Evaluation of Seven Different Atmospheric Reanalysis Products in the Arctic*

Lindsay, R. W.; Wensnahan, Mark; Schweiger, Axel; Zhang, J.

doi:10.1175/jcli-d-13-00014.1

Cited by 486 publications

(446 citation statements)

References 44 publications

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“…Trace precipitation amounts for solid precipitation were assigned values from 0.03 to 0.07 mm that varied inversely with latitude following Mekis and Vincent (2011). CFSR, MERRA and ERA-Interim monthly mean temperature and precipitation data were previously evaluated over the Canadian Arctic by Rapaić et al (2015) and over the entire Arctic by Lindsay et al (2014). Both papers indicate that MERRA and ERA-Interim have relatively small warm and wet biases compared to other reanalyses, while CFSR was found to have particularly large positive precipitation biases.…”

Section: Atmospheric Reanalyses and Gridded Surface Observationsmentioning

confidence: 99%

“…As a consequence, climate model evaluations over such regions are often carried out using station observations or reanalyses (e.g. Lindsay et al 2014;Glisan and Gutowski 2014a, b;Matthes et al 2010Matthes et al , 2015Wilson et al 2012). In this study, we use surface observations of mean, minimum and maximum daily temperature (Tmean, Tmin and Tmax, respectively) and daily precipitation (Pr) from the climate stations included in the National Climate Data and Information Archive at Environment and Climate Change Canada (http://ccds-dscc.…”

Section: Surface Observationsmentioning

confidence: 99%

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Evaluation of CORDEX-Arctic daily precipitation and temperature-based climate indices over Canadian Arctic land areas

et al. 2017

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Section: Atmospheric Reanalyses and Gridded Surface Observationsmentioning

confidence: 99%

Section: Surface Observationsmentioning

confidence: 99%

Evaluation of CORDEX-Arctic daily precipitation and temperature-based climate indices over Canadian Arctic land areas

et al. 2017

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“…MERRA is run on a 1/2 • latitude by 2/3 • longitude global grid with 72 hybrid-sigma vertical levels to produce analyses from 1979 to present. MERRA has been evaluated extensively since its release (Cullather and Bosilovich, 2011b;Kennedy et al, 2011; and has compared favorably with other reanalysis products in the Arctic (Zib et al, 2012;Cullather and Bosilovich, 2011;Lindsay et al, 2014).…”

Section: Atmospheric Datamentioning

confidence: 99%

Investigating the local-scale influence of sea ice on Greenland surface melt

et al. 2017

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Abstract. Rapid decline in Arctic sea ice cover in the 21st century may have wide-reaching effects on the Arctic climate system, including the Greenland ice sheet mass balance. Here, we investigate whether local changes in sea ice around the Greenland ice sheet have had an impact on Greenland surface melt. Specifically, we investigate the relationship between sea ice concentration, the timing of melt onset and open-water fraction surrounding Greenland with ice sheet surface melt using a combination of remote sensing observations, and outputs from a reanalysis model and a regional climate model for the period of 1979-2015. Statistical analysis points to covariability between Greenland ice sheet surface melt and sea ice within Baffin Bay and Davis Strait. While some of this covariance can be explained by simultaneous influence of atmospheric circulation anomalies on both the sea ice cover and Greenland melt, within Baffin Bay we find a modest correlation between detrended melt onset over sea ice and the adjacent ice sheet melt onset. This correlation appears to be related to increased transfer of sensible and latent heat fluxes from the ocean to the atmosphere in early sea ice melt years, increasing temperatures and humidity over the ice sheet that in turn initiate ice sheet melt.

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“…Downward surface solar radiation data were obtained four times per day from the European Centre for Medium-Range Weather Forecast (ECMWF) EraInterim re-analyses (Dee et al, 2011;Lindsay et al, 2014). The data (four values per day) were averaged to daily means and have been available since 1979.…”

Section: Input Data Setsmentioning

confidence: 99%

Seasonal cycle and long-term trend of solar energy fluxes through Arctic sea ice

Arndt

Nicolaus

2014

The Cryosphere

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Abstract. Arctic sea ice has not only decreased in volume during the last decades, but has also changed in its physical properties towards a thinner and more seasonal ice cover. These changes strongly impact the energy budget, and might affect the ice-associated ecosystems. In this study, we quantify solar shortwave fluxes through sea ice for the entire Arctic during all seasons. To focus on sea-ice-related processes, we exclude fluxes through open water, scaling linearly with sea ice concentration. We present a new parameterization of light transmittance through sea ice for all seasons as a function of variable sea ice properties. The maximum monthly mean solar heat flux under the ice of 30 × 10 5 Jm −2 occurs in June, enough heat to melt 0.3 m of sea ice. Furthermore, our results suggest that 96 % of the annual solar heat input through sea ice occurs during only a 4-month period from May to August. Applying the new parameterization to remote sensing and reanalysis data from 1979 to 2011, we find an increase in transmitted light of 1.5 % yr −1 for all regions. This corresponds to an increase in potential sea ice bottom melt of 63 % over the 33-year study period. Sensitivity studies reveal that the results depend strongly on the timing of melt onset and the correct classification of ice types. Assuming 2 weeks earlier melt onset, the annual transmitted solar radiation to the upper ocean increases by 20 %. Continuing the observed transition from a mixed multi-year/first-year sea ice cover to a seasonal ice cover results in an increase in light transmittance by an additional 18 %.

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Evaluation of Seven Different Atmospheric Reanalysis Products in the Arctic*

Cited by 486 publications

References 44 publications

Evaluation of CORDEX-Arctic daily precipitation and temperature-based climate indices over Canadian Arctic land areas

Evaluation of CORDEX-Arctic daily precipitation and temperature-based climate indices over Canadian Arctic land areas

Investigating the local-scale influence of sea ice on Greenland surface melt

Seasonal cycle and long-term trend of solar energy fluxes through Arctic sea ice

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