Bioremediation of benzene from groundwater by calcium peroxide (CaO2) nanoparticles encapsulated in sodium alginate

Journal of the Taiwan Institute of Chemical Engineers

Volumn 78, Issue , 2017, Pages 299-306

  Mosmeri, Hamid ^a   Alaie, Ebrahim ^a   Shavandi, Mahmoud ^a   Dastgheib, Seyed Mohamad Mehdi ^a   Tasharrofi, Saeideh ^a  

^a RESEARCH INSTITUTE OF PETROLEUM INDUSTRY RIPI   (Iran)

Author keywords

Benzene remediation; Bioremediation; CaO2; Encapsulation; Modified Fenton; ORC

Indexed keywords

ADDITION REACTIONS; BENZENE; BIOREMEDIATION; BIOTECHNOLOGY; CALCIUM; EFFLUENT TREATMENT; GROUNDWATER; NANOPARTICLES; OXIDATION; PEROXIDES; POLLUTION; WATER TREATMENT;

CAO2; COLUMN EXPERIMENTS; INITIAL TEMPERATURES; LOWER TEMPERATURES; MICROBIAL POPULATIONS; MODIFIED FENTON; OXYGEN GENERATION; REACTIVE BARRIERS;

ENCAPSULATION;

EID: 85021891263     PISSN: 18761070     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jtice.2017.06.020     Document Type: Article

References (50)

