The Cyborg jellyfish article should research deep sea-against climate change first appeared at the online magazine Basic Thinking. You can start the day well every morning via our newsletter update.
US researchers have created cyborg jellyfish by equipping moon jellyfish with microelectronics to better understand the deep sea. The hope: findings that help in the fight against climate change.
Scientists have created “cyborg” jellyfish to explore the depths of the oceans. Equipped with tiny microelectronics, these bio-hybrid creatures are said to Researchers at the University of Colorado in Boulder (Cu Boulder) Developed, important data about climate change.
This research is of great importance, since climate change heats the oceans and increases the acidity due to the absorption of carbon monoxide from the atmosphere, which in turn endangers different sea creatures.
Reaching the deepest parts of the oceans is a challenge and requires expensive equipment. However, jellyfish can naturally penetrate these depths, which makes them an ally for research. Therefore, the Cu bouldering team examined the moon jellyfish biomechanics to improve their organic hybrid creations.
Cyborg jellyfish against climate change
In order to create the cyborg jellyfish, engineer Nicole Wu developed a system that resembles a pacemaker. The microelectronics stimulate the swimming muscles of the jellyfish, causing them to contract and steer the jellyfish in a desired direction.
Moon jellies have no brain or spinal cord, but they have a primitive, overlapping nerve network that is well suited for WUS purposes. The researcher describes the jellyfish as the most energy -efficient animals on the planet. She hopes to decipher this efficiency to create the next generation of underwater vehicles.
In order to understand better, how jellyfish swimming, the researchers use the so-called particle-picture velocimetry (PIV). This technique pursues tiny tracer particles floating in the water by illuminating it with laser light.
Traditionally, these particles consist of synthetic materials such as hollow glass balls or polystyrene balls. However, these materials can be expensive. The costs are around 379.42 euros per kilogram. At the same time, they cover health and environmental risks.
A greener path to research the sea currents?
In search of a more sustainable solution, WU and her team decided to examine different types of strengths, including corn and arrow root strength, as biodegradable tracer particles. These options are easily available, inexpensive (sometimes only 3.80 euros per kilogram) and do not harm the environment.
After tests of different strengths, they found that cornstarch and arrow rooting strength seem best suitable for PIV applications. They could visualize the water currents created by the floating jellyfish as well as synthetic particles.
This success is a big step for marine research. The goal is a safer and more affordable way to investigate the biomechanics of sea life without damaging the environment. By using the natural efficiency of jellyfish and the development of sustainable research tools, scientists could monitor changes in the oceans more effectively and thus contribute to the protection of the underwater world.
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The Cyborg jellyfish article should research deep sea-against climate change, first appeared on Basic Thinking. Follow us too Google News and Flipboard Or subscribe to our update newsletter.
As a Tech Industry expert, I believe that the idea of using cyborg jellyfish for deep sea research against climate change is a fascinating and innovative approach. Jellyfish are already well-adapted to marine environments, and by enhancing them with technology, we can potentially gather valuable data and insights from the depths of the ocean that were previously inaccessible.
By equipping jellyfish with sensors and other monitoring devices, researchers can track changes in ocean temperatures, acidity levels, and other key indicators of climate change. This data can help us better understand the impact of human activities on marine ecosystems and inform conservation efforts.
Furthermore, the use of cyborg jellyfish can also enable researchers to explore and study remote and hazardous deep-sea environments with greater precision and efficiency. This could lead to groundbreaking discoveries and advancements in ocean science and technology.
Overall, I believe that the development and deployment of cyborg jellyfish for deep sea research against climate change have the potential to revolutionize our understanding of the oceans and play a crucial role in addressing the challenges of climate change. It is an exciting and promising avenue that should be further explored and supported by the tech industry.
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