Central IT Services

IT services are provided at MPI-M by the Central IT Services (CIS) group.

The most important services of the Central IT Services are:

  • Procurement, setup and management of IT hardware and software for both users (laptops, PCs) and infrastructure (servers, networks, etc.)
  • Central user administration
  • Provision of an efficient network (LAN, WLAN)
  • Central IT help desk as a contact point for all IT-related issues
  • Provision of services to support daily work (e.g. version management, project management, websites, etc.)
  • Ensuring secure IT operations (failover, backup, IT security)

Detailed documentation on the IT Group’s offerings can be found in the Wiki of the institute.

An account (username and password) is required to use most IT services. Usually, an account will be created for you as soon as you have a contract with MPI-M. If you are a guest at MPI-M and need an account, your group leader at MPI can request an account for you. Further details are described in the institutes Wiki.

If you have any questions or problems using the IT systems at MPI-M, please contact the IT help desk.

Please note that questions regarding the DKRZ systems (e.g. Levante or data archive) will be answered by the DKRZ user support.

Contact

Rainer Weigle

Group leader
Tel.: +49 (0)40 41173-373
rainer.weigle@we dont want spammpimet.mpg.de


Helpdesk

Tel.: +49 (0)40 41173-361
help-it@we dont want spammpimet.mpg.de

More Content

Climate change amplified by permafrost cloud feedback

Researchers at the Max Planck Institute for Meteorology shed light on what may happen if the frozen soils thaw in response to global heating. Landscapes in the Arctic and subarctic zone are often very wet with water saturated soils and an extensive lake- and wetland cover shaping the moisture and energy exchange with the atmosphere. To some extent, the abundance of water is caused by the presence of permafrost, that is those parts of the ground that remain perennially frozen. Such soil layers have underlain large parts of the region since the last glacial maximum and strongly inhibit the movement of water below the surface.

In a new study, Philipp de Vrese, Tobias Stacke, Veronika Gayler and Victor Brovkin use simulations with the ICON model to show that permafrost degradation facilitates a drying of the landscape and increases regional temperatures via an atmospheric feedback: During the warm season, drier surface conditions reduce the moisture transport into the atmosphere. The latter lowering the relative humidity in the boundary layer and diminishing low-altitude cloud cover. Since clouds reflect more sunlight than the snow-free land surface, the reduced cloudiness allows more solar radiation to reach the surface, increasing temperatures and accelerating the thawing of the ground.

The temperature effect of such permafrost cloud feedback is not limited to the regional scale, since higher temperatures in the Arctic and subarctic zones significantly impact the net energy difference between equatorial and polar regions. Despite the northern permafrost region covering only about 5 % of the globe, the study reveals this feedback effect is similar in magnitude to physical- and biophysical climate feedbacks acting on the global scale.

Philipp de Vrese, the lead author, commented: “It was really astonishing that a spatially limited process would have such large-scale consequences. Fortunately, the warming due to the permafrost cloud feedback is likely accounted for in the most recent projections, as we have merely isolated an effect that should already be included in simulations with current-generation models.” However, Tobias Stacke cautioned: “This depends also very much on how well the land surface models represent the hydrology in permafrost regions. Even in high-resolution simulations, many of the relevant processes cannot yet be represented.”  Victor Brovkin added: “In the public debate, the impact of permafrost thawing on the climate is mostly associated with the resulting release of methane and carbon dioxide. It was surprising to find out that physical climate processes due to changes in permafrost hydrology could also strongly amplify global warming.”

Original publication

de Vrese, P., Stacke, T., Gayler, V., &  Brovkin, V. (2024). Permafrost cloud feedback may amplify climate change. Geophysical Research Letters, 51, e2024GL109034. https://doi.org/10.1029/2024GL109034

Contact

Dr. Philipp de Vrese
Max Planck Institute for Meteorology
philipp.de-vrese@mpimet.mpg.de

Climate change amplified by permafrost cloud feedback

Researchers at the Max Planck Institute for Meteorology shed light on what may happen if the frozen soils thaw in response to global heating. Landscapes in the Arctic and subarctic zone are often very wet with water saturated soils and an extensive lake- and wetland cover shaping the moisture and energy exchange with the atmosphere. To some extent, the abundance of water is caused by the presence of permafrost, that is those parts of the ground that remain perennially frozen. Such soil layers have underlain large parts of the region since the last glacial maximum and strongly inhibit the movement of water below the surface.

