A novel in situ technology for the treatment of nitrate contaminated groundwater

A novel in situ membrane technology was developed to remove nitrate (NO3-) from groundwater. Membrane-fed hydrogen gas (H2) was used as an electron donor to stimulate denitrification. A flow-through reactor fit with six hollow-fiber membranes (surface area = 93 cm2) was designed to simulate groundwater flowing through an aquifer with a velocity of 0.3 m/day. This membrane technology supported excellent NO3- and nitrite (NO2-) removal once H2 and carbon limitations were corrected. The membrane module achieved a maximum H2 flux of 1.79 x 10(-2) mg H2/m2 s, which was sufficient to completely remove 16.4 mg/L NO3(-)-N from a synthetic groundwater with no NO2- accumulation. In addition, this model in situ treatment process produced a high quality water containing <0.5 mg/L total organic carbon.     

Comparison of pulsed and continuous addition of H2 gas via membranes for stimulating PCE biodegradation in soil columns

Column experiments were performed to investigate a technology for remediating aquifers contaminated with chlorinated solvents. The technology involves installation of hollow-fiber membranes in the subsurface to supply hydrogen gas (H2) to groundwater to support biological reductive dechlorination in situ. Three laboratory-scale columns [control (N2 only), continuous H2, and pulsed H2] were packed with aquifer material from a trichloroethene (TCE)-contaminated wetland in Minnesota and supplied with perchloroethene (PCE)-contaminated synthetic groundwater. The main goals of the research were: (1) evaluate the long-term performance of the H2 supply system and (2) compare the effects of pulsed (4 h on, 20 h off) versus continuous H2 supply (lumen partial pressure approximately 1.2 atm) on PCE dechlorination and production of by-products (i.e. methane and acetate). The silicone-coated fiberglass membranes employed in these experiments were robust, delivering H2 steadily over the entire 349-day experiment. Methane production decreased when H2 was added in a pulsed manner. Nevertheless, the percentage of added H2 used to support methanogenesis was similar in both H2-fed columns (92-93%). For much of the experiment, PCE dechlorination (observed end product = dichloroethene) in the continuous and pulsed H2 columns was comparable, and enhanced in comparison to the natural attenuation observed in the control column. Dechlorination began to decline in the pulsed H2 column after 210 days, however, while dechlorination in the continuous H2 column was sustained. Acetate was detected only in the continuous H2 column, at concentrations of up to 36 microM. The results of this research suggest that in situ stimulation of PCE dechlorination by direct H2 addition requires the continuous application of H2 at high partial pressures, favoring the production of bioavailable organic matter such as acetate to provide a carbon source, electron donor, or both for dechlorinators. Unfortunately, this strategy has proven to be inefficient, with the bulk of the added H2 used to support methanogenesis.     

Modeling Biofilms on Gas-Permeable Supports: Concentration and Activity Profiles

Several investigators have shown that membrane oxygenation provides a number of advantages in biological treatment. These include operational flexibility, reduced energy requirements, and less stripping of volatile compounds. Membranes have also been observed to provide a support surface for microbial growth. This steady-state model study investigates the microbial uptake of oxygen and a carbon-source substrate for aerobic, heterotrophic biofilms on gas permeable membrane- and impermeable solid-supported surfaces. The model predictions indicate that very different concentration and activity profiles may be found in biofilms grown on solid surfaces and gas permeable membranes. For a solid-supported biofilm the highest concentrations of oxygen and substrate and the greatest microbial activity are located on the outside of the biofilm. For a membrane-supported film, the oxygen and substrate are never present at the same location in their maximum concentrations, and the location of maximum biological activity in the biofilm can occur at other locations within the film. These differences may lead to significant differences in the microbial ecology and populations of biofilms and, in turn, in biofilm morphology.     

Model for In Situ Perchloroethene Dechlorination via Membrane-Delivered Hydrogen

A one-dimensional contaminant fate and transport model was developed to simulate reductive dechlorination of perchloroethene (PCE) in an anaerobic aquifer supplied with hydrogen via a gas-permeable membrane curtain. The model predicted that providing hydrogen at transfer rates equal to the reducing-equivalent demand associated with the groundwater PCE flux would mineralize 75% of the PCE-bound chlorine to chloride and, furthermore, that 0.55 moles of chloride would be released per mole of hydrogen transferred. Supplying higher hydrogen transfer rates was predicted to result in slightly lower dechlorination efficiencies and significantly lower dechlorination yields due to greater methanogenic growth and concomitant displacement of dehalorespirers away from the hydrogen-supply membranes. The model also predicted that high hydrogen-utilizing biomass concentrations would develop near the membranes, resulting in minimal hydrogen dispersal. Model predictions were qualitatively similar to results attained in experimental soil column studies; however, incorporation of homoacetogenesis and acetate utilization by dehalorespirers, as well as hydrogen production via fermentation of biomass decay products, would have improved agreement between model simulations and experimentally observed dechlorination performance.     

