Adams, J. A. a Reddy, K. R., 1999: Laboratory study of air sparging TCE-contaminated saturated soils and groundwater. In: Ground Water Monitoring and Remediation, roč. 19, č. 3, s. 182 – 190.
Adriano, D. C., Bollag, J. M., Frankerberger Jr., W. T. a Sims, R. C., 1999: Bioremediation of contaminated soils. Madison, American Society of Agronomy – Crop Science Society of America – Soil Science Society of America, 820 s.
Adriano, D. C., Wenzel, W. W., Vangronsveld, J. a Bolan, N. S., 2004: Role of assisted natural remediation in environmental cleanup. In: Geoderma, 122, s. 121 – 142.
AFCEE, 1999a: Natural attenuation of fuel hydrocarbons, performance and cost results from multiple air force demonstration sites. Air Force Center for Environmental Excellence, Technology Demonstration Summary Report, AFCEE, Technology Transfer Division, Brooks Air Force Base, TX 78235.
AFCEE, 1999b: Natural attenuation of chlorinated solvents, performance and cost results from multiple air force demonstration sites. Air Force Center for Environmental Excellence Technology Demonstration Summary Report, AFCEE, Technology Transfer Division, Brooks Air Force Base, TX 78235.
Ahlfeld, D. P., 1993: Fluid flow mechanisms that govern air sparging effectiveness. In: Ground Water, roč. 31, č. 5, s. 829 – 830.
Ahlfeld, D. P., Dahmani, A. a Ji, W., 1994: A conceptual model of field behavior of air sparging and its implications for application. In: Ground Water Monitoring and Remediation, roč. 14, č. 4, s. 132 – 139.
Ahmad, F., McGuire, T. M., Lee, R. S. a Becvar, E., 2007: Consideration for the design of organic mulch Permeable Reactive Barriers. In: Remediation, s. 59 – 72.
Aines, R. D. a Robin, L. N., 1998. They all like it hot: faster cleanup of contaminated soil and groundwater. Science and Technology Review, Lawrence Livermore National Laboratory, Livermore, California, UCRL-52000-98-5, May 1998.
Alam, M., 2004: Bioreduction of hexavalent chromium: flow-through column experiments and reactive transport. PhD. Thesis. Washington State University, August 2004.
American Society of Civil Engineers, American Water Works Association, 1997: Water treatment plant design, 3rd edition. McGraw-Hill Professional, 806 s.
Amro, H., Tuffaha, R., Zenati, S. a Jneidi, M., 2007: Remediation of polluted waters and wastewater by irradiation processing in Jordan. In: Remediation of polluted waters and wastewater by radiation processing. Final report of the research coordination meeting (RCM) 4 – 9 September 2006, Vienna, Austria. IAEA-TECDOC. IAEA, Vienna, s. 89 – 108.
Anderson, E. I. a Mesa, E., 2006: The effects of vertical barrier walls on the hydraulic control of contaminated groundwater. In: Advances in Water Resources, 29, s. 89 – 98.
Anderson, R. T., Vrionis, H. A., Ortiz-Bernad, I., Resch, C. T., Long, P. E., Dayvault, R., Karp, K., Marutzky, R., Metzter, D. R., Peacock, A., White, D. C., Lowe, M. a Lovley, D. R., 2003: Stimulating the in situ activity of geobacter species to remove uranium from the groundwater of a uranium-contaminated aquifer. In: Appl. Environ. Microbiol., roč. 69, č. 10, s. 5 884 – 5 891.
Andreottola, G., Dallago, L. a Ferrarese, E., 2008: Feasibility study for the remediation of groundwater contaminated by organolead compounds. In: J. Hazard. Mater., č. 156, s. 488 – 498.
Anonym, 1991: Engineering Bulletin, Chemical Oxidation Treatment. EPA/540/2-91/025, 8 s.
Anonym, 1994: Air Sparging for Site Remediation. Battelle Memorial In Battelle Inst., Columbus, OH. 160 s.
Anonym, 1998: Horizontal wells. Subsurface contaminants focus area. Innovative Technology Summary Report, DOE/EM-0378, 17 s.
Anonym, 2002a: Reference document on best available techniques in common waste water and waste gas treatment/management systems in the chemical sector. Integrated pollution prevention and control, Institute for Prospective Technological Studies, Joint Research Centre, Seville.
Anonym, 2002b: Guidelines on remediation of contaminated sites. Environmental Guidelines No. 7, Danish Ministry of Environment, 290 s.
Anonym, 2004: Biosparging with air for treatment of MTBE. Remedial Project Manager News, Spring, s. 7 – 9.
Anonym, 2005: Cost and performance report, Multi-site in situ air sparging. Technical Report, TR-2260-ENV, Naval Facilities Engineering Service Center, 30 s.
Anonym, 2007a: Assessment of the performance of engineered waste containment barriers. National Research Council (US), 134 s.
Anonym, 2007b: Principles of chemical oxidation technology for the remediation of groundwater and soil 2007: RegenOx. Design and application manual. Regenesis Bioremediation Products (1011 Calle Sombra), San Clemente, CA 92673.
Appelo, C. A. J. a Postma, D., 1993: Geochemistry, groundwater and pollution. Rotterdam, Balkema, 536 s.
Appelo, C. A. J., 1996: Multicomponent ion exchange and chromatography in natural systems. In: Lichtner, P. C., Steefel, C. I. a Oelkers, E. H. (eds.): Reactive transport in porous media. Rewiews in mineralogy, č. 34. Washington, Mineralogical Society of America, s. 193 – 227.
Arceivala, S. J. a Asolekar, S. R., 2006: Wastewater treatment for pollution control and reuse. Tata McGraw-Hill, 518 s.
ARTEC, 2006: Výzkumné centrum Pokročilé sanační technologie a procesy. Čiastk. správa. 191 s.
ASTM, 1998: Standard guide for remediation of ground water by natural attenuation at petroleum release sites. American Society for Testing and Materials, E: 1943 – 98, 42 s.
Aulenta, F., Potalivo, M., Majone, M., Papini, M. P. a Tandoi, V., 2006: Anaerobic bioremediation of groundwater containing a mixture of 1,1,2,2-tetrachloroethane and chloroethenes. In: Biodegradation, 17, s. 193 – 206.
Azadpour-Keeley, A., Russell, H. H. a Sewell, G. W., 1999: Microbial processes affecting monitored natural attenuation of contaminants in the subsurface. Ground Water Issue, EPA/540/S-99/001, 18 s.
Azadpour-Keeley, A., Keeley, J. W., Russell, H. H. a Sewell, G. W., 2001: Monitored natural attenuation of contaminants in the subsurface: processes. In: Ground Water Monitoring & Remediation, Spring 2001, roč. 21, č, 2, s. 97 – 107.
Baker, D. M. a Benson, C. H., 1996: Review of factors affecting In situ air sparging. Proceedings of 1996 ASCE Specialty Conference, Washington, DC, s. 292 – 310.
Bakker, L. M. M., Tonnaer, H., Michelberger, H. S., Pijls, C. G. J. M. a Fillipponi, P., 2000: Full scale operation of aerobic biobarriers. In: Telford, T. (ed.): Proceedings of the ConSoil conference 2000. Leipzig, Nemecko, FZK/TNO, č. 2, s. 932 – 938.
Bal, A. S. a Dhagat, N. N., 2001: Upflow anaerobic sludge blanket reactor – a review. In: Indian J. Environ. Health, roč. 43, č. 2, s. 1 – 82.
Banásová, V., 2004: Rastliny na banských odpadoch. In: Seminár Banské odpady 2004. Bratislava, PriF UK, 6 s.
Barry, D. A., Prommer, H., Miller, C. T., Engesgaard, P., Brun, A. a Zheng, C., 2002: Modelling the fate of oxidisable organic contaminants in groundwater. In: Advances in Water Resources, 25, s. 945 – 983.
Baruth, E. E., American Society of Civil Engineers, American Water Works Association, 2004: Water treatment plant design, 4th edition. McGraw-Hill Professional, 896 s.
Basařová, P. a Horn, D., 2003: Studium hydrodynamiky flotace plastů. CHISA 2003.
Bass, D. H. a Brown, R. A., 1995: Performance of air sparging systems – a review of case studies. In: Petroleum Hydrocarbons and Organic Chemicals in Ground Water: Prevention, Detection and Restoration. Dublin – Ohio, Ground Water Publishing Company, s. 621 – 636.
Bastiaens, L., Dries, J., Vos, J., Simons, Q., De-Smet, M. a Diels, L., 2005: Comparison of different multibarrier concepts designed for treatment of groundwater containing mixed pollutants. IAHS-AISH-Publication, 298, s. 45 – 51.
Bausmith, D. S., Campbell, D. J. a Vidie, R. D., 1996: In situ air stripping: using air sparging and other in situ methods calls for critical judgement. Water Environment and Technology, February, s. 45 – 51.
Behrend, C. a Heesche-Wagner, K., 1999: Formation of hydride-meisenheimer complexes of picric acid (2,4,6- trinitrophenol) and 2,4-dinitrophenol during mineralization of picric acid by Nocardioides sp. strain CB 22-2. In: Applied and Environmental Microbiology, roč. 65, č. 4, s. 1 372 – 1 377.
Bekins, B. A., Rittmann, B. E. a MacDonald, J. A., 2001a: Natural attenuation strategy for groundwater cleanup focuses on demonstrating cause and effect. Eos, Transactions, AGU, roč. 82, č. 5, s. 57 – 58.
Bekins, B. A., Cozzarelli, I. M., Godsy, E. M., Warren, E., Essaid, H. I. a Tuccillo, M. E., 2001b: Progression of natural attenuation processes at a crude oil spill site: II. Controls on spatial distribution of microbial populations. In: J. Contaminant Hydrology, 53, s. 387 – 406.
Bender, J., Duff, M. C., Phillips, P. a Hill, M., 2000: Bioremediation and bioreduction of dissolved U(VI) by microbial mat consortium supported on silica gel particles. In: Environ. Sci. Technol., 34, s. 3 235 – 3 241.
Benner, M. L., Mohtar, R. H. a Lee, L. S., 2002: Factors affecting air sparging remediation systems using field data and numerical simulations. In: J. Hazard. Mater., roč. 95, č. 3, s. 305 – 329.
Bergersen, L., Jacobsson, J. a Meijer, D., 2006: Solving the impact of high toxic loads in the produced water at the Kollsnes gas terminal by applying the MPPE technology. Produced Water – Best Management Practices, 29 & 30 November 2006, 10 s.
Beyke, G., 1998: 6-phase electrical heating. In Situ Thermal Treatment Conference, U. S. EPA, Atlanta.
Beyke, G. a Fleming, D., 2005: In situ thermal remediation of DNAPL and LNAPL using electrical resistance heating. Remediation, s. 5 – 22.
Bhandari, A., Champagne, P., Lo, I. M. C., Ong, S. K., Surampalli, R. Y. a Tyagi, R. D. (eds.), 2007: Remediation technologies for soils and groundwater. ASCE Publications, 449 s.
Bianchi-Mosquera, G. C., Allen-King, R. N. a Mackay, D. M., 1994: Enhancing degradation of dissolved benzene and toluene using a solid oxygen-releasing compound. In: Ground Water Monitor. and Remed., roč. 14, č. 1, s. 120 – 128.
Birke, V., Burmeier, H. a Rosenau, D., 2003: Design, construction, and operation of tailored permeable reactive barriers. In: Practice Periodical of Hazardous Toxic and Radioactive Waste Manage, roč. 7, č. 4, s. 264 – 280.
