TY - JOUR
T1 - Atmospheric mercury concentrations
T2 - Measurements and profiles near snow and ice surfaces in the Canadian Arctic during Alert 2000
AU - Steffen, Alexandra
AU - Schroeder, William
AU - Bottenheim, Jan
AU - Narayan, Julie
AU - Fuentes, Jose D.
N1 - Funding Information:
The authors would like to thank the following for their support and assistance during this campaign: Jim Milne, Dan Wile, Gary Heard and Ron Verrall (Defence Research Establishment Atlantic), Major J.P. Paris and MWO M. Goupil (Canadian Forces), Greg Lawson (National Waters Research Institute) for the snow data, Ann Louise Sumner (Purdue University) for the snowpack temperature data, Doug Worthy (Meteorological Service of Canada) for the GAW data, Canadian Forces Station Alert personnel, Global Atmospheric Watch personnel, Alert Weather Station personnel, Mark Lilly and the other participants in the ALERT 2000 project, in particular Al Gallant (MSC) for tireless logistical support. Funding was provided by the Meteorological Service of Canada and the Northern Contaminants Program of Northern Affairs and Development Canada. JDF acknowledges the support that the Office of Polar Programs of the US National Science Foundation provided to carry out the Ice Camp measurements included in this study
PY - 2002
Y1 - 2002
N2 - Gaseous elemental mercury (GEM) concentration measurements were made during the Alert 2000 campaign in Alert, Nunavut, Canada, between February and May 2000. GEM exhibits dramatic mercury depletion events (MDE) concurrently with ozone in the troposphere during the Arctic springtime. Using a cold regions pyrolysis unit, it was confirmed that GEM is converted to more reactive mercury species during the MDEs. It was determined that on average 48% of this converted GEM was recovered through pyrolysis suggesting that the remaining converted GEM is deposited on the snow surfaces. Samples collected during this campaign showed an approximate 20 fold increase in mercury concentrations in the snow from the dark to light periods. Vertical gradient air profiling experiments were conducted. In the non-depletion periods GEM was found to be invariant in the air column between surface and 1-2m heights. During a depletion period, GEM was found to be invariant in the air column except at the surface where a noticeable increase in the GEM concentration was observed. Concurrent ozone concentration profiles showed a small gradient in the air column but a sharp decrease in ozone concentration at the surface. Other profile studies showed a 41% average GEM concentration difference between the interstitial air in the snow pack and ∼2m above the surface suggesting that GEM is emitted from the snow pack. Further profile studies showed that during MDEs surface level GEM exhibits spikes of mercury concentrations that were over double the ambient GEM concentrations. It is thought that the solar radiation may reduce reactive mercury that is deposited on the snow surface during a MDE back to its elemental form which is then increasingly released from the snow pack as the temperature increases during the day. This is observed when wind speeds are very low. Crown
AB - Gaseous elemental mercury (GEM) concentration measurements were made during the Alert 2000 campaign in Alert, Nunavut, Canada, between February and May 2000. GEM exhibits dramatic mercury depletion events (MDE) concurrently with ozone in the troposphere during the Arctic springtime. Using a cold regions pyrolysis unit, it was confirmed that GEM is converted to more reactive mercury species during the MDEs. It was determined that on average 48% of this converted GEM was recovered through pyrolysis suggesting that the remaining converted GEM is deposited on the snow surfaces. Samples collected during this campaign showed an approximate 20 fold increase in mercury concentrations in the snow from the dark to light periods. Vertical gradient air profiling experiments were conducted. In the non-depletion periods GEM was found to be invariant in the air column between surface and 1-2m heights. During a depletion period, GEM was found to be invariant in the air column except at the surface where a noticeable increase in the GEM concentration was observed. Concurrent ozone concentration profiles showed a small gradient in the air column but a sharp decrease in ozone concentration at the surface. Other profile studies showed a 41% average GEM concentration difference between the interstitial air in the snow pack and ∼2m above the surface suggesting that GEM is emitted from the snow pack. Further profile studies showed that during MDEs surface level GEM exhibits spikes of mercury concentrations that were over double the ambient GEM concentrations. It is thought that the solar radiation may reduce reactive mercury that is deposited on the snow surface during a MDE back to its elemental form which is then increasingly released from the snow pack as the temperature increases during the day. This is observed when wind speeds are very low. Crown
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U2 - 10.1016/S1352-2310(02)00112-7
DO - 10.1016/S1352-2310(02)00112-7
M3 - Article
AN - SCOPUS:0036283777
SN - 1352-2310
VL - 36
SP - 2653
EP - 2661
JO - Atmospheric Environment
JF - Atmospheric Environment
IS - 15-16
ER -