Deep-sea trenches, like the Mariana Trench, are some of the most extreme environments on Earth. We know a lot about the immense pressure and darkness down there, but much remains a mystery. What are some of the recent advancements in ...
Components & Working: A Tsunami Warning Centre operating on 24x7 basis. A network of land-based seismic stations for earthquake detection. A network of 12 Bottom Pressure Recorders (that could detect and measure a change in water level of 1 cm at water depths of up to 6 km of water). A network oRead more
Components & Working:
A Tsunami Warning Centre operating on 24×7 basis.
A network of land-based seismic stations for earthquake detection.
A network of 12 Bottom Pressure Recorders (that could detect and measure a change in water level of 1 cm at water depths of up to 6 km of water).
A network of tsunami buoy system it measures the change in height of the water column then this water column height is communicated and then relayed via satellite to the tsunami warning center.
Real-time observational network for upper ocean parameters and surface met-ocean parameters.
A network of 50 real time tide gauges, radar- based coastal monitoring stations and current meter moorings to monitor progress of tsunami and storm surges .
The EWS receives real-time Seismic data from the National Seismic Network the system detects all earthquake events of more than 6 Magnitude occurring in the Ocean . BPRs installed in the Deep Ocean and Buoys are the key sensors to confirm the triggering of Tsunami through INSAT end-to-end communication takes place and disseminate alerts to MHA by satellite- based virtual private network (VPN DMS). This network enables early warning center to disseminate warnings to the MHA, as well as to the State Emergency Operations Centers.
Recent advances in oceanographic equipment have significantly increased our understanding of deep-sea trench biology. Autonomous Underwater Vehicles (AUVs), such as the "ABYSS," are essential for this research. These robotic submarines can dive to great depths, navigate intricate underwater terrain,Read more
Recent advances in oceanographic equipment have significantly increased our understanding of deep-sea trench biology. Autonomous Underwater Vehicles (AUVs), such as the “ABYSS,” are essential for this research. These robotic submarines can dive to great depths, navigate intricate underwater terrain, and collect data autonomously over lengthy periods of time. They create accurate maps of the seafloor and gather samples from previously inaccessible areas, offering fresh information about these fascinating habitats. Remotely operated vehicles (ROVs) are also required for deep-sea exploration. These tethered robots, which are operated from the surface, are outfitted with high-definition cameras, manipulator arms, and a variety of sensors. ROVs, like the “Deep Discoverer,” have explored the Mariana Trench, recording amazing photographs and films while also gathering biological and geological samples.
This hands-on experience with the deep-sea environment allows scientists to investigate life forms and ecosystems directly, resulting in the discovery of new species and a greater knowledge of how life adapts to such harsh conditions.
Furthermore, new sensor technologies, such as chemical and biological sensors, have increased our capacity to monitor environmental conditions and identify indications of life. These technology advances are providing new insights into the biodiversity and biological dynamics of deep-sea trenches.
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