Characterization of the Microstructure of Ceramics Used in Multilayer Ceramic Capacitors by Means of the Scanning Laser Acoustic Microscope

Analytical data obtained by the scanning laser acoustic microscope (SLAM) on multilayer ceramic capacitors can be correlated to microstructural elastic properties of the dielectric and electrode materials, to the quality of bonding between the layers, and to construction variables, such as materials thicknesses, number of layers, etc. These data can be used to build up predictive models of high-quality and poor-quality components, which is very important for nondestructive screening of high-reliability parts. Although SLAM screening of multilayer capacitors (such as specified in MIL-C-123) is quite straight forward and in current use for quality control, dilemmas can occur in which batches of nominally identical parts demonstrate widely different ultrasonic transmission and widely different SLAM images. These differences correspond to elastic property differences which may affect reliability. In this paper the authors discuss materials characterization aspects of acoustic microscopy as it pertains to multilayer ceramic capacitors. [Key words: capacitors, multilayer, ultrasonics, electrical properties, lasers.]     

The effect of a flaxseed oil-enhanced diet on the product quality of farmed brook trout (Salvelinus fontinalis) fillets

Abstract: The effects of dietary modification with flaxseed oil‐enhanced (Flax) feed on the product quality of brook trout fillets were examined. Trout were fed a commercial feed supplemented with fish oil (CD) or flaxseed oil (Flax) for 165 d before harvesting. Proximate composition and fatty acid profile were determined on fillets. Quality parameters of the raw fillets were examined over the storage period by measuring color (L*, a*, b*), muscle pH, and thiobarbituric acid reactive substances test. Evaluations on the cooked fillets included sensory evaluation with triangle tests and a paired preference test. There were no differences in proximate composition between the groups; however, the total omega‐3 fatty acids were greater in Flax fillets (P < 0.05). Diet and day were shown to interact in their effect on whiteness, pH, and lipid oxidation (P < 0.05); however, linear regression did not determine that malondialdehyde concentration was associated with time in either diet type implying that lipid oxidation in the vacuum‐packed fish was controlled at storage temperatures (4°C). Sensory panelists were able to choose the odd sample in a replicated triangle test analyzed using the β‐binomial model, and there was preference for Flax fillets (P < 0.05). Results indicate that a Flax‐enhanced diet would have favorable effects on product quality of farmed brook trout.     

Stimulating hydrogenotrophic denitrification in simulated groundwater containing high dissolved oxygen and nitrate concentrations

In agricultural areas, nitrate (NO3-) is a common groundwater pollutant as a result of extensive fertilizer application. At elevated concentrations, NO3- consumption causes methemoglobinemia in infants and has been linked to several cancers; therefore, its removal from groundwater is important. The addition of hydrogen gas (H2) via gas-permeable membranes has been shown to stimulate denitrification in a laboratory-scale reactor. This research, using large columns packed with aquifer material to which a simulated groundwater was fed, was conducted to further identify the conditions required for the use of membrane-delivered H2 in situ. In this study, we show that this novel technology was capable of treating highly contaminated (25 mg/L NO3- -N) and oxygenated (5.5mg/L dissolved oxygen) water, but that nutrient addition and gas pressure adjustment was required. Complete NO3- reduction was possible without the accumulation of either NO2- or N2O when the H2 lumen pressure was increased to 17 psi and phosphate was added to the groundwater. The total organic carbon content of the effluent, 110 cm downgradient of H2 addition, did not increase. The results from these experiments demonstrate that this technology can be optimized to provide effective NO3- removal in even challenging field applications.     

Enhancement of Omega-3 Fatty Acid Content in Rainbow Trout (Oncorhynchus mykiss) Fillets

ABSTRACT:  A commercial diet for rainbow trout ( Oncorhynchus mykiss ) was supplemented with 0 (control), 8.5%, or 15.0% (w/w) of flaxseed oil (FO). Trouts were harvested on days 0, 30, 60, 90, and 120. Boneless skinless trout fillets were recovered from fish and analyzed for fatty acid profile (FAP) and total fat. While the total fat levels of fillets were not ( P > 0.05) affected by FO supplementation, the FAP was. The lowest ( P < 0.05) proportion of saturated fatty acids was obtained from 15%, followed by 8.5% FO group, and the control group. The opposite results were observed for the unsaturated fatty acids. The highest ( P < 0.05) content of omega-3 fatty acids (ω-3 FA) in fillets was determined in the 15.0%, followed by the 8.5% FO group, and the control group. While the 15.0% and 8.5% of FO supplementation increased ( P < 0.05) concentration of linolenic acid (ALA, 18:3n3) in fillets, the eicosapentaenoic (EPA, 20:5n3) and docosahexaenoic acids (DHA, 22:6n3) contents decreased ( P < 0.05). At the same time, higher ( P < 0.05) concentration of linoleic (L, 18:2n6) and lower ( P < 0.05) concentration of arachidonic acids (AN, 20:4n6) in fillets were obtained in the 15.0% FO group compared with the control group. The ω-3/ω-6 FA ratio was also improved ( P < 0.05) by supplementing basal diet with 15.0% FO. Our results suggest that trout fillets with enhanced content of ω-3 FA can be developed from trout raised in aquaculture systems fed diets supplemented with 15.0% FO. These fillets could be a basis to develop novel functional aquatic foods for some niche markets.