DOCSLIB.ORG

Laboratory Evaluation of a Two-Stage Treatment System for TCE Cometabolism by a Methane-Oxidizing Mixed Culture

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Laboratory Evaluation of a Two-Stage Treatment System for TCE Cometabolism by a Methane-Oxidizing Mixed Culture Laboratory Evaluation of a Two-Stage Treatment System for TCE Cometabolism by a Methane-Oxidizing Mixed Culture Laurence H. Smith,1 Perry L. McCarty2 1Department of Process and Environmental Technology, Massey University, Palmerston North, New Zealand; telephone: 64-6-356-9099; fax: 64-6-350-5654; e-mail: [email protected]. 2Environmental Engineering and Science, Department of Civil Engineering, Stanford University, Stanford, California 94305-4020 Received 5 July 1996; accepted 30 December 1996 Abstract: The objective of this research was to evaluate INTRODUCTION several factors affecting the performance of a two-stage treatment system employing methane-oxidizing bacteria Biodegradation of trichloroethylene (TCE) contaminated for trichloroethylene (TCE) biodegradation. The system water has gained increased interest due to the potential for consists of a completely mixed growth reactor and a plug-flow transformation reactor in which the TCE is co- TCE destruction rather than transfer to another medium, as metabolized. Laboratory studies were conducted with in air stripping and activated carbon adsorption. Both aero- continuous growth reactors and batch experiments bic and anaerobic bacteria are capable of transforming TCE. simulating transformation reactor conditions. Perfor- The aerobic bacteria generally employ oxygenases, such as mance was characterized in terms of TCE transformation methane monooxygenase (MMO) in methanotrophic bacte- capacity (TC, g TCE/g cells), transformation yield (TY, g ria, to oxidize TCE to TCE epoxide, which is subsequently TCE/g CH ), and the rate coefficient ratio k /K 4 TCE S,TCE mineralized in mixed cultures (Arciero et al., 1989; Ensign (L/mg-d). The growth reactor variables studied were sol- ids retention time (SRT) and nutrient nitrogen (N) con- et al., 1992; Fogel et al., 1986; Nelson et al., 1988; Tsien et centration. Formate and methane were evaluated as po- al., 1989; Wackett and Gibson, 1988). Some of the highest tential transformation reactor amendments. Comparison rates of TCE oxidation have been obtained in methanotro- of cultures from 2- and 8-day SRT (nitrogen-limited) phic pure and mixed cultures, particularly in the cases of growth reactors indicated that there was no significant methanotrophs expressing the soluble form of MMO (Al- effect of growth reactor SRT or nitrogen availability on TC varez-Cohen and McCarty, 1991a; Oldenhuis et al., 1991; or T , but N-limited conditions yielded higher Y Tsien et al., 1989). The design of aerobic treatment systems kTCE/KS,TCE. The TCE cometabolic activity of the 8-day SRT, N-limited growth reactor culture varied significantly for TCE destruction is complicated because TCE oxidation is a cometabolic process; the bacteria do not gain carbon or during a 7-year period of operation. The TC and TY of the resting cells increased gradually to levels a factor of 2 energy for growth from the reaction. Because of the com- higher than the initial values. The reasons for this in- plexity of the processes involved, it is not yet obvious how crease are unknown. Formate addition to the transforma- to optimize a treatment system for TCE biodegradation. tion reactor gave higher TC and TY for 2-day SRT growth One approach suggested by several investigators employs reactor conditions and significantly lower T ,T,and C Y a two-stage treatment system (Fig. 1) in which the culture kTCE/KS,TCE for 8-day SRT N-limited conditions. Methane addition to the transformation reactor inhibited TCE co- produced in a growth reactor is contacted with the TCE- metabolism at low TCE concentrations and enhanced contaminated water in a separate treatment reactor where TCE cometabolism at high TCE concentrations, indicat- TCE degradation occurs (Alvarez-Cohen and McCarty, ing that the TCE cometabolism in the presence of meth- 1991c; Dobbins et al., 1995; Folsom and Chapman, 1991; ane does not follow simple competitive inhibition kinet- McFarland et al., 1992; Tschantz et al., 1995). This reactor ics. © 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 55: 650– configuration has several advantages over a single reactor. 