Boparai, H. K., Comforty, S., Sheaz, P. J. a Szecsody, J. E., 2008: Remediating explosive-contaminated groundwater by in situ redox manipulation (ISRM) of aquifer sediments. In: Chemosphere, 71, s. 933 – 941.
Bowles, M. W., 1997: The trench and gate groundwater remediation system. Diploma thesis. University of Calgary, Faculty of Graduate Studies, Department of Geology and Geophysics, Calgary, Alberta, Kanada.
Braida, W. J. a Ong, S. K., 2001: Air sparging effectiveness: laboratory characterization of air-channel mass transfer zone for VOC volatilization. In: J. Hazard. Mater., roč. 87, č. 1 – 3, s. 241 – 258.
Bratby, J., 2006: Coagulation and flocculation in water and wastewater treatment. 2nd ed. IWA Publishing, 407 s.
Brooks, M. C., Wise, W. R. a Annable, M. D., 1999: Fundamentals changes in in situ air sparging flow patterns. GWMR, s. 105 – 113.
Brown, R. A., Hicks, R. J. a Hicks, P. M., 1994: Use of air sparging for in situ bioremediation. In: Hinchee, R. E. (ed.): Air sparging for site remediation. Boca Raton, FL, Lewis Publishers, s. 38 – 55.
Bruce, D. A., 2002: Anchors, micropiles, rock grouting and deep mixing: a decade of progress in the United States. Geosytems, Venetia (Pittsburgh), PA.
Bryant, J. D. a Wilson, J. T., 2003: In situ chemical oxidation reduction and precipitation of heavy metals in soils and groundwater. United States Patent 6623646.
Bures, G. H., 2005: Using oil field technology and in situ bioremediation for accelerated site remediation, abstract. P. Eng. – Frac Rite Environmental, 3 s.
Burke, G. K., 2007: Vertical and horizontal groundwater barriers using jet grout panels and columns. Grouting for Ground Improvement: Innovative Concepts and Applications (GSP 168), Part of Geo-Denver 2007: New Peaks in Geotechnics. Proceedings of Sessions of Geo-Denver, s. 1 – 10.
Cantrell, K. J., Kaplan, D. I. a Wietsma, T. W., 1995: Zero- valent iron for the in situ remediation of selected metals in groundwater. In: J. Haz. Mat. 42, s. 201 – 212.
Carey, M. A., Fretwell, B. A., Mosley, N. G. a Smith, J. W. N., 2002: Guidance on the design, construction, operation and monitoring of permeable reactive barriers. National Groundwater & Contaminated Land Centre report NC/01/51, Environment Agency, Bristol, 141 s.
Celenza, G. J., 2000: Industrial waste treatment process engineering: specialized treatment systems, Vol. III. CRC Press, 205 s.
CGER, 1994: Alternatives for ground water cleanup. Committee on Ground Water Cleanup Alternatives, National Research Council, 316 s.
CGER, 2000: Natural attenuation for groundwater remediation. Commission on Geosciences, Environment and Resources, Washington, National Academy Press, 211 s.
Cicek, N., 2003: A review of membrane bioreactors and their potential application in the treatment of agricultural wastewater. In: Canad. Biosystems Engineering, č. 45, s. 637 – 649.
Cline, S. R., West, O. R., Siegrist, R. L. a Holden, W. L., 1997: Performance of in situ chemical oxidation field demonstrations at DOE sites. ASCE In Situ Remediation of the GeoEnvironment Conference Minneapolis Convention Center, Minneapolis, MN. October 5 – 7, 1997.
Cohen, R. M., Mercer, J. W., Greenwald, R. M. a Beljin, M. S., 1997: Design guidelines for conventional pump-and-treat systems. EPA Ground water issue, EPA/540/S-97/504. 38 s.
Comninellis, Ch. a Chen, G., 2009: Electrochemistry for the environment. Springer, 350 s.
Cooney, D. O., 1998: Adsorption design for wastewater treatment. CRC Press, 190 s.
Cooper, W. J., Curry, R. D. a O’Shea, K. E., 1998: Environmental application of ionizing radiation. New York, Wiley-Interscience, 722 s.
Cothern, C. R. a Rebers, P. A., 1990: Radon, radium, and uranium in drinking water. CRC Press, 286 s.
Cozzarelli, I. M., Bekins, B. A., Baedecker, M. J., Aiken, G. R., Eganhouse, R. P. a Tuccillo, M. E., 2001: Progression of natural attenuation processes at a crude-oil spill site: I. Geochemical evolution of the plume. In: J. Contaminant Hydrology, 53, s. 369 – 385.
Cullen, R. W. a Reiner, K. J., 1989: Arsenic speciation in the environment. In: Chem. Review, 89, s. 713 – 764.
Cunningham, S. D. a Ow, D. W., 1996: Promises and prospects of phytoremediation. In: Plant Physiol., 110, s. 715 – 719.
Dale, M. J., 2005: Natural attenuation processes and site monitoring. PPK Environment and Infrastructure, Australia, 13 s.
Daněk, L., 2003: Podzemní a pilotové stěny. In: 5. Odborná konference doktorského studia s mezinárodní účastí – Brno 2003, s. 23 – 26.
Davis, E., 1997: How heat can enhance in situ soil and aquifer remediation: Important chemical properties and guidance on choosing the appropriate technique. EPA/540/S-97/502, Robert S. Kerr Environmental Research Laboratory.
Davis, E., 1998: Steam injection for soil and aquifer remediation. EPA/540/S-97/505, United States Environmental Protection Agency, Ground Water Issue, 16 s.
Davis, E., Akladiss, N., Hoey, R., Brandon, B., Nalipinski, M., Carroll, S., Heron, G., Novakowski, K. a Udell, K., 2005: Steam enhanced remediation research for DNAPL in fractured rock boring. Air Force Base, Limestone, Maine, EPA/540/R-05/010 August 2005, 211 s.
Davis, J. A. a Kent, D. B., 1990: Surface complexation modeling in aqueous geochemistry. In: Hochella, M. F. a White, A. F. (eds.): Mineral-water interface geochemistry. Reviews in mineralogy, č. 23, Washington, Mineralogical society of America, s. 177 – 260.
De Rijk, S. E., Van der Graaf, J. H. J. a Den Blanken, J. G., 1994: Bubble size in flotation thickening. In: Wat. Res., roč. 28, č. 2, s. 465 – 473.
DeBusk, W. F, 1999: Wastewater treatment wetlands: applications and treatment efficiency. Soil and Water Science Department, Florida Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of Florida, s. 7.
Delleur, J. W., 2007: Groundwater engineering. The handbook. Sec. ed.. Tazlor and Francis Group, ISBN 978-0-8493-4316-2.
Demers, I., Fincha, J. a El-Ammouria, E., 2009: Use of activated silica sol as a flocculant in the treatment of acid mine drainage to promote sludge stability. In: Minerals Engineering, roč. 22, č. 5, s. 506 – 512.
Demnerová, K., 2000: Biotechnologie životního prostředí. Praha, TEMPUS – VŠCHT.
Demnerová, K., 2003: Bioremediační technologie k odstranění polychlorovaných bifenylů ze životního prostředí. In: Holoubek, I. (koordinátor, projekt manager), Adamec, V., Bartoš, M., Černá, M., Čupr, P., Bláha, K., Demnerová, K., Drápal, J., Hajšlová, J., Holoubková, I., Jech, L., Klánová, J., Kocourek, V., Kohoutek, J., Kužílek, V., Machálek, P., Matějů, V., Matoušek, J., Matoušek, M., Mejstřík, V., Novák, J., Ocelka, T., Pekárek, V., Petira, K. Provazník, O., Punčochář, M., Rieder, M., Ruprich, J., Sáňka, M., Tomaniová, M., Vácha, R., Volka, K. a Zbíral, J., 2003: Úvodní národní inventura persistentních organických polutantů v České republice. Projekt GF/CEH/01/003: Enabling activities to facilitate early action on the implementation of the Stockholm convention on persistent organic pollutants (POPs) in the Czech Republic. Brno, TOCOEN, v zastoupení Konsorcia RECETOX – TOCOEN & Associates, TOCOEN Report No. 249, Brno.
DeMuth, S., 2008: A cost comparison of organic versus inorganic ion exchange resin for remediation of high-level waste. In: Remed. J., roč. 10, č. 1, s. 107 – 117.
Dercová, K., Makovníková, J., Barančíková, B. a Žuffa, J. 2005: Bioremediácia toxických kovov kontaminujúcich vody a pôdy. In: Chemické listy, č. 99, s. 682 – 693.
Devipriya, S. a Yesodharan, S., 2005: Photocatalytic degradation of pesticide contaminants in water. In: J. Solar Energy Materials & Solar Cells, č. 86, s. 309.
Dokken, K., Gamez, D., Herrera, L, Tiemann, K. J., Pingitore, N. E., Chianelli, P. R. a Gardea-Torresdey, J. L., 1999: Characterization of chromium (VI) bioreduction and chromium (III) binding to alfalfa biomass. In: Proceedings of the 1999 Conference on Hazardous Waste Research, St. Louis, Missouri, May 24 – 27.
Dolejš, P., 2006: Návrhové parametry a separační účinnost flotace – ověření v provozu první vodárenské flotace v ČR na ÚV Mostiště. In: Sborník X. mezinárodní konference Voda, Zlín 2006, s. 131 – 136.
Doronina, N. V., Nazarov, N. M., Ezhov, V. A. a Trotsenko, I. A., 2006: Biodegradation of methyl and ethyl acetates by immobilized Pseudomonas esterophilus cells (Article in Russian). In: Prikl. Biokhim. Mikrobiol., roč. 42, č. 1, s. 52 – 54.
Drinan, J. a Whiting, N. E., 2001: Water & wastewater treatment: a guide for the nonengineering professional. CRC Press, 316 s.
Duarte, C. L., Sampa, M. H. O., Rela, P. R., Oikawa, H., Silveira, C. G. a Azevedo, A. L., 2002: Advanced oxidation process by electron-beam-irradiation-induced decomposition of pollutants in industrial effluents. In: Radiat. Phys. Chem., č. 63, s. 647 – 651.
Dubánek, V., 2006a: Kapitola 3.2.2.6. Srážení, koagulace, flokulace, flotace. In: Matějů, V. (ed.): Kompendium sanačních technologií. 1. vyd. Chrudim, Vodní zdroje Ekomonitor, s. 163 – 164.
Dubánek, V., 2006b: Kapitola 3.2.2.7. Výmena iontu. In: Matejů, V. (ed.): Kompendium sanačních technologií. 1. vyd. Chrudim, Vodní zdroje Ekomonitor, s. 164 – 168.
Early, T., Borden, B., Heitkamp, M., Looney, B. B., Major, D., Waugh, W. J., Wein, G., Wiedemeier, T., Vangelas, K. M., Adams, K. M. a Sink, C. H., 2006: Enhanced attenuation: a reference guide on approaches to increase the natural treatment capacity of a system. Washington Savannah River Company, Aiken, SC 29808, WSRC-STI-2006-00083, 147 s.
Eckenfelder, W. W., Bowers, A. R. a Roth, J. A., 1992: Chemical oxidation-technologies for the nineties: proceedings of the First International Symposium, Chemical Oxidation: Technology for the Nineties. Vanderbilt University, Nashville, Tennessee, February 20 – 22, 1991, CRC Press, 310 s.
Edzwald, J. K., 1995: Principles and applications of dissolved air flotation. In: Wat. Sci. Tech., roč. 31, č. 3 – 4, s. 1 – 23.
