Neil deGrasse Tyson Explains The Three-Body Problem

Neil deGrasse Tyson Explains...
16 Apr 202411:44

Summary

TLDRThe video script offers an insightful explanation of the three-body problem, a concept in astrophysics that describes the difficulty in predicting the motion of three celestial bodies interacting through gravity. The script begins with the simpler two-body problem, which Isaac Newton famously solved using his laws of gravity and mechanics. However, when a third body is introduced, such as Jupiter affecting the Earth's orbit around the Sun, the problem becomes chaotic and unpredictable. The script highlights that Newton himself was concerned about the stability of the solar system due to these gravitational tugs. The solution to this problem was developed over a century later through perturbation theory, which allows for the calculation of the effects of small, repeating tugs on a two-body system. The video also distinguishes between the unrestricted three-body problem, which is mathematically unsolvable due to its chaotic nature, and the restricted three-body problem, where one body is much smaller than the other two and thus its influence is negligible. This simplified version is solvable and is applicable to scenarios like the double-star system portrayed in Star Wars. The script concludes by emphasizing the inherent chaos in celestial mechanics and how scientists model this chaos statistically rather than attempting to predict the exact behavior of each body.

Takeaways

  • 🌌 The two-body problem, such as the Earth and the Moon orbiting their common center of gravity, is perfectly solvable using Newton's laws of gravity and mechanics.
  • 🌍 Newton applied his equations to the Earth-Moon-Sun system, which also worked, but he was concerned about the stability of the solar system due to gravitational tugs from other planets like Jupiter.
  • 😇 Newton suggested that God might be responsible for maintaining the stability of the solar system when his calculations couldn't account for all the gravitational interactions.
  • 📚 Over a century later, Pierre-Simon Laplace developed perturbation theory, a branch of calculus that helped to understand the net effect of small, repeated gravitational tugs in a two-body system being perturbed by a third body.
  • 🔍 Perturbation theory showed that the small gravitational tugs from a distant third body, like Jupiter, would often cancel each other out over time, contributing to the stability of the solar system.
  • 📚 Napoleon Bonaparte, known for his interest in science, read Laplace's work and questioned why he did not mention the role of God in the stability of celestial bodies; Laplace responded that his calculations did not require such a hypothesis.
  • ⭐ The three-body problem, involving three stars of roughly equal mass, leads to mathematically chaotic and unpredictable orbits, making it unsolvable in the traditional sense.
  • 🌟 In the context of a double star system with a planet, like in Star Wars, the setup is an example of the restricted three-body problem, which is solvable because the mass of the planet is much less than the two stars.
  • 🚫 The unrestricted three-body problem, where all three bodies have comparable masses, is unsolvable due to the inherent chaos in the system, which leads to exponentially divergent outcomes from minor changes in initial conditions.
  • 🤔 The concept of chaos in the three-body problem means that while we can model the general behavior over time, we cannot predict the exact trajectory of each body indefinitely.
  • 🔮 For systems with more than three bodies, such as star clusters, we can use computational models to simulate their behavior, but the inherent chaos means we cannot predict the precise positions of all bodies at any given time.

Q & A

  • What is the two-body problem in the context of celestial mechanics?

    -The two-body problem refers to predicting the motion of two celestial bodies that interact only with each other through gravitational force. It is perfectly solvable using Newton's laws of motion and his law of universal gravitation.

  • How does the Earth-Moon system relate to the concept of the two-body problem?

    -The Earth-Moon system is an example of a two-body problem where both the Earth and the Moon orbit their common center of gravity. Despite the Earth being much more massive, it still moves in response to the gravitational pull of the Moon.

  • What is perturbation theory and how is it related to the three-body problem?

    -Perturbation theory is a branch of calculus developed to solve the three-body problem by considering the gravitational influence of a third body as a small 'perturbation' to the otherwise solvable two-body problem. It allows for the approximation of the paths of celestial bodies over time.

  • Why did Isaac Newton consider the solar system to be stable despite the presence of multiple bodies?

    -Newton believed the solar system to be stable because his laws of motion and gravitation, when applied to the Earth-Moon-Sun system, seemed to hold true. He attributed the stability to divine intervention, suggesting that God corrects any instabilities.

  • What is the restricted three-body problem and how does it differ from the general three-body problem?

    -The restricted three-body problem is a special case where two bodies have approximately equal masses and the third body has a mass much smaller compared to the other two. This problem is solvable because the smaller body's influence on the two larger bodies can be neglected, simplifying the equations.

  • How does the concept of chaos theory apply to the three-body problem?

    -Chaos theory is applied to the three-body problem because small changes in the initial conditions can lead to vastly different outcomes over time, making long-term predictions impossible. The system is considered chaotic, meaning it is highly sensitive to initial conditions.

