Abstract
Cocopeat is a cheap and easily available organic product. In this study, kinetics of hexavalent chromium [Cr(VI)] stabilization by cocopeat in three soils with different pH and organic carbon content, and the effects of influencing factors including ionic strength (0.03, 0.1 and 0.3 M KCl), temperature (10, 25 and 35 °C) and pH (5.2, 6.2 and 7.2) were investigated in a set of batch experiments by varying Cr(VI) and cocopeat concentrations. In this research, there was no possibility of spiking the soils with the same range of initial Cr(VI) concentration. Addition of Cr(VI) in higher levels masked the effect of soil on Cr(VI) reduction in a calcareous soil, while lower levels resulted in complete stabilization of Cr(VI) in a slightly acid soil. Cocopeat efficiently stabilized Cr(VI) in the soil suspensions within a few days. The time trend of Cr(VI) reduction was different in the three soil samples. The rate of Cr(VI) stabilization strongly increased with decreasing pH and increasing temperature, while remained unchanged with changes in ionic strength. Finally, the overall empirical pseudo-first order rate equation was determined to describe the reduction rate of Cr(VI) by cocopeat in soils.
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Abad M, Noguera P, Puchades R, Maquieira A, Noguera V (2002) Physico-chemical and chemical properties of some coconut dusts for use as a peat substitute for containerized ornamental plants. Bioresour Technol 82:241–245
Abdul Khalil HPS, Siti Alwani M, Mohd Omar AK (2006) Chemical composition, anatomy, lignin distribution, and cell wall structure of Malaysian plant waste fibers. BioResources 1(2):220–232
Albadarin AB, Glocheux Y, Ahmad MNM, Walker GM, Mangwandia C (2014) Novel comparison of kinetic models for the adsorption-coupled reduction of Cr(VI) using untreated date pit biomaterial. Ecol Eng 70:200–205
Allison LE, Moodie CD (1965) Carbonate. In: Black CA et al (eds) Methods of soil analysis, Part, vol 2. Chemical and microbiological properties. SSSA and ASA, Madison, WI, USA, pp 1379–1400
ATSDR, Agency for Toxic Substances and Disease Registry (2012) Toxicological profile for chromium. Atlanta, GA: US Department of Health and Human Services
Awang Y, Shaharom AS, Mohamad RB, Selamat A (2009) Chemical and physical characteristics of coco peat based media mixtures and their effects on the growth and development of Celosia Cristata. Am J Agric Biol Sci 4:63–71
Barnhart J (1997) Occurrences, uses, and properties of chromium. Regul Toxicol Pharmacol 26(1):S3–S7
Bartlett RJ, Kimble JM (1976) Behavior of chromium in soils: II. Hexavalent forms Journal of Environmental Quality 5:383–386
Bolan NS, Adriano DC, Natesan R, Koo B (2003) Effects of organic amendments on the reduction and phytoavailability of chromate in mineral soil. J Environ Qual 32:120–128
Brose DA, James BR (2010) Oxidation-reduction transformations of chromium in aerobic soils and the role of electron-shuttling quinones. Environ Sci Technol 44:9438–9444
Cassel DK, Nielsen DR (1986) Field capacity and available water capacity. In: Klute A (ed) Methods of soil analysis. Part I: Physical and Mineralogical Methods. SSSA and ASA. Madison, WI, USA, pp 901–926
Chapman HD (1965) Cation exchange capacity. In: Black CA (ed) Methods of soil analysis. Part 2: chemical and microbiological properties. SSSA and ASA, Madison, WI, USA, pp 891–901
Chen CP, Juang KW, Lee DY (2012) Effects of liming on Cr(VI) reduction and Cr phytotoxicity in Cr(VI)-contaminated soils. J Soil Sci Plant Nutr 58:135–143
Chiu CC, Cheng CJ, Lin TH, Juang KW, Lee DY (2009) The effectiveness of four organic matter amendments for decreasing resin-extractable Cr(VI) in Cr(VI)-contaminated soils. J Hazard Mater 161:1239–1244
Choppala G, Bolan N, Seshadri B (2013) Chemodynamics of chromium reduction in soils: implications to bioavailability. J Hazard Mater 261:718–724
Conant RT, Ryan MG, Agren GI, Birge HE, Davidson EA, Eliasson PE, Evans SE, Fery CP et al (2011) Temperature and soil organic matter decomposition rates—synthesis of current knowledge and a way forward. Glob Chang Biol 17:3392–3404
Daneshvar N, Salari D, Aber S (2002) Chromium adsorption and Cr(VI) reduction to trivalent chromium in aqueous solutions by soya cake. J Hazard Mater 94:49–61