ESTCP, 1999: Technology status review, chemical oxidation. Environmental Security Technology Certification Program.
ESTCP, 2002: Multi-Site Air Sparging. Environmental Security Technology Certification Program, Battelle Memorial Institute Columbus, Ohio. 115 s.
Fan, F. M., Brown, R. C., Sung, S. W., Huang, C. P., Ong, S. K. a van Leeuwen, J. H., 2003: Comparisons of polymeric and conventional coagulants in arsenic (V) removal. In: Water Environ. Res, roč. 75, č. 4, s. 308 – 313.
Farhadian, M., Vachelard, C., Duchez, D. a Larroche, Ch., 2008: In situ bioremediation of monoaromatic pollutants in groundwater. In: A review. Bioresource Technology, č. 99, s. 5 296 – 5 308.
Faust, S. D. a Aly, O. M., 1998: Chemistry of water treatment. 2nd ed. CRC Press, 581 s.
Fetter, C. W., 1999: Contaminant hydrogeology. 2nd ed. Prentice Hall, Upper Saddle River, NJ 07458.
Finstein, M. S. a Morris, M. L., 1975: Microbiology of municipal solid waste composting. In: Advances Appl. Microbiol., č. 19, s. 113 – 151.
Fitz, W. J. a Wenzel, W. W., 2002: Arsenic transformations in the soil-rhizosphere-plant system: fundamentals and potential application to phytoremediation. In: J. Biotechnol., č. 99, s. 259 – 278.
Forni, C., Cascone, A., Fiori, M. a Migliore, L., 2002: Sulphadimethoxine and Azolla filiculoides Lam.: a model for drug remediation. In: Water Research, roč. 36, č.e 13, s. 3 398 – 3 403.
Friis, A. K., 2006: The potential for reductive dechlorination after thermal treatment of TCE contaminated aquifers. Ph.D. Thesis. Institute of Environment & Resources. Technical University of Denmark, Kgs. Lyngby. 59 s.
Friis, A. K., Heron, G., Albrechtsen, H. J., Udell, K. S. a Bjerg, P. L., 2006. Anaerobic dechlorination and redox activities after full-scale electrical resistance heating (ERH) of a TCE-contaminated aquifer. In: J. Contaminant Hydrol., č. 88, s. 219 – 234.
FRTR, 2008: Remediation technologies screening matrix and reference guide. Federal Remediation Technologies Roundtable, version 4.0.
Fruchter, J. S., Cole, C. R., Williams, M. D., Vermeul, V. R., Amonette, J. E., Szecsody, J. E., Istok, J. D. a Humphrey, M. D., 2000: Creation of a subsurface permeable treatment zone for aqueous chromate contamination using in situ redox manipulation. In: Ground Water Monitoring and Remediation, č. 20, s. 66 – 77.
Fry, J. C., Gadd, G. M., Herbert, R. A. J. a Watson-Craik, I. A., 1992: Microbial control of pollution. Symposium 48, Society for General Microbiology, Cambridge University Press, Port Chester, NY. 343 s.
Gadd, G. M., 2000: Bioremedial potential of microbial mechanisms of metal mobilization and immobilization. In: Curr. Opinion Biotechnol., č. 11, s. 271 – 279.
Gadd, G. M., 2001: Microbial metal transformations. In: J. Microbiol., roč. 39, č. 2, s. 83 – 88.
Gandy, C. J., Smith, J. W. N. a Jarvis, A. P., 2007: Attenuation of mining-derived pollutants in the hyporheic zone: A review. Science of the Total Environment, 373, s. 435 – 446.
Gavaskar, A. R., Gupta, N., Sass, B. M., Fox, T., Janosy, R. J. a Hick, J., 2000: Design guidance for application of permeable barriers for groundwater remediation. Battelle, Columbus, Ohio, 167 s.
Gazea, B., Adam, K. a Kontopoulos, A., 1996. A review of passive systems for the treatment of acid mine drainage. In: Miner. Eng., č. 9, s. 23 – 42.
Genske, D. D., 2003: Urban land degradation, investigation, remediation. Berlin – Heidelberg – New York, Springer-Verlag, ISBN 3-540-43845-9.
Geoflex, 2009: Plastový štetovnicový systém. Technológie zakladania stavieb. Cofra – firemný materiál.
Geolock, 2009: Vertikálna tesniaca stena. Technológie zakladania stavieb. Cofra – firemný materiál.
Getoff, N., 2002: Factors influencing the efficiency of radiation-induced degradation of water pollutants. In: Radiation Phys. Chem., č. 65, 437 s.
Gibert, O., Ferguson, A. S., Kalin, R. M., Doherty, R., Dickson, K. W., McGeough, K. L., Robinson, J. a Thomas, R., 2007: Performance of a sequential reactive barrier for bioremediation of coal tar contaminated groundwater. In: Environ. Sci. Technol., č. 41, s. 6 795 – 6 801.
Gidarakos, E. a Aivalioti, M., 2007: Large scale and long term application of bioslurping: The case of a Greek petroleum refinery site. In: J Hazard. Mater., č. 149, s. 574 – 581.
Gilmore, T., Looney, B. B., Cutshall, N., Major, D., Wiedemeier, T., Chapelle, F. H., Truex, M., Early, T., Heitkamp, M., Waugh, J., Peterson, D., Wein, G., Bagwell, Ch., Ankeny, M., Vangelas, K. M., Adams, K. M. a Sink, C. H., 2006: Characterization and monitoring of natural attenuation of chlorinated solvents in groundwater: a system approach. WSRC-STI-2006-00084, Rev. 1, 65 s.
Glick, B. R., 2003: Phytoremediation: synergistic use of plants and bacteria to clean up the environment. In: Biotechnol. Advances, č. 21, s. 383 – 393.
Gordon, M. J., 1998: Case history of a large-scale air sparging/soil vapor extraction system for remediation of chlorinated volatile organic compounds in ground water. In: Ground Water Monitoring and Remediation, č. 18, s. 137 – 149.
Grady, C. P. L., Daigger, G. T. a Lim H. C., 1999: Biological wastewater treatment. 2nd ed. CRC Press, 1 076 s.
Gregory, J., 2006: Particles in water, properties and processes. Taylor & Francis, 180 s.
Gu, B., Yan, K., Zhou, P., Watson, D. B., Park, M. a Istok, J., 2005: Natural humics impact uranium bioreduction and oxidation. In: Environ. Sci. Technol., č. 39, s. 5 268 – 5 275.
Gudbjerg, J., 2001: Thermal remediation technologies. Lecture notes. Environment & Resources DTU, Technical University of Denmark.
Guertin, J., Jacobs, J. A. a Avakian, C. P., 2004: Chromium (VI) handbook. Independent Environmental Technical Evaluation Group, CRC Press, 784 s.
Hamer, D. A., 1989: Constructed wetlands for wastewater treatment: Municipal, industrial, and agricultural. CRC Press, 831 s.
Hamer, G., 1997: Microbial consortia for multiple pollutant biodegradation. In: Pure Appl. Chem., 69, 11, s. 2 343 – 2 356.
Hasegawa, M. H., 2000: Surfactant-enhanced subsurface remediation of DNAPLs at the former Naval air station Alameda, California. In: Proceedings International Conference on Remediation of chlorinated and recalchrant compounds, May 22 – 25, Monterey, USA.
HAZWRAP, 1995: In situ bioremediation using horizontal wells. Innovative Technology Summary Report, Hazardous Waste Remedial Actions Program prepared for US Department of Energy.
He, Y. T., Wilson, J. T . a Wilkin, R. T., 2008: Transformation of reactive iron minerals in a permeable reactive barrier (biowall) used to treat TCE in groundwater. In: Environ. Sci. Technol., 42, s. 6 690 – 6 696.
Hendrych, J., Kubal, M., Beneš, P. a Vacek, P., 2008: Vliv vlastností tuhých matric na spotřebu oxidantu při in situ chemické oxidaci manganistanem draselným. In: Acta Montanistica Slovaca, rič. 13, č. 3, s. 285 – 289.
Heron, G., Christensen, T. H. a Enfield, C. G., 1998: Henry's law constant for trichloroethylene between 10 and 95 degrees C. In: Environ. Sci. Technol., 32, 10, s. 1 433 – 1 437.
Heron, G., Gierke, J. S., Faulkner, B., Mravik, S., Wood, L. a Enfield, C. G., 2002: Pulsed air sparging in aquifers contaminated with dense nonaqueous phase liquids. In: Ground Water Monitor. Remed., 22, 4, s. 73 – 82.
Heron, G., Carroll, S. a Nielsen, S. G. D., 2005: Full-scale removal of DNAPL constituents using steam enhanced extraction and electrical resistance heating. In: Ground Water Monitor. Remed., 25, 4, s. 92 – 107.
Hinchee, R. E., Means, J. L. a Burris, D. R. (Eds.), 1995: Bioremediation of inorganics. Columbus, OH, Battelle Press, 174 s.
Holubec, M., 2000: Sanácia podzemných vôd a zemín. Biologická degradácia. In: Práce a štúdie č. 140. Bratislava, VÚVH, ISBN 80-968536-3-5, 107 s.
Hønning, J. a Skou, J., 2003: In situ chemical oxidation of PCE polluted ground water aquifers. Master thesis from Institute of Environment & Resources, Technical University of Denmark.
Hønning, J., 2007: Use of in situ chemical oxidation with permanganate in PCE-contaminated clayey till with sand lenses. Ph.D. Thesis, May 2007. Institute of Environment & Resources, Technical University of Denmark. 61 s.
Horáková, D., 2006: Bioremediace. Brno, Masarykova Univerzita, Přírodovědecká fakulta, Ústav experimentální biologie, 83 s.
Horseman, S. T., Higgo, J. J. W., Alexander, J. a Harrington, J. F., 1996: Water, gas, and solute movement through argillaceous media. Report CC-96/1, OECD, Nuclear energy agency, 290 s.
Hrapovic, L., Sleep, B. E., Major, D. J. a Hood, E. D., 2005: Laboratory study of treatment of trichloroethene by chemical oxidation followed by bioremediation. In: Environ. Sci. Technol., 39, s. 2 888 – 2 897.
Hubáčková, J. a Erben, V., 1989: Využití flotace při procesu úpravy vody. In: Práce a studie, seš. 172. Praha, VÚV, 120 s.
Huling, S. G. a Pivetz, B. E., 2006: In situ chemical oxidation. US EPA Engineering Issue. 58 s.
Hyman, D. M. a Watzlaf, G. R., 1995. Mine drainage characterization for the successful design and evaluation of passive treatment system. In: 17th Annual National Association of Abandoned Mine Lands Conference, French Lick, s. 170 – 185.
Chambers, C. D., 1991: In situ treatment of hazardous waste-contaminated soils. In: Pollution technology review – Vyd. 199. William Andrew, 533 s.
Chaney, R. L., Malik, M., Li, Y. M., Brown, S. L., Brewer, E. P., Angle, J. S. a Baker, A. J., 1997: Phytoremediation of soil metals. In: Current Opinion Biotechnol., 8, s. 279 – 284.
Chapelle, R., Brigmon, R., Early, T., Finneran, K., Gilmore, T., Heitkamp, M., Journey, C., Looney, B., Major, D., Riley, R., Wein, G. a Wiedemeier, T., 2004: Baseline natural attenuation processes: Lines of inquiry supporting monitored natural attenuation of chlorinated solvents. United States Department of Energy, WSRC-TR-2003-00329, 82 s.
Cheremisinoff, P. N., 1995: Handbook of water and wastewater treatment technology. CRC Press, 833 s.
