請用此 Handle URI 來引用此文件:
http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/50134
完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 劉懷勝 | |
dc.contributor.author | Yi-An Chang | en |
dc.contributor.author | 張逸安 | zh_TW |
dc.date.accessioned | 2021-06-15T12:30:35Z | - |
dc.date.available | 2018-08-31 | |
dc.date.copyright | 2016-08-31 | |
dc.date.issued | 2016 | |
dc.date.submitted | 2016-08-04 | |
dc.identifier.citation | Aburto-Medina, A., E. M. Adetutu, S. Aleer, J. Weber, S. S. Patil, P. J. Sheppard, A. S. Ball and A. L. Juhasz (2012). 'Comparison of indigenous and exogenous microbial populations during slurry phase biodegradation of long-term hydrocarbon-contaminated soil.' Biodegradation 23(6): 813-822.
Aislabie, J., D. J. Saul and J. M. Foght (2006). 'Bioremediation of hydrocarbon-contaminated polar soils.' Extremophiles 10(3): 171-179. Al-Araji, L., R. N. Z. R. A. Rahman, M. Basri, A. B. Salleh, N. M. Nasaruddin, K. Harikrishna, R. Y. Othman, L. S. Hoon, J. A. Harikrishna (2007). 'Microbial Surfactant.' Asia Pacific J. Molec. Biol. Biotechnol 15: 99-105. Alexander, M. (1980). 'In Dynamics, Exposure and Harzard Assessment of Toxic Chemicals.' Biodegradation of toxic chemicals in water and soil. :179-190. Alexander, M. (1999). 'Biodegradation and Bioremediation 2.' New York: Academic Press: 271-279. Allard, A. S. and A. H. Neilson (1997). 'Bioremediation of organic waste sites: A critical review of microbiological aspects.' International Biodeterioration & Biodegradation 39(4): 253-285. Altas, R.M., and Bartha, R. (1977). 'The microbiology of aquatic oil spills.' Advanced and Applied Microbiology 22: 225-266. Alvarez, H. M., M. F. Souto, A. Viale and O. H. Pucci (2001). 'Biosynthesis of fatty acids and triacylglycerols by 2,6,10,14-tetramethyl pentadecane-grown cells of Nocardia globerula 432.' Fems Microbiology Letters 200(2): 195-200. Aspray, T. J., D. J. C. Carvalho and J. C. Philp (2007). 'Application of soil slurry respirometry to optimise and subsequently monitor ex situ bioremediation of hydrocarbon-contaminated soils.' International Biodeterioration & Biodegradation 60(4): 279-284. Atlas, R. and J. Bragg (2009). 'Bioremediation of marine oil spills: when and when not - the Exxon Valdez experience.' Microbial Biotechnology 2(2): 213-221. Bell, K. S., J. C. Philp, D. W. J. Aw and N. Christofi (1998). 'A review - The genus Rhodococcus.' Journal of Applied Microbiology 85(2): 195-210. Berthe-Corti, L. and W. Ebenhoh (1999). 'A mathematical model of cell growth and alkane degradation in Wadden Sea sediment suspensions.' Biosystems 49(3): 161-189. Bobe, A., C. M. Coste and J. F. Cooper (1997). 'Factors influencing the adsorption of fipronil on soils.' Journal of Agricultural and Food Chemistry 45(12): 4861-4865. Boopathy, R. (2000). 'Factors limiting bioremediation technologies.' Bioresource Technology 74(1): 63-67. Bouwer, E. J. and A. J. B. Zehnder (1993). 'Bioremediation of Organic-Compounds - Putting Microbial-Metabolism to Work.' Trends in Biotechnology 11(8): 360-367. Britton, L. N. (1984). 'Microbial degradation of organic compounds. ' Marcel Dekker New York. Cai Yuehua, Zhang Dan, Jiang Lin, Zhong Maosheng, Peng Chao, Jiang Dengdeng (2013). 'A review: The technologies of chemical pre-oxidation combining biodegradation for PAHs contaminated soils treatment .' Environmental Engineering: 150-155. Carberry, J. B. and T. M. Benzing (1991). 'Peroxide Preoxidation of Recalcitrant Toxic-Waste to Enhance Biodegradation.' Water Science and Technology 23(1-3): 367-376. Casella, S. and W. J. Payne (1996). 