Gaseous planets close to their star could see their hydrogen atmospheres evaporate, leaving behind helium that could be detected by the James Webb Space Telescope.
Is it a choice before a choice?#freewill #neuroscience #consciousness #documentary #documentaryfilm
A ring looping around the icy dwarf planet Quaoar is located much farther from its parent body than scientists thought was possible.
Dramatic advances in quantum computing, smartphones that only need to be charged once a month, trains that levitate and move at superfast speeds. Technological leaps like these could revolutionize society, but they remain largely out of reach as long as superconductivity—the flow of electricity without resistance or energy waste—isn’t fully understood.
One of the major limitations for real-world applications of this technology is that the materials that make superconducting possible typically need to be at extremely cold temperatures to reach that level of electrical efficiency. To get around this limit, researchers need to build a clear picture of what different superconducting materials look like at the atomic scale as they transition through different states of matter to become superconductors.
Scholars in a Brown University lab, working with an international team of scientists, have moved a small step closer to cracking this mystery for a recently discovered family of superconducting Kagome metals. In a new study, they used an innovative new strategy combining nuclear magnetic resonance imaging and a quantum modeling theory to describe the microscopic structure of this superconductor at 103 degrees Kelvin, which is equivalent to about 275 degrees below 0 degrees Fahrenheit.
Top 10 upcoming future technologies | trending technologies | 10 upcoming tech.
Future technologies are currently developing at an acclerated rate. Future technology ideas are being converted into real life at a very fast pace.
These Innovative techs will address global challenges and at the same time will make life simple on this planet. Let’s get started and have a look at the top technologies of the future | Emerging technologies.
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Artificial Superintelligence or short, ASI, also known as digital superintelligence is the advent of a hypothetical agent that possesses intelligence far surpassing that of the smartest and most gifted human minds.
If we as a species manage not to destroy ourselves up until the advent of true artificial general intelligence, the moment of the next phase for our survival in a post AGI world, will be even more paramount.
The consensus among AI experts is that the time it takes to go from AGI or artificial general intelligence to ASI or artificial superintelligence, is exceptionally shorter than the time it takes to achieve AGI from current narrow artificial intelligence systems.
So we really have only one try to make it right.
Have you ever thought about what the world will look like in the future? and the type of technology that we will have? The technology that’s created is very fascinating. Comment your thought on this and please share.
If you like this video check out.
👉 Have They Discovered Earth 2?
https://youtu.be/gZMaGB8PSZw.
👉 What Will 2030 Look Like? ***Amazing***
Discover how a binary pair of T Tauri stars created a giant bubble in the Barnard 18 molecular cloud. Learn about the significant impact of these young stars on their surroundings, read on now!
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Hyperbole aside, we have only scratched the surface of what the new technology may eventually become. ChatGPT has the markings of artificial narrow intelligence (ANI). That is, AI that is designed to perform specific tasks.
The first signs of life emerged on Earth in the form of microbes about four billion years ago. While scientists are still determining exactly when and how these microbes appeared, it’s clear that the emergence of life is intricately intertwined with the chemical and physical characteristics of early Earth.
“It is reasonable to suspect that life could have started differently—or not at all—if the early chemical characteristics of our planet were different,” says Dustin Trail, an associate professor of earth and environmental sciences at the University of Rochester.
But what was Earth like billions of years ago, and what characteristics may have helped life to form? In a paper published in Science, Trail and Thomas McCollom, a research associate at the University of Colorado Boulder, reveal key information in the quest to find out. The research has important implications not only for discovering the origins of life but also in the search for life on other planets.