659, 1997. Keywords: cometabolism; methanotroph; trichloroethy- Since the growth reactor does not receive the contaminated lene; reactor; aerobic water stream, the growth conditions can be controlled to produce a culture with optimum TCE cometabolic activity and the effect of TCE transformation product toxicity (Al- Correspondence to: L. Smith varez-Cohen and McCarty, 1991a; Fox et al., 1990; Henry Contract grant sponsor: Gas Research Institute; Westinghouse Savannah and Grbic-Galic, 1991a; Oldenhuis et al., 1991) is isolated River Corporation from the growth environment. Competitive inhibition be- © 1997 John Wiley & Sons, Inc. CCC 0006-3592/97/040650-10 Figure 1. Proposed treatment system schematic (Alvarez-Cohen and McCarty, 1991c). tween methane and TCE (Henry and Grbic-Galic, 1991b; rate and extent are sought because it is generally believed Lanzarone and McCarty, 1990; Oldenhuis et al., 1989; Sem- that formate does not present complicating effects (Alvarez- prini et al., 1991) is avoided because the methane utilization Cohen et al., 1991b; Brusseau et al., 1990; Henry et al., and TCE cometabolism reactions are separated. Culture 1991a; Henrysson and McCarty, 1993; Koh et al., 1993; growth in a continuous stirred tank reactor (CSTR) and Oldenhuis et al., 1989; Tschantz et al., 1995; Tsien et al., contaminant degradation in a plug-flow reactor (PFR) pro- 1989) such as competitive inhibition that may occur when vide the ideal kinetic conditions for each of these processes. methane is used (Henry and Grbic-Galic, 1991b; Lanzarone In this study, factors of importance to the design of a and McCarty, 1990; Oldenhuis et al., 1989; Semprini et al., two-stage methanotrophic reactor system were evaluated 1991). While intracellular storage materials such as poly-b- through the use of a mixed culture expressing soluble MMO hydroxybutyrate (PHB) might be utilized by the microor- (Alvarez-Cohen et al., 1992). The variables in growth reac- ganisms to regenerate NADH (Gottschalk 1986), its rate of tor conditions studied included the effects of solids retention mobilization for this purpose is slow relative to TCE come- time (SRT) and nitrogen availability. Transformation reac- tabolism rates in some cases (Henrysson and McCarty, tor variables included residence time and formate and meth- 1993). ane as potential amendments. TCE transformation product toxicity has been observed Important biochemical processes that may limit the rate in studies of purified MMO (Fox et al., 1990), in pure and extent of TCE cometabolism include TCE transforma- cultures (Henry and Grbic-Galic, 1991a; Oldenhuis et al., tion product toxicity and the availability of reducing power 1991), and in mixed cultures (Alvarez-Cohen and McCarty, for regeneration of the electron carrier NADH for MMO 1991b; Henry and Grbic-Galic, 1991a; Stensel et al., 1992). activity (Fig. 2). Supplemental formate is commonly used to It is caused by nonspecific covalent bonding of daughter support regeneration of NADH in studies of cometabolic products of TCE epoxide to MMO, and possibly other bio- reactions of methanotrophic cultures when the maximum molecules in the cell, causing cell inactivation (Fox et al., 1990). The extent of enzyme or cell inactivation is propor- tional to the extent of TCE transformation (Alvarez-Cohen and McCarty, 1991a; Oldenhuis et al., 1991). Product tox- icity significantly reduces TCE transformation rates, espe- cially at high TCE/biomass ratios. Methane can function both as an electron donor for NADH regeneration (Fig. 2) and as a competitive inhibitor of TCE cometabolism. However, the reports on the effect of methane on TCE cometabolism have been varied. In many Figure 2. Biochemical pathway for methane oxidation by methanotro- cases, methane acted as a competitive inhibitor (Broholm et phic bacteria (Anthony, 1986). al., 1992; Fennel et al., 1993; Henry and Grbic-Galic, SMITH AND MCCARTY: AEROBIC TREATMENT OF TCE USING METHANOTROPHS 651 1991b; Lanzarone and