'Potential of denitrifiers for soil environment protection.' Fems Microbiology Letters 140(1): 1-8. Cerniglia, C. E., and D. T., Gibson (1977). 'Metabolism of naphthalene by Cunnunghaella elegans.' Applied and Environmental Microbiology 34: 363-370. Chang, W.-N., C.-W. Liu and H.-S. Liu (2009). 'Hydrophobic cell surface and bioflocculation behavior of Rhodococcus erythropolis.' Process Biochemistry 44(9): 955-962. Chiou C.T., Porter P. E., Schmedding D. W. (1983). 'Partition equilibriums of nonionic organic compounds between soil organic matter and water. ' Environ Sci Technol 17: 227-231. Collins, M. D., M. Goodfellow and D. E. Minnikin (1982). 'A Survey of the Structures of Mycolic Acids in Corynebacterium and Related Taxa.' Journal of General Microbiology 128(Jan): 129-149. Conte, P., A. Agretto, R. Spaccini and A. Piccolo (2005). 'Soil remediation: humic acids as natural surfactants in the washings of highly contaminated soils.' Environ Pollut 135(3): 515-522. Coon, M. J. (2005). 'Omega oxygenases: Nonheme-iron enzymes and P450 cytochromes.' Biochemical and Biophysical Research Communications 338(1): 378-385. Cooney, J. J., S. A. Silver and E. A. Beck (1985). 'Factors Influencing Hydrocarbon Degradation in 3 Fresh-Water Lakes.' Microbial Ecology 11(2): 127-137. Cravo-Laureau, C., V. Grossi, D. Raphel, R. Matheron and A. Hirschler-Rea (2005). 'Anaerobic n-alkane metabolism by a sulfate-reducing bacterium, Desulfatibacillum aliphaticivorans strain CV2803.' Applied and Environmental Microbiology 71(7): 3458-3467. de Carvalho, C. C. C. R. and M. M. R. da Fonseca (2002). 'Maintenance of cell viability in the biotransformation of (-)-carveol with whole cells of Rhodococcus erythropolis.' Journal of Molecular Catalysis B-Enzymatic 19: 389-398. de Carvalho, C. C. C. R. and M. M. R. da Fonseca (2005). 'The remarkable Rhodococcus erythropolis.' Applied Microbiology and Biotechnology 67(6): 715-726. Dibble, J. T. and R. Bartha (1979). 'Effect of Environmental Parameters on the Biodegradation of Oil Sludge.' Applied and Environmental Microbiology 37(4): 729-739. Doick, K. J. and K. T. Semple (2003). 'The effect of soil:water ratios on the mineralisation of phenanthrene:LNAPL mixtures in soil.' FEMS Microbiology Letters 220(1): 29-33. Eastcott, L., W. Y. Shiu, D. Mackay (1988). 'Environmentally relevant physical-chemical properties of hydrocarbons: a review of data and development of simple correlateons.' Oil and Chemical Pollution 4: 191-216. Evans, G. M., and Furlong, J. C. (2003). 'Contaminated Land and Bioremediation.' Environmental Biotechnology Theory and Application: 91-94. Eweis, J. B., Ergas, S. J., Chang, D. P. Y., and Schroeder, E. D. (1998). 'Bioremediaton Principles.' McGraw-Hill Companies, Inc.: 111-113. Fehse, K.-U., H. Borg, E. Sorkau, K. Pilchowski and L. Luckner (2009). 'Correcting the Effect of the Sorbent to Solution Ratio on Sorption Isotherms from Batch Tests with Soils and Sediments.' Water, Air, & Soil Pollution 210(1-4): 211-220. Finnerty, W. R. (1992). 'The Biology and Genetics of the Genus Rhodococcus.' Annual Review of Microbiology 46: 193-218. Fritsche, W., M. Hofrichter (2000). 'Aerobic degradation by microorganisms.' : 145-155. Gaudy, A. F., and Elizabeth, T. G. (1980). 'Microbiology for Environmental Scientist and Engineers.' Mcgraw-Hill, Inc.: 55-80. Gibson, D. T. (1984). 'Microbial degradation of organic compounds.' Marcel Dekker New York. Goldberg, S. (2005). 