Environmental Science Technology

Halden, R.U., Happel, A.M., and Schoen, S.R., Evaluation of standard methods for the analysis of methyl ferf-butyl ether and related oxygenates in gasoline-contaminated groundwater, Environmental Science Technology, 35 (7), 1469-1474, 2001. [Pg.1051]

Allen D.J. and Brent G.F. Sequestering C02 by mineral carbonation stability against acid rain exposure. 2010 Environmental Science Technology 44(7) 2735-2739. [Pg.167]

NordbottenJ.M., Celia M.A., et al. Semianalytical solution for C02 leakage through an abandoned well. 2005 Environmental Science Technology 39(2) 602-611. [Pg.172]

Davis A, Ruby MV, Bergstrom PD. 1992. Bioavailability of arsenic and lead in soils from the Butte, Montana, mining district. Environmental Science Technology 26 461-468. [Pg.507]

MacPherson, T. Greer, C.W. Zhou, E., et al., Application of SPME/GC-MS to Characterize Metabolites in the Biodesulfurization of Organosulfur Model Compounds in Bitumen. Environmental Science Technology, 1998. 32(3) pp. 421—426. [Pg.213]

Ayala, M. Robledo, N. R. Lopez-Munguia, A., and Vazquez-Duhalt, R., Substrate specificity and ionization potential in chloroperoxidase-catalyzed oxidation of diesel fuel. Environmental Science Technology, 2000. 34(13) pp. 2804-2809. [Pg.224]

Moller, P., Paces, T., Dulski, P., Morteani, G. 2002. Anthropogenic Gd in Surface Water, Drainage System, and the Water Supply of the City of Prague, Czech Republic. Environmental Science Technology, 36, 2387-2394. [Pg.222]

St. Louis, V.L., Rudd, J.W.M., Kelly, C.A., Hall, B.D., Rolfhus, K.R., Scott, K.J., Lindberg, S.E. Dong, W. 2001. Importance of the forest canopy to fluxes of methyl mercury and total mercury to boreal ecosystems. Environmental Science Technology, 35.15, 3089-98. [Pg.247]

Kimball, B.A., Broshears, R.E., Bencala, K.E., McKnight, D.M. 1994. Coupling of hydrologic transport and chemical reaction in a stream affected by acid mine drainage. Environmental Science Technology, 28, 2065-2073. [Pg.252]

Runkel, R.L. Kimball, B.A. 2002. Evaluating remedial alternatives for an acid mine drainage system - application of a reactive transport model. Environmental Science Technology, 36, 1093-1101. [Pg.253]

Porvari, P., Verta, M., Munthe, J., Haapanen, M. 2003. Forestry practices increase mercury and methyl mercury output from boreal forest catchments. Environmental Science Technology, 37, 2389-2393. [Pg.270]

Baker, A. 2001. Fluorescence excitation-emission matrix characterization of some sewage- impacted rivers. Environmental Science Technology, 35, 948-953. [Pg.308]

Chin, Y.P., Aiken, G.R., Danielsen, K.M. 1997. Binding of pyrene to aquatic and commercial humic substances The role of molecular weight and aromaticity. Environmental Science Technology, 31, 1630-1635. [Pg.308]

Harris, A. Davidson, C. 2005. The role of resuspended soil in lead flows in the California south coast air basin. Environmental Science Technology, 39, 7410-7415. [Pg.473]

Temminghof, E., van der Zee, S., De Haan, F. (1997). Copper mobility in a copper-contaminated sandy soil as affected by pH and solid and dissolved organic matter. Environmental Science Technology, 31, 1109-1115. [Pg.436]

Kopczynski SL, Lonneman WA, Sutterfield FD, et al. 1972. Photochemistry of atmospheric samples in Los Angeles. Environmental Science Technology 6(4) 342-347. [Pg.239]

Hansel CM, Fendorf S, Sutton S, NewviUe M. 2001. Characterization of Fe plaque and associated metals on the roots of mine-waste impacted aquatic plants. Environmental Science Technology 35 3863-3868. [Pg.266]