Cheremisinoff, N. P., 2002: Handbook of water and wastewater treatment technologies. Butterworth-Heinemann, 636 s.
Chilakapati, A., 1999: Optimal design of a subsurface redox barrier. AIChE journal, ISSN 0001-1541, roč. 45, č. 6, s. 1 342 – 1 350.
Christensen, O. F., Cassiani, G., Diggle, P. J., Ribeiro, P. Jr. a Andreotti, G., 2004: Statistical estimation of the relative efficiency of natural attenuation mechanisms in contaminated aquifers. In: Stoch. Envir. Res. Risk Ass., 18, s. 339 – 350.
IAEA, 2006: Applicability of monitored natural attenuation at radioactively contaminated sites. International Atomic Energy Agency, Vienna. Technical Reports Series No. 445. 105 s.
IAEA, 2007: Radiation processes: Environmental applications. International Atomic Energy Agency, Vienna. 71 s.
Ibeanusi, V. M. a Grab, D. A., 2004: Radionuclide biological remediation resource guide. US Environmental Protection Agency, Region 5, Superfund Division, Chicago, IL, 60604. 62 s.
Inglezakis, V. J. a Poulopoulos, S. G., 2006: Adsorption, ion exchange and catalysis: design of operations and environmental applications. Elsevier, 602 s.
Isherwood, W. F., Ziagos, J., Nichols, J., Krauter, P. a Rice, Jr., D., 1992: Enhancing aquifer cleanup with reinjection. Lawrence Livermore National Laboratory. Livermore, California, s. 103 – 109.
Istok, J. D., Senko, J. M., Krumholz, L. R, Watson, D., Bogle, M. A., Peacock, A., Chang, Y. J. a White, D. C., 2004: In situ bioreduction of technetium and uranium in a nitrate-contarninated aquifer. In: Environ. Sci. Technol., 38, 2, s. 468 – 475.
ITRC, 2003: Technical and regulatory guidance document for constructed treatment wetlands. Interstate Technology and Regulatory Council, 199 s.
ITRC, 2005a: Technical and regulatory guidance for in situ chemical oxidation of contaminated soil and groundwater, 2nd edition. Interstate Technology and Regulatory Cooperation Work Group, In Situ Chemical Oxidation Work Team.
ITRC, 2005b: Permeable reactive barriers: Lessons learned/new directions, PRB-4. Interstate Technology & Regulatory Council ITRC, Washington, DC.
ITRC, 2008: Enhanced attenuation: Chlorinated organics team. Interstate Technology & Regulatory Council, 444 North Capitol Street, NW, Suite 445, Washington, DC 20001. 67 s.
IUPAC, 1971: Manual of symbols and terminology for physicochemical quantities and units, appendix II, Definitions, terminology and symbols in colloid and surface chemistry. International union of pure and applied chemistry, Adopted by the IUPAC Council at Washington DC USA on 23 July 1971.
Jacimovic, N., Hosoda, T., Ivetic, M. a Kishida, K., 2007: A novel approach in numerical simulation of contaminant removal by air sparging. In: Water Scie. Technol., Water Suppl., 7, 3, s. 163 – 170.
Jackson, T. O., 2004: Case studies analysis: Environmental stigma and monitored natural attenuation. In: Appraisal J., Spring, s. 111 – 118.
Jandeková, R., 2006: Bioremediační technologie pro odstranění toxických látek z vodného prostředí. Bakalářská práce. Brno, Masarykova Univerzita, Přírodovědecká fakulta, Výzkumné centrum pro chemii životního prostředí a ekotoxikologii, 56 s.
Jardine, P. M., Watson, D. B., Blake, D. A., Beard, L. P., Brooks, S. C., Carley, J. M., Criddle, C. S., Doll, W. E., Fields, M. W., Fendorf, S. E, Geesey, G. G. , Ginder-Vogel, M., Hubbard, S. S., Istok, J. D., Kelly, S., Kemner, K. M., Peacock, A. D., Spalding, B. P., White, D. C, Wolf, A., Wu, V. a Zhou, J., 2005: Techniques for assessing the performance of in situ bioreduction and immobilization of metals and radionuclides in contaminated subsurface environments. Oak Ridge National Laboratory, 20 s.
Jazdanian, A. D., Reddy, K. R., Gonzalez, J. V. a Ala, P., 2004: Evaluation of different slurry materials for containment wall construction at a dense nonaqueous phase liquid-contaminated site. In: Advances Water Res., 29, s. 89 – 98.
Jirasko, D., 2004: Aplikace propustných reakčných bariér pro sanaci kontaminovaných podzemných vod. 6 s.
Johnson, C. D., Barry, D. A., Christofi, N. a Patel, D., 2001a: Potential for anaerobic biodegradation of linear alkylbenzene cable oils: Literature review and preliminary investigation. In: Land Contamin. Reclam., 9, 3, s. 279 – 291.
Johnson, P. C., Johnson, R. L., Bruce, C. L. a Leeson, A., 2001b: Advances in situ air sparging/biosparging. In: Bioremed. J., 5, 4, s. 251 – 266.
Johnson, C. D., Truex, M. J. a Clement, T. P., 2006: Natural and enhanced attenuation of chlorinated solvents using RT3D. Pacific Northwest National Laboratory Richland, Washington 99352, 64 s.
Johnson, R. L., Johnson, P. C., McWhorter, D. B., Hinchee, R. E. a Goodman, I., 1993: An overview of in situ air sparging. In: Ground Water Monitor. Remed., roč. 13, č. 4, s. 127 – 135.
Johnston, C. D., Rayner, J. L. a Briege, D., 2002: Effectiveness of in situ air sparging for removing NAPL gasoline from a sandy aquifer near Perth. In: West. Australia. J. Contamin. Hydrol., 59, 1 – 2, s. 87 – 111.
Jordan, R. N., Nichols, E. P. a Cunningham, A. B., 1999: The role of (bio)surfactant sorption in promoting the bioavailability of nutrients localized at the solid-water interface. In: Wat. Sci. Tech., roč. 39, č. 7, s. 91 – 98.
Judd, S., 2006: The MBR Book: Principles and applications of membrane bioreactors for water and wastewater treatment. Elsevier, 317 s.
Juhlin, R., Butherus, M., Daniel, J., Ingle, D. S., Heron, G. a McGee, B., 2004: Successful field-scale in situ thermal NAPL remediation at the young-rainey star center. Proceedings of the Fourth International Conference on Remediation of Chlorinated and Recalcitrant Compounds, Monterey, CA, May 2004, ISBN 1-57477-145-0. Columbus, OH, Battelle Press, 9 s.
Julio, S. S. a Drueker, A. S., 2002: Air sparging remediation: a study on heterogeneity and air mobility reduction. In: J. Hazard. Subst. Res., Volume Three 7 – 1, Kansas State University, 20 s.
Kadlec, R. H. a Knight, R. L., 1996: Treatment wetlands: Theory and implementation. CRC Press, 893 s.
Kadlec, R. H. a Wallace, S., 2008: Treatment wetlands. CRC Press, 1 016 s.
Kaduková, J., Miškufová, A. a Štofko, M., 2006: Využitie rastlín na stabilizáciu a čistenie pôdy a vody kontaminovanej kovmi. In: Acta Montanistica Slovaca, roč. 11, č. 2, s. 130 – 136.
Kao, C. M., Chen, C. Y., Chen, S. C., Chien, H. Y. a Chen, Y. L., 2008: Application of in situ biosparging to remediate a petroleum-hydrocarbon spill site: Field and microbial evaluation. In: Chemosphere, 70, 8, s. 1 492 – 1 499.
Kao, C. M., Chen, S. C. a Liu, J. K., 2001: Development of a biobarrier for the remediation of PCE-contaminated aquifers. In: Chemosphere, 43, s. 1 071 – 1 078.
Kassenga, G. R., Pardue, J. H, Blair, S. a Ferraro, T., 2003: Treatment of chlorinated volatile organic compounds in upflow wetland mesocosms. In: Ecol. Eng., roč. 19, č. 5, s. 305 – 323.
Kassenga, G., Pardue, J. E. L., Moe, W. M. a Bowman, K. S., 2004: Hydrogen thresholds as indicators of dehalorespiration in constructed treatment wetlands. In: Environ. Sci. Technol, roč. 28, č. 4, s. 1 024 – 1 030.
Kassenga, G. R., 2003: Treatment of chlorinated volatile organic compounds using wetland systems. A Dissertation. Graduate Faculty of the Louisiana State University, 252 s.
Keely, J. F., 1989: Performance evaluations of pump-and-treat remediations. EPA Superfunf Groundwater Issue, U.S. Environmental Protection Agency. EPA/540/4-89/005.
Khan, S. A., Hamayun, M. a Ahmed, S., 2006: Degradation of 4-aminophenol by newly isolated Pseudomonas sp. strain ST-4. In: Enzyme Microbial Technol., roč. 38, č. 1 – 2, s. 10 – 13.
Kim, H., Choi, K. M., Moon, J. W. a Annable, M. D., 2006: Changes in air saturation and air-water interfacial area during surfactant-enhanced air sparging in saturated sand. In: J. Contaminant Hydrol., roč. 88, č. 1 – 2, s. 23 – 35.
Kim, H. M., Hyun, Y. a Lee, K. K., 2007: Remediation of TCE-contaminated groundwater in a sandy aquifer using pulsed air sparging: Laboratory and numerical studies. In: J. Environ. Eng., 133, 4, s. 380 – 388.
Kirtland, B. C. a Aelion, C. M., 2000: Petroleum mass removal from low permeability sediment using air sparging/soil vapor extraction: impact of continuous or pulsed operation. In: J. Contaminant Hydrol., roč. 41, č. 3 – 4, s. 367 – 383.
Klinchuch, L. A., Goulding, N., James, S. R. a Gies, J. J., 2007: Deep air sparging – 15 to 46 m beneath the water table. In: Ground Water Monitor. Remed., roč. 27, č. 3, s. 118 – 126.
Kmeť, S., 1992, Flotácia. Bratislava, Alfa, 350 s.
Korte, N. E., 2001: Zero-valent iron permeable reactive barriers: A review of performance. Environmental Sciences Division Publication, No. 5056, ORNL/TM-2000/345, 36 s.
Kram, M. L. a Goetz, F., 1999: Natural attenuation general data guide. Port Hueneme, California, Naval Facilities Engineering Service Center, 33 s.
Krumme, M. L., Timmis, K. N. a Dwyer, D. F., 1993: Degradation of trichloroethylene by Pseudomonas cepacia G4 and the constitutive mutant strain G4 5223 PR1 in aquifer microcosms. In: Appl. Environ. Microbiol., 59, s. 2 746 – 2 749.
Krupka, K. M. a Martin, W. J., 2001: Subsurface contaminant focus area: Monitored natural attenuation (MNA) – programmatic, technical, and regulatory issues. Washington, D.C., US Department of Energy, 138 s.
Kubal, M., Janda, V., Bene, P. a Hendrych, J., 2008: Metoda in situ chemické oxidace a její použití při nápravě starých ekologických zátěží. In: Chem. Listy, 102, s. 493 – 499.
Kummling, K. E., Gray D. J., Power J. P. a Woodland S. E., 2002: Gas-phase chemical reduction of hexachlorobenzene and other chlorinated compounds: Waste treatment experience and applications. In: 6th Int. HCH & Pesticides Forum, 20 – 22 March 2001, Poznan, Poland. 5 s.
Larsen, M., Burken, J., Machackova, J., Karlson, U. G. a Trapp, S., 2008: Using tree core samples to monitor natural attenuation and plume distribution after a PCE spill. In: Environ. Sci. Technol., 42, s. 1 711 – 1 717.