1. ATSDR, U.D., Toxicological profile for benzene agency for toxic substances and disease registry, US Department of Health and Human Services. Public Health Service, 1993.
2. Xie, Y, Li, X, Liu, X, Du, X, Li, F, Cao, Y, Performance evaluation of remediation scenarios for DNAPL contaminated groundwater using analytical models and probabilistic methods. Proc Environ Sci 31 (2016), 264–273.
3. Xin, B-P, Wu, C-H, Wu, C-H, Lin, C-W, Bioaugmented remediation of high concentration BTEX-contaminated groundwater by permeable reactive barrier with immobilized bead. J Hazard Mater 244 (2013), 765–772.
4. Rasmussen, G., Fremmersvik, G., Olsen, R.A., Treatment of creosote-contaminated groundwater in a peat/sand permeable barrier—a column study. J Hazard Mater 93:3 (2002), 285–306.
5. Guerin, TF, Horner, S, McGovern, T, Davey, B, An application of permeable reactive barrier technology to petroleum hydrocarbon contaminated groundwater. Water Res 36:1 (2002), 15–24.
6. Huang, G, Liu, F, Yang, Y, Deng, W, Li, S, Huang, Y, et al. Removal of ammonium-nitrogen from groundwater using a fully passive permeable reactive barrier with oxygen-releasing compound and clinoptilolite. J Environ Manage 154 (2015), 1–7.
7. Huang, G, Huang, Y, Hu, H, Liu, F, Zhang, Y, Deng, R, Remediation of nitrate–nitrogen contaminated groundwater using a pilot-scale two-layer heterotrophic–autotrophic denitrification permeable reactive barrier with spongy iron/pine bark. Chemosphere 130 (2015), 8–16.
8. Liu, J., He, L., Dong, F., Hudson-Edwards, K.A., The role of nano-sized manganese coatings on bone char in removing arsenic (V) from solution: Implications for permeable reactive barrier technologies. Chemosphere 153 (2016), 146–154.
9. Statham, T.M., Stark, S.C., Snape, I., Stevens, G.W., Mumford, K.A., A permeable reactive barrier (PRB) media sequence for the remediation of heavy metal and hydrocarbon contaminated water: a field assessment at Casey Station, Antarctica. Chemosphere 147 (2016), 368–375.
10. Wang, Y., Pleasant, S., Jain, P., Powell, J., Townsend, T., Calcium carbonate-based permeable reactive barriers for iron and manganese groundwater remediation at landfills. Waste Manage 53 (2016), 128–135.
11. De Pourcq, K., Ayora, C., García-Gutiérrez, M., Missana, T., Carrera, J., A clay permeable reactive barrier to remove Cs-137 from groundwater: column experiments. J Environ Radioact 149 (2015), 36–42.
12. Muchitsch, N., Van Nooten, T., Bastiaens, L., Kjeldsen, P., Integrated evaluation of the performance of a more than seven year old permeable reactive barrier at a site contaminated with chlorinated aliphatic hydrocarbons (CAHs). J Contam Hydrol 126:3 (2011), 258–270.
13. Thiruvenkatachari, R., Vigneswaran, S., Naidu, R., Permeable reactive barrier for groundwater remediation. J Ind Eng Chem 14:2 (2008), 145–156.
14. Chen, L., Liu, F., Liu, Y., Dong, H., Colberg, P.J., Benzene and toluene biodegradation down gradient of a zero-valent iron permeable reactive barrier. J Hazard Mater 188:1 (2011), 110–115.
15. Freidman, B.L., Gras, S.L., Snape, I., Stevens, G.W., Mumford, K.A., The performance of ammonium exchanged zeolite for the biodegradation of petroleum hydrocarbons migrating in soil water. J Hazard Mater 313 (2016), 272–282.
16. Jun, D., Yongsheng, Z., Weihong, Z., Mei, H., Laboratory study on sequenced permeable reactive barrier remediation for landfill leachate-contaminated groundwater. J Hazard Mater 161:1 (2009), 224–230.
17. Liang, S., Kao, C., Kuo, Y., Chen, K., Application of persulfate-releasing barrier to remediate MTBE and benzene contaminated groundwater. J Hazard Mater 185:2 (2011), 1162–1168.
18. Georgi, A., Schierz, A., Mackenzie, K., Kopinke, F.-D., Colloidal activated carbon for in-situ groundwater remediation—Transport characteristics and adsorption of organic compounds in water-saturated sediment columns. J Contam Hydrol 179 (2015), 76–88.
19. Teerakun, M., Reungsang, A., Lin, C.-J., Liao, C.-H., Coupling of zero valent iron and biobarriers for remediation of trichloroethylene in groundwater. J Environ Sci 23:4 (2011), 560–567.
20. Choi, J.-H., Kim, Y.-H., Choi, S.J., Reductive dechlorination and biodegradation of 2, 4, 6-trichlorophenol using sequential permeable reactive barriers: laboratory studies. Chemosphere 67:8 (2007), 1551–1557.
21. Liu, S.-J., Jiang, B., Huang, G.-Q., Li, X.-G., Laboratory column study for remediation of MTBE-contaminated groundwater using a biological two-layer permeable barrier. Water Res 40:18 (2006), 3401–3408.
22. Cassidy, D.P., Irvine, R.L., Use of calcium peroxide to provide oxygen for contaminant biodegradation in a saturated soil. J Hazard Mater 69:1 (1999), 25–39.
23. 2) for use in modified Fenton chemistry. J Hazard Mater 152:3 (2008), 1164–1170.
24. Qian, Y., Zhou, X., Zhang, Y., Zhang, W., Chen, J., Performance and properties of nanoscale calcium peroxide for toluene removal. Chemosphere 91:5 (2013), 717–723.
25. Wang, H., Zhao, Y., Li, T., Chen, Z., Wang, Y., Qin, C., Properties of calcium peroxide for release of hydrogen peroxide and oxygen: A kinetics study. Chem Eng J 303 (2016), 450–457.