  • Why is the three-body problem considered unsolvable?

    -The three-body problem is considered unsolvable because there is no general analytical solution that can predict the motion of three bodies over time due to the inherent chaos in their interactions. Solutions can only be approximated numerically.

  • What is the significance of the three-body problem in the context of astrophysics and celestial mechanics?

    -The three-body problem is significant because it represents a fundamental challenge in understanding the dynamics of celestial bodies. It highlights the limitations of classical mechanics and the need for advanced mathematical tools like perturbation theory and numerical simulations to study complex systems.

  • How did Pierre-Simon Laplace contribute to the understanding of the three-body problem?

    -Pierre-Simon Laplace developed perturbation theory, which is a method for approximating the solutions to the three-body problem by treating the gravitational influence of one body as a small perturbation on the two-body problem.

  • What is the role of numerical simulations in studying the three-body problem?

    -Numerical simulations play a crucial role in studying the three-body problem by allowing scientists to model the system's behavior over time. These simulations can provide insights into the system's evolution, even when an analytical solution is not possible.

  • How does the three-body problem relate to real-world celestial systems, such as star clusters?

    -The three-body problem is a foundational concept for understanding more complex celestial systems, like star clusters, where the motion of thousands of stars is influenced by gravitational interactions. While individual predictions may not be possible, statistical models can describe the overall behavior of such systems.

  • What was Napoleon's involvement with the three-body problem and celestial mechanics?

    -Napoleon is noted for having read and appreciated the works on celestial mechanics by Laplace. He questioned Laplace about the absence of any mention of God as the 'architect of the system' in his work, to which Laplace responded that such a hypothesis was unnecessary for his mathematical treatment of the subject.

Outlines

00:00

🌌 Understanding the Three-Body Problem

This paragraph explains the three-body problem, starting with the two-body problem where the Earth and the Moon orbit their common center of gravity. It highlights how Isaac Newton solved the two-body problem with his laws of gravity and mechanics, and then extended his equations to the Earth-Moon-Sun system. The paragraph then discusses Newton's concerns about the stability of the solar system when considering the gravitational influence of other planets like Jupiter. It mentions Newton's reliance on the idea of a divine intervention to maintain stability, which was later addressed with the development of perturbation theory by Pierre-Simon Laplace, a new branch of calculus that could account for the small, repeating gravitational tugs of a third body on a two-body system.

05:02

📚 Historical Insight on Celestial Mechanics

This section delves into the historical aspect of the three-body problem, mentioning Napoleon's interest in the field of celestial mechanics. It recounts how Napoleon engaged with Laplace over his work, pointing out the absence of a mention of God as the 'architect' of the system. Laplace's response, indicating that such a hypothesis was unnecessary for his mathematical treatment, is highlighted as a significant moment. The paragraph also touches on the concept of a double star system, like the one depicted in Star Wars, and introduces the idea of a three-body problem involving three stars and a planet, which leads to mathematically chaotic orbits and the inherent instability of such a system.

10:04

🌠 The Restricted Three-Body Problem and Chaos Theory

The final paragraph discusses the restricted three-body problem, where two massive bodies orbit each other and a third, much smaller body orbits these two. This scenario is solvable and was applicable to the Star Wars depiction of a double star system with a planet. It explains that while the restricted three-body problem can be solved, the general three-body problem is unsolvable due to its inherent mathematical chaos. Small changes in initial conditions can lead to exponentially divergent outcomes, making long-term prediction impossible. The paragraph concludes by emphasizing the role of chaos theory in modeling such systems, where we can only predict statistical behaviors over time rather than precise trajectories.

Mindmap

Keywords

💡Three-body problem

The three-body problem is a classical problem in physics where three celestial bodies, such as stars or planets, interact with each other through gravitational forces. It is a challenge because the problem cannot be solved analytically; the future positions and velocities of the bodies cannot be predicted exactly due to the inherent chaos in the system. In the video, this concept is central as it discusses the complexities and the historical attempts to understand the orbits and interactions of celestial bodies.

💡Center of mass

The center of mass is the point at which the mass of a system, such as the Earth and the Moon, is considered to be concentrated. It is the average location of the body's mass. In the context of the video, the concept is used to explain how both the Earth and the Moon orbit their common center of mass, which is not necessarily at the center of either body.

💡Perturbation theory

Perturbation theory is a mathematical technique used to approximate solutions to problems that cannot be solved exactly. In the video, it is mentioned as a method developed to account for the small, but recurring gravitational 'tugs' that a third body, like Jupiter, has on a two-body system, such as the Earth-Sun system. This theory allows for the prediction of the system's behavior over time, despite the presence of the third body.

