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Energy, Aerosols and Ion-Excited X-Ray Emission*
Published online by Cambridge University Press: 06 March 2019
Abstract
Rapid changes in methods of energy production and utilization are occurring in California, as elsewhere. The affects of such changes upon atmospheric aerosols have been monitored since January, 1973, as part of the continuing study of California aerosols undertaken by U.C. Davis for the California Air Resources Board. A primary goal of the program is to identify aerosol sources in detail, thus allowing energy related components to be isolated and evaluated at many locations throughout the state.
Use of ion-excited x-ray emission as the major (although not exclusive) method of elemental analysis is well suited to this program for a number of reasons. Among them include; 1. The sensitivity allows particle-sized aerosol samples to be easily collected, 2. The low cost (under $6, per sample) allows many samples to be run within a fixed budget, 3, The large number of elements seen in the average sample allows source identification by element to element to weather correlations. In addition, the samples are suitable for light element analysis by alpha scattering, for elements H through Cl, thus allowing an inventory to be made of all the aerosol mass in the atmosphere within the size range of the sampler.
- Type
- Research Article
- Information
- Copyright
- Copyright © International Centre for Diffraction Data 1974
Footnotes
*
Program supported by California Air Resources Board and NSF/RANN.
References
1.
Rhodes, J. R., Pradzynski, A. H., Hunter, C. B., Payne, J. S., and Lindgren, J. L., “Energy Dispersive X-Ray Fluorescence Analysis of Air Particulates in Texas,” Environmental Science and Technology, Vol. 6, No. 10, p. 922–927, Oct. (1972).Google Scholar
2.
Jaklevic, J. M., Goulding, E. S., Jarret, B. V. and Meng, J. D., “Application of X-Ray Fluorescence Techniques to Measure Elemental Composition of Particles in the Atmosphere,” Lawrence Berkeley Laboratory Publication LBL-1743, July, (1973).Google Scholar
3.
Harrison, J. F. and Eldred, R. A., “Automatic Data Acquisition and Reduction For Elemental Analysis of Aerosol Samples,” Advances in X-Ray Analysis, Vol. 17, p. 560–570, Plenum Press, (1973).Google Scholar
4.
Cahill, T. A. and Feeney, P. J., “Contribution of Freeway Traffic to Airborne Particulate Matter,” Report to the California Air Resources Board on Contract ARB“502, Crocker Nuclear Laboratory, University of California, Davis, (1973).Google Scholar
5.
Spruny, K. R. and Lodge, J. P. Jr., “Collection Efficiency Tables For Membrane Filters,” Hatlonal Center For Atmospheric Research Publication NCAR-TN/STR-77, Boulder Colorado, Aug. (1972).Google Scholar
6.
Whitby, K. T., Husar, R. B. and Liu, B. Y. H., Journal Colloid Interface Science, 39, p. 177, (1972).Google Scholar
7.
Rhodes, J. R. and Hunter, C. B., “Particle Size Effects in X-Ray Emission Analysis,” Journal of X-Ray Spectrometry, 1, p. 113–117, (1972).Google Scholar
8.
Novakov, T., Harker, A. B. and Siekhaus, W., “Sulfates in Pollution Particulates,” Lawerence Berkeley Laboratory, USAEC Contract W-7405-EMG-48, (1973).Google Scholar