Latest news with #WeizhengFu
Time of India
2 days ago
- Health
- Time of India
Japanese study unveils how earthquakes quietly disrupt satellites and communications
Source: Reuters While earthquakes have been traditionally linked to surface-level destruction, new findings show that their effect goes far beyond the crust of the Earth reaching into the upper atmosphere and even interfering with space-based technologies. In a pioneering piece of research, scientists from Nagoya University have been able to develop the first-ever 3D visualisation of atmospheric disturbances in the ionosphere resulting from a significant earthquake. With data from Japan's extensive network of more than 4,500 Global Navigation Satellite System (GNSS) receivers, the scientists charted the ripple of the 7.5-magnitude Noto Peninsula Earthquake on January 1, 2024. What they found, reported in the journal Earth, Planets and Space , not only deepens the knowledge of earthquakes travelling through the atmosphere but also poses serious issues of satellite vulnerability and communication. 3D imaging reveals how earthquakes disrupt the ionosphere The ionosphere is a highly charged atmosphere of Earth between 60 and 1,000 kilometres high that plays a critical role in global communications by bending and slowing down radio waves from satellites. Earthquakes, as it happens, can perturb this sensitive layer by creating acoustic waves that propagate upward from the surface. To observe these disturbances, scientists tracked delays in GNSS satellite signals induced by changes in the electron density of the ionosphere. By using tomography methods, as in medical CT scans, they imaged the dynamic 3D behaviour of the ionosphere in response to the seismic shockwaves. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like Giao dịch CFD với công nghệ và tốc độ tốt hơn IC Markets Đăng ký Undo About ten minutes following the earthquake, wave-like ripples that are similar to those patterns created in concentric circles when a stone is thrown into water started to emanate in the ionosphere. These ripples, also referred to as seismo-ionospheric perturbations, showed unexpected tilts in their structures that were not included in previous models. New insights reveal earthquakes don't emit waves from a single source Earlier science reference models had long considered that the waves created by a quake have a single point source. The 3D visualizations presented in this study told a different story. The waves were not coming from one but rather from several rupture points along a 150-kilometre fault. Dr. Weizheng Fu, lead author, said earthquakes release energy not from a point source but evolve gradually along fault lines. The researchers' new model took this dynamic rupture process into account by modeling wave emissions from sections of the fault in time intervals of some 30 seconds. This new method successfully replicated the angled sound wave patterns observed in the ionosphere. This change in comprehension greatly enhances our potential to forecast and make sense of the atmospheric influence of immense seismic occurrences. Study warns of seismic effects on navigation and communication tools The potential of this research extends far beyond scientific understanding. Ionospheric disturbances have the potential to degrade the precision of GPS systems, to slow down satellite communications, and to affect navigation tools—concerns which are of the utmost importance during disaster relief and aviation. Co-author Professor Yuichi Otsuka highlighted the wider technological significance of the research. "By knowing how these waves are created and how they change, we can start to predict and buffer risks in communication systems before and after earthquakes," he explained. In addition to increasing technological resilience, the research also opens the door to better earthquake early warning systems . Historically dependent on ground-based sensors, the systems could be greatly enhanced by the inclusion of atmospheric data, specifically patterns seen in the ionosphere. Also Read | Strawberry Moon 2025: June's full moon to light up the sky this month- know date, time, and the science behind the name
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Business Standard
4 days ago
- Science
- Business Standard
Shockwaves in space: Earthquakes found to shake up satellite signals