'Equations and Models Describing Adsorption Processes in Soils. ' Soil Science Society of America, 677 S. Chemical Processes in Soils. SSSA Book Series 8. Goodfellow, M., G. Alderson and J. S. Chun (1998). 'Rhodococcal systematics: problems and developments.' Antonie Van Leeuwenhoek International Journal of General and Molecular Microbiology 74(1-3): 3-20. Gorgenyi, M., J. Dewulf, H. Van Langenhove and K. Heberger (2006). 'Aqueous salting-out effect of inorganic cations and anions on non-electrolytes.' Chemosphere 65(5): 802-810. Gurtler, V., B. C. Mayall and R. Seviour (2004). 'Can whole genome analysis refine the taxonomy of the genus Rhodococcus?' Fems Microbiology Reviews 28(3): 377-403. Hamby, D. M. (1996). 'Site remediation techniques supporting environmental restoration activities - A review.' Science of the Total Environment 191(3): 203-224. Harkey, G. A., P. L. Vanhoof and P. F. Landrum (1995). 'Bioavailability of Polycyclic Aromatic-Hydrocarbons from a Historically Contaminated Sediment Core.' Environmental Toxicology and Chemistry 14(9): 1551-1560. Hommel, R. K. (1990). 'Formation and physiological role of biosurfactants produced by hydrocarbon-utilizing microorganisms Biosurfactants in hydrocarbon utilization.' Biodegradation 1(2-3): 107-119. Hua, Z. Z., J. Chen, S. Y. Lun and X. R. Wang (2003). 'Influence of biosurfactants produced by Candida antarctica on surface properties of microorganism and biodegradation of n-alkanes.' Water Research 37(17): 4143-4150. Huesemann, M. H. (1995). 'Predictive Model for Estimating the Extent of Petroleum Hydrocarbon Biodegradation in Contaminated Soils.' Environmental Science & Technology 29(1): 7-18. International Atomic Energy Agency (2006,b). 'In-situ vitrification.' Iversen, C., M. Lane and S. J. Forsythe (2004). 'The growth profile, thermotolerance and biofilm formation of Enterobacter sakazakii grown in infant formula milk.' Lett Appl Microbiol 38(5): 378-382. Juwarkar, A. A., S. K. Singh and A. Mudhoo (2010). 'A comprehensive overview of elements in bioremediation.' Reviews in Environmental Science and Bio/Technology 9(3): 215-288. Kan, A. T., G. M. Fu, M. A. Hunter and M. B. Tomson (1997). 'Irreversible adsorption of naphthalene and tetrachlorobiphenyl to Lula and surrogate sediments.' Environmental Science & Technology 31(8): 2176-2185. Kathiravan, M. N., R. Karthick and K. Muthukumar (2011). 'Ex situ bioremediation of Cr(VI) contaminated soil by Bacillus sp.: Batch and continuous studies.' Chemical Engineering Journal 169(1-3): 107-115. Kile, D. E. and C. T. Chiou (1989). 'Water Solubility Enhancements of Ddt and Trichlorobenzene by Some Surfactants Below and above the Critical Micelle Concentration.' Environmental Science & Technology 23(7): 832-838. Kohler, M., I. L. Genz, B. Schicht and E. V (1984). 'Microbial Desulfurization of Petroleum and Heavy Petroleum Fractions .4. Anaerobic Degradation of Organic Sulfur-Compounds of Petroleum.' Zentralblatt Fur Mikrobiologie 139(4): 239-247. Korda, A., P. Santas, A. Tenente and R. Santas (1997). 'Petroleum hydrocarbon bioremediation: sampling and analytical techniques, in situ treatments and commercial microorganisms currently used.' Applied Microbiology and Biotechnology 48(6): 677-686. Kurane, R., K. Hatamochi, T. Kakuno, M. Kiyohara, K. Kawaguchi, Y. Mizuno, M. Hirano and Y. Taniguchi (1994). 'Purification and Characterization of Lipid Bioflocculant Produced by Rhodococcus-Erythropolis.' Bioscience Biotechnology and Biochemistry 58(11): 1977-1982. Kuyukina, M. S., I. B. Ivshina, M. I. Ritchkova, J. C. Philp, C. J. Cunningham and N. Christofi (2003). 