I love that science has been branching out into these niche material science properties that we are now learning about. Nature is absolutely amazing and In a way, nature gives motivation. Just like how dark humor can be therapeutic for a individual; it can motivate you to attempt to look at things & try to find a new perspective/approach to solve a problem. The best inventors, philosophers, artists seem to be able to be comfortable with facing things and learning to harness the ability of how you observe things as a tool and through perspective experimenting, you can sometimes stumble upon new methods/manner's on how to solve problems in ways that others didn't notice/see/or understand. (Just like how Einstein had the ability to get lost in hypothetical thought and imagine different perspectives and then it stumbled upon his path towards learning about light/energy/physics etc.) That came from Einstein taking a category that previously was in a state of limbo, but he was willing to look at it and see if he could find anything else out about it. So if we ever get demotivated, remember that even things we think we fully understand; have the total possibility that we can look at it/observe it in a new light that others haven't and totally find a new layer of complexity or depth to a topic. So even if we are faced with a lot of difficult situations, roadblock's, the best thing is the universe is full of amazing intracity so the chance of further understanding the world around us is profoundly possible and to me that's very motivational and Nature itself some how seems to have a way of always keeping that inner child like curiosity alive with-in my Life.
I know it's a bit late, and that it wasn't exactly the purpose of the video, but I'd like to know more about the potential theoretical applications of these additional states of matter. Knowing about states of matter is cool, but applying them, even in theory, is better.... And it would help me wrap my mind around the concept of what these other states are. Just a thought.
I don't think we really have an application in mind for these potential states of matter. They seem too extreme to be reproduced. But we never know. We might understand something in the process that unlocks potential technologies that we can't even think of right now. I think that is the exciting part about fundamental research, we don't know what we will find.
I do know supercritical fluids are actually relatively common at an industrial level, supercritical CO2 is also used in the production of aerogel. And those legitimate hoverboard that floated around the internet a while back did use superconductors, which is why you needed liquid nitrogen to power them, and there are other uses for those iirc. But for the rest, idk.
The PARTICLE TRAIN! Previously I suggested that eternal photons made electron positron pairs, (as well as all standard model particles). Here's how. Start with a PARTICLE TRAIN, each time you add an electron or positron car to the train, you get a new particle. The only rule is the cars have to alternate from electron to positron. Think of a wave with trough always alternating with crest. Photons as electron positron pairs could make the main parts of an atom in the brief time after the Big Bang under those extreme and never repeated conditions. Charges are the cars on our particle train. Positive positron (+), Negative electron (-). Positron (+) Electron (-) Photon (+) (-) Proton (+) (-) (+) Anti Proton (-) (+) (-) Neutron (+) (-) (+) (-) Anti Neutron (-) (+) (-)(+) . The PROTONS and NEUTRONS are made from ELECTRONS and POSITRONS! When this production of particles was over, most anti particles with charge; positrons, and anti protons, didn't exist on their own. They were LOCKED INTO PROTONS OR NEUTRONS. That way conservation of charge was maintained. That also explains the MISSING ANTI MATTER PROBLEM! This from Wikipedia article Matter Creation: It is possible to create all fundamental particles in the standard model, including quarks, leptons and bosons using photons of varying energies above some minimum threshold, whether directly (by pair production), or by decay of the intermediate particle (such as a W− boson decaying to form an electron and an electron-antineutrino).
There are actually a few different states of matter that I didn't mention that may exist in neutron stars. I left them out at I am not sure how much direct evidence we have for them at the moment. But surely some of the proposed states do exist.
Just as absolute zero can not be reached because of the uncertainty principle, there can not be an absolutely 100% pure neutron star. It seems its the uncertainty principle that gives rise to infinite possibilities.
19th state of matter dark matter is a state of matter a molecule can copy paste itself as long as energy enters its system in this case water, during the process the mass increases I donot know why. Pretty amazing .
I have seen so many videos explaining concepts I physics and I have never understood jack shit until I stumbled upon your channel. Thank you for making such easy to understand content!!! :D
scientists love the word super XD
haha we sure do.
This settled some curiosities I've had about matter, great vid!
Glad you enjoyed it.
Really well made and interesting video, as always :)
Cheers mate. Glad you enjoyed it.