McCarty, 1990; Leahy et al., 1989; eral salts medium, TCE-saturated water, and the bacterial Oldenhuis et al., 1989, 1991; Phelps et al., 1990; Semprini culture were added to each bottle to give a final liquid et al., 1991), but it has also been found to be stimulatory at volume of 100 mL at initial biomass and aqueous TCE low concentrations and inhibitory at high concentrations concentrations of 150–400 mg VSS/L and 0.9–17 mg/L, (Brusseau et al., 1990; Chang and Alvarez-Cohen, 1995b) respectively. The initial headspace TCE concentration was and to have no effect on TCE cometabolism (Strand et al., measured at least twice prior to addition of the organisms. 1990; Strandberg et al., 1989). Headspace was periodically analyzed for TCE, methane, and oxygen. At least one control bottle without organisms was carried through each experiment and always had insig- MATERIALS AND METHODS nificant TCE losses over 1 week in comparison to sample variability. TCE cometabolism rate coefficients were deter- Experimental Procedures mined by weighted nonlinear least squares analysis of the integrated Monod equation (Smith et al., manuscript in Reagents preparation). Reagents used were TCE (99+% pure ACS reagent, Aldrich Chemicals, Milwaukee, WI), methane (99.0% pure com- Bioreactor Studies of TCE Cometabolism Rate pressed gas, Liquid Carbonic, Chicago, IL), propylene Some TCE cometabolism rate experiments were conducted (99.0% pure compressed gas, Scott Specialty Gases, Fre- in 2-L computer-controlled bioreactors operated under mont, CA), and sodium formate (99.35% pure ACS reagent, batch conditions to simulate the plug-flow kinetics of the Fisher Scientific; Fair Lawn, NJ). transformation reactor (Fig. 1) as described previously (Smith et al., 1997). Samples of mixed culture from the Growth Reactors 7.3-L growth reactor were diluted to 100–200 mg VSS/L in mineral salts medium (Fogel et al., 1986) supplemented Methane-oxidizing mixed cultures were grown in three with 6.5–8.6 mg/L dissolved TCE and in some cases 20 mM semicontinuous stirred tank reactors. One had a 7.3-L liquid sodium formate or 5.6 mg/L dissolved methane.
Load more

Recommended publications
  • Aerobic Cometabolism of Chlorinated Aliphatic Hydrocarbons by Subsurface Microbes Grown on Methane, Propane and Butane from the Mcclellan Air Force Base
    AN ABSTRACT OF THE THESIS OF Adisorn Tovanabootr for the degree of Masters of Science in Civil Engineering presented on April 23, 1997. Title: Aerobic Cometabolism of Chlorinated Aliphatic Hydrocarbons by Subsurface Microbes Grown on Methane, Propane and Butane from the McClellan Air Force Base. Abstract approved: Lewis Semprini Subsurface microorganisms from the McClellan Air Force Base were grown in batch aquifer microcosms on methane, propane, and butane as gaseous cometabolic substrates. The potential for aerobic cometabolism of chlorinated aliphatic hydrocarbons including trichloroethylene (TCE), 1,1,1-trichloroethane (1,1,1-TCA), and chloroform (CF) was determined. Stimulation of microorganisms on all of the substrates tested indicates a diverse microbial community exists in the McClellan subsurface. Indigenous methane and propane-utilizers were capable of transforming TCE and CF. Propane- utilizers very effectively transformed TCA, while methane-utilizers could not transform 1,1,1-TCA. The butane-utilizers were not able to degrade any of the CAHs tested. TCE was transformed most rapidly during the period of active methane consumption, and continued at a slower rate for about 1 weeks after methane was consumed. The propane culture remained active for up to four weeks after propane was consumed, and the rate followed first order kinetics. Different TCE transformation yields (Tv) (mg CAH/mg substrate) developed in replicate microcosms with time. Changes in TCE transformation ability resulted from changes in TCE concentration or TCE product toxicity. Both methane and propane-utilizers showed a positive correlation between initial TCE transformation rates and primary substrate utilization rates. The ratio of the zero order TCE transformation rate to primary substrate utilization rate was directly proportional to the ultimate transformation yield.