'Bioremediation of crude oil-contaminated soil using slurry-phase biological treatment and land farming techniques.' Soil & Sediment Contamination 12(1): 85-99. Lambert, S. M. (1968). 'Omega a Useful Index of Soil Sorption Equilibria.' Journal of Agricultural and Food Chemistry 16(2): 340-&. Larkin, M. J., L. A. Kulakov and C. C. R. Allen (2005). 'Biodegradation and Rhodococcus - masters of catabolic versatility.' Current Opinion in Biotechnology 16(3): 282-290. Larkin, M. J., L. A. Kulakov and C. C. R. Allen (2006). 'Biodegradation by members of the genus Rhodococcus: Biochemistry, physiology, and genetic adaptation.' Advances in Applied Microbiology, Vol 59 59: 1-29. Leahy, J. G. and R. R. Colwell (1990). 'Microbial-Degradation of Hydrocarbons in the Environment.' Microbiological Reviews 54(3): 305-315. Leite, O. T. (1996). 'Cleaning up incineration exhaust.' Environmental Engineering World 2: 6-11. Lichtinger, T., G. Reiss and R. Benz (2000). 'Biochemical identification and biophysical characterization of a channel-forming protein from Rhodococcus erythropolis.' Journal of Bacteriology 182(3): 764-770. Liu, C.-W. and H.-S. Liu (2011). 'Rhodococcus erythropolis strain NTU-1 efficiently degrades and traps diesel and crude oil in batch and fed-batch bioreactors.' Process Biochemistry 46(1): 202-209. Liu, C. W., W. N. Chang and H. S. Liu (2009). 'Bioremediation of n-alkanes and the formation of biofloccules by Rhodococcus erythropolis NTU-1 under various saline conditions and sea water.' Biochemical Engineering Journal 45(1): 69-75. Liu, P., D. Zhu, H. Zhang, X. Shi, H. Sun and F. Dang (2008). 'Sorption of polar and nonpolar aromatic compounds to four surface soils of eastern China.' Environ Pollut 156(3): 1053-1060. Lu, Y. F. and J. J. Pignatello (2002). 'Demonstration of the 'Conditioning effect' in soil organic matter in support of a pore deformation mechanism for sorption hysteresis.' Environmental Science & Technology 36(21): 4553-4561. Mackay, D., and McAuliff, C.D. (1988). 'Fate of hydrocarbons discharged at sea.' Oil and Chemical Pollution 5: 1-20. Madsen, E. L. (1991). 'Determining Insitu Biodegradation - Facts and Challenges.' Environmental Science & Technology 25(10): 1663-1673. Menzie, C. A., B. B. Potocki and J. Santodonato (1992). 'Exposure to Carcinogenic Pahs in the Environment.' Environmental Science & Technology 26(7): 1278-1284. Minkina, T. M., D. L. Pinskii, S. S. Mandzhieva, E. M. Antonenko and S. N. Sushkova (2011). 'Effect of the particle-size distribution on the adsorption of copper, lead, and zinc by Chernozemic soils of Rostov oblast.' Eurasian Soil Science 44(11): 1193-1200. Molina-Barahona, L., L. Vega-Loyo, M. Guerrero, S. Ramirez, I. Romero, C. Vega-Jarquin and A. Albores (2005). 'Ecotoxicological evaluation of diesel-contaminated soil before and after a bioremediation process.' Environ Toxicol 20(1): 100-109. Morgan, P., R. Watkinson (1994). 'Biodegradation of components of petroleum.' Biochemistry of Microbial Degradation: 1-31. Muchaonyerwa, P., T. Chevallier, O. L. Pantani, P. Nyamugafata, S. Mpepereki and C. Chenu (2006). 'Adsorption of the pesticidal toxin from Bacillus thuringiensis subsp. tenebrionis on tropical soils and their particle-size fractions.' Geoderma 133(3-4): 244-257. Mulligan, C. N. (2005). 'Environmental applications for biosurfactants.' Environmental Pollution 133(2): 183-198. Niescher, S., V. Wray, S. Lang, S. R. Kaschabek and M. Schlomann (2006). 