I love that science has been branching out into these niche material science properties that we are now learning about. Nature is absolutely amazing and In a way, nature gives motivation. Just like how dark humor can be therapeutic for a individual; it can motivate you to attempt to look at things & try to find a new perspective/approach to solve a problem. The best inventors, philosophers, artists seem to be able to be comfortable with facing things and learning to harness the ability of how you observe things as a tool and through perspective experimenting, you can sometimes stumble upon new methods/manner's on how to solve problems in ways that others didn't notice/see/or understand. (Just like how Einstein had the ability to get lost in hypothetical thought and imagine different perspectives and then it stumbled upon his path towards learning about light/energy/physics etc.)
That came from Einstein taking a category that previously was in a state of limbo, but he was willing to look at it and see if he could find anything else out about it.
So if we ever get demotivated, remember that even things we think we fully understand; have the total possibility that we can look at it/observe it in a new light that others haven't and totally find a new layer of complexity or depth to a topic. So even if we are faced with a lot of difficult situations, roadblock's, the best thing is the universe is full of amazing intracity so the chance of further understanding the world around us is profoundly possible and to me that's very motivational and Nature itself some how seems to have a way of always keeping that inner child like curiosity alive with-in my Life.
I know it's a bit late, and that it wasn't exactly the purpose of the video, but I'd like to know more about the potential theoretical applications of these additional states of matter. Knowing about states of matter is cool, but applying them, even in theory, is better.... And it would help me wrap my mind around the concept of what these other states are. Just a thought.
I don't think we really have an application in mind for these potential states of matter. They seem too extreme to be reproduced. But we never know. We might understand something in the process that unlocks potential technologies that we can't even think of right now. I think that is the exciting part about fundamental research, we don't know what we will find.
I do know supercritical fluids are actually relatively common at an industrial level, supercritical CO2 is also used in the production of aerogel. And those legitimate hoverboard that floated around the internet a while back did use superconductors, which is why you needed liquid nitrogen to power them, and there are other uses for those iirc. But for the rest, idk.
The PARTICLE TRAIN! Previously I suggested that eternal photons made electron positron pairs,
(as well as all standard model particles). Here's how.
Start with a PARTICLE TRAIN, each time you add an electron or positron car to the train, you get a new particle.
The only rule is the cars have to alternate from electron to positron. Think of a wave with trough always alternating with crest.
Photons as electron positron pairs could make the main parts of an atom in the brief time after the Big Bang under those extreme and never repeated conditions.
Charges are the cars on our particle train.
Positive positron (+),
Negative electron (-).
Positron (+)
Electron (-)
Photon (+) (-)
Proton (+) (-) (+) Anti Proton (-) (+) (-)
Neutron (+) (-) (+) (-) Anti Neutron (-) (+) (-)(+) .
The PROTONS and NEUTRONS are made from
ELECTRONS and POSITRONS!
When this production of particles was over, most anti particles with charge; positrons, and anti protons, didn't exist on their own. They were LOCKED INTO PROTONS OR NEUTRONS. That way conservation of charge was maintained. That also explains the MISSING ANTI MATTER PROBLEM!
This from Wikipedia article Matter Creation:
It is possible to create all fundamental particles in the standard model, including quarks, leptons and bosons using photons of varying energies above some minimum threshold, whether directly (by pair production), or by decay of the intermediate particle (such as a W− boson decaying to form an electron and an electron-antineutrino).
Please stop using meth.
I enjoyed this video very much, thank you.
Glad you enjoyed it
Interesting. One question: have all described states actually been observed or are some of them only theoretical?
Why are you showing helium 3 nuclei as cooper pairs were they not electrons pairs !!! @ 10:36
More please! and thank you.
Surely a Neutron Star is made up of stripped Protons and Neutrons which is a distinct state of matter?
There are actually a few different states of matter that I didn't mention that may exist in neutron stars. I left them out at I am not sure how much direct evidence we have for them at the moment. But surely some of the proposed states do exist.
Just as absolute zero can not be reached because of the uncertainty principle, there can not be an absolutely 100% pure neutron star.
It seems its the uncertainty principle that gives rise to infinite possibilities.
It's so-called degenerate matter
states of matter in a neutron star:
th-cam.com/video/1Ou1MckZHTA/w-d-xo.html
19th state of matter dark matter is a state of matter a molecule can copy paste itself as long as energy enters its system in this case water, during the process the mass increases I donot know why. Pretty amazing .
I have seen so many videos explaining concepts I physics and I have never understood jack shit until I stumbled upon your channel. Thank you for making such easy to understand content!!! :D
I am glad you found the video useful. It is pretty hard to make these things understandable, so I try my best.
@@ScienceDiscussed it literally is the best !!
At this point, who cares? Make it 20 states of matter or 100.
Give every under grad a matter state for that matter.