Basic Climate Data

New data for Germany and Bavaria

In 2025, there was an UPDATE with the following additions:

• - The climate database has been updated for the observation period up to 2020.
• - The climate model ensemble was supplemented with additional model runs (Euro-Cordex) and expanded to include historical simulations.
• - The bias correction of the simulation data was performed using in-house software.
• - The result data was interpolated onto a finer grid, taking topographical features into account.

Differences

The difference to the Impact2C dataset used from 2019 onwards is essentially a more comprehensive model ensemble of 17 runs for the RCP8.5 scenario. The resulting statistics for selected climate indicators for a 30-year period are therefore based on 30x17=510 annual values (instead of 120). In comparison, there may be significant deviations in the development of individual indicators.

The range of the annual mean temperature in Germany remains roughly the same at 11°C to 14°C (RCP8.5 to 2100). Greater differences are apparent in the mean number of hot days. In the current data, the value is just under 30 days. Previously, it was slightly more than 20 days in Germany.

The more comprehensive ensemble also has an impact on total precipitation. The more models there are, the greater the range of variability in annual precipitation. On average, developments remain at historical levels. However, more heavy rainfall and higher average temperatures favor longer dry spells.

Observation data: 1961-2020

Only measuring stations that have been part of the DWD station network since 1961 were taken into account for updating the observation data set. These include approximately 220 synoptic stations and approximately 1,200 precipitation stations. All of them provide daily values for meteorological parameters. Due to the limited station density, small-scale phenomena and regional characteristics in particular cannot be depicted with complete accuracy. This station network also forms the basis for the preparation of scenario data (see Interpolation).

Climate model ensemble: historical and future

The RCP8.5 climate model ensemble, which currently comprises 17 simulations, has been supplemented with historical simulation periods dating back to 1971. The entire simulation period thus covers a total of 130 years. The ensemble for the RCP2.6 scenario is significantly smaller because fewer runs are available for it. For the historical period, the current version allows comparisons between developments in the model ensemble and in the observations. Many of the indicators show that the simulations are consistent with the observations. Phenomena such as spring droughts show discrepancies that indicate weaknesses in the model.

Climate model ensemble

Regional climate model ensemble

In order to derive regional climate impacts from future climate development paths (in accordance with the RCP scenarios), it is necessary to refine global climate model simulations (GCMs) for large regions such as Europe. This is usually achieved by using them as input for higher-resolution regional climate models (RCMs). These models are able to reproduce the regional characteristics of temperature and precipitation distribution more realistically, as they better reflect effects caused by topography and land use, among other things.

Extensive simulation data from [Euro-Cordex] https://cds.climate.copernicus.eu/datasets/projections-cordex-domains-single-levels?tab=download provides the basis and data foundation (see table) for enabling climate services for Europe, Germany, and federal states. The simulation period covers the historical periods from 1971 onwards and extends into the scenario period until 2100. Each individual model combination represents a possible realization of climatic and meteorological development. Typically, time slices of 30 years are considered, whose variability and means are explained by 30x17=510 annual values. The totality of the values results in ranges that are composed of both internal variability and model uncertainty.

It is well known that there are systematic errors between models and measurements. For the historical comparison period, these can be quantified in order to adjust (align) the simulation values. Existing trends in the data are retained in the process. There are established methods for this in climate impact research (Lange, 2019). This is because the size of the so-called model bias is not the sole criterion for evaluating climate model simulations.

Daily data on a uniform grid is required to align the model values with the observation values. This is specified by the generated observation data set. To transfer the model values to the observation grid, the model data is first transferred to the station network. To do this, the values of the nearest grid point are assigned to the station coordinates. Interpolation is then performed in the same way as for the base data set. This step ensures that simulation data and observation data have the same spatial assignment. In this way, climatic developments can be seamlessly represented in map and diagram form.

The two climate model ensembles RCP2.6 and RCP8.5 span the possible range of events within which the future climate in Germany may develop. Existing discrepancies between observed and simulated developments cannot be resolved at this point in time, as this is a continuous process of further developing scientific knowledge. Phenomena that trigger prolonged drought are therefore the subject of current research with relevance across sectors of climate impact research.

Table: Simulation matrix of the underlying combinations of regionalized global model simulations (GCMs) by regional models (RCMs): RCP8.5 – 17 models, RCP2.6 – 7 models. No EuroCordex simulations are available for the RCP scenarios for the empty fields.