'Identification and structural characterisation of novel trehalose dinocardiomycolates from n-alkane-grown Rhodococcus opacus 1CP.' Applied Microbiology and Biotechnology 70(5): 605-611. Palmer, S. E. (1993). 'Effect of biodegradation and water washing on crude oil composition.' Organic Geochemistry. Park, J. H., X. Zhao, T. C. Voice (2002). 'Development of kinetic basis for bioavailability of sorbed naphthalene in soil slurries.' Water Research 36: 1620-1628. Partovinia, A., F. Naeimpoor and P. Hejazi (2010). 'Carbon content reduction in a model reluctant clayey soil: slurry phase n-hexadecane bioremediation.' J Hazard Mater 181(1-3): 133-139. Paul, E.A., Tu, C.M. (1965). ' Alteration of microbial activities, mineral nitrogen and free amino acid constituents of soils byphysical treatment.' Plant Soil 22: 207-219. Pinelli, D., F. Fava, M. Nocentini and G. Pasquali (1997). 'Bioremediation of a polycyclic aromatic hydrocarbon-contaminated soil by using different aerobic batch bioreactor systems.' Journal of Soil Contamination 6(3): 243-256. Pirnik, M. P. (1976). 'Microbial oxidation of methyl branched alkane.' CRC Crit. Rev. Microbial 5: 413-422. Piwowarczyk, A. A. and N. M. Holden (2012). 'Adsorption and Desorption Isotherms of the Nonpolar Fungicide Chlorothalonil in a Range of Temperate Maritime Agricultural Soils.' Water Air and Soil Pollution 223(7): 3975-3985. Ram, N. M., Bass, D.H., Falotico, R., Leahy, M. (1993). 'A decision framework for selecting remediation technologies at hydrocarbon-contaminated sites.' J. Soil Contam 2(2): 167-189. Ratledge, C. (1988). 'Products of hydrocarbon-microorganism interaction.' Biodeterioration 7: 219-236. Reddy, P. G., H. D., Singh, P. K., Roy, and J. N., Baruah (1982) 'Predominant role of hydrocarbon solubilization in the microbial uptake of hydrocarbons.' Biotechnol. Bioeng. 24: 1241-1269. Riser-Roberts, E. (1998). 'Remediation of Petroleum contaminated soils: biological, physical, and chemical processes.' CRC. Rojo, F. (2009). 'Degradation of alkanes by bacteria.' Environmental Microbiology 11(10): 2477-2490. Rosen, M. J. (1989). 'Selection of Surfactant Pairs for Optimization of Interfacial Properties.' Journal of the American Oil Chemists Society 66(12): 1840-1843. Rueter, P., R. Rabus, H. Wilkes, F. Aeckersberg, F. A. Rainey, H. W. Jannasch and F. Widdel (1994). 'Anaerobic Oxidation of Hydrocarbons in Crude-Oil by New Types of Sulfate-Reducing Bacteria.' Nature 372(6505): 455-458. Russo, L., L. Rizzo and V. Belgiorno (2012). 'Ozone oxidation and aerobic biodegradation with spent mushroom compost for detoxification and benzo(a)pyrene removal from contaminated soil.' Chemosphere 87(6): 595-601. Sastre, J., E. Hernandez, R. Rodriguez, X. Alcobe, M. Vidal and G. Rauret (2004). 'Use of sorption and extraction tests to predict the dynamics of the interaction of trace elements in agricultural soils contaminated by a mine tailing accident.' Sci Total Environ 329(1-3): 261-281. Scherrer, P. and G. Mille (1990). 'Biodegradation of Crude-Oil in Experimentally-Polluted Clayey and Sandy Mangrove Soils.' Oil & Chemical Pollution 6(3): 163-176. Sekelsky, A. M. and G. S. Shreve (1999). 'Kinetic model of biosurfactant-enhanced hexadecane biodegradation by Pseudomonas aeruginosa.' Biotechnology and Bioengineering 63(4): 401-409. Sokolovska, I., R. Rozenberg, C. Riez, P. G. Rouxhet, S. N. Agathos and P. Wattiau (2003). 