Section 2.2 | Geophysical Imaging

[Translate to English:] Feldmessung in Chile
Santa Gracia, Chile: A rover with a drop weight stands in the Chilean coastal cordillera. What at first glance looks like the Mars-Rover Curiosity lost on Earth is a device for visualising the subsurface. In the Chilean highlands there is what is known in geophysics as the “critical zone”. In this area, deep weathering and the associated interactions between geological and biological processes are transforming the intact rock into weathered regolith rock. In order to visualise the structure of the Critical Zone, we use active and passive seismic experiments to image the seismic structure around these wells. Thanks to the application of Bayesian inversion imaging techniques, the results can be presented in 2D and 3D extrapolation of the deep weathering structures derived from lithological, petrophysical, geochemical and microbiological data at the wells. (Photo: R. Trichandi)
Drop weight in the Alay Mountains, Kyrgyzstan
Kyrgystan: Central Asia is one of the most tectonically active regions on Earth and is influenced by two major climate systems, the westerly wind zone and the monsoon. As the population and concentration of values grow in Central Asia, so does their vulnerability to natural disasters. Therefore, risk and vulnerability assessments are a key task in preparing the affected states and societies for such recurring extreme events. With shallow seismic investigations (a drop weight can be seen in the picture) and paleoseismological trenches, we are investigating the spatio-temporal development of the Main Pamir Thrust in Kyrgyzstan. (Photo: C. Haberland, GFZ)
Active seismic experiment in Chile using a seismic land streamer to image subsurface structure. Recent geological processes may have obscured evidence of fault zones. Using geophysical imaging methods, the existence of such paleo faults can be proven. These subsurface imaging data can then be used as a vital input for the early assessment of geo-hazards.
Morguilla, Chile: Active seismic experiment in Chile using a seismic land streamer to image subsurface structure. Recent geological processes may have obscured evidence of fault zones. Using geophysical imaging methods, the existence of such paleo faults can be proven. These subsurface imaging data can then be used as a vital input for the early assessment of geo-hazards. (Photo: R. Trichandi, GFZ)
Setting up a seismic station in Lusatia. The seismic station records the ambient seismic noise, from which the 3-D underground structure is determined using ambient noise tomography.
Lausitz, Germany: Setting up a seismic station in Lusatia. The seismic station records the ambient seismic noise, from which the 3-D underground structure is determined using ambient noise tomography. (Photo: T. Ryberg, GFZ)
Car and Person in Antartkis, The flags mark the positions of the sensors (electrodes and induction coil magnetometers).
Ekström Ice Shelf, Antarctica: The transition zone between the ice shelf and the glacier, as well as the properties of subglacial rocks, are crucial for understanding the dynamics of the Antarctic ice sheet. To expand our knowledge in this area, we are using magnetotellurics (MT) to map the electrical conductivity of sediments and rocks under the ice sheet. MT is particularly environmentally friendly because it does not require any artificial signals and does not interfere with nature. The flags mark the positions of the sensors (electrodes and induction coil magnetometers). (Photo: O. Ritter)
For the MOSMIN project, fiber optic cables are being laid in Zambia to measure the subsurface. This technology work well in cities and underwater with already existing cables, as well as when deployed specifically to measure the subsurface.
Kalumbila, Sambia: As part of the EU project MOSMIN, a fiber optic cable is being installed along a tailings dam in Zambia. Using Distributed Acoustic Sensing (DAS) over a length of 5 km, the cable will densely sample the seismic wave field radiating through the dam, collecting important information for monitoring its structural integrity. (Photo: V. Rodriguez Tribaldos, GFZ)
3 days before Etna broke out in Oktober 21
Etna, Italy: Seismic wave fields change the material they pass through, and these changes can be measured. These reactions are important because they are linked to natural hazards such as earthquakes, volcanic eruptions and landslides, as well as the condition of buildings. Conventional seismic sensors offer high temporal resolution but low spatial resolution. Thanks to fibre optic cables that were laid along the Etna. A classic (telecommunications) fibre optic cable was used as a sensor, which allows a high spatial resolution in the metre range. This also made it possible to measure the eruption of Mount Etna in October 2021. (Photo: P. Jousset)
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The outermost solid shell of the Earth, the Earth’s crust, is regarded by human beings as their foundation. To understand and survey this anthroposphere, as well as to make predictions about its evolution and use is the task of near-surface and applied geophysics. In doing so, it is equally important to understand the global processes of plate tectonics and what drives geodynamics, as well as it is to study small-scale phenomena that, for instance, may influence the decision how to utilize the subsurface (e.g., exploration, water, infrastructure). Equally, imaging, quantification, and assessment of geohazards at an early stage (e.g., mass movements, sinkholes, environmental changes) are challenging, the more if they occur in urban areas.

In order to explore the subsurface we apply various geophysical methods which are sensitive for different physical properties. In four working groups we concentrate on seismic and electromagnetic methods. In field experiments and on the computer - and supported by innovative developments of measuring instruments - these methods are further developed. With the help of simulations these methods are used for predictions of the subsurface structure of the subsurface and the involved processes.

Our aims and tasks

  • Carry out basic and applied research as entity.
  • Foster prediction capabilities with non-invasive measurements. Enhance exploration and monitoring for and during subsurface use.
  • Aid assessment of natural hazards and georesources.
  • Develop quantitative methods especially for urban areas and related to hazards.
  • Provision of large infrastructure for the geo-community

Research Topics in our Section

Title of the working group: Geophysical Instrument Pool Potsdam
Working group leader: Dr. Christian Haberland    Prof. Dr. Oliver Ritter

Projects of the working group:

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Title of the working group: Seismics
Working group leader: Dr. Klaus Bauer    Dr. Stefan Lüth

Projects of the working group:

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Title of the working group: Distributed Acoustic Sensing
Working group leader: Prof. Dr. Charlotte Krawczyk    Dr. Verónica Rodriguez Tribaldos

Projects of the working group:

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Title of the working group: Elektromagnetics | Magnetotellurics
Working group leader: PD Dr. Ute Weckmann    Prof. Dr. Oliver Ritter  

Projects of the working group:

Title of the Young Investigators Group: Helmholtz Young Investigators
Working group leader: Dr. Verónica Rodríguez Tribaldos
Researchers involved: Dr. Laura Pinzon Rincon 

Projects of the working group:

Prices and Accolades

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