El-Shafey EI (2005) Behaviour of reduction-sorption of chromium(VI) from an aqueous solution on a modified sorbent from rice husk. Water Air Soil Pollut 163:81–102
Gambrell RP, Patrick WH (1982) Manganese. In: Page AL et al (eds) Methods of soil analysis. Part 2: chemical and microbiological methods. SSSA and ASA, Madison, WI. USA. pp 313-322
Gardea-Torresdey JL, Tiemann KJ, Armendariz V, Bess-Oberto L, Chianelli RR, Rios J, Parsons JG, Gamez G (2000) Characterization of Cr(VI) binding and reduction to Cr(III) by the agricultural byproducts of Avena monida (Oat) biomass. J Hazard Mater 80:175–188
Garg UK, Kaur MP, Garg VK, Sud D (2007) Removal of hexavalent chromium from aqueous solution by agricultural waste biomass. J Hazard Mater 140:60–68
Gee GW, Bauder JW (1986) Particle-size analysis. In: Klute A (ed) Methods of soil analysis. Part 1: physical and mineralogical methods. SSSA and ASA, Madison, WI, USA, pp 383–411
Hasan SH, Singh KK, Prakash O, Talat M, Ho YS (2008) Removal of Cr(VI) from aqueous solutions using agricultural waste ‘maize bran’. J Hazard Mater 152:356–365
Henryk K, Jaraslaw C, Witold Z (2016) Peat and coconut fiber as biofilters for chromium adsorption from contaminated wastewaters. Environ Sci Pollut Res 23:527–534
Hsu LC, Wang SL, Lin YC, Wang MK, Chiang PN, Liu JC, Kuan WH, Chen CC, Tzou YM (2010) Cr (VI) removal on fungal biomass of Neurospora crassa: the importance of dissolved organic carbons derived from the biomass to Cr (VI) reduction. Environ Sci Technol 44(16):6202–6208
Huang SW, Chiang PN, Liu JC, Hung JT, Kuan WH, Tzou YM, Wang SL, Huang JH, Chen CC, Wang MK, Loeppert RH (2012) Chromate reduction on humic acid derived from a peat soil-exploration of the activated sites on HAs for chromate removal. Chemosphere 87:587–594
James BR, Bartlett RJ (1983) Behavior of Chromium in Soils: VI. Interaction between oxidation-reduction and organic complexation. VII. Adsorption and Reduction of Hexavalent Forms. J Environ Qual 12:173–181
Jiang J, Xu R, Wang Y, Zhao A (2008) The mechanism of chromate sorption by three variable charge soils. Chemosphere 71:1469–1475
Kantar C, Cetin Z, Demiray H (2008) In situ stabilization of chromium (VI) in polluted soils using organic ligands: the role of galacturonic, glucuronic and alginic acids. J Hazard Mater 159:287–293
Khorshid M, Oustan S, Najafi N, Khataee A (2016) Treatment of Cr(VI)-spiked soils using sulfur-based amendments. Arch Agron Soil Sci 62:1474–1485
Kowalski Z (1994) Treatment of chromic tannery wastes. J Hazard Mater 37(1):137–144
Landrot G, Ginder-Vogel M, Sparks D (2010) Kinetics of chromium (III) oxidation by manganese(IV) oxides using quick scanning X-ray absorption fine structure spectroscopy (Q-XAFS). Environ Sci Technol 44:143–149
Li L, Liu S, Zhu T (2010) Application of activated carbon derived from scrap tires for adsorption of rhodamine B. J Environ Sci 22:1273–1280
Lierop WV (1990) Soil pH and lime requirement determination. In: Westerman RL (ed) Soil testing and plant analysis. SSSA and ASA, Madison, WI. USA, pp 73–126
López-Luna J, González-Chávez MC, Esparza-García FJ, Rodríguez-Vázquez R (2009) Toxicity assessment of soil amended with tannery sludge, trivalent chromium and hexavalent chromium, using wheat, oat and sorghum plants. J Hazard Mater 163(2-3):829–834
Losi ME, Amrhein C, Frankenherger WT (1994) Bioremediation of chromate contaminated groundwater by reduction and precipitation in surface soils. J Environ Qual 23(6):1141–1150
Nelson DW, Sommers LE (1996) Total carbon, organic carbon, and organic matter. In: Sparks DL et al (eds) Methods of soil analysis. Part 3: Chemical methods. SSSA and ASA, Madison, WI. USA. pp. 961-1010
Ohta A, Kagi H, Tsuno H, Nomura M, Oki T (2012) Speciation study of Cr(VI/III) reacting with humic substances and determination of local structure of Cr binding humic substances using XAFS spectroscopy. Geochem J 46:409–420
Park D, Yun YS, Park JM (2004) Reduction of hexavalent chromium with the brown seaweed Ecklonia biomass. Environ Sci Technol 38:4860–4864
Park D, Yun YS, Park JM (2005) Use of dead fungal biomass for the stabilization of hexavalent chromium: screening and kinetics. Process Biochem 40:2559–2565
Park D, Lim SR, Lee HW, Park JM (2008) Mechanism and kinetics of Cr(VI) reduction by waste slag generated from iron making industry. Hydrometallurgy 93:72–75
