Abstract
We previously reported that a simple treatment—addition of only small amounts of water to coal fly ash (CFA) to form CFA paste followed by aging for 1–4 weeks—is advantageous for the immobilization of highly soluble B, F, Cr, and As. In this study, we investigated the leachability of Ca, SO4, B, and As over time from non-aged and aged CFA samples to elucidate a possible immobilization mechanism. For this purpose, two types of CFA samples, one showing effective immobilization of B and As by water addition and aging (sample A) and the other showing less or no immobilization (sample B), were examined. Calcium and SO4, B, and As in non-aged sample A dissolved immediately after the start of the leaching test, indicating that these elements existed in highly soluble particles. After the rapid dissolution, their concentrations in the leachate gradually increased, possibly due to the dissolution of glassy phases. During the 1-week leaching test, the B and As concentrations in the leachate finally decreased. The addition of only small amounts of water to CFA (Sample A) for aging produce both alkaline and supersaturation conditions for the formation of several types of Ca-bearing secondary minerals such as calcite and ettringite, which are formed under alkaline conditions. Boron and As originally existing as highly soluble particles in CFA are expected to be incorporated into and/or sorbed on these secondary minerals as water-insoluble phases. Compared to non-aged CFA, their leachability from the aged sample A remained lower throughout the entire leaching test. Possibly due to these secondary minerals being formed on the CFA surface, B and As dissolutions associated with glassy phases are also prevented. In contrast, the pH of the leachate from CFA (sample B) at the beginning of the leaching test was acidic and then abruptly became alkaline. This means that water-soluble particles that can produce acidic conditions are also contained in these alkaline CFAs. Dissolution of these substances during aging makes it difficult to generate alkaline conditions in the CFA paste. Consequently, the formation of secondary minerals and the concomitant immobilization of toxic elements are prevented.
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References
Ahmaruzzaman, M. (2010). A review on the utilization of fly ash. Progress in Energy and Combustion Science, 36, 327–363.
Baba, A., Gurdal, G., Sengunalp, F., & Ozay, O. (2008). Effects of leachant temperature and pH on leachability of metals from fly ash: case study: can thermal power plant, province of Canakkale, Turkey. Environmental Monitoring and Assessment, 139, 287–298.
Baba, A., Gurdal, G., & Şengünalp, F. (2010). Leaching characteristics of fly ash from fluidized bed combustion thermal power plant: case study: Çan (Çanakkale-Turkey). Fuel Processing Technology, 91, 1073–1080.
Banerjee, S. S., Jayaram, R.,. V., & Joshi, M. V. (2003). Removal of Nickel(II) and Zinc(II) from wastewater using fly ash and impregnated fly ash. Separation Science and Technology, 38, 1015–1032.
Banerjee, S. S., Joshi, M. V., & Jayaram, R. V. (2005). Removal of Cr(VI) and Hg(II) from aqueous solutions using fly ash and impregnated fly ash. Separation Science and Technology, 39, 1611–1629.
Blissett, R. S., & Rowson, N. A. (2009). A review of the multi-componemt utilization of coal fly ash. Fuel, 97, 1–23.
Bothe, J. M., & Brown, P. W. (1998). Phase formation in the system CaO–Al2O3–B2O3–H2O at 23±1°C. Journal of Hazardous Materials, B63, 199–210.
Cox, J. A., Lundquist, G. L., Przyjazny, A., & Schmulbach, C. D. (1978). Leaching of boron from coal ash. Environmental Science & Technology, 12, 722–723.
van der Hoek, E. E., Bonouvrie, P. A., & Comans, R. N. J. (1994). Sorption of As and Se on mineral components of fly ash: relevance for leaching processes. Applied Geochemistry, 9, 403–412.
Diamadopoulos, E., Ioannidis, S., & Sakellaropoulos, G. P. (1993). As(V) removal from aqueous solutions by fly ash. Water Research, 27, 1773–1777.
Dutta, B. K., Khanra, S., & Mallic, D. (2009). Leaching of elements from coal fly ash: Assessment of its potential for use in filling abandoned coal mines. Fuel, 88, 1314–1323.
Gabrisova, A., Havlica, J., & Sahu, S. (1991). Stability of calcium sulphoaluminate hydrates in water solutions with various pH values. Cement and Concrete Research, 21, 1023–1027.
Harkness, J. S., Sulkin, B., & Vengosh, A. (2016). Evidence for coal ash ponds leaking in the southeastern United States. Environmental Science & Technology, 50, 6583–6592.
Hassett, D. J. (1994). Scientifically valid leaching of coal conversion solid residues to predict environmental impact. Fuel Processing Technology, 39, 445–459.
Hassett, D. J., Pflughoeft-Hassett, D. F., & Heebink, L. V. (2003). Leaching of CCB’S: over 25 years of research. In proceedings of the international ash utilisation symposium. Kentucky: University of Kentucky.
Hiraga, Y., & Shigemoto, N. (2010). Boron uptake behavior during ettringite synthesis in the presence of H3BO3 and in a suspension of ettringite in H3BO3. Journal of Chemical Engineering of Japan, 43, 865–871.