Leães, F. L., Daniel, F. L., Mello, G. B., Battisti, V., Bogusz, Jr., S., Emanuelli, T., Fries, L. L. M. a Costabeber, I., 2006: Degradation of polychlorinated biphenyls (PCBs) by Staphylococcus xylosus in liquid media and meat mixture. In: Food Chem. Toxicol., roč. 44, č. 6, s. 847 – 854.
Lee, J. J., Yoon, J. H., Yang, S. Y. a Lee, S. T., 2006: Aerobic biodegradation of 4-methylpyridine and 4-ethylpyridine by newly isolated Pseudonocardia sp. strain M43. In: FEMS microbiol. lett., 254, 1, s. 95 – 100.
Leeson, A., Johnson, P. C., Johnson, R. L, Hinchee, R. E. a McWhorter, D. B., 1999: Air sparging design paradigm. Draft. Battelle, 505 King Avenue, Columbus, Ohio, 432Gi, 150 s.
Lenke, H., Pieper, D. H., Bruhn, C. a Knackmuss, H. J., 1992: Degradation of 2,4-dinitrophenol by two Rhodococcus erythropolis strains. In: Appl. Environ. Microbiol., roč. 58, č. 9, s. 2 928 – 2 932.
Liles, D. S, Lutes, C. C, Page, G. B. a Suthersan, S. S., 2005: In situ chemical stabilization of metals and radionuclides through enhanced anaerobic reductive precipitation. Application of a commercial technology to DOE Needs. 9 s.
Lin, S. H. a Juang, R. S., 2008: Adsorption of phenol and its derivatives from water using synthetic resins and low-cost natural adsorbents: A review. In: J. Environ. Management, roč. 90, č. 3, s. 1 336 – 1 349.
Liptak, B. G., 2006: Instrument Engineers' Handbook: Process control and optimization. CRC Press, 2 464 s.
Liu, C., Zachara, J. M., Zhong, L., Kukkadupa, R., Szecsody, J. E. a Kennedy, D. W., 2005: Influence of sediment bioreduction and reoxidation on uranium sorption. In: Environ. Sci. Technol., roč. 39, č. 11, s. 4 125 – 4 133.
Liu, D. H. F. a Lipták, B. G., 2000: Wastewater treatment. CRC Press, 457 s.
Lubrecht, M., 1995: Horizontal wells tilt industrial site pollutants: Multiple challenges spawn innovative solutions. In: Soil Groundwater Cleanup Magazine.
Lundegard, P. D. a LaBrecque, D., 1995: Air sparging in a sandy aquifer (Florence, Oregon, USA.): Actual and apparent radius of influence. In: J. Contaminant Hydrol., roč. 19, č. 1, s. 1 – 27.
Macková, M. a Macek, T., 2005: Využití rostlin k eliminaci xenobiotik z životního prostředí. Praha, Výskumní ústav rostlinné výroby, 28 s.
Madrid, F., Liphadzi, M. S. a Kirkham, M. B., 2003: Heavy metal displacement in chelate-irrigated soil during phytoremediation. In: J. Hydrol., 272, 1 – 4, s. 107 – 119.
Manaka, M., Seki, Y., Okuzawa, K., Kamioka, H. a Watanabe, Y., 2007: Natural attenuation of dissolved uranium within a small stream of central Japan. In: Limnology, 8, s. 143 – 153.
Marks, P. J., Wujcik, W. J. a Loncar, A. F., 1994: Remediation technologies screening matrix and reference guide, 2nd edition. West Chester, PA, DOD Environmental Technology Transfer Committee, Roy F. Weston, 461 s.
Matějů, V. (ed.), 2006: Kompendium sanačních technologií. 1. vyd. Chrudim, Vodní zdroje Ekomonitor, 241 s.
Matis, K. A., 1995: Flotation science and engineering. New York, N.Y, Marcel Dekker, 558 s.
Matthews, S. M., Boegel, A. J. a Loftis, J. A., 2006: Radiolytic decomposition of environmental contaminants and site remediation using an electron accelerator. In: Remed. J., roč. 3 č. 4, s. 459 – 481.
McGuire, T. M., Newell, C. J., Looney, B. B. a Vangelas, K. M., 2003: Historical and retrospective survey of monitored natural attenuation: A line of inquiry supporting monitored natural attenuation and enhanced passive remediation of chlorinated solvents. WSRC-TR-2003-00333, Aiken, SC, Westraghouse Savannah River Company, Savannah River Site, 96 s.
Meggyes, T. a Simon, F. G., 2000: Removal of organic and inorganic pollutants from groundwater using permeable reactive barriers. Part 2. Engineering of permeable reactive barriers. In: Land Contamin. Reclam., roč. 8, č. 3, s. 175 – 188.
Meijer, D. Th. a Kuijvenhoven, C. A. T., 2001: Field-proven removal of dissolved hydrocarbons from offshore produced water by the macro porous polymer-extraction technology. Offshore Technology Conference, Houston, Texas, 30 April-3 May. OTC 13217. 9 s.
Mezyk, S. P., Helgeson, T., Cole, S. K., Cooper, W. J., Fox, R. V., Gardinali, P. R. a Mincher, B. J., 2006: Free radical chemistry of disinfection by products. 1. Kinetics of hydrated electron and hydroxyl radical reactions with halonitromethanes in water. In: J. Phys. Chem., A, 110, s. 2 176 − 2 180.
Miller, R. R., 1996a: Bioslurping technology. Overview Report TO-96-05. Pittsburgh, PA, Ground-Water Remediation Technologies Analysis Center, 10 s.
Miller, R. R., 1996b: Phytoremediation. Technology Overview Report TO-96-03. Pittsburgh, PA,Ground-Water Remediation Technologies Analysis Center.
Miller, R. R., 1996c: Air sparging. Technology Overview report TO-96-04. Pittsburgh, PA, Ground-Water Remediation Technologies Analysis Center, 14 s.
Miller, R. R., 1996d: Artificially induced or blast-enhanced fracturing. Technology Overview Report. Pittsburgh, PA, Ground-Water Remediation Technologies Analysis Center, 13 s.
Miller, R. R., 1996e: Horizontal wells. Technology Overview Report. Pittsburgh, PA, Ground-Water Remediation Technologies Analysis Center, 13 s.
Miller, R. R. a Roote, D. S., 1997: In-well vapor stripping. Technology Overview Report TO-97-01. Pittsburg, Ground Water Remediation Technologies Analysis Center GWRTAC, 17 s.
Mincher, B. J., Curry, R. C. a Brey, R., 2000: Method to simultaneously improve PCB radiolysis rates in transformer oil and to close the chlorine mass balance. In: Environ. Sci. Technol., roč. 34, č. 16, s. 3 452 – 3 455.
Mohamed, A. M. I., El-Menshawy, N. a Saif, A. M., 2007: Remediation of saturated soil contaminated with petroleum products using air sparging with thermal enhancement. In: J. Environ. Management, roč. 83, č. 3, s. 339 – 350.
Motsch, Ch., Schug, B., Bärlin, M., Kirchholtes, H. J. a Ertel, T., 2002: Integrated concept for groundwater remediation. In situ remediation techniques. Results of the evaluation of suitable technologies and combination of technologies, UW-Umweltwirtschaft GmbH, Stuttgart.
MSE, 1998. Dynamic underground stripping and hydrous pyrolysis/oxidation cost analysis. MSE Technology applications, Butte, Montana, June 1998.
Mwegoha, W. J. S., 2008: The use of phytoremediation technology for abatement soil and groundwater pollution in Tanzania: opportunities and challenges. In: J. Sustainable Develop. Africa, roč. 10, č. 1. s. 140 – 156.
Neculita, C. M., Zagury, G. J. a Bussière, B., 2007: Passive treatment of acid mine drainage in bioreactors using sulfate-reducing bacteria: Critical review and research needs. In: J. Environ. Qual., 36, s. 1 – 16.
Némethyová, M., Kováčiková, M. a Matys, M., 2000: Metódy sanácie skládok – starých environmentálnych záťaží. Atlas sanačných metód. In: Vest. Ministerstva životného prostredia, roč. VIII, čiast. 6.
Neumann, S. a Fatula, P., 2009: Ion Exchangers for Environmental Protection, Asian Water, April 2009, SHP Media. 5 s.
Newell, C. J., Fisher, R. T. a Hughes, J., 1997a: Subsurface hydrogen injection for the in situ bioremediation of chlorinated solvents. US Patent 5602296, Feb. 17, 1997.
Newell, C. J. Fisher, R. T. a Hughes, J., 1997b: Direct hydrogen addition for the in situ biodegradation of chlorinated solvents. NGWA Petroleum Hydrocarbons Conference, Houston, Texas.
NFESC, 1996: Best practices manual for bioslurping. Naval Facilities Engineering Service Center NFESC, Port Hueneme, CA.
NFESC, 1998: Application guide for bioslurping, Vol. I, Summary of the principles and practices of bioslurping. Naval Facilities Engineering Service Center, Port Hueneme, CA.
NFESC, 2001: Final air sparging guidance document. Technical Report TR-2193-ENV, Battelle, Columbus, OH 43201 – 2693.
NFESC, 2003: Use of prepump separation technologies to enhance cost-effectiveness of bioslurper systems – long term demonstration. Technical Report TR-2220-ENV, Naval Facilities Engineering Service Center, Port Hueneme, CA.
Nobre, R. C. M. a Nobre, M. M. M., 2004: Natural attenuation of chlorinated organics in a shallow sand aquifer. In: J. Hazard. Mater., 110, s. 129 – 137.
Noyes, R., 1991: Handbook of pollution control processes. ISBN 0815512902. Vyd. William Andrew, 758 s.
Nyer, E. K., 1992: Groundwater treatment technology. John Wiley, 306 s.
Nyer, E. K., 2000: Practical techniques for groundwater and soil remediation. Boča Raton, Florida,Lewis Publishers, s. 214.
Olsen, R. H., Mikesell, M. D., Kukor, J. J. a Byrne, A. M., 1995: Physiological attributes of microbial BTEX degradation in oxygen-limited environments. In: Environ. Health. Perspect., 103 5, s. 49 – 51.
Pačes, T., 1983: Základy geochémie vod. Praha, Academia, 304 s.
Palmer, C. D. a Fish, W., 1992: Chemical enhancements to pump-and-treat remediation. US EPA Ground Water Issue, EPA/540/S-92/001. 20 s.
Park, C. H., Keyhan, M., Wielinga, B., Fendorf, S. a Matin, A., 2000: Purification to homogeneity and characterization of a novel Pseudomonas putida chtomate reductase. In: Appl. Environ. Mkrobiol., 66, s. 1 788 – 1 795.
Pars, H. M. a Meijer, D. Th., 1998: Removal of dissolved hydrocarbons from production water by Macro Porous Polymer Extraction (MPPE). SPE International Conference on Health, Safety, and Environment in Oil and Gas Exploration and Production, 7 – 10 June 1998, Caracas, Venezuela, 7 s.
Pastusyek, F., 2006: Kapitola 3.1.3.10. Radiolytický rozklad. In: Matejů, V. (ed.): Kompendium sanačních technologií. 1. vyd. Chrudim, Vodní zdroje Ekomonitor, s. 134 – 136.
Pastuszek, F., Vacek, K. a Vondruska, V., 1993: In situ radiation cleaning of underground water contaminated with cyanides – six years of experience. In: Radiation Phys Chem., roč. 42, č. 4 – 6, s. 699 – 700.
