37: 183-189. https://doi.org/10.2136/sssaj1985.03615995004900010016x.
Putro, J.N., Santoso, S.P., Ismadji, S., Ju, Y.H. 2017. Investigation of heavy metal adsorption in binary system by nanocrystalline cellulose—Bentonite nanocomposite: Improvement on extended Langmuir isotherm model. Microporous Mesoporous Mater 246: 166–177.
Reyhanitabar, A., Gilkes, R.J. 2010. Kinetics of DTPA extraction of zinc from calcareous soils from Iran. 19th World Congress of Soil Science, Soil Solutions for a Changing World. 1–6 August, Brisbane, Australia, 19-22.
Reyhanitabar, A., Karimian, N. 2008. Kinetics of copper desorption of selected calcareous soils from Iran American-Eurasian J Agric & Environ Sci 4(3): 287-293.
Shirvani, M., Kalbasi, M., Shariatmadari, H., Nourbakhah, F., and Najafi, B. 2006. Sorption-desorption of cadmium in aques palygorskite, sepiolite, and calcite suspensions: Isotherm hysteresis. Chemosphere 65, 2178-2184.
Windom, H.I., Byrd, J.T., Smith, R.G., and Huan, F. 1991. Inadequacy of NASQUAN data for assessing metal trends in the nation's rivers. Environ. Sci. Technol. 25. 1137-1142.
Yongkui, Y., Li, L., Dingyong, W. 2008. Effect of dissolved organic matter on adsorption and desorption of mercury by soils. Journal of Environmental Sciences. 20: 1097–1102.
تحقیقات آب و خاک ایران
دوره 56، شماره 9
آذر 1404
صفحه 2393-2410

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