    [Show full text]
  • Technical Protocol for Evaluating Natural Attenuation of Chlorinated
    United States Office of Research and EPA/600/R-98/128 Environmental Protection Development September 1998 Agency Washington DC 20460 Technical Protocol for Evaluating Natural Attenuation of Chlorinated Solvents in Ground Water TECHNICAL PROTOCOL FOR EVALUATING NATURAL ATTENUATION OF CHLORINATED SOLVENTS IN GROUND WATER by Todd H. Wiedemeier Parsons Engineering Science, Inc. Pasadena, California Matthew A. Swanson, David E. Moutoux, and E. Kinzie Gordon Parsons Engineering Science, Inc. Denver, Colorado John T. Wilson, Barbara H. Wilson, and Donald H. Kampbell United States Environmental Protection Agency National Risk Management Research Laboratory Subsurface Protection and Remediation Division Ada, Oklahoma Patrick E. Haas, Ross N. Miller and Jerry E. Hansen Air Force Center for Environmental Excellence Technology Transfer Division Brooks Air Force Base, Texas Francis H. Chapelle United States Geological Survey Columbia, South Carolina IAG #RW57936164 Project Officer John T. Wilson National Risk Management Research Laboratory Subsurface Protection and Remediation Division Ada, Oklahoma NATIONAL RISK MANAGEMENT RESEARCH LABORATORY OFFICE OF RESEARCH AND DEVELOPMENT U. S. ENVIRONMENTAL PROTECTION AGENCY CINCINNATI, OHIO 45268 i NOTICE The information in this document was developed through a collaboration between the U.S. EPA (Subsurface Protection and Remediation Division, National Risk Management Research Laboratory, Robert S. Kerr Environmental Research Center, Ada, Oklahoma [SPRD]) and the U.S. Air Force (U.S. Air Force Center for Environmental Excellence, Brooks Air Force Base, Texas [AFCEE]). EPA staff were primarily responsible for development of the conceptual framework for the approach presented in this document; staff of the U.S. Air Force and their contractors also provided substantive input. The U.S. Air Force was primarily responsible for field testing the approach presented in this document.
    [Show full text]
  • Cometabolic Degradation of Polycyclic Aromatic Hydrocarbons (Pahs) and Aromatic Ethers by Phenol- and Ammonia-Oxidizing Bacteria
    AN ABSTRACT OF THE DISSERTATION OF Soon Woong Chang for the degree of Doctor of Philosophy in Civil Engineering presented on November 11, 1997. Title: Cometabolic Degradation of Polycyclic Aromatic Hydrocarbons (PAHs) and Aromatic Ethers by Phenol- and Ammonia-Oxidizing Bacteria Redacted for Privacy Abstract approved: /Kenneth J. Williamson Cometabolic biodegradation processes are potentially useful for the bioremediation of hazardous waste sites. In this study the potential application of phenol- oxidizing and nitrifying bacteria as "priming biocatalysts" was examined in the degradation of polycyclic aromatic hydrocarbons (PAHs), aryl ethers, and aromatic ethers. We observed that a phenol-oxidizing Pseudomonas strain cometabolically degrades a range of 2- and 3-ringed PAHs. A sequencing batch reactor (SBR) was used to overcome the competitive effects between two substrates and the SBR was evaluated as a alternative technology to treat mixed contaminants including phenol and PAHs. We also have demonstrated that the nitrifying bacterium Nitrosomonas europaea can cometabolically degrade a wide range polycyclic aromatic hydrocarbons (PAHs), aryl ethers and aromatic ethers including naphthalene, acenaphthene, diphenyl ether, dibenzofuran, dibenzo-p-dioxin, and anisole. Our results indicated that all the compounds are transformed by N. europaea and that several unusual reactions are involved in these reactions. In the case of naphthalene oxidation, N. europaea generated predominantly 2­ naphthol whereas other monooxygenases generate 1-naphthol as the major product. In the case of dibenzofuran oxidation, 3-hydroxydibenzofuran initially accumulated in the reaction medium and was then further transformed to 3-hydroxy nitrodibenzofuran in a pH- and nitrite-dependent abiotic reaction. A similar abiotic transformation reaction also was observed with other hydroxylated aryl ethers and PAHs.
