Status of high‐latitude precipitation estimates from observations and reanalyses

An intercomparison of high‐latitude precipitation characteristics from observation‐based and reanalysis products is performed. In particular, the precipitation products from CloudSat provide an independent assessment to other widely used products, these being the observationally based Global Precipi...

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Bibliographic Details
Published in:Journal of geophysical research. Atmospheres 2016-05, Vol.121 (9), p.4468-4486
Main Authors: Behrangi, Ali, Christensen, Matthew, Richardson, Mark, Lebsock, Matthew, Stephens, Graeme, Huffman, George J., Bolvin, David, Adler, Robert F., Gardner, Alex, Lambrigtsen, Bjorn, Fetzer, Eric
Format: Article
Language:English
Subjects:
Annual precipitation
Antarctica
Assessments
Atmospheric precipitations
Brackish
Climate
Climate models
Climate prediction
Climatic analysis
Climatology
Clouds
Cold season
Diagnostic systems
Energy policy
Environmental assessment
Estimates
Geophysics
Global precipitation
Government agencies
GRACE (experiment)
Gravity
high latitude
Intercomparison
Latitude
Marine
Meteorology
Northern Hemisphere
observation
Ocean-atmosphere interaction
Oceans
Outliers (statistics)
Precipitation
Precipitation (meteorology)
Precipitation estimation
Products
Rain
reanalysis
remote sensing
Seasons
Snow
Snow accumulation
Snowfall
Summer precipitation
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Summary:An intercomparison of high‐latitude precipitation characteristics from observation‐based and reanalysis products is performed. In particular, the precipitation products from CloudSat provide an independent assessment to other widely used products, these being the observationally based Global Precipitation Climatology Project (GPCP), Global Precipitation Climatology Centre, and Climate Prediction Center Merged Analysis of Precipitation (CMAP) products and the ERA‐Interim, Modern‐Era Retrospective Analysis for Research and Applications (MERRA), and National Centers for Environmental Prediction‐Department of Energy Reanalysis 2 (NCEP‐DOE R2) reanalyses. Seasonal and annual total precipitation in both hemispheres poleward of 55° latitude are considered in all products, and CloudSat is used to assess intensity and frequency of precipitation occurrence by phase, defined as rain, snow, or mixed phase. Furthermore, an independent estimate of snow accumulation during the cold season was calculated from the Gravity Recovery and Climate Experiment. The intercomparison is performed for the 2007–2010 period when CloudSat was fully operational. It is found that ERA‐Interim and MERRA are broadly similar, agreeing more closely with CloudSat over oceans. ERA‐Interim also agrees well with CloudSat estimates of snowfall over Antarctica where total snowfall from GPCP and CloudSat is almost identical. A number of disagreements on regional or seasonal scales are identified: CMAP reports much lower ocean precipitation relative to other products, NCEP‐DOE R2 reports much higher summer precipitation over Northern Hemisphere land, GPCP reports much higher snowfall over Eurasia, and CloudSat overestimates precipitation over Greenland, likely due to mischaracterization of rain and mixed‐phase precipitation. These outliers are likely unrealistic for these specific regions and time periods. These estimates from observations and reanalyses provide useful insights for diagnostic assessment of precipitation products in high latitudes, quantifying the current uncertainties, improving the products, and establishing a benchmark for assessment of climate models. Key Points ERA‐Interim and MERRA agree closely with CloudSat precipitation over high‐latitude oceans Over Antarctica total snowfall from GPCP and CloudSat are almost identical, about 178 mm/yr GPCP likely overestimates snowfall over Eurasia
ISSN:2169-897X
2169-8996
DOI:10.1002/2015JD024546