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  • The Force

  • is what gives a Jedi his power.

  • It's an energy field created by all living things.

  • It surrounds us and penetrates us.

  • It binds the galaxy together.

  • So, that's a fairly deep quote, isn't it? Fairly deep quote.

  • And so, I got contacted by a journalist for The Guardian.

  • They were doing an article on The Force

  • and they wanted to know, from a physicist,

  • well, what were your thoughts on The Force?

  • The Force, of course, is taken

  • -- and George Lucas himself has admitted this --

  • that it was informed by, sort of,

  • concepts of Eastern mysticism

  • and tying together the world, the universe,

  • in terms of

  • almost like a spiritual force that binds us,

  • binds us all together.

  • But it also obeys your commands.

  • Now, I have a lot of problems,

  • when it comes to quantum mechanics, for example,

  • where quantum mechanics is abused

  • in terms of 'quantum woo'

  • and the idea that quantum mechanics

  • tells us

  • that everything is bound together, and that, um,

  • you know, Brady's electrons and my electrons

  • are all part of one holistic, integrated whole.

  • Kid, I've flown from one side of this galaxy to the other.

  • I've seen a lot of strange stuff;

  • but I've never seen anything

  • to make me believe there's one

  • all-powerful force controlling everything.

  • In this universe, that doesn't happen

  • for reasons I've discussed at length in other videos.

  • But let's think about what --

  • you know, what --

  • What could be the origin of The Force in Star Wars?

  • Is there a universe where it might be possible?

  • Let's say my starting point is existing physics,

  • and let's think about how we would

  • have to modify that existing physics

  • to, um, to have something like The Force in the universe around us.

  • What's remarkable in this universe

  • and with current existing physics

  • is that quantum mechanics,

  • at one level,

  • quantum physics *does* tell us

  • that Brady's and my electrons

  • are coupled together.

  • Binds the galaxy together.

  • It *does* tell us that my electrons

  • are coupled with the building over there;

  • are coupled with small, blue, furry creatures on Alpha Centauri;

  • are coupled with

  • the universe at whole.

  • Quantum mechanics does tell us that.

  • And in fact, we can't really think,

  • in some ways

  • -- in terms of the theoretical context --

  • we can't think of an individual electron;

  • we've got to think of them all coupled together.

  • Its energy surrounds us

  • and binds us.

  • That's called 'entanglement' and, that's,

  • and that sounds very much like The Force.

  • But why doesn't it work in this universe?

  • Well, the reason it doesn't work in [this] universe is

  • that coupling is so *incredibly* tiny;

  • incredibly tiny. You may as well say,

  • if I do this [exhales a puff of breath],

  • that I've affected the orbit of Mars.

  • That's sort of what it's like saying.

  • There is an effect,

  • but that effect is not only *tiny*;

  • it's utterly, completely,

  • totally, fundamentally

  • negligible. It doesn't affect anything

  • in the world around us.

  • [Brady, off camera:] You're almost making the case there, though.

  • You're saying, "For you and me, we can't do it; but maybe a Jedi,

  • [Brady continues] "who is more sensitive or can amplify these things"

  • But what would have to happen --

  • So, it's interesting because, um, there are people

  • like Deepak Chopra; there are people

  • in *this* universe, in this world

  • who claim that this coupling happens.

  • But the coupling doesn't happen.

  • Quantum mechanics, if --

  • [Brady, off camera:] But *you* just said the coupling happens.

  • No! The coupling happens *theoretically*

  • and you have to set the *theory* up

  • so that that, um, coupling is within the theory.

  • But there's a big difference between

  • a theory

  • and something that happens practically,

  • or something that's measurable.

  • As I say, the theory tells us there's

  • a coupling; but that coupling is at the level of --

  • It's just so far off the scale,

  • not only could we not measure it;

  • we couldn't even begin to hope to measure it

  • with *whatever* technology,

  • because it's *completely* overridden by any other effect.

