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Elevation correction of ERA-Interim temperature data in complex terrain

Hydrology and Earth System Sciences (2012) 16(12) 4661-4673
DOI: 10.5194/hess-16-4661-2012
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Abstract

Air temperature controls a large variety of environmental processes, and is an essential input parameter for land surface models, for example in hydrology, ecology and climatology. However, meteorological networks, which can provide the necessary information, are commonly sparse in complex terrains, especially in high mountainous regions. In order to provide temperature data in an adequate temporal and spatial resolution for local scale applications a new elevation correction method has been developed that is able to downscale 3-hourly ERA-Interim temperature data. The scheme is based on model internal vertical lapse rates derived from different ERA-Interim pressure levels and has been validated for twelve meteorological stations in the German and Swiss Alps. The method was also compared with two other statistical, lapse rate based correction approaches. The results indicate that the use of model internal ERA-Interim lapse rates can significantly improve the downscaling performance when compared to the standard procedure of using fixed lapse rates. © 2012 Author(s). CC Attribution 3.0 License.

Figures

  • Fig. 1. Location of the twelve meteorological stations (triangles), and ERA-Interim 0.25◦× 0.25◦ grids (dashed line). Twelve stations were clustered into four groups according to the different ERAInterim grids. The elevation ranges from 22 m to 4783 m a.s.l., with a DEM resolution of 90 m.
  • Fig. 2. Correlation and MAE (◦C) between daily mean ERAInterim 2 m temperature and E-2 OBS data (0.25◦× 0.25◦, period from 1979 to 2010) extended Simmons’ investigation (5◦× 5◦, monthly, period from 1989 to 2001). The values labeled in the grid are the MAEs. The dots are the center points of ERA-Interim grid, the crosses are the center points of E-OBS grid and the triangles are the test sites. ERA-Interim and E-OBS grids are shifted in latitude and longitude direction by 0.125◦, i.e. the center point of the E-OBS grid is located at the cross junction of four ERA-Interim grids. The average value of every four ERA-Interim points was calculated for the corresponding E-OBS grid.
  • Table 1. Test sites information (ERA height is the ERA-Interim model elevation).
  • Fig. 3. Schematic illustration of measured lapse rate and ERAInterim derived lapse rates for Group 1. 0m was calculated based on the two largest-elevation-difference stations (e.g. Garmisch and Zugspizte station). Temperatures as well as the geopotential heights of the 700 hPa, 850 hPa and 925 hPa level were used for calculating 0700 925, 0850 925 and 0700 850. The dashed blue line represents the mean geopotential height of the corresponding pressure level (for the period 1979–2010).
  • Table 2. Fixed monthly lapse rates extracted from Kunkel (1989) and Liston and Elder (2006).
  • Table 3. Applied lapse rate (0) and reference temperature (Tref) of four correction methods for twelve test stations.
  • Table 4. Comparison of ERA-Interim 2 m temperature with 3-hourly and daily data of twelve meteorological stations. The NSE as well as the RMSE and MAE in ◦C are also listed, and the elevations (m) are labeled in brackets.
  • Fig. 4. The scatter plots show the comparison of 3-hourly ERA-Interim 2 m temperature and meteorological stations for Group 1, (a) Garmisch station (1979–2010), (b) Zugspitzplatt station (1999–2010) and (c) Zugspitze station (1979-2010). All the related accuracy measures can be found in Table 4.

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CITATION STYLE

APA

Gao, L., Bernhardt, M., & Schulz, K. (2012). Elevation correction of ERA-Interim temperature data in complex terrain. Hydrology and Earth System Sciences, 16(12), 4661–4673. https://doi.org/10.5194/hess-16-4661-2012

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