In a new study, Philipp de Vrese, Tobias Stacke, Veronika Gayler and Victor Brovkin use simulations with the ICON model to show that permafrost degradation facilitates a drying of the landscape and increases regional temperatures via an atmospheric feedback: During the warm season, drier surface conditions reduce the moisture transport into the atmosphere. The latter lowering the relative humidity in the boundary layer and diminishing low-altitude cloud cover. Since clouds reflect more sunlight than the snow-free land surface, the reduced cloudiness allows more solar radiation to reach the surface, increasing temperatures and accelerating the thawing of the ground.

The temperature effect of such permafrost cloud feedback is not limited to the regional scale, since higher temperatures in the Arctic and subarctic zones significantly impact the net energy difference between equatorial and polar regions. Despite the northern permafrost region covering only about 5 % of the globe, the study reveals this feedback effect is similar in magnitude to physical- and biophysical climate feedbacks acting on the global scale.

Philipp de Vrese, the lead author, commented: “It was really astonishing that a spatially limited process would have such large-scale consequences. Fortunately, the warming due to the permafrost cloud feedback is likely accounted for in the most recent projections, as we have merely isolated an effect that should already be included in simulations with current-generation models.” However, Tobias Stacke cautioned: “This depends also very much on how well the land surface models represent the hydrology in permafrost regions. Even in high-resolution simulations, many of the relevant processes cannot yet be represented.”  Victor Brovkin added: “In the public debate, the impact of permafrost thawing on the climate is mostly associated with the resulting release of methane and carbon dioxide. It was surprising to find out that physical climate processes due to changes in permafrost hydrology could also strongly amplify global warming.”

Original publication

de Vrese, P., Stacke, T., Gayler, V., &  Brovkin, V. (2024). Permafrost cloud feedback may amplify climate change. Geophysical Research Letters, 51, e2024GL109034. https://doi.org/10.1029/2024GL109034

Contact

Dr. Philipp de Vrese
Max Planck Institute for Meteorology
philipp.de-vrese@mpimet.mpg.de

Climate change amplified by permafrost cloud feedback

Researchers at the Max Planck Institute for Meteorology shed light on what may happen if the frozen soils thaw in response to global heating. Landscapes in the Arctic and subarctic zone are often very wet with water saturated soils and an extensive lake- and wetland cover shaping the moisture and energy exchange with the atmosphere. To some extent, the abundance of water is caused by the presence of permafrost, that is those parts of the ground that remain perennially frozen. Such soil layers have underlain large parts of the region since the last glacial maximum and strongly inhibit the movement of water below the surface.

In a new study, Philipp de Vrese, Tobias Stacke, Veronika Gayler and Victor Brovkin use simulations with the ICON model to show that permafrost degradation facilitates a drying of the landscape and increases regional temperatures via an atmospheric feedback: During the warm season, drier surface conditions reduce the moisture transport into the atmosphere. The latter lowering the relative humidity in the boundary layer and diminishing low-altitude cloud cover. Since clouds reflect more sunlight than the snow-free land surface, the reduced cloudiness allows more solar radiation to reach the surface, increasing temperatures and accelerating the thawing of the ground.

The temperature effect of such permafrost cloud feedback is not limited to the regional scale, since higher temperatures in the Arctic and subarctic zones significantly impact the net energy difference between equatorial and polar regions. Despite the northern permafrost region covering only about 5 % of the globe, the study reveals this feedback effect is similar in magnitude to physical- and biophysical climate feedbacks acting on the global scale.

Philipp de Vrese, the lead author, commented: “It was really astonishing that a spatially limited process would have such large-scale consequences. Fortunately, the warming due to the permafrost cloud feedback is likely accounted for in the most recent projections, as we have merely isolated an effect that should already be included in simulations with current-generation models.” However, Tobias Stacke cautioned: “This depends also very much on how well the land surface models represent the hydrology in permafrost regions. Even in high-resolution simulations, many of the relevant processes cannot yet be represented.”  Victor Brovkin added: “In the public debate, the impact of permafrost thawing on the climate is mostly associated with the resulting release of methane and carbon dioxide. It was surprising to find out that physical climate processes due to changes in permafrost hydrology could also strongly amplify global warming.”

Original publication

de Vrese, P., Stacke, T., Gayler, V., &  Brovkin, V. (2024). Permafrost cloud feedback may amplify climate change. Geophysical Research Letters, 51, e2024GL109034. https://doi.org/10.1029/2024GL109034

Contact

Dr. Philipp de Vrese
Max Planck Institute for Meteorology
philipp.de-vrese@mpimet.mpg.de