  • It's, as I say, it's like me [exhales a puff of breath] doing that,

  • and expecting that

  • not only have I affected the orbit of Mars,

  • but I've affected the orbit of planets around

  • Alpha Centauri, or whatever.

  • So it's a very theoretical concept,

  • and the problem is --

  • [Brady:] But you never ____ theoretical; weak.

  • [Brady, off camera:] It does exist; you *did* affect Mars just then; just not very much.

  • Exactly! But, you know, so,

  • in terms of the context of, um,

  • what it means for our everyday lives --

  • Can we control it?

  • Does it make a difference?

  • So --

  • What would need to happen

  • to have something like The Force in this universe,

  • in terms of coupling us all together?

  • Well, that f[orce] -- somehow would have to amplify

  • that entanglement.

  • We'd have to somehow, you know, in terms of,

  • um,

  • me being able to connect with Brady

  • from my electrons, to entangle with Brady's,

  • so I could influence his thoughts, for example.

  • How would I influence his thoughts?

  • Well, I'd have to change the biochemistry?

  • And what's the biochemistry about?

  • It's about electrons?

  • So, somehow my electrons would have to couple --

  • they'd have to become strongly quantum mechanically entangled with Brady's electrons.

  • How would we do that?

  • I don't know.

  • [Brady, off camera:] But I thought you said our electrons *are* entangled already.

  • Our elec --

  • [Brady, off camera:] And we're close to each other.

  • But that, but that level of entanglement

  • is so absolutely minuscule.

  • [Brady:] Isn't entanglement like pregnant? You can't be weakly pregnant.

  • Absolutely you can be.

  • [Brady:] You're entangled, or you're not entangled.

  • No! No, no, no, no. There's a whole range of different entan --

  • So, electrons in the same atom

  • can have a strong degree of entanglement;

  • electrons in different objects

  • can have a very, very weak degree of entanglement;

  • electrons on either side of the universe --

  • that entanglement is so *incredibly* small --

  • the coupling is so incredibly small

  • that it's just --

  • I cannot begin to describe just how incr --

  • [stammers]

  • incredibly and totally

  • minuscule and negligible it is.

  • [Brady, off camera:] Well Professor, if there are degrees of entanglement --

  • [Brady:] What's the SI unit for entanglement?

  • So an, well, [stammers]

  • You'd have to think of -- the best way of thinking about it

  • is in terms of --

  • if you've got, ah --

  • No, it's a very very good question, Brady.

  • Best way of thinking about it is in terms of:

  • What are the energies?

  • Right? So, if you've got, ah,

  • a system at one particular energy --

  • you've got an object at one particular energy; you've got an object over here at another particular energy.

  • So, is the energy of this object

  • affected by this object, and vice-versa?

  • That's the best way of thinking about it.

  • So, if you bring two atoms together,

  • and what happens is that the electrons will start to interact --

  • they'll overlap -- and at some point, you no longer think of it as

  • individual atoms; they become a molecule.

  • Alright? So that's a fairly strongly,

  • in terms of the electrons, that's a fairly strongly entangled system.

  • But if you break that out,

  • you don't need to go very, very far at all

  • where this atom

  • just does not feel the influence of this atom at all.

  • And that's over the course of just a few atomic diameters. The bond breaks.

  • So, they're not entangled; they're not communicating with each other.

  • Move this to even a *fraction* of a millimeter,

  • and this atom really does not care

  • about the presence of this atom,

  • in terms of the energies of the electrons in this atom.

  • Move it to the other side of the universe,

  • and that, as I said, that effect is just

  • completely and utterly washed out

  • by us *breathing*, for one thing;

  • by the vibrations, the thermal vibrations

  • of the atoms in the table.

  • So the quantum mechanics that happens down here

  • at the atomic level

  • just doesn't scale up.

  • [Brady, off camera:] It's almost like you're saying,

  • [Brady:] Sure, it's there, but us -- but it's weak and us mortals would never see or measure it.

