Scientists are using laser-based tracking and gravity data to improve how we monitor both satellites and space debris. By blending these methods, they can now predict orbits more precisely and gather insights on Earth’s gravity and water masses.

How are the Earth’s gravitational field and the paths of satellites and space debris connected? Earth’s gravitational field shapes the orbits of satellites and debris, and shifts in these orbits can reveal changes in the gravitational field, which also offers insights into water mass distribution on Earth.

In the COVER project, researchers at TU Graz’s Institute of Geodesy have enhanced gravity field calculations by combining satellite gravity measurements with satellite laser ranging (SLR). This approach not only improves gravity field models but also refines tracking and predictions for objects in orbit. These advancements are now available in the Gravity Recovery Object-Oriented Programming System (GROOPS) software—an open-source tool the Institute provides on GitHub.

Data from space shows water tilting up toward the north side of the Dickson Fjord as it sloshed from south to north and back every 90 seconds for nine days after a 2023 rockslide.

The international Surface Water and Ocean Topography (SWOT) satellite mission, a collaboration between NASA and France’s CNES (Centre National d’Études Spatiales), detected the unique contours of a tsunami that sloshed within the steep walls of a fjord in Greenland in September 2023. Triggered by a massive rockslide, the tsunami generated a seismic rumble that reverberated around the world for nine days. An international research team that included seismologists, geophysicists, and oceanographers recently reported on the event after a year of analyzing data.

The SWOT satellite collected water elevation measurements in Dickson Fjord on Sept. 17, 2023, the day after the initial rockslide and tsunami. The data was compared with measurements made under normal conditions a few weeks prior, on Aug. 6, 2023.