Further Literature: Lange, S.: Trend-preserving bias adjustment and statistical downscaling with ISIMIP3BASD (v1.0), Geosci. Model Dev., 12, 3055–3070, https://doi.org/10.5194/gmd-12-3055-2019, 2019.

Bandwidth

The underlying regional climate model ensemble includes seven simulations for the RCP 2.6 scenario and 17 simulations for the RCP 8.5 scenario.

To estimate the ranges, model uncertainty and internal (year-on-year) variability were combined, sorted, and the value below which 10% and 90% of the values lie was used for the time series representation. Only the mean values are shown on the map. For a 30-year period and a model ensemble of 17 simulations, this means a pool of 17 x 30 = 510 annual values is available for the respective climate indicators.

Note: During the observation period, the range results exclusively from the internal variability of 30 annual values. Against this background, model uncertainty and internal variability were combined to estimate the range in the scenario data.

Interpolation

To display the climate indicators derived from the daily climate data, a method was used in which the available information at the locations of the measuring stations was interpolated to grid points. Their spatial resolution is approximately 4 x 4 km, for which elevation values from a digital terrain model are also available. Among other things, the method takes into account existing gradients of values at different altitudes in the station network. Before the actual interpolation, the altitude effects in the station network are eliminated. The value sought at the corresponding grid point is then determined by a weighted summation of the station data within a specified radius of influence (neighboring stations), whereby the sum is then divided by the number of stations. The elevation effect is then applied to the target grid according to the elevation values.

Further Literature:
Cressie N., 1993, Statistics for spatial data, Wiley Series in Probability and Statistics
https://app.readthedocs.org/projects/pykrige/downloads/pdf/latest/](https://app.readthedocs.org/projects/pykrige/downloads/pdf/latest/

Observation data

Historical observations of climatic developments, as presented in the Climate section, are based on station data that has been part of the DWD measurement network since 1961.
They provide daily values for meteorological parameters at approximately 220 synoptic stations and approximately 1,200 precipitation stations.
This station data set forms the basis for homogenization and spatial interpolation to a high-resolution grid, taking topographical conditions into account. Values from neighboring stations are taken into account during homogenization and interpolation. Derived climate indicators are calculated on the basis of the interpolated daily data. Possible artifacts cannot be ruled out in individual cases.

Scenario Selection

The KlimafolgenOnline portal shows two of the four Main Representative Concentration Pathways (RCP2.6, RCP4.5, RCP6.0 and RCP8.5). These were developed by the scientific community for the fifth assessment report of the Intergovernmental Panel on Climate Change (IPCC).

The RCP scenarios 2.6 and 8.5 used in the portal take into account different levels of greenhouse gas-induced radiative forcing for the period 2021-2100. The decisive factor for the respective differences in temperature increase in the scenarios is the intensity of future climate protection measures from 2021 to 2100, which influence radiative forcing and greenhouse gas concentrations.

The RCP 2.6 scenario shows a possible development that is expected to comply with the global two-degree limit. This requires strong climate protection measures. The two-degree limit is a political target, as scientists believe that the effects of climate change would remain manageable if warming were to remain below this temperature. More detailed information can be found in the German synthesis report of the IPCC's Fifth Assessment Report. This document is available as a PDF file in the menu under Climate Knowledge. At the UN Climate Change Conference in Paris in December 2015, 195 countries agreed on a new agreement to combat global warming. According to this agreement, global warming is to be limited to “well below two degrees” compared to pre-industrial conditions.

Das Szenarium RCP 8.5 ist das Worst-Case-Szenarium. Es betrachtet eine mögliche Klimaentwicklung bei weiter steigenden Treibhausgasemissionen ohne zusätzliche Klimaschutzmaßnahmen. Daraus ergibt sich ein weltweit mittlerer Temperaturanstieg zwischen 3,6 °C und 4,1 °C bis 2100 gegenüber vorindustriellem Nineau, wenn man die derzeitig zur Verfügung stehenden Szenarienläufe der globalen Klimamodelle zugrunde legt.

In Germany, the average temperature increase by 2100 compared to pre-industrial levels will be in the range of +2°C (RCP2.6) and +5°C (RCP8.5).