Bioremediation technologies for treatment of PAH-contaminated soil and strategies to enhance process efficiency

被引：180

作者：

Mohan S.V. ^{[1
,2
]}

Kisa T. ^{[2
]}

Ohkuma T. ^{[2
]}

Kanaly R.A. ^{[3
]}

Shimizu Y. ^{[2
]}

机构：

[1] Bioengineering and Environmental Centre, Indian Institute of Chemical Technology

[2] Research Center for Environmental Quality Management, Kyoto University, Otsu

[3] Department of Technology and Ecology, Graduate School of Global Environmental Studies, Kyoto University

来源：

Reviews in Environmental Science and Bio/Technology | 2006年 / 5卷 / 4期

关键词：

Bacterial chemotaxins; Bioaugmentation; Bioavailability; Biomimetic catalytic system; Bioremediation; Biostimulation; Factors; Polycyclic aromatic hydrocarbons (PAHs); Rhizoremediation; Technologies;

D O I：

10.1007/s11157-006-0004-1

中图分类号：

学科分类号：

摘要：

The complex and diverse structural configurations of polycyclic aromatic hydrocarbons (PAHs), combined with their low bioavailability, hydrophobic nature, strong sorption phenomena, and high persistence in soil makes the design of effective bioremediation methodologies a challenge. The multi-phasic nature of the bioremediation process, restricted mass transfer and non-availability of degrading soil microflora further compound the problem. In this direction, this communication presents a focused review of bioremediation technologies used recently for the treatment of PAH-contaminated soils. The specific roles of important factors affecting bioremediation process efficiency are discussed. Finally some of the recently used strategies to enhance bioremediation process efficiency, including bioaugmentation, biostimulation, rhizoremediation, the use of chemotaxins, the biomimetic catalytic system approach, and integrated techniques, are reviewed. © Springer Science+Business Media B.V. 2006.

引用

页码：347 / 374

页数：27

共 179 条

[51]

Garon D., Sage L., Wouessidjewe D., Seigle-Murandi F., Enhanced degradation of fluorine in soil slurry by Absidia cylindrospora and maltosyl-cyclodextrin, Chemosphere, 56, pp. 159-166, (2004)

[52]

Gibb A., Chu A., Wong R.C.K., Goodman R.H., Bioremediation kinetics of crude oil at 5°C, J Environ Eng, 127, pp. 818-824, (2001)

[53]

Gijs D.B., Sparrevik M., Nutrient-limited biodegradation of PAH in various soil strata at a creosote contaminated site, Biodegradation, 11, pp. 391-399, (2000)

[54]

Gogoi B.K., Dutta N.N., Goswami P., Krishna Mohan T.R., A case study of bioremediation of petroleum-hydrocarbon contaminated soil at a crude oil spill site, Adv Environ Res, 7, pp. 767-782, (2003)

[55]

Goi A., Trapido M., Degradation of polycyclic aromatic hydrocarbons in soil: The Fenton reagent versus ozonation, Environ Technol, 25, pp. 155-164, (2004)

[56]

Gong Z., Alef K., Wilke B., Mai M., Li P., Assessment of microbial respiratory activity of a manufactured gas plant soil after remediation using sunflower oil, J Hazard Mater, B124, pp. 217-223, (2005)

[57]

Guerin T.F., Bioremediation of phenols and polycyclic aromatic hydrocarbons in creosote contaminated soil using ex-situ land treatment, J Hazard Mater, B65, pp. 305-315, (1999)

[58]

Guerin T.F., Long-term performance of a land treatment facility for the bioremediation of non-volatile oily wastes, Resour Conserv Recycl, 28, pp. 105-120, (2000)

[59]

Guerin W.F., Boyd S.A., Bioavailability of naphthalene associated with natural and synthetic sorbents, Water Res, 31, pp. 1504-1512, (1997)

[60]

Guerin W.F., Mueller S.A., Boyd S.A., Quantitative assessment of sorbed substrate bioavailability using a mineralization kinetics approach, 84th Annual Meeting, Soil Science Society of America, (1992)

← 1 2 3 4 5 6 7 8 9 10 →