'Carbon source-induced modifications in the mycolic acid content and cell wall permeability of Rhodococcus erythropolis E1.' Applied and Environmental Microbiology 69(12): 7019-7027. Song, H. G., X. P. Wang and R. Bartha (1990). 'Bioremediation Potential of Terrestrial Fuel Spills.' Applied and Environmental Microbiology 56(3): 652-656. Steinberg, S. M., J. J. Pignatello and B. L. Sawhney (1987). 'Persistence of 1,2-Dibromoethane in Soils - Entrapment in Intraparticle Micropores.' Environmental Science & Technology 21(12): 1201-1208. Sun, H., M. Tateda, M. Ike and M. Fujita (2003). 'Short- and long-term sorption/desorption of polycyclic aromatic hydrocarbons onto artificial solids: effects of particle and pore sizes and organic matters.' Water Research 37(12): 2960-2968. Sun, H., W. Wu and L. Wang (2009). 'Phenanthrene partitioning in sediment-surfactant-fresh/saline water systems.' Environ Pollut 157(8-9): 2520-2528. Sutcliffe, I. C., A. K. Brown and L. G. Dover (2010). 'The rhodococcal cell envelope: Composition, organisation and biosynthesis.' Biology of Rhodococcus: 29-71. Thomas, J. M. and C. H. Ward (1989). 'Insitu Biorestoration of Organic Contaminants in the Subsurface.' Environmental Science & Technology 23(7): 760-766. Ulrici, W. (2000). 'Contaminated soil areas, different countries and contaminants, monitoring of contaminants.' Environmental Process II. Soil Decontamination Biotechnology 11: 5-42. U.S. Environmental Protection Agency (EPA) (1996). 'Soil washing process.' U.S. Environmental Protection Agency (EPA) (2004). 'Steam stripping.' Vangronsveld, J., J.V., Colpaert, K. K., Van Tichelen (1996). ' Reclamation of a bare industrial area contaminated by non-ferrous metals: Physico-chemical and biological evaluation of the durability of soil treatment and revegetation.' Environmental Pollution 94: 131-140. Van Hamme, J. D., A. Singh and O. P. Ward (2003). 'Recent advances in petroleum microbiology.' Microbiology and Molecular Biology Reviews 67(4): 503-+. Van Stempvoort, D. and K. Biggar (2008). 'Potential for bioremediation of petroleum hydrocarbons in groundwater under cold climate conditions: A review.' Cold Regions Science and Technology 53(1): 16-41. Vasudevan, D., Bruland, G. L., Torrance, B. S., Upchurch, V. G. and MacKay, A. A. (2009). 'pH-dependent ciprofloxacin sorption to soils: Interaction mechanisms and soil factors influencing sorption.' Geoderma 151(3-4): 68-76. Venkata Mohan, S., Ramakrishna M., S. Shailaja and P. N. Sarma (2007). 'Influence of soil-water ratio on the performance of slurry phase bioreactor treating herbicide contaminated soil.' Bioresour Technol 98(13): 2584-2589. Vidali, M. (2001). 'Bioremediation. An overview.' Pure and Applied Chemistry 73(7): 1163-1172. Voudrias, E., Fytianos, F. and Bozani, E. (2002). 'Sorption Description isotherms of Dyes from aqueous solutions and Waste Waters with Different Sorbent materials.' Global Nest, The Int.J. 4(1): 75-83. Wainwright, M. (1999). 'An Introduction to Environmental Biotechnology.' Kluwer Academic Publishers: 38-39. Walworth, J. L., and Reynolds, C. M. (1995). 'Bioremediation of a petroleum-contaminated cryic soil: effects of phosphorus, nitrogen, and temperature.' Journal of Soil Contamination 4(3): 299-310. Watkinson, R. J. and P. Morgan (1990). 'Physiology of aliphatic hydrocarbon-degrading microorganisms.' Biodegradation 1(2-3): 79-92. Weber Jr, W., J., W. Huang, E. J. LeBoeuf (1999). 'Geosorbent organic matter and its relationship to the binding and sequestration of organic contaminants.' Colloids Surf. A 151: 167-179. Wentzel, A., T. E. Ellingsen, H. K. Kotlar, S. B. Zotchev and M. Throne-Holst (2007). 