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Development of Surrogate Surfaces for Assessing Dry Deposition of Atmospheric Hg
Seth Lyman, Mae Gustin*
University of Nevada, Reno, Department of Natural Resources
and Environmental Science
Reno, Nevada 89557
Eric Prestbo
Tekran Instrument Corporation, 330 Nantucket Blvd., Toronto,
ON M1P2P4
Phil Kilner
Frontier Geosciences, 414 Pontius Avenue North, Seattle,
Washington 98109
| Dry deposition is thought to be an important
pathway for input of mercury to aquatic and terrestrial environments,
but methods to measure mercury dry deposition flux are not well established.
Polysulfone cation-exchange membranes are being developed as surrogate
surfaces to estimate dry deposition of reactive gaseous mercury (RGM).
In a preliminary study, accumulation of mercury on membranes was well
correlated with air RGM concentrations (r = 0.93, p <0.001) and with
modeled RGM deposition (r = 0.97, p <0.001), though deposition to membranes
was about five times greater than modeled RGM deposition. Field experiments
are being done in Reno, Nevada, USA to characterize uptake rates of ambient
RGM under differing environmental conditions. Laboratory experiments are
being done to characterize gaseous elemental mercury and RGM uptake by
the membranes as a function of atmospheric concentrations as well as different
temperature, humidity, light and atmospheric chemistry exposures. These
will help us establish uptake rates as a function of exposure concentrations
that can then be compared to field data and modeled deposition values.
We have also begun deployment of the membranes at other field sites where
air speciation and a variety of other environmental parameters are being
measured in the United States. These data will allow us to assess membrane
behavior in different environmental conditions. Additionally, optimal
handling and deployment procedures are being developed, and the cation-exchange
membranes are being compared against other surfaces for efficiency of
RGM uptake.
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