Gadgetory

how do you measure something that's really really small well first you might try a measuring tape then calipers and if you've got a big budget you might treat yourself to a scanning electron microscope but there is one very clear problem with all of those solutions a they're too small and B they don't use lasers at Lago they had the right idea so by shooting a laser for kilometres down this tube they're able to get an accuracy of one ten thousandth the charge diameter of proton that's like measuring from here to the closest star with the accuracy of a hair which I don't know I still don't have context for that but it got them the Nobel Prize for Physics and they were the first ones to get gravitational waves detected so awesome glass wire lets you instantly see your current and past network activity you can detect malware and block badly behaving apps on your PC and Android device and you can use offer code Lynas to get 25% off glass wire at the link below gravitational waves happen all the time every time the mass accelerates waves ripple through space-time so like I'm actually waving space-time right now but it only really becomes noticeable when crazy massive things start accelerating like black holes colliding when Einstein first predicted gravitational waves in 1916 he thought they were a problem with his algebra and then later when he believed that they were real he figured it would still be impossible to detect them but of course that hasn't stopped people from trying in the 50s Josef Weber first tried to detect gravitational waves using the 6000 pound chunk of aluminum the idea is that it would resonate when gravitational waves went through it and that we picked up by these piezoelectric crystals on the top unfortunately it just wasn't possible to get the precision needed in 1972 though ray vise wrote a paper detailing just how an interferometer could be used to detect gravitational waves basically he wrote a laser beam could go through a beam splitter and then down to four kilometer long tubes at the end of each of these tubes would be a mirror that sends the beam back where it would be recombined by the beam splitter and then measured normally when recombined in this manner the two beams would destructively interfere but if a gravitational wave were to pass through the detector it should physically distort space and time causing the length of the two arms to vary slightly change compared to each other this would change the interference of the two beams ultimately changing the signal on the photo detector at the end in 2002 then Caltech and MIT joined forces to create I'll ago a proof that this could work and after extensive research and an upgrade to advanced LIGO we were able to successfully detect gravitational waves in 2015 and by we of course I mean humans as a species not me I wasn't involved so behind us is the beam splitter so it comes from the laser room back there which is why we have to have these laser glasses on get split rate around here and then get sent off the arms that way in that way it then travels back in and is detected over there somewhere unsurprisingly taking measurements that precisely in the real world is a lot easier said than done any particles in the air will cause the laser to scatter and although they're only sending in 20 watts of laser power the way it works is to have the beam trapped as a standing wave inside so after 300 bounces or so that amplifies it to about a hundred kilowatts with power like that even a tiny speck of dust on the mirror could absorb enough heat to permanently damage it meaning that the four kilometer tubes or arms have to be under an ultra high vacuum so this is the concrete that goes around the arm it doesn't actually help with the laser - but it's just a protective from like cars animals stray bullets or whatever the real magic though happens in this three millimeter thick stainless steel tube which is hold two one trillionth of an ATM even the vacuum outside the International Space Station can't hold a candle to what they've got going on in here so how did they build it well first they cooked or more accurately baked now if regular stainless steel was used for this hydrogen and other particles on the metal could contaminate the vacuum so to combat this every inside surface needs to be heated to at least 170 degrees Celsius and held there for an extended amount of time now for the nuts and bolts that's pretty simple I mean I could do that with my toaster oven at home but for something this large what they had to do was pump a quadrant of it full of electricity effectively using the resistance of the metal to turn it into a heater and hold it at a hundred and seventy for a month with the vacuum pumps running to remove all the contaminants I guess that's probably why they wouldn't let us inside we are the contaminants so cool now the laser can make its way from one end to the other but what about the mirrors on the end even something as small as a truck on the highway or an earthquake in Taiwan would create too much vibration for gravitational wave detection which I guess is probably why they put their air-conditioner way off away from the building rather than up on top of it like normal people this is one of the mirrors from I'll ago to reduce the high frequency vibrations the mirror is hung like a pendulum by this steel wire and the lower frequency vibrations are decreased by the springs on the lower base but they obviously weren't done there in the newer version the mirror is hung from four pendulums by glass fibers and that is far from the end on the bottom of the table there's actually a