German scientists have launched an ambitious project to capture the clouds in 3D

Regarding a big step of climate science, German researchers are launching a project for many years to completely change how we understand and simulate the impact of clouds on the earth’s climate. The initiative aims to surpass the traditional one -dimensional cloud model to create a comprehensive three -dimensional representation form, and it may solve the long -term challenges in climate forecast.

The project was launched at the Leibniz Institute in Leipzig’s Leibniz Institute (Tropos), bringing together about 25 researchers from the German leading institutions. Their task: Decoding the complex relationship between the cloud structure and radiation mode that has been plagued by scientists since the satellite weather dawn.

Research profile pointed out: “The average cloud covers two-thirds of the surface of our earth, so it is the largest filter in our atmosphere.” This dual nature of Yun-they can cool or warm the height and one day of the day according to their structure, height and daytime time. The ability of the earth-to make them a key participant in climate dynamics.

The timing of the plan is called C3SAR (cloud 3D structure and radiation), which is in line with the major progress of satellite technology. The latest generation of METEOST weather satellites and new ESA climate satellite garden nursing (operation since 2024) provides unprecedented space resolution in space cloud observation.

The current climate model and satellite observation results will see the cloud as uniform-this is a simplified object that scientists have long-term problems. Due to technical limitations and pure complexity of cloud behavior, this excessive simplification continues. The new research team aims to solve this gap by developing more complex methods to capture the natural variability of the cloud.

The core of the project will be a large -scale wild sports planned by Richardaßmann Observatory in the summer of 2026 in the summer of 2026. The event will deploy a variety of musical instruments, including a new small gold planning network (Pyrnet) from Tropos, which previously collected data in the United States in 2023 in 2023. These devices will record solar radiation with a second interval and provide unprecedented details about how cloud affects solar radiation to the surface of the earth.

The research team represents Cologne University, Ludwig-Maxlian-Sonifen, Hanover University of Leibniz University, German Meteorological Agency and Toro Persia. The project is funded by the German Research Foundation (DFG), which can be extended for up to eight years, which allows comprehensive long -term research.

At the scene, the research will benefit from the EU research infrastructure Actris, which maintains atmospheric super sites throughout Germany and Europe. These facilities have provided high -resolution data on cloud layers and radiation modes, providing a strong foundation for the new 3D modeling work.

The meaning of this study exceeds pure scientific interests. As the global climate model is difficult to accurately predict the future climate model, a better understanding of cloud behavior can significantly improve the accuracy of forecasting. The project is specifically aimed at correcting errors in climate modeling and Yunyao sensing.

DFG is providing support for 5626 (Project Number 513446258) through the research team, which shows that Germany promotes climate science by promoting climate science through innovative methods for long -term challenges.

With the continuous development of satellite technology and the increase in computing capabilities, the project has positioned German research institutions as the forefront of the hard work of unveiling one of the most long -lasting mysteries of climate science: how clouds shaped the climate future of our planet.