26. Zhang, X., Gu, X., Lu, S., Miao, Z., Xu, M., Fu, X., et al. Degradation of trichloroethylene in aqueous solution by calcium peroxide activated with ferrous ion. J Hazard Mater 284 (2015), 253–260.
27. Watts, R.J., Dilly, S.E., Evaluation of iron catalysts for the Fenton-like remediation of diesel-contaminated soils. J Hazard Mater 51:1-3 (1996), 209–224.
28. Yeh, C.-H., Lin, C.-W., Wu, C.-H., A permeable reactive barrier for the bioremediation of BTEX-contaminated groundwater: microbial community distribution and removal efficiencies. J Hazard Mater 178:1 (2010), 74–80.
29. Lin, C.-W., Wu, C.-H., Tang, C.-T., Chang, S.-H., Novel oxygen-releasing immobilized cell beads for bioremediation of BTEX-contaminated water. Bioresour Technol 124 (2012), 45–51.
30. Wei, W., Reddy, D.H.K., Bediako, J.K., Yun, Y.-S., Aliquat-336-impregnated alginate capsule as a green sorbent for selective recovery of gold from metal mixtures. Chem Eng J 289 (2016), 413–422.
31. Furusawa, T., Kurayama, F., Shiba, M., Kadota, R., Sato, M., Suzuki, N., CaO-loaded alginate capsule modified with silane coupling agents for transesterification of rapeseed oil with methanol. Chem Eng J 288 (2016), 473–481.
32. Messaoud, G.B., Sánchez-González, L., Jacquot, A., Probst, L., Desobry, S., Alginate/sodium caseinate aqueous-core capsules: a pH-responsive matrix. J Colloid Interface Sci 440 (2015), 1–8.
33. Wang, J.-P., Zhang, X.-X., Wang, X.-C., Preparation, characterization and permeation kinetics description of calcium alginate macro-capsules containing shape-stabilize phase change materials. Renewable Energy 36:11 (2011), 2984–2991.
34. Wang, J.-Y., Jin, Y., Xie, R., Liu, J.-Y., Ju, X.-J., Meng, T., et al. Novel calcium-alginate capsules with aqueous core and thermo-responsive membrane. J Colloid Interface Sci 353:1 (2011), 61–68.
35. Johnson, S., Woolhouse, K., Prommer, H., Barry, D., Christofi, N., Contribution of anaerobic microbial activity to natural attenuation of benzene in groundwater. Eng Geol 70:3 (2003), 343–349.
36. Hao, J., Qiu, S., Li, H., Chen, T., Liu, H., Li, L., Roles of hydroxyl radicals in electrolyzed oxidizing water (EOW) for the inactivation of Escherichia coli. Int J Food Microbiol 155:3 (2012), 99–104.
37. Lee, C.-S., Le Thanh, T., Kim, E.-J., Gong, J., Chang, Y.-Y., Chang, Y.-S., Fabrication of novel oxygen-releasing alginate beads as an efficient oxygen carrier for the enhancement of aerobic bioremediation of 1, 4-dioxane contaminated groundwater. Bioresour Technol 171 (2014), 59–65.
38. Xue, Y., Gu, X., Lu, S., Miao, Z., Brusseau, M.L., Xu, M, et al. The destruction of benzene by calcium peroxide activated with Fe (II) in water. Chem Eng J 302 (2016), 187–193.
39. Palmroth, M., Langwaldt, J., Aunola, T., Goi, A., Münster, U., Puhakka, J., et al. Effect of modified Fenton's reaction on microbial activity and removal of PAHs in creosote oil contaminated soil. Biodegradation 17:2 (2006), 29–39.
40. Wink, D.A., Nims, R.W., Saavedra, J.E., Utermahlen, W.E., Ford, P., The Fenton oxidation mechanism: reactivities of biologically relevant substrates with two oxidizing intermediates differ from those predicted for the hydroxyl radical. Proc Natl Acad Sci 91:14 (1994), 6604–6608.
41. Fritsche, W., Hofrichter, M., Aerobic degradation by microorganisms. Biotechnology Set. 2nd ed., 2008, 144–167.
42. Padhi, S.K., Gokhale, S., Benzene biodegradation by indigenous mixed microbial culture: kinetic modeling and process optimization. Int Biodeterior Biodegrad 119 (2017), 511–519.
43. Zhang, H., Choi, H.J., Huang, C.-P., Optimization of Fenton process for the treatment of landfill leachate. J Hazard Mater 125:1 (2005), 166–174.
44. 2: implications in solar water disinfection. Appl Catal B: Environ 51:4 (2004), 283–302.
45. Aronsson, K., Rönner, U., Influence of pH, water activity and temperature on the inactivation of Escherichia coli and Saccharomyces cerevisiae by pulsed electric fields. Innovative Food Sci Emerg Technol 2:2 (2001), 105–112.
46. Ortega-Gómez, E., Fernández-Ibáñez, P., Martín, M.B., Polo-López, M., García, B.E., Pérez, J.S., Water disinfection using photo-Fenton: effect of temperature on Enterococcus faecalis survival. Water Res 46:18 (2012), 6154–6162.
47. Wang, S., A comparative study of Fenton and Fenton-like reaction kinetics in decolourisation of wastewater. Dyes Pigm 76:3 (2008), 714–720.
48. Coulon, F., McKew, B.A., Osborn, A.M., McGenity, T.J., Timmis, K.N., Effects of temperature and biostimulation on oil‐degrading microbial communities in temperate estuarine waters. Environ Microbiol 9:1 (2007), 177–186.
49. Camci-Unal, G., Alemdar, N., Annabi, N., Khademhosseini, A., Oxygen‐releasing biomaterials for tissue engineering. Polym Int 62:6 (2013), 843–848.
50. Abdi, S.I.H., Choi, J.Y., Lau, H.C., Lim, J.O., Controlled release of oxygen from PLGA-alginate layered matrix and its in vitro characterization on the viability of muscle cells under hypoxic environment. Tissue Eng Regener Med 10:3 (2013), 131–138.