0:02 Uncertainty principle in action!

"Its a mistake to think of the big bang as happening at a specific place, the big bang happened everywhere, its just at the time everywhere was very close together" is a great explanation, I love the way it was phrased.

I love how after Moriarty says sports are bad for you, everyone else says they broke their ligaments.

"Where did my atoms go?" A bit worrisome if you suddenly lose your atoms.

0:20. ok that about sums it up lol

I laughed too hard at "where have my atoms gone?"

I love the amazing consistency with which these physicists answered the questions. Impressive. Most impressive.

I love the expression on their faces when they're talking. It's as if they're truly happy with the profession they've chosen in their lives. And they are so amused to share their fascinating knowledge.

So in Britain it's "maths" and in America it's "math"... but in Britain it's "sport" and in America it's "sports". What are we doing?

"You can't reach absolute zero." "You can't reach absolute zero." "You can't reach absolute zero." "You can't reach absolute zero." OKAY. COULD YOU CRUSH MY DREAMS ANY HARDER?!

Where have my atoms gone ..

Professor Moriarty - do you do sport No all physical exercise is bad for your health xD love it

I love how excited they get when they're asked good questions xD They get all restless in their seat and quite expressive.

This one video explains more about the "cosmic microwave background" and "the big bang" fundamentals than most of all the other videos done interviewing a single person... awesome content here!

I love how enthusiastic these guys are. Every time I need a little faith in humanity restored I watch a few videos from this channel!

I love these videos "where have my atoms gone? so perfect:)

these guys are SO great! :) i wish the videos never ended.

"Where have my atoms gone?" Now THERE'S a physicist who has spent too much time in the chemistry department, experimenting with LSD

Not many videos about astronomy, cosmology, or quantum mechanics impress me but the simplicity of these answers is brilliant. Great questions and wonderfully explained.

4:07 I remember my TV used to do that when I was a kid and I had the antenna. Brings me back. I haven't seen a TV with an antenna in a very long time.

Question: If, during the start of the Big Bang there was extremely heavy concentration of matter and energy in a small space, why did it not turn into a black hole?

"Where have my atoms gone" is a thought provoking insight into the existential dilemma we face every day.

he had a miles davis poster. what a cool dude

beautifully quoted " not only looking out at distances but also back in time"

The big stretch! lol, I can think of a few that would fit that description, not just the BB. Personally, I think what you have stumbled on here is pure genius.

Well this took a turn

4:20 when i learned this in early 60's, you were told to adjust the contrast control tell the field settles down but not empty and then you still see many dots that come and go, that being the background radiation. I was eight or nine at the time...

perpetual motion has been invented its called the Atom.

It's 2021 and this footage is from 2010. The questions in this vid are timeless, 11 years is a faint amount of time but in KZbin time... it's massive. Great upload! Ageing respectably.

There should be a Brady Haran convention, which would get people featured in Sixty Symbols, Numberphile, Nottingham Science etc together to deliver lectures to visitors and meet and greet them and such. That'd be great. :)

"In the history of physics everything, every discovery, was thought to be impossible until somebody did it." Does that help?

If one were to imagine that the electrons were entirely still, what implications would it have on overall molecular structure and position of charges?

I am not a scientist but an avid layman. Are these ideas, movement at absolute zero and Heisenberg uncertainty, the basis of the Bose-Einstein condensate? Since nothing can ever stop an electron other than its annihilation, some other property of electrons is exhibited very near absolute zero? They appear to be cloud-like because there is only a probability and nothing more that a given electron is in a given place at a given time? Do I have at least a not totally embarrassing layman's grasp of it?

6:28 lmao the cuts are hilarious, great editing 😂

70 (km/s)/Mpc, it was first calculated by the Hubble telescope by measuring something called the redshift. The value is ~2.27e-18 hertz which has been calculating by how much the light spectrum of distant stars is being shifted towards the infra-red end of the spectrum.

Black and blue or white and gold? 4:00

"Where did my atoms go?" - Dr. Manhattan

electron uncertainty be like: "Say my name"

3:10 Finally someone explained that in a way I actually understood.

“If the Universe is expanding slower than the speed of light why has not the light from the Big Bang already passed us?” This is the question I have been asking myself for years. Really good explanation!

9 years later I'm still laughing at "where've my atoms gone?!"

Isn't it more accurate to say that electrons don't actually "orbit" a nucleus but rather exist in a standing wave of probability as to their position? The misconception of electrons flying around orbits like little planets is still being foisted on the public by the use of the Bohr model, which is horribly out of date! I see this even in so-called "science" museums, where accuracy is also ignored when the nucleus is shown as a large lump almost as big as the electron cloud instead of as a tiny blip 100,000 times smaller than this cloud. Why is this so hard to correct, I wonder?