    [Show full text]
  • A Model of in Situ Bioremediation That Includes the Effect of Rate- Limited Sorption and Bioavailability J
    A MODEL OF IN SITU BIOREMEDIATION THAT INCLUDES THE EFFECT OF RATE- LIMITED SORPTION AND BIOAVAILABILITY J. Huang and M.N. Goltz Department of Engineering and Environmental Management, Air Force Institute of Technol- ogy, Wright-Patterson Air Force Base, OH 45433-7765; Phone: (937) 255-2998, Fax: (937) 656-4699 ABSTRACT In situ bioremediation is a groundwater and soil remediation technology that makes use of indigenous or introduced microorganisms to degrade contaminants in the subsurface. One factor affecting the feasibility of in situ bioremediation is the availability of the contaminant to the microorganisms. It is typically assumed that the contaminant is only available for biodegradation in the aqueous phase. However, many organic contami- nants of interest are sorbed to soil in the subsurface, and the sorbed contaminant is presumably unavailable for bioremediation. If bioremediation is attempted, the rate of desorption of contaminant from the sorbed phase is a factor in determining the availability of the contaminant to the degrading microorganisms and hence, the efficacy of the remediation. In this work, a transport model is presented that accounts for both biodegradation and desorption kinetics. The model is run using realistic parameter values obtained from a recent field evaluation of in situ aerobic cometabolic bioremediation at Edwards AFB, to demonstrate the potential impact of rate-limited sorption on bioremediation efficacy. The model allows remediation managers to better understand the impact of the in situ bioremediation technology on the fate and transport of contaminants, ultimately helping these managers design and implement solutions to contamination problems. Key words: modeling, bioavailability, sorption, cometabolism, bioremediation BACKGROUND In situ bioremediation is a technology that is currently being studied (and increasingly imple- mented) in the hope that it may be useful in remediating the nations hazardous waste sites.
