Atmospheric Chemistry and Physics Discussions
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9
3
2009
10.5194/acpd-9-14235-2009
http://www.atmos-chem-phys-discuss.net/9/14235/2009/
http://www.atmos-chem-phys-discuss.net/9/14235/2009/acpd-9-14235-2009.html
http://www.atmos-chem-phys-discuss.net/9/14235/2009/acpd-9-14235-2009.pdf
14235
14261
2009-06-30
Now you see it, now you don't: impact of temporary closures of a coal-fired power plant on air quality in the Columbia River Gorge National Scenic Area
D. A. Jaffe
djaffe@u.washington.edu
D. R. Reidmiller
Department of Science and Technology, University of Washington-Bothell, USA
Department of Atmospheric Sciences, University of Washington-Seattle, USA
We have analyzed 14 years of aerosol data spanning 1993–2006 from the
IMPROVE site at Wishram, Washington (45.66° N, 121.00° W; 178 m above
sea level) in the Columbia River Gorge (CRG) National Scenic Area
(<a href="http://www.fs.fed.us/r6/columbia/" target="_blank">http://www.fs.fed.us/r6/columbia/</a>) of the Pacific Northwest of the US. Two
types of analyses were conducted. First, we examined the transport for days
with the highest fine mass concentrations (particulate matter with diameter
<2.5μm or, PM<sub>2.5</sub>) using HYSPLIT back-trajectories. We found
that the highest PM<sub>2.5</sub> concentrations occurred during autumn and were
associated with easterly flow, down the CRG. Such flow transports emissions
from a large coal power plant and a large agricultural facility into the
CRG. This transport was found on 20 out of the 50 worst PM<sub>2.5</sub> days and
resulted in an average daily concentration of 20.1 μg/m<sup>3</sup>, compared
with an average of 18.8 μg/m<sup>3</sup> for the 50 highest days and 5.9 μg/m<sup>3</sup>
for all days. These airmasses contain not only high PM<sub>2.5</sub>
concentrations but also elevated aerosol NO<sub>3</sub><sup>−</sup> concentrations.
These results suggest that emissions from large industrial and agricultural
sources on the east end of the CRG, including the coal-fired power plant at
Boardman, Oregon, have a significant impact on air quality in the region.
<br><br>
In the second analysis, we examined PM<sub>2.5</sub> concentrations in the CRG
during periods when the Boardman power plant was shut down due to repairs
and compared these values with concentrations when the facility was
operating at near full capacity. We also examined this relationship on the
days when trajectories suggested the greatest influence from the power plant
on air quality in the CRG. From this analysis, we found significantly higher
PM concentrations when the power plant was operating at or near full
capacity. We use these data to calculate that the contribution to PM<sub>2.5</sub>
mass in the CRG from the Boardman plant was 0.90 μg/m<sup>3</sup> averaged
over the entire year, 3.94 μg/m<sup>3</sup> if only the month of November is
considered and 7.40 ug/m<sup>3</sup> if only November days when the airflow is
"down-gorge" (from east to west). This represents 15–56% of PM<sub>2.5</sub>
mass in the CRG. In all 3 cases the difference in PM<sub>2.5</sub>
concentrations
are statistically significant at a >95% confidence interval for the
comparison of normal plant emissions vs shutdown conditions. We, therefore,
find that the coal-fired power plant at Boardman, Oregon is a significant
contributor to PM<sub>2.5</sub> concentrations in the CRG.
Draxler, R. and Rolph, G. D.: HYSPLIT (HYbrid Single-Particle Lagrangian Integrated Trajectory) Model access via NOAA ARL READY web site, NOAA Air Resources Laboratory, Silver Spring, MD, available at: http://www.arl.noaa.gov/ready/hysplit4.html (last access: May 2009), 2002.
Eatough, D. J., Richter, B. E., Eatough, N. L., and Hansen, L. D.: Sulfur chemistry in smelter and power-plant plumes in the western United States, Atmos. Environ., 15(10–1), 2241–2253, 1981.
Eldred, R. A., Ashbaugh, L. L., Cahill, T. A., Flocchini, R. G., and Pitchford, M. L.: Sulfate levels in the southwest during the 1980 copper smelter strike, J. Air Pollut. Cont. Assoc., 33(2), 110–113, 1983.
Fenn, M. E., Geiser, L., Bachman, R., Blubaugh, T. J., and Bytnerowicz, A.: Atmospheric deposition inputs and effects on lichen chemistry and indicator species in the Columbia River Gorge, USA, Environ. Pollut., 146(1), 77–91, 2007.
Green, M., Xu, J., Adhikari, N., and Nikolich, G.: Causes of Haze in the Gorge (CoHaGo), Final Report, Southwest Clean Air Agency, available at: http://www.swcleanair.org/gorgereports.html, last access: July 2006.
Hewitt, C. N.: The atmospheric chemistry of sulphur and nitrogen in power station plumes, Atmos. Environ., 35(7), 1155–1170, 2001.
Malm, W. C., Schichtel, B. A., Ames, R. B., and Gebhart, K. A.: A 10-year spatial and temporal trend of sulfate across the United States, J. Geophys. Res., 107(D22), 4627, doi:10.1029/2002JD002107, 2002.
Malm, W. C., Sisler, J. F., Huffman, D., Eldred, R. A., and Cahill, T. A.: Spatial and seasonal trends in particle concentration and optical extinction in the United States, J. Geophys. Res., 99(D1), 1347–1370, 1994.
Pitchford, M. L., Green, M. C., Morris, R., Emery, C., Sakata, R., Swab, C., and Mairose, P. T.: Columbia River Gorge Air Quality Study, Final Science Summary Report, available at: http://www.swcleanair.org/gorgereports.html (last access: February 2008), 2008.
Romo-Kröger, C. M., Kiley, J. R., Dinator, M. I., and Llona, F.: Heavy metals in the atmosphere coming from a copper smelter in Chile, Atmos. Environ., 28, 705–711, 1994.
Seinfeld, J. H. and Pandis, S. N.: Atmospheric Chemistry and Physics: From Air Pollution to Climate Change, 2nd edition, Wiley-Interscience, Hoboken, New Jersey, 1232 pp., 2006.
Sharp, J. and Mass, C. F.: Columbia Gorge Gap Winds: Their Climatological Influence and Synoptic Evolution, Weather Forecast., 19(6), 970–992, 2004.
Vong, R. J., Moseholm, L., Covert, D. S., Sampson, P. D., O'Loughlin, J. F., Stevenson, M. N., Charlson, R. J., Zoller, W. H., and Larson, T. V.: Changes in rainwater acidity associated with closure of a copper smelter, J. Geophys. Res., 93(D6), 7169–7179, 1988.