When the Earth shakes, the impact doesn't stop at the surface. New research reveals that powerful earthquakes can send shockwaves all the way into space, disrupting satellite signals and GPS systems by disturbing the charged upper layers of our atmosphere. Scientists from Nagoya University in Japan have made the first 3D visualisation of how the atmosphere reacted to a powerful 7.5-magnitude earthquake that hit the Noto Peninsula on 1 January 2024. They used data from over 4,500 Global Navigation Satellite System (GNSS) receivers across Japan. Their research, published in the journal Earth, Planets and Space, shows how earthquakes can send complex sound waves into the upper atmosphere, disturbing a layer called the ionosphere. These disturbances can affect satellite communications and GPS signals, and challenge what scientists previously believed about how these waves travel. What is the Ionosphere, and why does it matter? The ionosphere is a part of the atmosphere that lies 60 to 1,000 kilometres above the Earth. It's filled with charged particles and plays an important role in sending radio signals from satellites to the ground. When the earthquake happened, it created sound waves that travelled upward into the ionosphere. These waves changed the amount of charged particles, which slowed down satellite signals. By measuring the delays in these signals, the researchers were able to calculate these changes and use a technique similar to a medical CT scan to build 3D images of the disturbances. Surprising patterns in the sky About 10 minutes after the earthquake, wave-like ripples appeared in the ionosphere, similar to the way water ripples after a stone is dropped in a pond. However, the team noticed something unusual – some of the waves tilted in a strange direction, south of the earthquake's epicentre, and slowly straightened out as they rose higher. Old models, which assumed that these waves came from a single point, couldn't explain this pattern. The breakthrough came when the scientists considered that the earthquake didn't rupture in one spot, but along a 150-kilometre fault line. Dr Weizheng Fu, the lead author, said, 'Earthquakes don't rupture at one point, but spread along faults.' Their updated model showed that the sound waves were created at different places along the fault, around 30 seconds apart. This matched what they observed in the sky. Why does this matter for technology and safety? These atmospheric changes can interfere with GPS systems and satellite signals, which are used in everything from smartphones to aeroplanes. Co-author Professor Yuichi Otsuka said, 'Understanding these patterns can help reduce the risk of technology failures during earthquakes.' The research could also help improve earthquake early warning systems. By watching for these atmospheric waves as well as ground movements, scientists may be able to give faster and more accurate alerts. Looking ahead: Applying the model to other natural disasters The team now plans to use this method to study how volcanic eruptions, tsunamis, and severe weather affect the ionosphere. This could improve how we prepare for disasters and monitor them in real time. By studying how earthquakes leave their mark in the sky, this research helps protect important systems and gives us a better understanding of how Earth and space are connected.
India Today
4 days ago
- Science
- India Today
Japanese scientists reveal how earthquakes can disrupt satellites in space
Earthquakes, the ripples beneath the planet from collision of tectonic plates, not only damages assets on the surface but also above the planet in University scientists, using Japan's dense network of over 4,500 Global Navigation Satellite System (GNSS) receivers, have produced the first 3D visualisation of atmospheric disturbances triggered by the 7.5-magnitude Noto Peninsula Earthquake on January 1, in Earth, Planets and Space, their study unveils how seismic activity generates complex sound waves in the ionosphere, disrupting satellite communications and challenging prior scientific Ionospheric Turbulence The ionosphere, a charged atmospheric layer 60–1,000 km above Earth, slows radio waves from analysing signal delays, the team calculated electron density changes caused by upward-travelling sound waves from the quake. Using tomography—akin to medical CT scans—they combined multi-angle satellite data to build dynamic 3D models of these 10 minutes post-quake, ripples resembling 'pond waves' emerged in the ionosphere. The 3D images revealed a key anomaly: tilted sound wave patterns south of the epicenter that gradually straightened vertically. The findings also offer clues for improving earthquake early warning systems. (Photo: Getty) advertisementTraditional models, assuming waves originate from a single point, failed to explain this breakthrough came when researchers incorporated multiple wave sources along the 150-km fault line. 'Earthquakes don't rupture at one spot but propagate across faults,' explained lead author Dr. Weizheng Fu. Their revised model showed waves generated 30 seconds apart from different fault sections, aligning with observed tilted disturbances can degrade GPS accuracy and satellite communications. 'Understanding these patterns helps mitigate tech vulnerabilities during quakes,' said Professor Yuichi Otsuka, findings also offer clues for improving earthquake early warning systems by tracking atmospheric waves alongside ground team plans to apply their model to study ionospheric impacts of volcanic eruptions, tsunamis, and extreme weather. This approach could enhance disaster preparedness and real-time monitoring, bridging Earth's surface and space-based unraveling the ionosphere's seismic fingerprints, this research marks a leap toward safeguarding critical infrastructure while deepening our grasp of Earth's interconnected Watch