Chen, R Pignatello, JJ. Role of quinone intermediates as electron shuttles in Fenton and photoassisted Fenton oxidations of aromatic compormds. Environmental Science Technology, 1997 31, 2399-2406. [Pg.71]

Regnier ZR, Scott BF. 1975. Evaporation rates of oil components. Environmental Science < Technology 9(5) 469-472. [Pg.190]

Browse through a research article in three different ACS journals Analytical Chemistry, Biochemistry, and Environmental Science Technology and perform the following tasks ... [Pg.35]

Browse through the Table of Contents of several Issues of Analytical Chemistry or Environmental Science Technology. In most issues, you will see that, in addition to research articles, the journal also contains news articles, editorials, features, and/or book reviews. Glance through the pages of two such items. For each item, jot down its title and the name of the journal section in which it appears identify the intended audience and purpose of the entry. [Pg.36]

Browse through three articles in one of the following journals The Journal of Organic Chemistry, Analytical Chemistry, Environmental Science Technology, or Chemical Research in Toxicology. Flow well do the articles adhere to the move structure illustrated in hgure 4.1 ... [Pg.121]

We begin with an excerpt from Environmental Science Technology (excerpt 4B). In a combined R D section, the authors tell us what happened when they coated different types of soil with randomly methylated P-cyclodextrins (RAMEB). Cyclodextrins are highly water-soluble, crystalline sugars their shape (referred to as toroidal) resembles a water pail without a bottom. The outer surfaces of the pail are hydrophilic (water-loving), which accounts for their solubility in water and their ability to attract water molecules. RAMEB alone adsorbs water molecules hence, the authors predicted that RAMEB-coated soils would adsorb more water than their noncoated counterparts. [Pg.125]

Environmental Science Technology recommends fewer than 20 references, while Analytical Chemistry specifies no more than 50. [Pg.546]

Format the following reference information for three different journals Environmental Science Technology, Chemical Research in Toxicology, and Analytical Chemistry. Follow the formatting examples in table 17.2. [Pg.561]

Darrach, M. R., A. Chutjian, and G. A. Plett. Trace explosives signatures from World War II unexploded undersea ordnance. Jet Propulsion Laboratory, Environmental Science Technology 32(9), 1354 (1998). [Pg.149]

Boxall A.B.A., D.W. Kolpin, B. Halhng-Sprensen, and J. ToUs (2003). Are veterinary medicines causing environmental risks Environmental Science Technology 37 286A-294A. [Pg.255]

McArdell C.S., E. Molnar, M.J. Suter, and W. Giger (2003). Occurrence and fate of macrolide antibiotics in wastewater treatment plants and in the Glatt Valley watershed, Switzerland. Environmental Science Technology 37 5479-5486. [Pg.275]

Friedlander, S.K, (1973). "Chemical Element Balances and Identification of Air Pollution Sources," Environmental Science Technology. 7, 235. [Pg.104]

T.J. (1980). "Identifying and Estimating the Relative Importance of Sources of Airborne Particles," Environmental Science Technology, lA, 62. [Pg.105]

Hammerle, R.H. and Pierson, W.R. (1975). "Sources and Elemental Composition of Aerosol in Pasadena, California, by Energy-Dispersive X-ray Fluorescence," Environmental Science Technology, % 1058. [Pg.105]

Moyers, J. L., Ranweiler, L. E., Hopf, S. B. and Korte, N. E. (1977). "Evaluation of Particulate Trace Species in Southwest Desert Atmosphere," Environmental Science Technology, 11, 789. [Pg.105]

In urban areas, the concentrations can of course be much greater. For example, in Paris in late September 1997, NOz concentrations exceeded 210 ppb (Environmental Science Technology, 1997). In metropolitan Toronto, Canada, peak 30-min average concentrations of 40 ppb have been reported (Schiff et al., 1986). In the Los Angeles area, maximum 1-h concentrations of about 200 ppb are encountered (Air Quality Management District summary data see Appendix IV). [Pg.575]

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