    [Show full text]
  • Pseudomonas Aeruginosa Strain MA01 Aerobically Metabolizes The
    Pseudomonas aeruginosa st rain MA01 aerobically metabolizes the aminodinitrotoluenes produced by 2,4,6=trinitrotoluenenitro group reduct ion Marc A. Alvarez, Christopher L. Kitts, James L. Botsford, and Pat J. Unkefer Abstract:Many microbes reduce the nitro substituents of 2,4,6-trinitrotoluene(TNT), producing aminodinitrotoluenes(ADNTs). These compounds are recalcitrant to further breakdown and are acutely toxic. In a search for organisms capable of metabolizing ADNTs, a bacterial strain was isolated for the ability to use 2-aminobenzoate (anthranilate) as sole C-source. This isolate, Pseudomonas aeruginosa MAO1, metabolized TNT by first reducing one nitro group to form either 2-amino-4,6-dinitrotoluene (2ADNT) or 4 -amino-2,6-dinitrotoluene(4ADNT). However, strain MA01 was distinct from other TNT-reducing organisms in that it transformed these compounds into highly polar metabolites through an 02-dependent process. Strain MAOl was able to cometabolize TNT, 2ADNT, and 4ADNT in the presence of a variety of carbon and energy sources. During aerobic cometabolism with succinate, 45% of uniformly ring-labeled [14C]TNT was transformed to highly polar compounds. Aerobic cometabolism of purified [14C]2ADN~and [14C]4ADNT with succinate as C-source produced similar amounts of these polar metabolites. During 02-limited cometabolism with succinate as C-source and nitrate as electron acceptor, less than 8% of the [14C]TNT was transformed to polar metabolites. Purified 2,6-diamino-4 -nitrotoluene was not metabolized, and while 2,4-diamino-6-nitrotoluenewas acetylated, the product (N-acetyl-2,4-diamino-6-nitrotoluene)was not further metabolized. Therefore, strain MAOl metabolized TNT by oxidation of the ADNTs and not by reduction the remaining nitro groups on the ADNTs.
    [Show full text]
  • Guidelines: Natural Attenuation of Chlorinated Solvents in Ground Water
    GUIDELINES NATURAL ATTENUATION OF CHLORINATED SOLVENTS IN GROUND WATER MINNESOTA POLLUTION CONTROL AGENCY SITE REMEDIATION SECTION © Minnesota Pollution Control Agency 2006 © Minnesota Pollution Control Agency 2006 TABLE OF CONTENTS EXECUTIVE SUMMARY ................................................................................................................................... III 1.0 SCREENING FOR NATURAL ATTENUATION.......................................................................................5 Screening for chlorinated ethylenes ...................................................................................................................7 Screening for contaminants other than chlorinated ethylenes.........................................................................8 2.0 DETAILED SITE CHARACTERIZATION: REFINEMENT OF THE SITE CONCEPTUAL MODEL...................................................................................................................................................................10 3.0 RATE ANALYSIS: ESTIMATES OF SITE-SPECIFIC ATTENUATION KINETICS ........................11 3.1 Falling contaminant concentrations: source decay terms......................................................................11 3.2 Groundwater attenuation rates and biodegradation rate (lambda) calculations................................12 3.3 Calculation of a natural attenuation capacity term ...............................................................................13 4.0 ABIOTIC DEGRADATION.........................................................................................................................14
    [Show full text]
  • Degradation of Polycyclic Aromatic Hydrocarbon by Pure Strain Isolated from Municipal Sludge: Synergistic and Cometabolism Phenomena
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by UTHM Institutional Repository International Conference on Environment 2010 (ICENV 2010) DEGRADATION OF POLYCYCLIC AROMATIC HYDROCARBON BY PURE STRAIN ISOLATED FROM MUNICIPAL SLUDGE: SYNERGISTIC AND COMETABOLISM PHENOMENA N. OTHMAN1,3, N. HUSSAIN2, S. ABDUL-TALIB3 1Engineering Faculty of Civil and Environmental Engineering, Universiti Tun Hussein Onn Malaysia, 86400 B.Pahat, Johor. Malaysia 2Faculty of Applied Science, Universiti Teknologi MARA, 40450 Shah Alam, Selangor. Malaysia 3Faculty of Civil Engineering, Universiti Teknologi MARA, 40450 Shah Alam, Selangor. Malaysia E-mail: [email protected] ABSTRACT Polycyclic aromatic hydrocarbons are classed as potentially hazardous chemicals of environmental and health concern. Some PAHs exhibit carcinogenic and mutagenic properties and are listed by the USEPA as priority pollutants. The principle process for the successful removal and elimination of PAHs from contaminated environment is microbial degradation. Many studies from temperate countries had reported on biodegradation of PAHs using microbial from petroleum contaminated area but limited information could be found from other medium. Thus, the previous studies have not investigated in detail the interaction among PAHs during biodegradation. This study was carried out to isolate PAHs degrading bacteria from municipal sludge and to determine the effect of enrichment substrate and PAH degradative bacteria activities during degradation of PAHs. Several microorganisms were isolated from municipal sludge for their ability to mineralize PAHs as sole carbon and energy source. Enrichment method process utilised single PAHs as a sole source of carbon. The pure culture was identified using the Biolog system. Biodegradation experiment was performed using 250 ml reactor flasks containing 50ml minimal media, 10% of bacterial inoculum and the specific PAHs.
