2020's Biggest Breakthroughs in Physics

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Tldr?

๐Ÿ‘๏ธŽ︎ 43 ๐Ÿ‘ค๏ธŽ︎ u/rdubya3387 ๐Ÿ“…๏ธŽ︎ Dec 27 2020 ๐Ÿ—ซ︎ replies

Didnโ€™t someone simulate the inside of a black hole as well?

๐Ÿ‘๏ธŽ︎ 2 ๐Ÿ‘ค๏ธŽ︎ u/msaluta86 ๐Ÿ“…๏ธŽ︎ Dec 28 2020 ๐Ÿ—ซ︎ replies

[removed]

๐Ÿ‘๏ธŽ︎ 7 ๐Ÿ‘ค๏ธŽ︎ u/[deleted] ๐Ÿ“…๏ธŽ︎ Dec 27 2020 ๐Ÿ—ซ︎ replies
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what would happen if you fell into a black hole if you'd asked albert einstein he would have told you that according to his general theory of relativity you'd be sucked into the black hole singularity the point where space-time curves steeply inward and all the laws of physics seem to break down after that nothing can escape in the 1970s stephen hawking took a semi-classical approach to black holes bringing together quantum theory and einstein's relativity he proved that black holes emit a small amount of heat that eventually causes the black hole to evaporate still according to hawking if you fell into a black hole you and your particles would be lost to the universe forever this is don page he was a postdoc with stephen hawking where they became friends despite the fact that they ultimately landed on either side of one of the most controversial debates in modern physics i looked at hawking's argument and became not convinced by it hawking's work implied that black holes violated a central principle of quantum mechanics called unitarity which says that the present always preserves information about the past so how could it be possible that black holes destroy information this became known as the black hole information paradox and for decades it made physicists queasy according to page if you were to fall into a black hole you wouldn't be gone for good particle by particle the information needed to reconstitute your body would re-emerge well it would be highly scrambled by the black hole it'd be much worse than even you know if you just cremated the body and and it turned into smoke and ashes but you know another analogy is if you burn up a book and you have all the ashes the information is still somewhere there is somewhere in the universe we believe the key to understanding why the information is preserved lies in a process called quantum entanglement when black holes emit radiation that radiation maintains a quantum mechanical link to its place of origin if you tried to measure the radiation or the black hole separately the information would look random but when you look at them together they exhibit a pattern you know if somebody took a coin and and and cut it in half and then you sort of shook it up and put it in two envelopes and send it off to two people then of course there would be what we call correlations in it if one person gets a head they know the other person would have tails and this this quantum entanglement is like that except it's an even more subtle this is the page curve which he created to track changes in the entanglement between a black hole and its radiation as it ages the degree to which the information is entangled is called its entanglement entropy at the start of a black hole's life its entanglement entropy is zero since it hasn't emitted any radiation and at the end its entanglement entropy is zero again since the black hole has evaporated but in between as radiation trickles out the entanglement entropy grows page showed that in theory information can escape from a black hole [Music] in a series of groundbreaking papers physicists have shown that the entanglement entropy of black holes really does follow the page curve these calculations give more evidence that indeed the information does come out but the details of how that actually happens and you know still remain to be remain to be understood and it of course it raises the picture that maybe space time itself is not fundamental maybe there's something deeper than space time and maybe the basic quantum description will involve something that's not space and time so i think there'll be parts of the puzzle i think that'll persist for many more decades another puzzle that's baffled the scientific community for decades is super conductivity when various solids are cooled to extremely low temperatures they can conduct electricity without losing energy this happens because the freezing temperature allows electrons to move slowly enough to overcome their natural repulsion with each other and they begin to form pairs like any good couple should they balance each other out and begin to move in the same direction when this happens electrical resistance disappears this is what makes superconductivity the holy grail of energy efficiency if only scientists could overcome the limitations of temperature this is ranga diaz this year he and a team at the university of rochester created a metallic compound that for the first time exhibited superconductivity at room temperature so you have a very small two diamond tips that's sitting opposite to each other and then you uh put your sample that you need to study in between those diamond tips so you can apply force mechanically diaz's team applied pressures almost as extreme as those found at the earth's core they did this by crushing the compound inside a microscopic niche they carved out of a diamond anvil then they triggered chemical reactions with a laser beam so that way we were able to really find the room temperature superconducted you know it's under pressure right what we have found is under pressure so somebody can argue that okay so you went from one extreme to another extreme so so who cares so you know what's a big deal in that sense right uh but i i i think there was a time that we were even the the scientists were thinking that room temperature superconducted is not possible um to be honest in the very first time when i when we saw this one i didn't really believe it and it was like okay this is too good to be true and why we are seeing this nice resistance everybody around the world contact me via email or phone calls and they were very excited and this is a landmark discovery but there are a lot of you know a lot of work to be done because even though we know the initial composition you know what are the material that we put together to pressurize it but we don't know actually what it is really what the sample is superconducting so that those studies need to be done so for now levitating trains lossless power transmission and perfect energy storage are still utopian dreams but diaz believes they're not far off i would say i'm very optimistic probably in the next five years or ten years may be able to get to a real application in 2006 an astronomer detected a brief and extremely powerful radio signal coming from a distant galaxy over the next few years dozens more were observed astronomers traded wild theories trying to explain them this year a fast radio burst was observed again but this time it came within our own galaxy in just a millisecond the source emitted 100 million times more power than the sun brian metzger and his colleagues at columbia university analyzed the data and found the source a magnetar so magnetar is a neutron star so neutron stars form when massive stars die at the end of their lives the core of the star collapses in and forms a neutron star a very compact object about the mass of our sun but the size of new york city and then the outer layers of the star explode as a supernova so so neutron star is what's left over and magnetar is an extreme version of a neutron star with a very strong magnetic field so there was a magnetar in our own galaxy that produced a flare of x-rays and arriving on earth at essentially the same time as the x-rays was a burst of radio emission which if we put it into a different distant galaxy would have looked a lot like a fast radio burst but we were you know identifying that it came from a magnetar within our own galaxy so that's pretty good circumstantial evidence you know that magnetars can produce fast radio bursts that's radio bursts are great because we can see them almost to the edge of the universe and so in addition to actually understanding what's producing them one of the exciting things is we can use them as as probes of the state of matter between us and the and the radio source and so i think that's you know very exciting as we discover more and more fast radio birds um and if it turns out that they that they come from magnetars then we're also probing uh where all the magnetars are in the whole universe which is something we didn't think you know was would have ever been possible you
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Channel: Quanta Magazine
Views: 2,984,173
Rating: 4.9359455 out of 5
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Id: D0-JbxX209g
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Length: 9min 2sec (542 seconds)
Published: Wed Dec 23 2020
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