Passive Microwave Melt Onset Retrieval Based on a Variable Threshold: Assessment in the Canadian Arctic Archipelago

Marshall, Stephen; Scott, K. Andrea; Scharien, Randall K.

doi:10.3390/rs11111304

Cited by 10 publications

(10 citation statements)

References 31 publications

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“…While first open water will be later than sea ice melt onset, the weak negative trend in first open water dates (-2.91 d decade -1 , p > 0.05) is consistent with findings from previous studies, highlighting that no significant trends in melt onset dates were found in the CAA (e.g. Mahmud et al 2016;Marshall et al 2019); while other Arctic regions (e.g. Baffin Bay, Eastern Greenland, Barents Sea, Beaufort Sea, and Chukchi Sea) have shown significantly earlier melt onset by 2.3 to 6.9 d decade -1 (e.g.…”

Section: Links In Sea Ice and Snow Phenologysupporting

confidence: 90%

Sea ice and snow phenology in the Canadian Arctic Archipelago from 1997 to 2018

Dauginis

Brown

2021

Arctic Science

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The multiple islands and narrow channels that form the Canadian Arctic Archipelago (CAA) complicate snow/ice monitoring, as coarse resolution satellite observations are unable to resolve smaller-scale changes in snow/ice cover. We present the first study showing the utility of the Interactive Multisensor Snow and Ice Mapping System (IMS) 24 km (1997–2018) and 4 km (2004–2018) products to investigate changes in sea ice and snow phenology together in the CAA. While ice break-up and snow retreat are shifting earlier (p>0.05), on par with other Arctic regions, the final summer clearing of ice is shifting later. This, combined with trends towards earlier ice freeze and snow fall (p<0.05), result in shorter open water and snow free seasons in the CAA. Spatial links between sea ice and snow are evident as significant clusters of trends were identified for all phenology parameters. The western regions were dominated by shifts toward shorter snow/ice seasons, while eastern regions tended to exhibit longer cover. Our research highlights the considerable regional and interannual variability in the timing of sea ice and snow advance/retreat within the CAA and emphasizes how the ice and snow dynamics in this complex region are responding to ongoing changing climate conditions.

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Section: Links In Sea Ice and Snow Phenologysupporting

confidence: 90%

Sea ice and snow phenology in the Canadian Arctic Archipelago from 1997 to 2018

Dauginis

Brown

2021

Arctic Science

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“…Figure 3 shows the time series of the AMSR-E MPF and daily average 2 m air temperature in the ERA5 dataset provided by the European Centre for Medium-Range Weather Forecasts (ECMWF, https://www.ecmwf.int/). The MO date is obtained by using the dynamic threshold variability method based on 36.5 GHz vertically polarized T B data [20]. The FO date is retrieved from the melt/freeze-up algorithm, using 19 and 37 GHz vertically polarized T B data [18].…”

Section: Estimating Meltwater Drainage Onset Timing and Durationmentioning

confidence: 99%

“…These data points outside the possible melt season are problematic and are not to be included; we only used the realistic time series over 10/10 ice concentration and between the MO and FO dates, as the black circles in Figure 3 show. If the threshold of the MO is not determined due to the high inter-quartile range in the histogram of the potential MO [20], a data point of more than 0 • C air temperature is used for determining a realistic time series.…”

Section: Estimating Meltwater Drainage Onset Timing and Durationmentioning

confidence: 99%

“…Satellite passive microwave and optical remote sensing is useful for monitoring the entire polar regions daily [15,16], although optical remote sensing is limited by cloud cover when observing sea ice conditions. Although the timing of melt onset (MO) has been derived using passive microwave remote sensing [17][18][19][20], little is known about large-scale DO timing and DD in the melt season.…”

Section: Introductionmentioning

confidence: 99%

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Estimating Meltwater Drainage Onset Timing and Duration of Landfast Ice in the Canadian Arctic Archipelago Using AMSR-E Passive Microwave Data

Tanaka

2020

Remote Sensing

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Meltwater drainage onset (DO) timing and drainage duration (DD) related to snowmelt-water redistribution are both important for understanding not only the Arctic energy and heat budgets but also the salt/heat balance of the mixed layer in the ocean and sea-ice ecosystem. We present DO and DD as determined from the time series of Advanced Microwave Scanning Radiometer-Earth observing system (AMSR-E) melt pond fraction (MPF) estimates in an area with Canadian landfast ice. To address the lack of evaluation on a day-by-day basis for the AMSR-E MPF estimate, we first compared AMSR-E MPF with the daily Medium Resolution Imaging Spectrometer (MERIS) MPF. The AMSR-E MPF estimate correlates significantly with the MERIS MPF (r = 0.73–0.83). The estimate has a product quality similar to the MERIS MPF only when the albedo is around 0.5–0.7 and a positive bias of up to 10% in areas with an albedo of 0.7–0.9, including melting snow. The DO/DD estimates are determined by using a polynomial regression curve fitted on the time series of the AMSR-E MPF. The DOs/DDs from time series of the AMSR-E and MERIS MPFs are compared, revealing consistency in both DD and DO. The DO timing from 2006 to 2011 is correlated with melt onset timing. To the best of our knowledge, our study provides the first large-scale information on both DO timing and DD.

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“…[11], respectively. In 2012, the MO detections using [9] are not possible since the AMSR2 data are available from 4 July. MO in 2012 is instead detected using the melt/freeze-up algorithm 10].…”

Section: Introductionmentioning

confidence: 99%