  • Absolutely. So therefore -- [Brady, off camera:] No, I'm saying,

  • [Brady:] It would take a special kind of person

  • [Brady:] to see it, or control or measure it;

  • [Brady:] and that special person is a Jedi.

  • Maybe. Maybe if -- But they have to,

  • they have to be able to control that entanglement,

  • and amplify that effect.

  • [Brady, off camera:] That's why they're so special. They -- [Professor:] Yeah, and it's a question of

  • how, I guess, with um --

  • I know this divides the community

  • and I don't want to have hordes of rampaging Star Wars fans chasing after me --

  • But maybe this midi-chlorian idea?

  • Maybe that somehow amplifies the entanglements?

  • It's an interesting idea. But,

  • the interesting thing here is that

  • within, as I say, within

  • quantum mechanics in this universe,

  • technically -- but I *really* want to stress that --

  • Technically, um,

  • you have to couple everything together --

  • you can't just assume: One electron here. You have to consider

  • *all* the electrons in the universe.

  • So, it's interesting. The Force is what gives the Jedi his power.

  • It's an energy field.

  • The Force is what gives a Jedi his power. It's an energy field.

  • Now, already a physicist goes,

  • "Hang on!" Because a force

  • and an energy

  • are *very* different things.

  • [Female voice:] Many Bothans died to bring us this information.

  • [Brady, off camera:] I think you're being a bit --

  • [Brady:] This is semantics, though, isn't it?

  • [Brady:] The reason I think this is semantics --

  • [Brady:] 'The Force' with a capital 'F' doesn't have to be a force [Professor:] True, true. That's true.

  • That's true. There is -- I am being, in terms of the pedantry, I guess,

  • it can just be thought of as,

  • as you say, The Force with a capital F

  • rather than a force.

  • But that distinction between force,

  • as a physicist sees it, and energy, is important.

  • But this is the good -- this is the really --

  • That's a bit of a pedantic one. That is a bit of a pedantic one.

  • But it's interesting --

  • It says, "It surrounds us and penetrates us."

  • Basically, that's what forces,

  • force fields, or fields, do in the universe.

  • In quantum field theory,

  • we think about the,

  • the field associated with an electron

  • or the field associated with a particle.

  • Which permeates all of space!

  • Or even the electron -- you're used to thinking

  • about the -- or hearing about the Higgs boson

  • and how that field permeates the universe;

  • but that's true of *every* field.

  • It does permeate the entire universe.

  • Those, um, what makes a difference

  • is that if you make a change here,

  • over here, it can only respond at the speed of light;

  • but that field in that sense

  • does permeate the entire universe.

  • So some of this,

  • you know, "It surrounds us and penetrates us."

  • There are fields around us -- force fields --

  • that indeed surround us and penetrate us.

  • So in that sense, you know, there is some

  • interesting aspects of The Force which connect with us.

  • Nothing more will I teach you today.

  • Clear your mind of questions.

  • Hmmmm.

  • [Brady, off camera:] What does a universe look like where

  • [Brady:] certain people can do it?

  • [Brady:] And does that universe behave differently? Could --

  • That universe would have to be --

  • Great, huge questions; and

  • I'm very much thinking on my feet here.

  • I haven't given this a huge amount of thought.

  • So, please feel free to shoot me down completely

  • in the comments. [Brady:] They will.

  • [Professor, laughing:] They will indeed.

  • But, um --

  • The interesting [thing] about that is,

  • if you are gonna chance a degree of entanglement,

  • it's not just *you* we have to worry about,

  • or the Jedi;

  • it's the environment itself.

  • Because, everything around us

  • in this universe

  • scatters those waves. Scatters those electron waves.

  • And, then you'd have to be able to

  • somehow locally

  • control.

  • What -- so, if the -- my, um --

  • [if] my wave function is connecting with Brady's wave function,

  • it's not just: I have to connect with Brady;

  • It's that I have to get rid of the influence of this table,

  • which might scatter that wave.