seismometer that measures any movement in the ground and then uses that information to manipulate voice coils and static electricity to actively cancel out the vibrations coming from the ground at this point then the mirrors are basically perfectly still but they still aren't done yet for some frequencies their level of accuracy is being determined by quantum mechanics in the Heisenberg uncertainty principle but even this can be reduced using quantum squeezing on a very basic level they can only know so much about the amplitude or phase of the laser light but for this application the amplitude of the light being detected matters a lot less so they're able to perform a quantum squeeze and get better accuracy out of the phase detection so they're using a KTP crystal that is a potassium titanal phosphate crystal and this is able to transform one green photon into two infrared photons or vice-versa energy is conserved here because the infrared light has less energy than the green light so what they do here is pump a crystal full of infrared light this is just to get a lot of green light and high-powered infrared lasers are easier to get and then that green light is sent into another KTP crystal but when those photons are emitted they our quantumly entangled now in a vacuum there naturally exists a lot of noise particularly when there is a very little light like around the dark end of the detector so by injecting these entangled photons they're able to remove the completely random vacuum noise and replace it with the entangled photons that produce noise that they like now you're probably thinking I am - holy sweet crap how could they even verify that these are actually gravitational waves they're detecting and the answer is by building another detector on the other side of the country so that if a gravitational wave is detected they can confirm that it isn't just a localized movement oh and also by using two observatories to try and find where the astronomical event is happening so with the accuracy of the interferometer mostly figured out how the heck do they acquire all the data and process it ah yes my friends we are finally getting to the computery part of the video in here they collect data from two hundred and fifty thousand channels simultaneously and then to isolate the signals being created by the detector from the computers they actually put the noisy bits of the computer CPUs power etc in another room a hundred and fifty feet down the hall and they connect them using fiber-optic PCI Express extenders the most important thing with the computing here though is timing so every processors clock in this server room is synced using a custom-built system since the processors timing has to be precisely known in order to calculate the time of events in the interferometer but it's not just synced in this room there are also computers at the very ends of the laser arms for kilometres away with their clocks perfectly synchronized - and the 22 microsecond transmission time delay taken into account oh and that second gravitational wave Observatory in Louisiana you guessed right the processor clocks are perfectly synchronized they're too once the data is collected it gets sent over to their server warehouse for analysis and very quick analysis is important since if there's a large astronomical event taking place they'll detect it here first and then they need to be able to tell their astronomers where to point the telescopes in a timely manner so all that processing is handled in here where they've got 6,000 processing course 64 GPUs almost 4 terabytes of RAM and close to five and a half petabytes of data stored on SSD spinning and tape storage the data is then copied from here to Caltech servers where it is further analyzed and made available to more scientists and then eventually the armchair physicists at home and they're still not done future plans to improve their accuracy involve using cryogenics to reduce the movement of the molecules on the mirrors detecting changes in the Earth's gravity to remove noise from movement below the earth's crust implementing quantum squeeze that can be changed throughout the frequency band and even building a space-based gravitational wave Observatory the goal is that with every little adjustment they should be able to see even further into space collecting a bit more data about how our universe works so a huge thanks to LIGO and particularly amber Iraq for letting us come and hang out in the observatory and a huge thanks to you guys for watching this video is brought to you by ting ting does rates not plans for your cell phone so you pay just six dollars per phone line plus the minutes messages and data you actually use each month usage gets shared across all your devices so the more phones on one ting account the less you end up paying per phone and with an average bill of just 23 bucks a month per phone ting is the smarter choice for mobile they offer service on two nationwide LTE networks so the phone that you already own will likely work with ting and there are no contracts and no overage fees so you can try ting for a month with no commitments so check out our link below it's Linus 2018 dot ting comm to get $25 off your bill or towards a new device so thanks for watching guys if this video sucker you're a member of the Flat Earth Society you know what to do but if it was awesome yet subscribed hit that like button or check out the link to where to buy the stuff we featured in the video just K yeah right also linked in the description is our merged stores has cool shirts like this one and our community forum which you should totally join