Apart from the tedious repetition that "you can't actually get to absolute zero" you seem assume that electrons are distinct particles in orbits rather than say, a wave of an integral number of wave lengths around a nucleus. At the moment we don't seem to have a relationship between temperature and wavelength (they are independent in a vacuum). Unless, the wave (electron) moves to a lower energy state (emitting energy) the electron (wave) would maintain its quantum state. Certainly the Brownian motion would cease at 0 K , and the mechanical motion of the atom would cease, but there is no reason to believe the wave would collapse. I do not recall any results that suggest that, as temperature is lowered, atomic structure changes valence or something of that sort. (Crystalline structures expand/contract somewhat but that is getting mixed up in the piezoelectric effect. Diamond has a coefficient of thermal expansion of 1E-6 / K but is that vibrations in the lattice or size of the atoms? I have not heard any claim that the carbon atoms shrink as the temperature is lowered). Additionally, there is no apparent dependence of Maxwell-Faraday equations on temperature (what is temperature in an absolute void?). Similarly, the photo-electron effect depends on the frequency of radiation and temperature. And of course, temperature is really just a measurement of the kinetic energy of the atom (molecule). Considering just a single atom, the kinetic energy is related to the inertial measurement frame. If we change the reference frame to match the atom, the absolute temperature is exactly zero. No energy is lost, the electron (wave) still continues about the nucleus as usual. This "trick" won't work with a collection of atoms since they are going all different directions. But, individually, each atom maintains its own atomic structure when the collection is cooled to 0K since it doesn't "know" what the other atoms are doing. (Unless you can show some kind of thermal entanglement phenomena!) To the editors at sixty symbols: you really needn't be so condescending. The You-tube viewers might not be as unlearned as you think.

What you are looking for is kinectic energy: K=mc^2(gamma-1) gamma=1/(sqrt(1 - (v^2/c^2)) Although this formula only applies to velocities greater than 0,1c because if aplied to cosmic matter(objects moving in space) because of gamma - the relativistic constant and gamma is used the see the correlation between time observed by us because objects faster than 0,1c suffer time contraction and its also used calculate time,energy in a moving referencial from a static referencial(e.g. The earth)

Can you make nice detailed video on PN junction?

moriarty is my spirit animal

Who are these people? They answer so brilliantly!

If you misplaced you atoms, is that like loosing your marbles? :-P

Great to see consistency between answers haha

Momentum is related to energy. Photons have momentum given by planck's constant divided by the photon's wavelength, or the photon's energy divided by its speed

Finally some physicists who are able to think in terms of "IF YOU COULD", and don't just grab on to physical reality for dear life.

So that's where the "s" at the end of "maths" came from - you took it off of "sports".

What about reaching Ab0 without knowing it?

I love that they all played sport, it shows you can live a rounded life and be a physicist, rather than a sequestered person that never exercises.

I wasn't expecting that sports question :)

Rename this vid to: SPORTS ARE BAD!

Yes they do keep moving. Temperature is a quality of the whole atom. It's the amount of energy/vibration it has. So atoms vibrate/move around more, the more energy they have. If the energy is taken away, the atom slows down and eventualy stops at absolute zero, but the subatomic particles move the same as they did before. Temperature is different from the quantum mechanics strong force and the shape of the wave-function determining kinetic energy, that governs the motion of electrons. At least that's how I understand it.

07:02 Must... resist... urge... to make... arrow... to the... knee... joke...

this videos is very interesting because its "matter" explaining it self how it works.

Heisenberg uncertainty principle is like the problem of determining position and velocity. If you want to determine velocity, it has to be over a range of positions. If you want to accurately determine position, you can only use a velocity of 0.

5:42 - "degrees kelvin"

I thought the title asked if erections move at absolute zero.

what stops light from moving faster than 300,000 km/s ? obviously it ain't friction.

So competitive. No one said anything like "yeah, I have lots of fun practicing my sport"...

May have to come with a new metaphorical personalization as the idea of "static between channels" make the kids go "huh?"

WHERE ARE MY ATOMS?!?!?!

What?! The Electros still whizz about at absolute zero? I feel raped now!

He couldnt find his atoms, yet they were right in front of him! Hah! Ill show myself out..

I never realized the TV picked up background microwave.

So what does temperature in Kelvin really measure?

Wait a minute. If electrons can never be stopped, not even at absolute zero, then that's means that they are always moving. Always. So electrons have been buzzing around their host nuclei for over 13 BILLION years. How is that possible? Wouldn't they run out of energy? Unless I'm missing something here, it seems as if electrons have infinite energy.

if atoms are always vibrating, could it be possible to create a device that harnesses these vibrations and converts that into energy? free energy??