  • So, the universe would have to behave very differently.

  • The energies would have to be different

  • in terms of, um,

  • the -- at the moment,

  • the atoms vibrating in this table

  • are scattering those waves;

  • which means that you don't have these

  • long-range entanglements.

  • You'd have to control *all* the physics.

  • You'd even have to probably think about

  • changing fundamental -- no, you *would*, definitely! --

  • changing fundamental constants,

  • which means that it wouldn't just be

  • you, Brady, that'd be affected,

  • or me, as a Jedi knight, that'd be affected.

  • The whole universe, the physics would have to be

  • very, very different.

  • And then it might look like a very different place indeed.

  • [Brady, off camera:] There's a long history

  • [Brady continues:] of humans not understanding what was around us,

  • [Brady continues:] gradually understanding what was around us,

  • [Brady continues:] and then being able to harness that to incredible effect,

  • [Brady continues:] good and bad. [Professor:] Yeah.

  • [Brady, off screen:] Atomic bombs are a brilliant example. [Professor:] Yes.

  • [Brady, off screen:] Who's to say that,

  • [Brady continues:] in a galaxy far, far away,

  • [Brady continues:] they haven't found a way to harness and use entanglement to their advantage,

  • [Brady continues:] and you just haven't thought of it yet,

  • [Brady continues:] because you're a silly human? [Professor:] That is --

  • My problem with that is,

  • is not, as I said, it's not just a question of

  • not being able to design the technology.

  • It's just that the energy scales associated with this --

  • ____ me, I would love to believe there's a universe out there with The Force.

  • That would be absolutely, absolutely fantastic,

  • that somewhere, you know, there is a universe like the Star Wars universe.

  • Wookies. I'd love to meet a wookie. [Wookie sound]

  • [Brady:] If Luke Skywalker walked into the room right now,

  • [Brady continues:] and used The Force in front of you --

  • [Brady continues:] he was controlling minds; he was moving things around --

  • [Brady continues:] Are you saying that quantum entanglement

  • [Brady continues:] would be your first line of inquiry

  • [Brady continues:] to figure out how he was doing it?

  • And there's no visible

  • sort of amplifier for his --

  • you know, waves associated from -- [Brady, off camera:] He just says, I'm a Jedi.

  • [Brady continues:] I'm a Jedi. I can just do this stuff. [Professor:] Yes.

  • I think I'd probably start

  • thinking about entanglement.

  • Um, the other interesting thing, as well, of course, is the,

  • um, the cognitive abilities,

  • or the pre-cognitive abilities --

  • The ability to see into the future.

  • [Yoda:] Through The Force, things you will see,

  • other places, the future, the past.

  • Well, it's interesting then, because in this universe,

  • we, you know, there are parallel worlds --

  • The whole, sort of, elaborate many worlds theory,

  • um, which again,

  • some physicists have a lot of time for,

  • other physicists don't have huge amount of time for.

  • But imagine a universe where

  • somehow, you could communicate with those other worlds,

  • which we can't, at the moment.

  • Could you tap into those other worlds?

  • Could you tap into other possibilities?

  • Because the idea is, in many types of 'many worlds' theories,

  • that every possibility happens.

  • Could you actually couple into those?

  • Could you somehow see into

  • the particular universe you need to see into those particular possibility?

  • [Obi-Wan Kenobi:] Use The Force, Luke.

  • [Professor:] That's, again, a very much fundamental quantum,

  • quantum effect. But let me stress, this is all science fiction.

  • ... or the remaining Type II calculation,

  • because it's really not worth trying to do this calculation

  • terribly carefully.

  • But, basically, it fires for

  • a couple of seconds.

  • So it's, you know, which is accurate enough

  • for these purposes.

  • We need to do the maths now,

  • if you want to actually figure out

  • what the energy is.

  • So, if I have...

The Force

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フォース - 60のシンボル (The Force - Sixty Symbols)

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    林宜悉 に公開 2021 年 01 月 14 日
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