Research Watch: VOC reactivity

ron. 1999, 33(13), 2101-2110). Assessment. Aquatic humic substances. Humic substances from open ... (Ho, Y. S.; McKay, G. "A Comparison of Chemisorpti...
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RESEARCH WATCH Air Airborne particles. The relationship was determined between particle mass (examined using a tapered element oscillating microbalance) and the number of ambient air particles in the submicrometer size range (examined using a scanning mobility particle sizer). (Morawska, L.; Johnson, G.; Ristovski, Z. D.; Agranovski, V. "Relation Between Particle Mass and Number for Submicrometer Airborne Particles," Atmos. Environ. 1999, 33(13), 1983-1990) Atmospheric aerosols. Hydroxymethanesulfonate (HMS), a product of the heterogeneous reaction between S(IV) and HCHO, was measured in aerosol samples, indicating it can exist outside of clouds. (Dixon, R. W.; Aasen, H. "Measurement of Hydroxymethanesulfonate in Atmospheric Aerosols," Atmos. Environ. 1999, 33(13), 2023-2029) VOC reactivity. VOC reactivity factors were determined from smog chamber experiments and compared with those derived from a reactivity factor model. (Kelly, N. A.; Chang, T. Y. "An Experimental Investigation of Incremental Reactivities of Volatile Organic Compounds," Atmos. Environ. 1999, 33(13), 2101-2110)

Source apportionment Degradation of chiral pesticides often takes place enantioselectively, yielding nonracemic residues. The distinct enantiomeric signatures of these residues can be used as markers to follow environmental transport and fate processes. T. F. Bidleman and R. L Falconer derived a relationship for estimating the contribution of chiral compounds from two different sources, A and B, in an A-B mixture. The apportionment equation that they developed requires only the enantiomer ratios of the two sources and the resultant mixture. The authors report that ER values can be determined with high precision and are not affected by analytical method recoveries or by abiotic processes that take place during transport. These advantages make ERs especially attractive for source apportionment. (Environ. Sci. Technol., this isiue, pp. 2299-2301)

criteria for assessing causality. (Joellenbeck, L. M.; Landrigan, E J.; Larson, E. L. "Gulf War Veterans' Illnesses: A Case Study in Causal Inference," Environ. Res. 1998, 79(2), 71-81)

Chemistry Chemisorption. Models describing the sorption of pollutants are compared, with results indicating that chemisorption processes could be rate limiting in the sorption step. (Ho, Y. S.; McKay, G. "A Comparison of Chemisorption Kinetic Models Applied to Pollutant Removal on Various Sorbents," Process Saf. Environ. Prot. 1998, 76(B4), 332-340)

Aquatic humic substances. Humic substances from open ocean, coastal, estuarine, and fluvial environments were characterized and compared on the basis of their thermogravimetric properties. (Esteves, V I.; Duarte, A. C. "Thermogravimetric Properties of Aquatic Humic Substances," Mar. Chem. 1999, 63(3-4), 225-233)

PCDD/DF chemistry. Mechanisms for formation and destruction of polychlorinated dioxins and furans (PCDDs, PCDFs) were determined by analyzing the behavior of fly ash in various incinerator environments. (Weber, R.; Sakurai, T; Hagenmaier, H. "Formation and Destruction of PCDD/PCDF During Heat Treatment of Fly Ash Samples From Fluidized Bed Incinerators," Chemosphere 1999, 38(11), 2633-2642)

Gulf War illnesses. In determining from published epidemiological literature whether evidence for a causal association exists between Gulf War service and illness in U.S. veterans, 11 published studies were analyzed using standardized epidemiological

PCDD/PCDF formation. Characteristic PCDF isomer distribution patterns found in samples from fluidized-bed incinerators were explained by a difference in the mechanism of formation due to a difference in fly ash composition. (Weber, R.; Hagen-

Assessment

maier, H. "PCDD/PCDF Formation in Fluidized Bed Incineration," Chemosphere 1999, 38(11), 2643-2654) Silver-sulfur compounds. X-ray and nuclear magnetic resonance data revealing the chains and networks formed by silver and sulfur atoms in inorganic and organic complexes are reviewed. (Bell, R. A.; Kramer, J. R. "Structural Chemistry and Geochemistry of Silver-Sulfur Compounds: A Critical Review," Environ. Toxicol. Chem. 1999, 28(1), 9-22)

Climate Archival CO2. Antarctic ice core records show that carbon dioxide concentrations increased by 80-100 ppmv 600 ± 400 yr after the warming of the last three deglaciations. (Fischer, H.; Wahlen, M.; Smith, J.; Mastroianni, D.; Deck, B. "Ice Core Records of Atmospheric CO, Around the Last Three Glacial Terminations," Science 1999, 283(5408), 1712-1714) Carbon cycle. The ice-core record of atmospheric COz concentrations over the Holocene epoch shows that the global carbon cycle has not been in steady state during the past 11,000 years. (Indermuhle, A., et al. "Holocene Carbon-Cycle Dynamics Based on C 0 2 Trapped in Ice at Taylor Dome, Antarctica," Nature 1999, 398(6723), 121-126)

JULY 1, 1999 / ENVIRONMENTAL SCIENCE & TECHNOLOGY / NEWS • 2 8 3 A