Paul, C. J., McNeil, M. S., Beck, F. P., Clark, P. J., Wilkin, R. T. a Puls, R. W., 2003: Capstone report on the application, monitoring, and performance of permeable reactive barriers for ground-water remediation: Volume 2 Long-term monitoring of PRBs: Soil and ground water sampling. EPA/600/R-03/045b, August 2003. 146 s.
PEREBAR, 2000: Long-term Performance of Permeable Reactive Barriers used for the Remediation of Contaminated Groundwater. Reactive materials and attenuation processes for permeable reactive barriers, National Technical University of Athens, EVKl-CT-1999-00035. 21 s.
Pikaev, A. K., 1998: Electron-beam purification of water and wastewater. Environmental Application of Ionizing Radiation. New York, Wiley-Interscience, s. 495 – 506.
Pitter, P., 1999: Hydrochemie. Praha, Vyd. VŠCHT, 568 s.
Place, M., Hoeppel, R., Chuandry, T., McCall, S. a Williamson, T., 2003: Application guide for bioslurping, principles and practices of bioslurping, Addendum: Use of pre-pump separation for improved bioslurper system operation. Washington, D.C., Department of Defense, 167 s.
Polenka, M., 2006: Kapitola 3.2.2.5. Sanační čerpání a čištění po vyčerpání. In: Matějů, V. (ed.): Kompendium sanačních technologií. 1. vyd. Chrudim, Vodní zdroje Ekomonitor, s. 154 – 158.
Postgate, J. R., 1979: The sulphate reducing bacteria. Cambridge University press, 151 s.
Prommer, H., Barry, D. A. a Davis, G. B., 1999: A one-dimensional reactive multi-component transport model for biodegradation of petroleum hydrocarbons in groundwater. In: Environ. Modell. Softw., 14, s. 213 – 223.
Prommer, H., Barry, D. A. a Davis, G. B., 2002: Modelling of physical and reactive processes during biodegradation of a hydrocarbon plume under transient groundwater flow conditions. In: J. Contamin. Hydrol., 59, s. 113 – 131.
Prommer, H., Barry, D. A. a Zheng, C., 2003: MODFLOW/MT3DMS-based reactive multicomponent transport modeling. In: Groundwater, roč. 41, č. 2, s. 1 – 11.
Prommer, H., Davis, G. B. a Barry, D. A., 2000: Biogeochemical transport modelling of natural and enhanced remediation processes in aquifers. In: Land Contamin. Reclam., roč. 8, č. 3, s. 217 – 224.
Ptáček, M., Erlebach, J. a Lischke, P., 1981: Čištění odpadních vod z galvanotechniky a chemické povrchové úpravy kovů. Praha, SNTL, 315 s.
Radjenovic, J., Matosic, M., Mijatovic, I., Petrovic, M. a Barceló, D., 2008: Membrane bioreactor (MBR) as an advanced wastewater treatment technology. In: Hdb. Env. Chem.,. 5, S/2, Berlin – Heidelberg, Springer-Verlag, s. 37 – 101.
Rahbeh, M. E. a Mohtar, R. H., 2007: Application of multiphase transport models to field remediation by air sparging and soil vapor extraction. Department of Agricultural Engineering, Purdue University, United States, Journal-of-Hazardous-Materials, 2007 MAY 08, 143(1 – 2), 47 s.
Ramírez, T., Armas, M. a Uzcátegui, M., 2007: Effect of accelerated electron beam on pesticides removal of effluents from flower plantations. In: Remediation of polluted waters and wastewater by radiation processing. Final report of the research coordination meeting (RCM) 4 − 9 September 2006, Vienna, Austria, IAEA-TECDOC. IAEA, Vienna.
Ramos, J. L., González-Pérez, M. M., Caballero, A. a van Dillewijn, P., 2005: Bioremediation of polynitrated aromatic compounds: plants and microbes put up a fight. In: Curr. Opin. Biotechnol., roč. 16, č. 3, s. 275 – 281.
Raskin, I., Kumar, P. B. A. N., Dushenkov, S. a Salt, D. E., 1994: Bioconcentration of heavy metals by plants. In: Curr. Opin. Biotechnol., 5, s. 285 – 290.
Reddy, K. R. a DeLaune, R. D., 2008: Biogeochemistry of wetlands: science and applications. CRC Press, 800 s.
Reddy, K. R., 2006: Overexploitation and contamination of shared groundwater resources. In: Darnault, J., 2006: Physical and chemical groundwater remediation technologies. ISBN: 978-1-4020-6983-3, s. 257 – 274.
Reddy, K. R. a Adams, J. A., 2008: Conceptual modeling of air sparging for groundwater remediation. Proceedings of the 9th International Symposium on Environmental Geotechnology and Global Sustainable Development, Hong Kong, June 2008. 18 s.
Reddy, K. R., Semer, R. a Adams, J. A., 1999: Air flow optimization and surfactant enhancement to remediate toluene-contaminated saturated soils using air sparging. Department of Civil and Materials Engineering, University of Illinois, Chicago, USA. In: Environ. Management Health, Spec. Iss. Groundwater, roč. 10, č. 1, s. 52 – 63.
Reddy, K. R. a Tekola, L., 2004: Remediation of DNAPL source zones in groundwater using air sparging. In: Land Contamin. Reclam., roč. 12, č. 2, s. 67 – 83.
Reddy, K. R. a Zhou, J., 1996: Finite element modeling of in situ air sparging for groundwater remediation. In: Proceedings of the Second International Congress on Environmental Geotechnics, Osaka, Japan, November 1996, s. 299 – 304.
Reeder, L. R., Cobbs, J. H., Field, J. W. Jr., Finley, W. D., Vokurka, S. C. a Rolfe, B. N., 1977. Review and assessment of deep well injection of hazardous waste, Vol. I. US EPA Cincinnati, OK, EPA/600/2-77/029a. 214 s.
Reinhard, M., Hopkins, G., Cunningham, J. a Lebron, C. A., 2000: Enhanced in situ anaerobic bioremediation of fuel-contaminated groundwater. NFESC Contract Report CR 00-005-ENV, 78 s.
Repert, D., Barber, R. B., Hess, K. M., Keefe, S. H., Kent, D. B., Leblanc, D. R. a Smith, R. L., 2006: Long-term natural attenuation of carbon and nitrogen within a groundwater plume after removal of the treated wastewater source. In: Environ. Sci. Technol., 40, s. 1 154 – 1 162.
Rice, R., 1996: Ozone reference guide: an overview of ozone fundamentals and municipal and industrial ozone applications. EPRI Community Environmental Center, Report CR-106435. St. Louis.
Robinson, J., Thomas, R., Wallace, S., Daly, P. a Kalin, R., 2006: In situ bioremediation of cyanide, PAHs and organic compounds using an engineered Sequenced Reactive Barrier (SEREBAR). In: Land Contamin. Reclam., roč. 14, č. 2, s. 478 – 482.
Rocca, C. D., Belgiorno, V. a Meriç, S., 2007: Overview of in situ applicable nitrate removal processes. In: Desalination, 204, s. 46 – 62.
Ronen, Z., Vasiluk, L., Abeliovich, A. a Nejidat, A., 2000: Activity and survival of tribromophenol-degrading bacteria in a contaminated desert soil. In: Soil Biol. Biochem., roč. 32, č. 11 – 12, s. 1 643 – 1 650.
Roote, D. S., 2000: Hydraulic, pneumatic and blast-enhanced fracturing, Technology status report, GWRTAC, s. 173.
Rubio, J., Souza, M. L. a Smith, R. W., 2002: Overview of flotation as a wastewater treatment technique. In: Miner. Eng., 15, s. 139 – 155.
Ruml, V. a Soukup, M., 1984: Likvidace toxických odpadů. Praha, SNTL, 264 s.
Russell, D. L., 2006: Practical wastewater treatment. John Wiley, 271 s.
Ryan, CH. R., 1987: Vertical barriers in soil for pollution containment, Geotechnical Practice for Waste Disposal ’87 (GSP 13), s. 182 – 204.
Sampa, M. H. O., Borrely, S. I. a Silva, B. L., 1995: The use of electron beam accelerator for the treatment of drinking water and wastewater in Brazil. In: Radiat. Phys. Chem., 46, s. 1 143 − 1 146.
Sampa, M. H. O., Rela, P. R., Las Casas, A., Mori, M. N. a Duarte, C. L., 2004: Treatment of industrial effluents using electron beam accelerator and adsorption with activated carbon: a comparative study. In: Radiat. Phys. Chem., 71, s. 459 – 462.
Sampa, M. H. O., Takács, E., Gehringer, P., Rela, P. R., Ramirez, T., Amro, H., Trojanowicz, M., Botelho, M. L., Han, B., Solpan, D., Cooper, W. J., Emmi, S. S. a Wojnárovits, L., 2007: Remediation of polluted waters and wastewater by radiation processing. In: Nukleonika, roč. 52, č. 4, s. 137 – 144.
Scott, G. H. a Jones, P. K., 2008: EPA research on chemical oxidation/in situ chemical oxidation.
Seagren, E. A. a Becker, J. G., 2002: Review of natural attenuation of BTEX and MTBE in groundwater. In: Practice periodical of hazardous, toxic, and radioactive waste management, July 2002, s. 156 – 172.
Semer, R., Adams, J. A. a Reddy, K. R., 1998: An experimental investigation of air flow patterns in saturated soils during air sparging. In: Geotech. Geol. Eng. J., roč.16, č. 1, s. 59 – 75.
Sengupta, A. K., 1995: Ion exchange technology: advances in pollution control. CRC Press, 385 s.
Seol, Y., Zhang, H. a Schwartz, F. W., 2003: A review of in situ chemical oxidation and heterogeneity. Columbus, OH, Department of Geological Sciences, The Ohio State University, 30 s.
SERDP a ESTCP, 2004: In situ chemical oxidation projects.
SERDP, 2000: Strategic environmental research and development program, Low-volume pulsed biosparging of hydrogen for bioremediation of chlorinated solvent plumes. Cleanup, CU-120.
Shaheen, R., Arefin, M. T. a Mahmud, R., 2007: Phytoremediation of boron contaminated soils by naturally grown weeds. In: J. Soil. Nature., roč. 1, č. 1, s. 1 – 6.
Sharma, P. K., Balkwill, D. L., Frenkel, A. a Vairavamurthy, M. A., 2000: A new Klebsiella planticola strain (Cd-l) grows anaerobically at high cadmium concentrations and precipitates cadmium sulfide. In: Appl. Environ. Microbiol., 66, s. 3 083 – 3 087.
Schnoor, J. L., 1997: Phytoremediation. Technology Overview Report TE-98-01. Pittsburgh, PA, Ground-Water Remediation Technologies Analysis Center.
Schuring, J. R., 2002: Fracturing technologies to enhance remediation. Technology Evaluation Report, TE-02-02. Pittsburgh, PA, Ground-Water Remediation Technologies Analysis Center, s. 52.
Schweitzer, P. A., 1997: Handbook of separation techniques for chemical engineers. McGraw-Hill Professional, 1 200 s.
Schwitzguébel, J. P., 2004: Potential of phytoremediation, an emerging green technology: European trends and outlook. In: Proc. Indian nat. Sci. Acad., B70, č. 1, s. 131 – 152.
Siegrist, R. L., 2000: In situ chemical oxidation for remediation of contaminated soil and ground water. Ground Water Currents, EPA 542-N-00-006, September 2000, Iss. No. 37. 6 s.