    [Show full text]
  • Final Report Use of Cometabolic Air Sparging to Remediate
    Final Report Use of Cometabolic Air Sparging to Remediate Chloroethene-Contaminated Groundwater Aquifers by Battelle 505 King Avenue Columbus, OH 43201 July 31, 2001 CONTENTS FIGURES....................................................................................................................................... iv TABLES ......................................................................................................................................... v ABBREVIATIONS AND ACRONYMS...................................................................................... vi ACKNOWLEDGEMENTS.........................................................................................................viii 1. Introduction................................................................................................................................ 1 1.1 Background Information.................................................................................................... 1 1.2 Official DoD Requirements Statements............................................................................. 2 1.3 Objectives of the Demonstration ....................................................................................... 3 1.4 Regulatory Drivers............................................................................................................. 3 1.5 Previous Testing of the Technology .................................................................................. 4 2. Technology Description............................................................................................................
    [Show full text]
  • Aerobic Cometabolism of Chlorinated Aliphatic Hydrocarbons by a Butane
    AN ABSTRACT OF THE THESIS OF Young Kim for the degree of Master of Science in Civil Engineering presented on September 4, 1996. Title: Aerobic Cometabolism of Chloroform by Butane and Propane Grown Microorganisms from the Hanford Subsurface Redacted for Privacy Abstract approved: Lew Semprini Batch microcosm studies were carried out to screen for microorganisms from the subsurface of Hanford DOE site that could cometabolically transform chloroform (CF) under aerobic conditions. The potential need for CF bioremediation at the Hanford site has resulted from the large release of carbon tetrachloride (CT) to the subsurface, of which a fraction anaerobically transformed to CF. Potential cometabolic substrates were screened for their ability to promote aerobic cometabolism of CF. The potential cometabolic substrates tested were isoprene, propene, octane, ammonia, methane, propane, and butane. Microcosms were constructed with 125 ml batch serum bottles filled with 25 g of aquifer solids, 50 ml of synthetic groundwater, and 60 ml of headspace air. Consumption of methane, butane, propane, and propene was slow, while the consumption of ammonia was very slow. Microorganisms stimulated on propene and octane showed no ability to transform CF. Limited CF was transformed in microcosms stimulated on ammonia and methane. Over 90 °,/0 transformation of CF was observed in microcosms stimulated on either butane or propane during the initial incubation. Successive addition studies with methane, propane, and butane microcosms were conducted, because these substrates showed the most potential for driving CF cometabolism. The studies indicated that the most effective CF transformation was achieved by butane-utilizers. CF transformation was correlated with the consumption of the primary substrate.