'Bacterial metabolism of long-chain n-alkanes.' Applied Microbiology and Biotechnology 76(6): 1209-1221. Whyte, L. G., S. J. Slagman, F. Pietrantonio, L. Bourbonniere, S. F. Koval, J. R. Lawrence, W. E. Inniss and C. W. Greer (1999). 'Physiological adaptations involved in alkane assimilation at a low temperature by Rhodococcus sp strain Q15.' Applied and Environmental Microbiology 65(7): 2961-2968. Wilson, S. C., Jones, K. C. (1993). 'Bioremediation of soil contaminated with polynuclear aromatic hydrocarbons (PAHs): a review.' Environmental Pollution 81: 229-249. Wu, W. and H. Sun (2010). 'Sorption-desorption hysteresis of phenanthrene--effect of nanopores, solute concentration, and salinity.' Chemosphere 81(7): 961-967. Yang, K., L. Z. Zhu and B. S. Xing (2006). 'Enhanced soil washing of phenanthrene by mixed solutions of TX100 and SDBS.' Environmental Science & Technology 40(13): 4274-4280. Yang, Y. N. and G. Y. Sheng (2003). 'Enhanced pesticide sorption by soils containing particulate matter from crop residue burns.' Environmental Science & Technology 37(16): 3635-3639. 王詩雯 (2013). '利用Rhodococcus erythropolis NTU-1細胞破乳化.' 國立台灣大學化學工程研究所碩士論文. 林詩凱 (2005). '利用混合菌株(TN-4)與單一菌株(Rhodococcus erythropolis NTU-1)處理正十六烷之研究. ' 台灣大學化學工程研究所碩士論文. 梁茂實 (2007). '微生物生物復育時細胞聚集與氫離子釋放的應用.' 國立台灣大學化學工程研究所碩士論文. 張緯農 (2003). '利用混合菌株(TN-4)處理異十九烷之研究.' 國立台灣大學化學工程研究所碩士論文. 張緯農 (2009). '利用Rhodococcus erythropolis進行碳氫化合物生物降解與細胞聚集現象之研究.' 國立台灣大學化學工程研究所博士論文. 華苟根 and 郭堅華 (2003). '紅球菌屬的分類及應用研究發展.' 微生物學通報 30: 107-111. 黃武良 (1999). '石油-大自然孕育千萬年的珍藏.' 地球科學園地. 廉景燕, 杜永亮, 郭敏 and 李鑫剛 (2009). '土壤中石油污染物的脫附過程.' 生態環境學報 18(3): 939-943. 劉志文 (2007) '微生物生物復育過程中細胞聚集現象之研究.' 國立台灣大學化學工程研究所碩士論文. 劉志文 (2011). 'Rhodococcus erythropolis NTU-1菌株對石油污染物之生物降解及生物吸附現象之應用.' 國立台灣大學化學工程研究所博士論文. 盧至人 (2002). '現地生物復育技術.' 台灣土壤及地下水環境保護協會簡訊: 3-5. 賴岳廷 (2014). '以柴油培養之Rhodococcus erythropolis NTU-1結塊處理水包油(O/W)型乳化液.' 台灣大學化學工程研究所碩士論文. 謝惠敏 (2011). '利用Rhodococcus erythropolis NTU-1細胞聚集現象移除正十六烷.' 國立台灣大學化學工程研究所碩士論文. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/50134 | - |
dc.description.abstract | 本研究主要利用菌株Rhodococcus erythropolis NTU-1的生物降解及包覆聚集能力來處理土壤中碳氫化合物。主要研究目的為探討以批式操作的方式培養,並且探討在固相中可能殘有的不可逆吸附的量值以及在固相中和液相中的特殊吸附平衡關係,並且去探討菌株最適當的培養條件,即是能夠有包覆現象產生的濃度範圍。實驗結果發現,會有結塊現象產生主要都是發生在初始添加量為400到1500 μL之間,即是液相中濃度介於1400 μL/L及6600 μL/L之間,其中液相濃度低於1400 μL/L可能會產生黃色片狀的型態,而高於6600 μL/L則可能會因為正十六烷太多而無法順利結塊。
本實驗並比較不同環境因子例如pH值及溫度後土壤中不可逆吸附量值的改變,以及探討了不同情況下得到的吸附等溫線。利用獲得的吸附等溫線,能夠藉由測量液相中的正十六烷濃度即可預測殘存在土壤中的正十六烷的量,並且估算出我們生物在這個系統中的處理效果。經過108小時的批式迴旋培養,即可去除土壤中超過80%的正十六烷的量。 綜括上述,以NTU-1處理在土壤中的油污的效果,是具有相當的潛力以及發展性。 | zh_TW |
dc.description.abstract | Pure culture of Rhodococcus erythropolis NTU-1 was utilized to test the biodegradability and bioflocculate formation in treatment of petroleum pollutant in the soil. This study evaluated the cultivation in batch system, and discussed the irreversible adsorption of n-hexadecane and special equilibrium between solid phase and liquid phase. We also tried to find the optimum amount of n-hexadecane in our batch system was about 400-1500 μL/ 100mL MSM for NTU-1 consumption. The concentration was about 1400-6600 μL/ L in liquid phase. It means that NTU-1 would trap n-hexadecane in biofloccules. If the concentration in liquid phase was less than 1400 μL/L, the morphological structure may be flakes; if the concentration in liquid phase was more than 6600 μL/L, there might be too much n-hexadecane in the medium to form bioflocculate formation.
