Australia may be far from the world’s seismic hotspots, but a team from the ARC Centre of Excellence for Gravitational Wave Discovery (OzGrav) at the Australian National University (ANU) is leading a breakthrough that could transform how earthquakes and tsunamis are detected worldwide. With $671,000 in new funding from the Australian Research Council’s (ARC) Discovery Projects (DP) scheme, Professor Bram Slagmolen and colleagues are developing technology capable of detecting earthquakes almost as soon as they happen at the speed of light.

When earthquakes strike, devastation can unfold in minutes or even seconds. Current early warning systems, such as those in Japan, rely on networks of seismometers to detect seismic waves. While effective, these systems can only provide limited notice, as seismic waves travel comparatively slowly through the Earth.

Professor Slagmolen explained the stakes “Our work focuses on creating early warning systems that could provide precious seconds for earthquakes and valuable minutes for tsunamis, allowing more time to safeguard lives, halt hazardous activities, and protect vital infrastructure such as power stations and gas pipelines.”

Those seconds matter. Extra lead time could allow high-speed trains to decelerate safely, surgeons to pause delicate procedures, or operators to shut down power grids in controlled ways. For tsunamis, additional minutes could mean entire coastal communities have time to evacuate.

So how does it work? The key lies in detecting prompt elasto-gravity signals, tiny changes in gravity generated the instant a fault ruptures in the Earth. Unlike seismic waves, which move at the speed of sound in rock, gravitational changes propagate at the speed of light.

Professor Robert Ward, OzGrav node leader at ANU, likens it to watching someone swing an axe across a field: you see the movement instantly, but the sound of the strike takes seconds to reach you. The gravitational “signal” arrives first, and with the right sensors, it can be measured before the destructive shaking begins. “Much of this system has been designed and fabricated here at ANU, it’s a huge engineering effort, and now we’re entering the phase of commissioning and testing.”

The team has already built and tested a prototype sensor. Now, they are installing it on a sophisticated seismic isolation platform, similar to those used in gravitational-wave observatories like Virgo in Italy and KAGRA in Japan, to filter out local vibrations and allow the sensor to focus only on gravitational changes.

Although Australia is not earthquake-prone, its scientists are global leaders in gravitational-wave detection, a field that requires ultra-sensitive instruments capable of measuring minuscule distortions in space-time. That expertise provides a unique advantage for tackling the challenge of gravitational earthquake detection.

“Australia may not experience major earthquakes, but we have world-class expertise in gravitational-wave detection, and that makes us uniquely placed to lead this research,” said Ward.

International collaboration is essential to the project’s success. Researchers in Japan and Switzerland are already testing smaller-scale versions of the sensor for both earthquake research and fundamental physics experiments. These partnerships ensure that the technology is not only refined in Australia but also tested in regions where earthquakes are more frequent, accelerating its path toward real-world deployment.

The coming years will focus on commissioning the upgraded sensor system and validating its performance. If successful, the technology could become an integral part of next-generation early warning systems, providing unprecedented speed and reliability.

For Ward, the ultimate goal is clear: “Ultimately, this technology could help solve a global problem: giving communities precious time to prepare before an earthquake or tsunami strikes.”

By uniting physics, engineering, and international cooperation, the ANU-led team is charting a path toward safer, more resilient societies. Their work demonstrates the power of fundamental research to address urgent global challenges.