The eruption also caused a tsunami, which was enhanced by the atmospheric pressure waves of the explosion – a phenomenon known as a meteotsunami. The deformation of the ocean’s surface from these large waves further disturbed the ionosphere. The GDGPS observed ionospheric disturbances caused by the explosion and subsequent meteotsunami in real time. The system monitors the density of electrons in the ionosphere (measured as total electron content units, or TECU) by tracking the delay of global navigation satellite systems (GNSS) signals as they travel through the atmosphere.
GNSS data can serve an important role in contributing to tsunami early warning systems, shaving precious time off tsunami warnings when every second of advanced notice can save lives. The NASA Research Opportunities in Space and Earth Science (ROSES) A.37 project Local Tsunami Early Warning With GNSS Earthquake Source Products, funded by the Applied Sciences Disasters program area, is using this GNSS data to detect ground movement and model earthquake activity that could lead to tsunamis. The team is integrating this data into tsunami early warning systems operated by the National Oceanic and Atmospheric Administration’s Center for Tsunami Research (CTR).
NASA’s Space Geodesy Project also supports tsunami risk reduction through collaborations with the International GNSS Service, which manages the GNSS-enhanced Tsunami Early Warning Systems (GTEWS), the International Association of Geodesy’s Global Geodetic Observing System (GGOS), and the Group on Earth Observations (GEO) Geodesy for the Sendai Framework Community Activity.
In the future, the ionospheric disturbance recorded by the GDGPS could also be integrated into these tsunami warning systems, increasing their effectiveness to warn communities and get people out of harm’s way before tsunami waves strike.