Sustainability of High Arctic Ponds in a Polar Desert Environment

Abnizova, Anna; Young, Kathy L.

doi:10.14430/arctic648

Cited by 24 publications

(49 citation statements)

References 34 publications

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“…Locally, shallow snowpacks exist across ponds, wet meadow and plateau sites in relation to deeper snow found in incised valleys and in lee of slopes where late-lying snowbeds occur. This is similar to other high arctic studies, though snow depth, density, and SWE values at PBP are more typical of polar oasistype landscapes (e.g., Woo and Guan 2006) than polar desert areas (e.g., Yang and Woo 1999;Abnizova and Young 2010), indicating that a shift in snowpack properties is now underway at PBP. During snowmelt, shallow snowpacks exhibit frequent, small melt events (ca., 5 mm/day) in contrast to deeper snowbeds (>25 mm/day).…”

Section: Discussionsupporting

confidence: 89%

“…Melt contributions due to the precipitation flux (rain-on-snowmelt, Q p ) are still limited in this landscape despite their importance in other arctic locations, such as maritime sites (Young et al 2006;Hansen et al 2014). Overall, daily melt patterns at PBP are similar to other high arctic landscapes Woo and Guan 2006;Abnizova and Young 2010) and serve to shape snow cover depletion patterns. Fig.…”

Section: Snowmelt Durationmentioning

confidence: 92%

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Snow cover variability at Polar Bear Pass, Nunavut

2018

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Information on arctic snow covers is relevant for climate and hydrology studies and investigations into the sustainability of both arctic fauna and flora. This study aims to (1) highlight the variability of snow cover at Polar Bear Pass (PBP) at a range of scales: point, local, and regional using both in situ snow cover measurements and remote sensing imagery products; and (2) consider how snow cover at PBP might change in the future. Terrain-based snow surveys documented the end-of-winter snowpacks over several seasons (2008)(2009)(2010)(2012)(2013), and snowmelt was measured daily at typical terrain types. MODIS products (snow cover) were used to document spatial snow cover variability across PBP and Bathurst and Cornwallis Islands. Due to limited data, no significant difference in snow cover duration can be identified at PBP over the period of record. Locally, end-of-winter snow cover does vary across a range of terrain types with snow depths and densities reflecting polar oasis sites. Aspect remains a defining factor in terms of snow cover variability at PBP. Northern areas of the Pass melt earlier. Regionally, PBP tends to melt out earlier than most of Bathurst Island. In the future, we surmise that snowpacks at PBP will be thinner and disappear earlier.

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Section: Discussionsupporting

confidence: 89%

Section: Snowmelt Durationmentioning

confidence: 92%

Snow cover variability at Polar Bear Pass, Nunavut

2018

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“…In 2009 only, temperature sensors were located at the bottom of late-lying snow beds on both the northern and southern slopes of PBP at depths of 0.8 and 0.6 m, respectively. Temporal snowmelt patterns were then tracked by Stowaway temperature sensors (±0.1 • C) to provide an indication of the timing and duration of the snowmelt period (Abnizova and Young 2010). A distinct change in temperature occurs when a snowpack becomes isothermal (0 • C), and again when the area becomes snow-free, as temperatures become equivalent to the air temperature.…”

Section: Snowmelt Observations Direct Surface Snowmelt (M) Measuremenmentioning

confidence: 99%

“…In some regions, conditions favourable for the development of freshwater ecosystems such as wetlands can be found (Abnizova and Young 2010). The majority of the wetlands are small (tens of square metres in area) and consist of patchy strips of vegetation.…”

Section: Introductionmentioning

confidence: 99%

“…The source of freshwater to an extensive wetland may come from a variety of sources such as precipitation (rain/snow), streamflow, overland seepage from ponds and lakes and ground ice melt (Abnizova and Young 2010). Generally, the most important and largest source of freshwater occurs during spring snowmelt (Pohl et al 2005) which often recharges wet meadows, ponds, lakes and streams.…”

Section: Introductionmentioning

confidence: 99%

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Snow cover and snowmelt of an extensive High Arctic wetland: spatial and temporal seasonal patterns

Assini

Young

2012

Hydrological Sciences Journal

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This study examined the end-of-winter snow storage, its distribution and the spatial and temporal melt patterns of a large, low gradient wetland at Polar Bear Pass, Bathurst Island, Nunavut, Canada. The project utilized a combination of field observations and a physically-based snowmelt model. Topography and wind were the major controls on snow distribution in the region, and snow was routinely scoured from the hilltop regions and deposited into hillslopes and valleys. Timing and duration of snowmelt at Polar Bear Pass were similar in 2008 and 2009. The snowmelt was initiated by an increase in air temperature and net radiation receipt. Inter-annual variability in spatial snowmelt patterns was evident at Polar Bear Pass and was attributed to a non-uniform snow cover distribution and local microclimate conditions. In situ field studies and modelling remain important in High Arctic regions for assessing wetland water budgets and runoff, in addition to model parameterization and validation of satellite imagery.

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Pond hydrology and dissolved carbon dynamics at Polar Bear Pass wetland, Bathurst Island, Nunavut, Canada

2012

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A large number of wetlands, lakes and ponds exist in northern Canada, Alaska and Siberia, and the hydrologic and ecological processes in these water bodies are now responding to a changing climate. A large wetland, Polar Bear Pass (PBP), situated in the middle of Bathurst Island is considered to be one of the most important ecological sites in the region. Numerous ponds exist at PBP and are connected to their surrounding watersheds by streams and groundwater inflow, receiving varying amounts of water and nutrients. In 2008 and 2009, the representative hydrology of typical ponds at PBP along with their quantity of dissolved organic and inorganic carbon (DOC and DIC, respectively) was evaluated. Pond DOC and DIC loads and composition differ depending on the presence or absence of one or more hydrologic linkages that a pond has with its catchment. Elevated DOC loads were mostly of terrestrial origin and occurred in ponds receiving meltwater from snowbeds and discharge from hillslope creeks. The seasonal shift in connectivity of a pond to its catchment was critical in controlling DOC loads and concentrations. The frequency and duration of summer precipitation had a strong control on pond hydrologic connectivity and elevated the contribution of terrestrial DOC from wetland to ponds, especially ones that were hydrologically connected. The estimated DOC yields from wet meadow catchments highlight their importance as a source of carbon to pond ecosystems downstream. These wetland areas and ponds are potentially significant pools of carbon and are sensitive to future climate changes in permafrost‐dominated environments. Copyright © 2012 John Wiley & Sons, Ltd.

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Sustainability of High Arctic Ponds in a Polar Desert Environment

Cited by 24 publications

References 34 publications

Snow cover variability at Polar Bear Pass, Nunavut

Snow cover variability at Polar Bear Pass, Nunavut

Snow cover and snowmelt of an extensive High Arctic wetland: spatial and temporal seasonal patterns

Pond hydrology and dissolved carbon dynamics at Polar Bear Pass wetland, Bathurst Island, Nunavut, Canada

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