    [Show full text]
  • Bench-Scale Study for the Bioremediation of Chlorinated Ethylenes at Point Mugu Naval Air Weapons Station, Point Mugu California, IRP Site 24
    AN ABSTRACT OF THE THESIS OF Matthew Thomas Keeling for the degree of Master of Science in Civil Engineering presented on November 23, 1998. Title: Bench-Scale Study for the Bioremediation of Chlorinated Ethylenes at Point Mugu Naval Air Weapons Station, Point Mugu California, IRP Site 24. Abstract approved. s Semprini Laboratory scale microcosm studies were conducted using site specific groundwater and aquifer solids to assess the feasibility of stimulating indigenous microorganisms in-situ to biologically transform Trichloroethylene (TCE) and its lesser chlorinated daughter products dichloroethylene (DCE) and vinyl chloride (VC). Three different treatments were conducted to determine the best approach for biologically remediating TCE under site specific conditions: anaerobic reductive dechlorination, aerobic cometabolism and sequential anaerobic/aerobic stimulation. Studies were conducted in batch serum bottles containing aquifer solids, groundwater and a gas headspace. Long-term (302 days) TCE anaerobic reductive dechlorination studies compared lactate, benzoate and methanol as potential anaerobic substrates. Site characteristic sulfate concentrations in the microcosms averaged 1,297 mg/L and TCE was added to levels of 2.3 mg/L. Substrates were added at one and a half times the stoichiometric electron equivalent of sulfate. Nutrient addition and bioaugmentation were also studied. Both benzoate and lactate stimulated systems achieved complete sulfate-reduction and prolonged dechlorination of TCE to VC and ethylene. Dechlorination was initiated between 15 to 20 days following lactate utilization and sulfate-reduction in the presence of approximately 300 mg/L sulfate. Benzoate amended microcosms did not initiate dechlorination until 120 to 160 days following the complete removal of available sulfate. After 302 days of incubation lactate and benzoate amended microcosms completely transformed TCE to VC with 7 to 15% converted to ethylene.
    [Show full text]
  • School of Chemical, Biological and Environmental Engineering O R E G O N S T a T E U N I V E R S I T Y
    SEMPRINI, Lewis 1 Distinguished Professor of Environmental Engineering School of Chemical, Biological and Environmental Engineering O R E G O N S T A T E U N I V E R S I T Y SEMPRINI, Lewis Distinguished Professor of Environmental Engineering DEGREES B.S. Chemical Engineering, University of California, Berkeley, 1974 M.S. Environmental Engineering, Stanford University, 1979 Engineers Degree Civil Engineering, Stanford University, 1981 Ph.D. Civil Engineering, Stanford University, 1986 ACADEMIC POSITIONS Research Assistant, Civil Engineering Department, Stanford University, and September 1977- September 1985 Teaching Assistant, Civil Engineering Department, Stanford University, September 1980-June 1981 Research Associate, Department of Civil Engineering, Stanford University, January 1986-December 1990 Lecturer, Department of Civil Engineering, Stanford University, September 1990-December 1990 Senior Research Associate, Department of Civil Engineering, Stanford University, January 1991- March 1993 Assistant Director, Western Region Hazardous Substance Research Center, Department of Civil Engineering, Stanford University, January 1990-March 1993 Associate Professor (Tenured 1996), Department of Civil, Construction, and Environmental Engineering, Oregon State University, March 1993-September 2000 Professor, Department of Civil, Construction, and Environmental Engineering, Oregon State University, September 2000-2006 Director of the Western Region Hazardous Substance Research Center, September 2001-2006 Professor, School of Chemical, Biological
    [Show full text]
  • Tech Bulletin Is to Describe Analyses That Can Be Used to Assess MNA at Chlorinated Ethene Sites by Answering the Following Questions
    MNA of Chlorinated Solvents: Aerobic Cometabolism & Abiotic Degradation Table of Contents 1.0 Overview and Purpose .......................................................................................................................... 2 2.0 Degradation Mechanisms during MNA ................................................................................................ 2 2.1 Aerobic Cometabolism ................................................................................................................ 2 2.2 Abiotic Degradation ..................................................................................................................... 3 3.0 Analyses for Evaluating Degradation during MNA .............................................................................. 4 3.1 QuantArray®-Chlor or CENSUS® qPCR ..................................................................................... 4 3.2 Magnetic Susceptibility ............................................................................................................... 5 3.3 X-ray Diffraction (XRD) ................................................................................................................ 6 3.4 Compound Specific Isotope Analysis (CSIA) .............................................................................. 6 4.0 14C TCE Degradation Rate Studies ......................................................................................................... 7 5.0 Sample Collection Procedures .............................................................................................................
    [Show full text]