In this study, we also evaluated different environment factors affecting the irreversible adsorption of n-hexadecane, including pH, temperature, salinity and aging. Different adsorption isotherm would be found by regression. By using the adsorption isotherm we got, we could estimate the n-hexadecane amount in soil by analyzing the concentration in the liquid phase. We could also estimate the biodegradability by NTU-1. Under the optimal condition, NTU-1 could remove more than 80% out of n-hexadecane after 108 hours incubation. To sum up, NTU-1 provided a feasible and potential method to treat contaminated soil in the batch system. | en |
dc.description.provenance | Made available in DSpace on 2021-06-15T12:30:35Z (GMT). No. of bitstreams: 1 ntu-105-R03524085-1.pdf: 5514088 bytes, checksum: 989499462c1fd4709179380bfe3b59e6 (MD5) Previous issue date: 2016 | en |
dc.description.tableofcontents | 摘要 I
Abstract Ⅱ 目錄 Ⅲ 表目錄 Ⅵ 圖目錄 Ⅷ 照片目錄 ⅩⅢ 第一章 導論 1 1.1 前言 1 1.2 研究目的及論文綱要 2 第二章 文獻回顧 3 2.1 石油碳氫化合物簡介及其對環境和人類的影響 3 2.2 處理石油碳氫化合物之方法 5 2.3 石油碳氫化合物移除機制 10 2.3.1 生物復育簡介 10 2.3.2 微生物攝取碳氫化合物之模式 15 2.3.3 微生物分解碳氫化合物之方式 21 2.4 微生物降解碳氫化合物之代謝途徑 23 2.4.1 直鍊烷之氧化機制 24 2.4.2 支鍊烷之氧化機制 27 2.5 菌株Rhodococcus erythropolis介紹 29 2.5.1 Rhodococcus erythropolis菌屬簡介 29 2.5.2 Rhodococcus erythropolis之特性及應用 32 2.6 土壤中油污染之復育技術 38 2.7 環境因子對微生物的影響 43 2.8 有機污染物在土壤中的吸附現象 46 第三章 實驗材料與方法 48 3.1 實驗菌株 48 3.2 培養基的組成 50 3.2.1 基礎礦物培養基 50 3.2.2菌株活化培養基 54 3.2.3菌株保存培養基 54 3.2.4計數平板培養基 56 3.3 實驗方法 57 3.3.1 菌株的活化及生長曲線 57 3.3.2 礦物培養基菌液製作 58 3.3.3 固相土壤和正十六烷污染的前處理 61 3.3.4 吸附等溫線的預測及迴歸實驗 62 3.3.5 不同條件下之土壤生物復育實驗 66 3.4 實驗藥品和儀器 70 3.4.1 實驗藥品 70 3.4.2 實驗儀器 71 第四章 結果與討論 72 4.1 正十六烷在土壤中無法被有效利用的不可逆吸附部份探討及比較 73 4.1.1 探討正十六烷在土壤與礦物培養基中無法算入平衡關係的不可逆脫附 74 4.1.2 改變不同條件下,對土壤中不可逆吸附的影響及討論 79 4.1.3 正十六烷隨污染時間增加對不可逆脫附的影響 89 4.2 正十六烷在固相土壤和液相培養基間的可逆吸附等溫線探討及比較 92 4.2.1 探討正十六烷在土壤與礦物培養基中可逆部分達成的平衡吸附曲線 92 4.2.2 改變不同固液比和溫度去探討對吸附等溫線的影響 105 4.2.3 改變不同污染物對固相土壤的接觸時間去探討對吸附等溫線的影響 120 4.3 含正十六烷固相土壤與礦物培養基添加NTU-1的生物降解及包覆能力 126 4.3.1固液比為1:40,土壤粒徑大小為20/50 mesh,初始溫度為30°C,NTU-1的處理結果 126 4.3.2固液比為1:20,土壤粒徑大小為20/50 mesh,初始溫度為30°C,NTU-1的處理結果 132 4.3.3固液比為1:10,土壤粒徑大小為20/50 mesh,初始溫度為30, 40°C,NTU-1的處理結果 136 4.3.4固液比為1:10,土壤粒徑大小為20/50 mesh,初始溫度為30 °C,固相土壤和正十六烷的接觸時間延長為120小時,NTU-1的處理結果 144 第五章 結論 150 參考文獻 153 | |
dc.language.iso | zh-TW | |
dc.title | 以Rhodococcus erythropolis NTU-1復育受正十六烷污染之土壤 | zh_TW |
dc.title | Rhodococcus erythropolis NTU-1 for the treatment of soil contaminated with n-Hexadecane | en |
dc.type | Thesis | |
dc.date.schoolyear | 104-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 鄭玉佳,江佳穎 | |
dc.subject.keyword | Rhodococcus erythropolis,生物復育,受污染的土壤,不可逆吸附, | zh_TW |
dc.subject.keyword | Rhodococcus erythropolis,bioremediation,contaminated soil,irreversible adsorption, | en |
dc.relation.page | 168 | |
dc.identifier.doi | 10.6342/NTU201601878 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2016-08-05 | |
dc.contributor.author-college | 工學院 | zh_TW |
dc.contributor.author-dept | 化學工程學研究所 | zh_TW |
顯示於系所單位: | 化學工程學系 |
文件中的檔案:
檔案 | 大小 | 格式 | |
---|---|---|---|
ntu-105-1.pdf 目前未授權公開取用 | 5.38 MB | Adobe PDF |
系統中的文件,除了特別指名其著作權條款之外,均受到著作權保護,並且保留所有的權利。