Hollis, F. J., Keren, R., & Gal, M. (1986). Boron release and sorption by fly ash as affected by pH and particle size. Journal of Environmental Quality, 17, 181–184.
Iwashita, A., Sakaguchi, Y., Nakajima, T., Takanashi, H., Ohki, A., & Kambara, S. (2005). Leaching characteristics of boron and selenium for various coal fly ashes. Fuel, 84, 479–485.
Izquierdo, M., & Querol, X. (2012). Leaching behavior of elements from coal combustion fly ash: an overview. International Journal of Coal Geology, 94, 54–66.
Jankowski, J., Ward, C. R., French, D., & Groves, S. (2006). Mobility of trace elements from selected Australian fly ashes and its potential impact on aquatic ecosystems. Fuel, 85, 243–256.
Komonweeraket, K., Cetin, B., Benson, C. H., Aydilek, A. H., & Edil, T. B. (2015). Leaching characteristics of toxic constituents from coal fly ash mixed soils under the influence of pH. Waste Management, 38, 174–194.
Lecuyer, I., Bicocchi, S., Ausset, P., & Lefevre, R. (1996). Physico-chemical characterization and leaching of desulphurization coal fly ash. Waste Management & Research, 14, 15–28.
Lemly, A. D. (2015). Damage cost of the Dan River coal ash spill. Environmental Pollution, 197, 55–61.
Liu, X., Zhao, X., Yin, H., Chen, J., & Zhang, N. (2017). Intermediate-calcium based cementitious materials prepared by MSWI fly ash and other solid wastes: hydration characteristics and heavy metals solidification behavior. Journal of Hazardous Materials, 349, 262–271.
Luhl, R., Vengosh, A., Dwyer, G., Hsu-Kim, H., & Deonarine, A. (2010). Environmental impacts of the coal ash spill in Kingston, Tennessee: an 18-month survey. Environmental Science & Technology, 44, 9272–9278.
Neupane, G., & Donahoe, R. J. (2013). Leachability of elements in alkaline and acidic coal fly ash samples during batch and column leaching tests. Fuel, 104, 758–770.
Ogawa, Y., Sakakibara, K., Suto, K., & Inoue, C. (2014). Immobilization of B, F, Cr, and As in alkaline coal fly ash through an aging process with water. Environmental Monitoring and Assessment, 186, 6757–6770.
Öztürk, N., & Kavak, K. (2005). Adsorption of boron from aqueous solutions using fly ash: batch and column studies. Journal of Hazardous Materials, 127, 81–88.
Polat, H., Vengosh, A., Pankratov, I., & Polat, M. (2004). A new methodology for removal of boron from water by coal and fly ash. Desalination, 164, 173–188.
Polowczyk, I., Ulatowska, J., Koźlecki, T., Bastrzyk, A., & Sawiński, W. (2013). Studies on removal of boron from aqueous solution by fly ash agglomerates. Desalination, 310, 93–101.
Polowczyk, I., Bastrzyk, A., Ulatowska, J., Szczałba, E., Koźlecki, T., & Sadowski, Z. (2016). Influence of pH on arsenic(III) removal by fly ash. Separation Science and Technology, 51, 2612–2619.
Sheng, G., Li, Q., & Zhai, J. (2012). Investigation on the hydration of CFBC fly ash. Fuel, 98, 61–66.
Solem-Tishmack, J. K., McCarthy, G. J., Docktor, B., Eylands, K. E., Thompson, J. S., & Hassett, D. J. (1995). High-calcium coal combustion by-products: engineering properties, ettringite formation, and potential application in solidification and stabilization of selenium and boron. Cement and Concrete Research, 25, 658–670.
Tessier, A., Campbell, P. G. C., & Bisson, M. (1979). Sequential extraction procedure for the speciation of particulate trace metals. Analytical Chemistry, 51, 844–851.
Zhang, M., & Reardon, E. J. (2003). Removal of B, Cr, Mo, and Se from wastewater by incorporation into hydrocalumite and ettringite. Environmental Science & Technology, 37, 2947–2952.
Zhao, S., Chen, Z., Shen, J., Kang, J., Zhang, J., & Shen, Y. (2017). Leaching mechanism of constituents from fly ash under influence of humic acid. Journal of Hazardous Materials, 321, 647–660.
Acknowledgements
The authors thank to Taiheiyo Cement Co. Ltd. for analyzing the chemical compositions of coal fly ash samples. This manuscript was greatly improved by the valuable comments from two anonymous reviewers.
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Ogawa, Y., Sakakibara, K., Seki, T. et al. Immobilization of Boron and Arsenic in Alkaline Coal Fly Ash through an Aging Process with Water and Elucidation of the Immobilization Mechanism. Water Air Soil Pollut 229, 359 (2018). https://doi.org/10.1007/s11270-018-3997-5
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DOI: https://doi.org/10.1007/s11270-018-3997-5