Why do they need to keep asserting "you can't reach absolute zero". It's not as if physics students are not familiar with 'ideal' situations while solving problems in school. We have frictionless surfaces, air that provides no resistance, gases that behave ideally, fluids that have no viscosity, harmonic motions with no energy loss, *perfect* resistors, capacitors and inductors, wires with zero resistance. All these situations are impossible in real life but our teacher didn't keep saying they can't exist over and over. I'm pretty sure almost everyone knows that the question is purely hypothetical. I'm NOT annoyed. I'm just wondering whether there is actually some reason why they need to repeat it.

oh yea, i replied to his question cause i thought he might be interested in it. i get that it was just the most convenient notation for them to choose and it made for a nice headline

I love you guys and wish you'd been my physics teachers. I did get a four-year degree in Astronomy (which of course included physics and math) so these days I call it Astrophysics because it sounds so much more impressive. I moved on to software design as a career but never lost my interest in the subject, and your videos bring back some fond memories as well as covering topics that hardly existed back in the sixties!

ok, i have a question about the cmb, if it was at a high frequency when it was emmited, and due to redshift has moved into the microwave part of the spectrum, so where did the energy go? because these microwave photons have less energy than the high frequency ones that were emmited.

In my understanding electrons don't "move" so much as pop in and out of existence, with a probability that we can determine concerning where. Anyone care to correct me on that, or confirm?

3:10 That's very weird to think of, but it absolutely makes sense.

3:00 This is a question I've always had and never asked.

What started the first electrons moving ? Was there a time of absolute zero motion in the universe and if so, what started everything in motion ?

OoOoh! you guys are from Nottingham Uni! Yaay! You’ve got a new subbie! 🙌 I have a question: What do you guys think about the concept of an oscillating universe? I know there’s a few different theories, so I’m interested to know what you guys think about those theories (and in particular, the oscillating universe theory) Fankoo!

Its best explained at 1:17, but basically its the same thing as reaching the speed of light, either you would need to be massless (i.e. light) or require an infinite amount of energy pushing you to travel at the speed of light. Similarly, if you wanted to bring something to absolute zero, you need an infinite amount of energy to work with. Another good example is limits, like those of the graph f(x)=1/x. As x approaches infinity, f(x) approaches 0 but never touches 0.

Is there a constant speed that electrons move around the nucleus of an atom? or is the speed relative to the type of atom. (ie: iron, cobalt, zinc, etc..)

Just based on what I currently know (or think I do >.

Never heard of electrons moving at ambient temperatures, but I never thought if they might start moving at absolute 0? :O

Please do another q&a with professors

can we stop electrons moving by using a combination of frequencies?

So is there theoretically any way to stop electrons from moving without using temperature? Are there quantum mechanical ways to do it?

These people are amazing. actually these are the people who should be featured in the people are awesome videos.

After the big bank, didn't some material get flung in the opposite direction? Can we detect that?

an even if you could, the act of observing it would necessarily change it's temperature, not to mention heat transfer is proportional to the temperature difference, so one would need a temperature below zero in order to bring another object to zero temperature, in which case you're just wasting your time and increasing entropy!

First, What if someone laws have flaws Second If we compress atoms to plank size, for instance, if the core of a neutron star is right at the brink of becoming a black hole, does neutrons stop moving and get fuzzed into the atom along with protons??

To put it in simple terms... It is analogous to if there was a straight track with an infinite number of lightbulbs that incrementally get farther and father from you. If those lightbulbs were to flash all that the same time (forgetting that the light would dissipate off other atoms, just assume the light does not dissipate), you would ALWAYS see light because when the photons of one lightbulb passed, the next one would be where you are. That is a simplified version of why.

I'm trying to think of what situation you'd be in that you'd need to know Uranium or Plutonium yields without understanding that E=mc^2 is only calculating the portion that becomes energy.

For the simplest and clearest explanation, read Feynman's book 6 easy pieces: They have to move, otherwise it will violate the uncertainty principle. You can't know an object's speed AND location.

I've always wondered the same thing. Like for example if you had a particle (a hydrogen ion for example) approaching an event horizon of a black hole. From the perspective of those outside of the gravity well, doesn't the particle take an infinite amount of time to cross the event horizon. If so, and if the temperature is defined as a quantity that is time dependent, wouldn't the limit, as the particle approaches the event horizon, of the particle's temperature reach absolute zero?

3:46 “Space and time are created from the Big Bang” The basic element required for occurrence, for a change anywhere in the emptiness of space is Time. For the Big Bang to happen, or for anything at all to happen, time is needed.

Also, how does the uncertainty principle reconcile with black holes? If matter collapses in on itself at the center then wouldn't that make it a quantum-scale entity (not sure if it counts as a particle)? If that's the case then shouldn't the principle apply? If it does, and you can measure it's position and momentum (by observations of the gravity well) would that violate the principle? Also, wouldn't that constrict movement and therefore bring the temperature down?

0:10 I think it would be fatal to lose your atoms. I mean, we lose atoms all the time, but if you last all of them, all at once, well, that would be bad.

If the doubling rate of the universe is the same as the doubling rate of 1mm, there's really nothing "expanding" anywhere near the speed of light. The distant galaxies aren't moving through space away from us , there's just more space between us than there used to be.