Siegrist, R. L., Crimi, M. L., Munakata-Marri, J., Langasekare, T., Dugan, P., Heiderscheid, J., Petri, B. a Sahl, J., 2008: Chemical oxidation for clean up of contaminated ground water. Methods and Techniques for Cleaning-up Contaminated Sites. Springer, s. 45 – 58.
Siegrist, R. L., Urynowicz, M. A., West, O. R., Crimi, M. L. a Lowe, K. S., 2001: Principles and practices of in situ chemical oxidation using permanganate. Columbus, Ohio, Battelle Press, s. 348.
Simon, F. G. a Meggyes, T., 2000: Removal of organic and inorganic pollutants from groundwater using permeable reactive barriers. Part 1. Treatment processes for pollutants. In: Land Contamin. Reclam., roč. 8, č. 2, s. 103 – 116.
Sincero, A. P. a Sincero, G. A., 2003: Physical-chemical treatment of water and wastewater. CRC Press, 832 s.
Singh, A. L., Kulshreshtha, U. C., Mohan, S. V. a Sarma, P. N., 2004: Fe(II) speciation and its uptake by free and immobilized cells of Pseudomonas fluorescens from industrial waste water. In: J. Environ. Sci. Eng., roč. 46, č. 4, s. 277 – 281.
Singh, V. P. a Stapleton, R. D. Jr. (Eds.), 2003: Biotransformations: Bioremediation Technology for Health and Environmental Protection. In: Progress Industr. Microbiol., 36.
Sinke, A. a le Hecho, I., 1999: Monitored natural attenuation: review of existing guidelines and protocols. TNO-MEP – R 99/313, 69 s.
Sittler, S. P. a Peacock, M. P., 1997: Innovative air sparging modifications to remediate organic compounds in non-optimum geologic formations. In: Proceedings of the 11th National Outdoor Action Conf. Expo., s. 259 – 271.
Skinner, S. J. W. a Schutte, C. F., 2006: The feasibility of a permeable reactive barrier to treat acidic sulphate- and nitrate-contaminated groundwater. In: Water SA, roč. 32, č. 2, s. 129 – 135.
Slater, L. a Binley, A., 2003: Evaluation of permeable reactive barrier (PRB) integrity using electrical imaging methods. In: Geophysics, roč. 68, č. 3, s. 911 – 921.
Sluys, J. T. M., 2001: MPPE: an emerging technology for the removal of hazardous contaminants from groundwater. Akzo Nobel MPP Systems.
Sluys, J. T. M., Levsen, K. a Rakel, K., 2000: Pilotversuch zur Aufbereitung von Explosivstoff-verunreinigtem Grundwasser mit neuem extraktiven Verfahren. WLB Wasser. In: Luft und Boden, č. 9. s. 26 – 28.
Smith, L. A. a Hinchee, R. E., 1993. In situ thermal technologies for site remediation. Boca Raton FL, Lewis Publishers.
Smith, L. A., Alleman, B. C. a Copley-Graves, L., 1994: Biological treatment options. In: Emerging Technology for Bioremediation of Metals (Means, J. L. and Hinchee, R. E., eds.). Ohio, Lewis Publishers, s. 1 – 12.
Somasundaran, P., 2006: Encyclopedia of Surface and Colloid Science, Vol. 1. CRC Press, 6 775 s.
Sookhak-Lari, K. a Safavi, H., 2008: A simulation-optimization model for “air sparging” and “pump and treat” groundwater remediation technologies. In: J. Environ. Inf., roč. 12, č. 1, s. 44 – 53.
Spellman, F. R., 2003: Handbook of water and wastewater treatment plant operations. CRC Press, 661 s.
Sposito, G., 1984: The surface chemistry of soils. Oxford, New York, 234 s.
Starr, R. C. a Cherry, J. C., 1994: In situ remediation of contaminated ground water: The funnel-and-gate system. In: Ground water, roč. 32, č. 3, s 465 – 476.
Stiber, N. A., Pantazidou, M. a Small, M. J., 2004: Embedding expert knowledge in a decision model: evaluating natural attenuation at TCE sites. In: J. Hazard. Mater., 110, s. 151 – 160.
STN EN 12063 (731022), 2003: Vykonávanie špeciálnych geotechnických prác. Štetovnicové steny.
STN EN 12715 (731006), 2003: Vykonávanie špeciálnych geotechnických prác. Injektáže.
STN EN 12716 (731007), 2003: Vykonávanie špeciálnych geotechnických prác. Prúdová injektáž.
STN EN 15237 (731024), 2007 Vykonávanie špeciálnych geotechnických prác. Zvislé odvodňovanie.
STN EN 1538 (73 1003), 2002: Vykonávanie špeciálnych geodetických prác. Podzemné steny.
Strnadová, N. a Janda, V., 1995: Technologie vody 1. Praha, Vyd. VŠCHT, 274 s.
Suthersan, S. S. a Payne, F. C., 2005: In situ remediation engineering. CRC Press, 511 s.
Suthersan, S. S., 1996: Remediation engineering: design concepts. CRC Press, 362 s.
Suthersan, S. S., 1999: In situ air sparging. Remediation engineering: design concepts. (Ed.: Suthan, S. a Suthersan, S. S.). Boca Raton: CRC Press.
Szecody, J. E., Fruchter, J. S., Williams, M. D., Vermeul, V. R. a Sklarew, D., 2004: In situ chemical reduction of aquifer sediments: Enhancement of reactive iron phases and TCE dechlorination. In: Environ. Sci. Technol., 38, s. 4 656 – 4 663.
Špirochová, I., Punčochářová, J., Kafka, Z., Kubal, M., Soudek, P. a Vaněk, T., 2001: Studium kumulace těžkých kovů v rostlinách. In: Chem. listy, 95, s. 335 – 336.
Šráček, O., Datel, J. a Mls, J., 2002: Kontaminační hydrogeologie. Univerzita Karlova v Praze, Nakl. Karolinum.
Thomas, W. J. a Crittenden, B. D., 1998: Adsorption technology and design. Butterworth-Heinemann, 271 s.
Thomson, N. R. a Johnson, R. L., 2000: Air distribution during in situ air sparging: an overview of mathematical modeling. In: J. Hazard. Mater., roč. 72, č. 2 – 3, s. 265 – 282.
Thornton, E. C., Gilmore, T. J., Olsen, K. B., Giblin, J. T. a Phelan, J. M., 2007: Treatment of a Chromate-Contaminated Soil Site by in situ Gaseous Reduction. In: Ground Water Monitor. Remed., roč. 27, č. 1, s. 56 – 64.
Tchobanoglous, G., Burton, F. L, Stensel, H. D., 2003: Wastewater engineering: treatment and reuse. 4. vyd. Metcalf a Eddy, McGraw-Hill Professional, 1 819 s.
Tiehm, A. a Schulze, S., 2003: Intrinsic aromatic hydrocarbon biodegradation for groundwater remediation. In: Oil Gas Sci. Technol. – Rev. IFP, roč. 58, č. 4, s. 449 – 462.
Till, B. A., Weathers, L. J. a Alvarez, P. J. J., 1998: Fe(0)-supported autotrophic denitrification. In: Environ. Sci. Technol. 32, s. 634 – 639.
Tong, W. a Rong, Y., 2008: Data evaluation of in situ chemical treatment for groundwater remediation at leaking underground storage tank sites in Los Angeles area, California.
Toze, S., Zappia, L. a Davis, G. B., 2000: Determination of the potential for natural and enhanced biotransformation of munition compounds contaminating groundwater in a fractured basalt aquifer. In: Land Contamin. Reclam., roč. 8, č. 3, s. 1 – 8.
Treybal, R. E., 1980: Mass-transfer operations, 3rd ed. New York, McGraw-Hffl.
Trojanowicz, M. a Drzewicz, M., 2002: Radiolytic degradation and toxicity changes in -irradiated solutions of 2,4-dichlorophenols. In: Radiation Phys. Chem.,. 65, s. 357.
Tsai, T. T., Kao, C. M., Yeh, T. Y. a Lee, M. S., 2008: Chemical oxidation of chlorinated solvents in contaminated groundwater: Review. In: Practice Period. Hazard. Toxic Radioactive Waste Management, roč. 12, č. 2, s.116 – 126.
Unger, A. J. A., Sudicky, E. A. a Forsyth, P. A., 1995: Mechanisms vontrolling vacuum extraction coupled with air sparging for remediation of heterogeneous formations contaminated by dense nonaqueous phase liquids. In: Water Res. Research, roč. 31, č. 8, s. 1 913 – 1 925.
US ACE, 1996: Engineering and design. Horizontal directional drilling for environmental applications. Technical Letter No. 1110-1-178, US Army Corps of Engineers, Washington, D. C.
US AFCEE, 1997: Engineering evaluation and cost analysis for bioslurper initiative (A005). US Air Force Center for Environmental Excellence, Technology Transfer Division, Brooks AFB, Texas, 87 s.
US Department of Defence, 2003: In situ remediation of MTBE-contaminated aquifers using propane biosparging. Environmental Security Technology Certification Program, Cost and Performance Report CU-0015.
US Department of Energy, 1994a: Volatile organic compounds in non-arid soils integrated demonstration. DOE/EM-0135P, Chapter 2.0, Directional Drilling.
US Department of Energy, 1994b: Technology Catalog. DOE/EM-0138P, Chapter 5.12, In Situ Air Stripping of VOCs Using Horizontal Wells.
US Department of Energy, 1998: Horizontal wells. Subsurface Contaminants Focus Area, Innovative Technology Summary Report, US Department of Energy, Office of Environmental Management, Office of Science and Technology, DOE/EM-0378, 17 s.
US Department of Energy, 2000: In situ redox manipulation. Subsurface Contaminants Focus Area, Inovative Technology Summary Report, DOE/EM-0499, US Department of Energy, 15 s.
US EPA, 1981: Control and treatment technology for the metal finishing industry – ion exchange. Summary Report US EPA, EPA 625/-81-007 June 1981, 46 s.
US EPA, 1993. Accutech pneumatic fracturing extraction and hot gas injection, Phase I. EPA RREL, EPA/540/R-93/509.
US EPA, 1994a. Manual: alternative methods for fluid delivery and recovery. US EPA, Office of Research and Development, Washington, DC. EPA/625/R-94/003.
US EPA, 1994b: How to evaluate alternative cleanup technologies for underground storage tank sites, a guide to corrective action plan reviewers. Office of Solid Wastes and Emergency Response 5403 W, EPA 510-B-94-003, Washington, D. C.
US EPA, 1994c: Air sparging. 34 s.
US EPA, 1995a: Handbook of constructed wetlands: General considerations. Vol. 1, 57 s., ISBN 0-16-052999-9.
US EPA, 1995b: In situ remediation technology status report: Hydraulic and pneumatic fracturing. US EPA, Office of Solid Waste and Emergency Response Technology Innovation Office Washington, DC. EPA542-K-94-005.
US EPA, 1995c: How to evaluate alternative cleanup technologies for underground storage tank sites. A guide to corrective action plan reviewers. Office of Solid Wastes and Emergency Response 5403 W, EPA-B-95-007, Washington, D. C.
US EPA, 1995d: In situ remediation technology status report: Thermal enhancements, Part 2: Six phase soil heating. EPA 542-K-94-009.
US EPA, 1997a: BIOPLUME III, version 1.0, September 1997.
US EPA, 1997b: BIOSCREEN, version 1.4, July 1997.
US EPA, 1998a: Permeable reactive barrier technologies for contaminant remediation. Technical Report, Office of Research and Development, Washington DC 20460, EPA-600-R-98-125, s. 1 – 39.
US EPA, 1998b: Evaluation of subsurface engineered barriers at waste sites. EPA 542-R-98-005, 148 s.