Rencoret J, Ralph J, Marques G, Gutierrez A, Martínez A, del Río JC (2013) Structural characterization of lignin isolated from coconut (Cocos nucifera) coir fibers. J Agric Food Chem 61:2434–2445
Rhoades JD (1996) Salinity: Electrical conductivity and total dissolved salts. In: Sparks DL et al (eds) Methods of soil analysis. Part 3: Chemical methods. SSSA and ASA, Madison, WI. USA. pp. 417-436
Rivero-Huguet M, Marshall WD (2009) Influence of various organic molecules on the reduction of hexavalent chromium mediated by zero-valent iron. Chemosphere 76(9):1240–1248
Sangi MR, Shahmoradi A, Zolgharnein J, Azimi GH, Ghorbandoost M (2008) Removal and recovery of heavy metals from aqueous solution using Ulmus carpinifolia and Fraxinus excelsior tree leaves. J Hazard Mater 155:513–522
Scaglia B, Tambone F, Adani F (2013) Cr(VI) reduction capability of humic acid extracted from the organic component of municipal solid waste. J Environ Sci 25:487–494
Shen YS, Wang SL, Huang ST, Tzou YM, Huang JH (2010) Biosorption of Cr(VI) by coconut coir: spectroscopic investigation on the reaction mechanism of Cr(VI) with lignocellulosic material. J Hazard Mater 179:160–165
Shen YS, Wang SL, Tzou YM, Yan YY, Kuan WH (2012) Removal of hexavalent Cr by coconut coir and derived chars: the effect of surface functionality. Bioresour Technol 104:165–172
Singh KK, Hasan SH (2005) Removal of copper from wastewater using rice polish (rice bran). J Indian Chem Soc 82:374–375
Sparks DL (1986) Kinetics of soil chemical processes. Academic Press, San Diego, CA
Suksabye P, Nakajima A, Thiravetyan P, Baba Y, Nakbanpote W (2009) Mechanism of Cr(VI) adsorption by coir pith studied by ESR and adsorption kinetic. J Hazard Mater 161:1103–1108
Tan WT, Ooi ST, Lee CK (1993) Removal of chromium (VI) from solution by coconut husk and palm pressed fibers. Environ Technol 14:277–282
Tassi E, Grifoni M, Bardelli F, Aquilanti G, La Felice S, Iadecola A, Lattanzi P, Petruzzelli G (2018) Evidence for the natural origins of anomalously high chromium levels in soils of the Cecina Valley (Italy). Environ Sci: Process Impacts 20(6):965–976
Tokunaga TK, Wan J, Firestone MK, Hazen TC, Olson KR, Herman DJ, Sutton SR, Lanzirotti A (2003) In situ reduction of chromium (VI) in heavily contaminated soils through organic carbon amendment. J Environ Qual 32:1641–1649
Tsopmo A, Gao Q, Baakdah MM (2014) Reduction of hexavalent chromium by digested oat bran proteins. Food Chem 153:171–176
USEPA, United States Environmental Protection Agency (1992) Chromium hexavalent (colorimetric), Method 7196A, Revision 1. Office of Solid Waste and Emergency Response. Washington, USA
Weng CH, Huang CP, Sanders PF (2001) Effect of pH on Cr(VI) leaching from soil enriched in chromate ore processing residue. Environ Geochem Health 23:207–211
Wittbrodt PR, Palmer CD (1995) Reduction of Cr(VI) in the presence of excessive soil fulvic acid. Environ Sci Technol 29:255–263
Wittbrodt PR, Palmer CD (1996) Effect of temperature, ionic strength, background electrolytes, and Fe(III) on the reduction of hexavalent chromium by soil humic substances. Environ Sci Technol 30:2470–2477
Wrobel K, Corrales Escobosa AR, Gonzalez Ibarra AA, Mendez Garcia M, Yanez Barrientos E, Wrobel K (2015) Mechanistic insight into chromium(VI) reduction by oxalic acid in the presence of manganese(II). J Hazard Mater 300:144–152
Wuana RA, Okieimen FE (2011) Heavy metals in contaminated soils: a review of sources, chemistry, risks and best available strategies for remediation. ISRN Ecology, Article ID 402647:1–20
Xiao W, Zhang Y, Li T, Chen B, Wang H, He Z, Yang X (2012) Reduction kinetics of hexavalent chromium in soils and its correlation with soil properties. J Environ Qual 41(5):1452–1458
Xu XR, Li HB, Li XU, Gu JD (2004) Reduction of hexavalent chromium by ascorbic acid in aqueous solutions. Chemosphere 57(7):609–613
Zhilin DM, Schmitt-Kopplin P, Perminova IV (2004) Reduction of Cr(VI) by peat and coal humic substances. Environ Chem Lett 2:141–145
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Khorshid, M., Oustan, S., Najafi, N. et al. Kinetic characterization of hexavalent chromium stabilization in contaminated soils amended with cocopeat. Arab J Geosci 13, 428 (2020). https://doi.org/10.1007/s12517-020-05421-8
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DOI: https://doi.org/10.1007/s12517-020-05421-8