回顾在地下交通建模的挥发性有机化合物的仪器

文摘

挥发性有机化合物(挥发性)是最常见的地下环境污染物通常在非水相液体的形式(NAPL)通过地下储油罐泄漏(私欲)和管道,意外泄漏、土地处置场所,工业废料蓄水池。挥发性有毒,诱变和致癌。因此,挥发性有机化合物的仪器在地下水污染地下构成严重威胁。有机化合物,由于其持久性和波动,呈现独特的包气带土壤环境问题。传输机制和底土的不确定性环境构成严重挑战发展中VOC运输模型化合物。除了平流和色散,VOC也进行一些复杂的化学反应,比如吸附、降解、挥发和离子交换。挥发性有机化合物的仪器的传输机制和传输建模研究主要是基于大量的实地研究和相关的实验室实验。这里的重点是审查的传输机制和建模方面的作用等石油燃料和其他有机化合物液体和液体废物有可能迁移通过地下地下水以及大气蒸汽扩散。

Kehua,你。,Hongbin, Zhan., “Comparisons of diffusive and advective fluxes of gas phase volatile organic compounds (VOCs) in unsaturated zones under natural conditions.”, Advances in Water Resources, 52, pp 221-231, 2013.
1. 迈克尔,o . Rivett。,Gary, P. Wealthall., Rachel, A. Dearden., Todd, A. McAlary., “Review of unsaturated zone transport and attenuation of volatile organic compound (VOC) plumes leached from shallow source zones.”, Journal of Contaminant Hydrology, 123(3-4), pp 130-156, 2011.
2. Hrissi, k . Karapanagioti。Petros Gaganis。,Vasilis, N. Burganos., “Modelling attenuation of volatile organic mixtures in the unsaturated zone : codes and usage.”, Environmental Modelling and Software, 18(4), pp 329-337, 2003.
3. Shyam,奈尔。,Douglas, Longwell., Christian, Seigneur., “Simulation of chemical transport in unsaturated soil.”, Journal of Environmental Engineering, 116(2), pp 214-235, 1990.
4. 布伦特,大肠睡眠。,“Modeling transient organic vapor transport in porous media with the dusty gas model.”, Advances in Water Resources, 22(3), pp 247-256, 1998.
5. 考克斯E。,Austrins, C., Spain, J., Shin, K., Nishino, S., Gossett, J., Giddings, C., Jennings, L., Edwards, E., Johnson, T., Duhamel, M., Sherwood, Lollar, B., “The truth is out there: unraveling the mystery of the missing DCE, vinyl chloride and ethane”. Battelle 7th international conference on remediation of chlorinated and recalcitrant compounds, Monterey, California, pp 18, 2010.
6. 迈克尔·j·日。,Richard, F. Reinke., James, A.M. Thomson., “Fate and transport of fuel components below slightly leaking underground storage tanks.”, Environmental Forensics, 2(1), pp 21-28, 2001.
7. 马里奥,Schirmer。,Barbara, J. Butler., “Transport behavior and natural attenuation of organic contaminants at spill sites.”, Toxicology, 205(3), pp 173-179, 2004.
8. Falta,前作空。,Javandel, I., Pruess, K., Witherspoon, P.A., “Density driven flow of gas in unsaturated zone due to the evaporation of volatile organic compounds.”, Water Resource Research, 25(10), pp2156-2169, 1989.
9. Chiyang李和Evangelos a . Voudrias”喷气燃料的迁移和吸附脂肪族蒸汽在非饱和土。”,水资源。28(12),页2447 - 2456。1994年。
10. Hinchee R。雷E和H。J,“多相运输石油碳氢化合物在地下环境理论和实际应用。”,Proc. Groundwater-Prevention石油碳氢化合物和有机化合物的检测和恢复,国家水井协会,休斯顿,德克萨斯州。,1985年。
11. 哈特菲尔德,K。,Stauffer, T.B., “Transport in porous media containing residual hydrocarbon . I : Model.”. Journal of Environmental Engineering, 119(3), pp 540-558, 1993.
12. Kunberger, T。Gabr,硕士,“Temperature effect on desorption kinetics of benzene on various soils. Waste Contaminant Remediation.”, Geo- Frontiers Congress, Austin, Texas, pp 1-11, 2005.
13. Seon,香港康。,Charles, S. Oulman., “Evaporation of petroleum products from contaminated soils.”, Journal of Environmental Engineering, 122(5), pp 384-387, 1996.
14. 莫卓普,P。,Olesen, T., Yoshikawa, S., Komatsu, T., Rolston, D.E., “Three porosity model for predicting the gas diffusion coefficient in undisturbed soil.”, Soil Science Society of America Journal, 68(3), pp 750–759, 2004.
15. 理发师,C。,Davis, G.B., Briegel, D., Ward, J.K., “Factors controlling the concentration of methane and other volatiles in groundwater and soil gas around a waste site.”, Journal of Contaminant Hydrology, 5, pp 155–169, 1990.
16. 帕克,J.C.,“Physical processes affecting natural depletion of volatile chemicals in soil and groundwater.”, Vadose Zone Journal, 2(2), pp 222–230, 2003.
17. 威廉姆斯,通用病房,R.S.纳,这位,” Dynamics of landfill gas migration in unconsolidated sands.”, Waste Management Research, 17(5), pp 327- 342, 1999.
18. Rivett,犯罪手法,Thornton, S.F., “Monitored natural attenuation of organic contaminants in groundwater: principles and application.”, Water Management, 161 (6), pp 381-392, 2008.
19. Parashar, R。,Govindaraju, R.S., “Moment analysis of fate and transport of volatile pollutants in porous media.”, World Water and Environmental Resources Congress, Philadelpia, pp 1-10, 2003.
20. 李,他。,Guo, H. Huang., Lu, H.W., “Characterization of petroleum-hydrocarbon fate and transport in homogeneous and heterogeneous aquifers using a generalized uncertainty estimation method.”, Journal of Environmental Engineering, 137(1), pp 1-8, 2011.
21. 康奈尔·l·D,“简单模型地下结合非饱和溶质运移,饱和区通路。《水文。332(3 - 4),361 - 373页,2007年。
22. molin, S。,Mayer, K.U., Amos, R.T., Bekins, B.A., “Vadose zone attenuation of organic compounds at a crude oil spill site - interactions between biogeochemical reactions and multicomponent gas transport.”, Journal of Contaminant Hydrology, 112 (1-4), pp 15–29, 2010.
23. 哎呀,G.W.,Oostrom, M., Freshley, M.D., Rockhold, M.L., Zachara, J.M., “Hanford Site Vadose Zone studies: an overview.”, Vadose Zone Journal. 6(4), pp 899-905, 2007.
24. 苏雷什,Kartha。,Rajesh, Srivastava., “Effect of immobile water content on contaminant transport in unsaturated zone.”, Journal of Hydro- Environment Research, 1(3-4), pp 206-215, 2008.
25. 曹国伟,山。,Daniel, B. Stephens., “An analytical solution for vertical transport of volatile chemicals in the vadose zone.”, Journal of Contaminant Hydrology, 18, pp 259-277, 1995.
26. [27]Troldborg, M。装箱,P。尼尔森,S。,Kjeldsen, P., Christensen, A., “Unsaturated zone leaching models for assessing risk to groundwater of contaminated sites.”, Journal of Contaminant Hydrology, 105(1-2), pp 28–37, 2009.