US EPA, 1998c: Field applications of in situ remediation technologies: Chemical oxidation. EPA 542-R-98-008.
US EPA, 1999a: Use of monitored natural attenuation at superfund. RCRA Corrective Action, and Underground Storage Tank Sites, Office of Solid Waste and Emergency Response, Directive No. 9200.47-17P.
US EPA, 1999b: Field applications of in situ remediation technologies: Permeable reactive barriers.
US EPA, 2000: Engineered approaches to in situ bioremediation of chlorinated solvents. Fundamentals and field applications. US EPA, Office of Solid Waste and Emergency Response, Technology Innovation Office, Washington, D. C. EPA 542-R-00-008.
US EPA, 2001a: A citizen’s guide to air stripping. The Citizen’s Guide Series, US EPA Office of Solid Waste and Emergency Response, Washington, DC 20460, 2 s. EPA 542-F-01-016.
US EPA, 2001b: Use of bioremediation at superfund sites. US EPA, Office of Solid Waste and Emergency Response, Technology Innovation Office, Washington, D. C., EPA 542-R-01-A19.
US EPA, 2001c: A citizen’s guide to fracturing. US EPA, Office of Solid Waste and Emergency Response. EPA 542-F-01-015.
US EPA, 2001d: A citizen's guide to chemical oxidation. EPA 542-F-01-013, April 2001.
US EPA, 2001e: A citizen's guide to in situ thermal treatment methods.
US EPA, 2002a: Field applications of in situ remediation technologies: permeable reactive barriers.
US EPA, 2002b: BIOCHLOR, version 2.2. March 2002.
US EPA, 2004a: How to evaluate alternative cleanup technologies for underground storage tank sites: A guide for corrective action plan reviewers. Office of Solid Waste and Emergency Response 5401G, EPA 510-R-04-002, Washington, D. C.
US EPA, 2004b: Performance monitoring of MNA remedies for VOCs in ground water. US EPA Cincinnati, OH 45268, EPA/600/R-04/027 April 2004, 92 s.
US EPA, 2004c: In situ thermal treatment of chlorinated solvents – fundamentals and field applications. EPA, 542-R-04-010, U. S. Environmental Protection Agency, 145 s.
US EPA, 2005: Cost-effective design of pump and treat systems, one of a series on optimization. EPA 542-R-05-008, Office of Superfund Remediation and Technology Innovation, 38 s.
US EPA, 2007: Treatment technologies for site cleanup: Annual status report (Twelfth Edition). US EPA report EPA-542-R-07-012, 290 s.
US EPA, 2008: Field application of a permeable reactive barrier for treatment of arsenic in ground water. EPA 600/R-08/093.
Vaishya, R. C., Sethy, M. M. a Reddy, K. R., 2007: Prevention of groundwater contamination through reactive barrier material (RBM) for use in landfill liners and in situ barriers to immobilize chromium. Groundwater Quality 2007: Securing Groundwater Quality in Urban and Industrial Environments, Fermantle, Western Australia, December 2 – 7,.
Van der Meer, A. B. a Brooks, Jr. P. E., 2007: Groundwater remediation via marcro porous polymer extraction. In: Remed. J., roč. 8, č. 4, s. 69 – 85.
Van Antwerp, D. J., Falta, R. W. a Gierke, J. S., 2008: Numerical simulation of field-scale contaminant mass transfer during air sparging. In: Vadose Zone J., roč. 7, č. 1, s. 294 – 304.
Vaníček, I., 2002: Sanace skládek, starých ekologických zátěží. Praha, Vyd. ČVUT, 247 s.
Varga, Š. a Tölgyessy, J., 1976: Rádiochémia a radiačná chémia. Bratislava, Alfa.
Varga, Š. a Tölgyessy, J., 1982: Základy radiačnej chémie a radiačnej technológie. Bratislava, Alfa.
Verfel, J., 1992: Injektování hornin a výstavba podzemních stěn. Bratislava, Bradlo, 511 s.
Veselá, L., Nemecek, J., Siglova, M. a Kubal, M., 2006: The biofiltration permeable reactive barrier: Practical experience from Synthesia. In: Int. Biodeter. Biodegrad., roč. 58, č. 3 – 4, s. 224 – 230.
Veselá, L., Vaněk, J. a Němeček, J., 2003: Biologický prvek při aplikacích podzemní reaktivní stěny. In: Halousková, O. (ed.): Sbor. Konf. Biodegradace VI. Seč, Vodní zdroje Ekomonitor, s. 86 – 91.
Vesilind, P. A., 2003: Wastewater treatment plant design. IWA Publishing, 512 s.
Waduge, W. A. P., Soga, K. a Kawabata, J., 2007: Physical modeling of LNAPL source zone remediation by air sparging. In: Vadose Zone J., roč. 6, č. 2, s. 413 – 422.
Waduge, W. A. P., Soga, K. a Kawabata, J., 2004: Effect of NAPL entrapment conditions on air sparging remediation efficiency. In: J. Hazard. Mater., roč. 110, č. 1 – 3, s. 173 – 183.
Walton, H. F., 1949: Ion exchange equilibria. In: Nachod, F. C. (ed.): Ion exchange, teory and application. New York, Academic press Publ., s. 3 – 28.
Wang, L. K., Hung, Y. T. a Shammas, N. K., 2005: Physicochemical treatment processes . Humana Press, 723 s.
Wang, L. K., Hung, Y. T. a Shammas, N. K., 2006: Handbook of environmental engineering, Vol. 4: Advanced physicochemical treatment processes. Humana Press, 690 s.
Wang, Q., Kim, D., Dionysiou, D. D., Sorial, G. A. a Timberlake, D., 2004: Sources and remediation for mercury contamination in aquatic systems – literature review. In: Environ. Pollution, 131, s. 323 – 336.
Warner, S. D., Yamane, C. L., Bice N. T., Szerdy, F. S., Vogan, J., Major, D. W. a Hankins, D. A., 1998: Technical update: the first comemrcial subsurface permeable ewactive treatment zone composed of granular zero-valent iron. Designing and Applying Treatment Technologies, Remediation of Chlorinated and Recalcitrant Compounds. Monterey, California, Battle press, 6 s.
Warner, S. D., Longino, B. L., Zhang, M., Bennett, P. a Szerdy, F. S., 2004: The first commercial permeable reactive barrier composed of granular iron − hydraulic and chemical performance at 10 years of operation. Presented at the First International Symposium on Permeable Reactive Barriers, Belfast, Northern Ireland March 16, 2004. Geomatrix Consultants, Oakland, California, USA.
Warner, S. D., Longino, B. L., Zhang, M., Bennet, P., Szerdy, F. S. a Hamilton, L. A., 2005: The first commercial permeable reactive barrier composed of granular iron: Hydraulic and chemical performance at 10 years of operation. IAHS-AISH-Publication, s. 32 – 42.
Watts, R. J. a Teel, A. L., 2006: Treatment of contaminated soils and groundwater using ISCO. Practice periodical of hazardous, toxic, and radioactive waste management, 10.1061/(ASCE)1090-025X(2006)10:1(2).
Weston, A. a Balba, T., 2003: Feasibility studies. In: Innovative Technol. Group, roč. 3, č. 5, 2 s.
Widdel, F., 1988. Microbiology and ecology of sulfate- and sulfurreducing bacteria. In: Zehnder, A. J. B. (ed.): Biology of anaerobic microorganisms. New York, John Wiley, s. 469 – 586.
Wiesmann, U., Choi, I. S. a Dombrowski, E. M., 2007: Fundamentals of biological wastewater treatment. Wiley-VCH, 362 s.
Wildeman, T. R., Filipek, L. H. a Gusek, J., 1994: Proof-of-principle studies for passive treatment of acid rock drainag andmill tailing solutions from a gold operation in Nevada. In: International Land Reclamation and Mine Drainage Conference and the Third International Conference on the Abatement of Acidic Drainage. Pittsburg, PA, s. 9 – 16.
Wildeman, T. R. a Updegraff, D. M., 1997: Passive bioremediation of metals and inorganic contaminants. In: Macalady, D. L. (ed.): Perspective in environmental chemistry. New York, Oxford Univ. Press, s. 473 – 495.
Wilkin, R. T., 2008: Contaminant Attenuation Processes at Mine Sites. In: Mine Water Environ., 27, s. 251 – 258.
Willow, M. A. a Cohen, R. R. H., 2003: pH, dissolved oxygen, and adsorption effects on metal removal in anaerobic bioreactors. In: J. Environ. Qual. 32, s. 1 212 – 1 221.
Wilson, D. D., 1994: Horizontal Environmental Wells September.
Wilson, J. T., 1999 Performance monitoring for natural attenuation of contaminants in aquifers. In: Proceedings Contaminated Site Remediation Conference “Challenges Posed by Urban and Industrial Contaminants”, Fremantle WA March 1999, s. 283 – 296.
Woods, R. J. a Pikaev, A. K., 1994: Applied radiation chemistry: radiation processing. New York, Wiley-Intersci., 535 s.
Xu, Z., Zhang, Q. a Fang, H. P., 2003: Applications of porous resin sorbents in industrial wastewater treatment and resource recovery. In: Critic. Rev. Environ. Sci. Technol., roč. 33, č. 4, s. 363 – 389.
Yak, H. K., Mincher, B. J., Chiu, K. H. a Wai, Ch. M., 1999: Supercritical fluid extraction/γ-radiolysis of PCBs from contaminated soil. In: J. Hazard. Mater., roč. 69, č. 2, s. 209 – 216.
Yang, X., Beckmann, D., Fiorenza, S. a Niedermeier, C., 2005a: Field study of pulsed air sparging for remediation of petroleum hydrocarbon contaminated soil and groundwater. In: Environ. Sci. Technol., roč. 39, č. 18, s. 7 279 – 7 286.
Yang, X., Glasser, H., Stoelting, R., Barden, M., Mickelson, G., Delwiche, J., Portz, E., Steinhermer, C., Alvarez, G., Hagerty, D., Petrofske, S. a Misky, D., 2005b: Natural attenuation study in Wisconsin and Illinois, 24 s.
Yin, Y. a Allen, H. E., 1999: In situ chemical treatment. Technology Evaluation Report TE-99-01. Pittsburg, Ground Water Remediation Technologies Analys Center, 82 s.
Ziemkiewicz, P. F., Skousen, J. G. a Simmons, J., 2003. Long-term performance of passive acid mine drainage treatment systems. In: Mine Water Environ., 22, s. 118 – 129.
Zolla, V., Sethi, R. a Di Molfetta, A., 2007: Performance assessment and monitoring of a permeable reactive barrier for the remediation of a contaminated site. In: Amer. J. Environ. Sci., roč. 3, č. 3, s. 158 – 165.
Internetové zdroje
http://www.veoliawaterst.com/autoflot/en/
https://portal.navfac.navy.mil/portal/page/portal/navfac/navfac_ww_pp/navfac_nfesc_pp/environmental/erb/bioreactor
http://www.ieg-technology.com/en/Soil-and-Groundwater-Remediation-Technologies/Groundwater-Circulation-Wells/Macro-Porous-Polymer-Extraction.html
© Atlas sanačných metód environmentálnych záťaží
Autori: Jana Frankovská, Jozef Kordík, Igor Slaninka, Ľubomír Jurkovič, Vladimír Greif,
Peter Šottník, Ivan Dananaj, Slavomír Mikita, Katarína Dercová a Vlasta Jánová
Štátny geologický ústav Dionýza Štúra, Bratislava 2010, 360 s,
ISBN 978-80-89343-39-3