💡Chaos theory

Chaos theory deals with the behavior of dynamic systems that are highly sensitive to initial conditions, meaning that small changes can lead to significant differences in outcomes. The video explains that the three-body problem exhibits chaotic behavior, making it impossible to predict the exact future state of the system due to the exponential divergence of outcomes from slightly different starting points.

💡Restricted three-body problem

The restricted three-body problem is a simplified version of the three-body problem where two bodies have much greater mass than the third, and the third body's influence on the other two is negligible. This problem is solvable, and the video uses the example of a planet orbiting two stars in a stable manner, as in the Star Wars universe, to illustrate this concept.

💡Orbit

An orbit is the path that an object in space takes around another object due to the force of gravity. The video discusses orbits in the context of the Moon orbiting the Earth, the Earth orbiting the Sun, and the complications that arise when additional bodies like Jupiter are introduced into the system.

💡Gravitational forces

Gravitational forces are the attractive forces that act between bodies with mass. In the video, these forces are central to the discussion of how celestial bodies interact and influence each other's orbits. The script mentions how the gravitational pull of Jupiter can affect the Earth's orbit around the Sun.

💡Isaac Newton

Sir Isaac Newton was an English mathematician, physicist, and astronomer, renowned for his laws of motion and universal law of gravitation. The video references Newton's work on the two-body problem and his initial concerns about the stability of the solar system when considering the three-body problem.

💡Celestial mechanics

Celestial mechanics is the branch of astronomy that deals with the motion of celestial objects and the forces that cause that motion. The video briefly mentions a series of books on this subject, highlighting the historical interest in understanding the complex dynamics of celestial bodies.

💡Napoleon

The video includes a historical anecdote about Napoleon Bonaparte, who is known to have read extensively on various scientific subjects, including celestial mechanics. The mention of Napoleon serves to illustrate the historical significance and interest in the three-body problem and its implications for understanding the cosmos.

💡Star clusters

Star clusters are groups of stars which orbit around a common center of mass. The video uses star clusters as an example to discuss the chaotic nature of systems with many bodies, where precise prediction of individual star movements is not feasible due to the complexity and chaos inherent in such systems.

Highlights

The Moon and the Earth orbit their common center of gravity, not the Earth alone.

The two-body problem is perfectly solvable using equations of gravity and mechanics.

Isaac Newton applied his equations to the Earth-Moon system and then to the Earth-Moon-Sun system.

Newton worried about the stability of the solar system due to gravitational tugs from other planets like Jupiter.

Newton suggested that God might occasionally intervene to stabilize the solar system.

Perturbation Theory, developed by Laplace 113 years after Newton, showed that small, repeated tugs in a two-body system can cancel out over time.

The solar system's stability can be understood through advanced calculus, which was not available to Newton.

Napoleon criticized Laplace for not mentioning God as the architect of the system, to which Laplace responded that his calculations made such a hypothesis unnecessary.

The three-body problem involves three stars of approximately equal mass and is mathematically chaotic, making it unsolvable.

In the three-body problem, small changes in initial conditions can lead to exponentially different outcomes, a characteristic of chaos.

The restricted three-body problem, where one body is much smaller than the other two, is solvable.

The Star Wars depiction of a double star system with a planet is an example of the restricted three-body problem.

The actual three-body problem is unsolvable due to its inherent chaos, unlike the restricted version.

Chaos theory allows us to model the behavior of the three-body problem statistically over time, rather than predicting exact outcomes.

The problem extends beyond three bodies; systems with more objects also exhibit chaotic behavior.

Star clusters with thousands of stars are an example of systems that we can model but cannot predict with precision.

The essence of the three-body problem is the unpredictability and chaos inherent in systems with three or more bodies.

Transcripts

00:00

you're going to get an astrophysicist

00:02

explanation of the literal three-body

00:05

problem without reference to anything

00:07

that's shown up on streaming services

00:09

and that means he's not gonna ruin the

00:11

show for you I don't know anything about

00:13

I don't know anything about the show but

00:15

I do know enough to describe the three

00:17

body problem to you coming up

00:21

[Music]

00:33

let's let's start simple okay okay okay

00:35

so as we know the moon orbits the earth

00:38

right but that's not the right way to

00:40

say it okay okay all right the Moon and

00:43

the Earth orbit their common center of

00:46

gravity oo so Earth is not just sitting

00:49

here right and the moon is going around

00:51

going around it they feel in their

00:53

Common Center you know where it is it's

00:55

a thousand miles beneath earth's surface

00:59

along line between the center of the

01:01

earth and the center of the Moon gotcha

01:04

so as the moon moves here that Center

01:06

Mass line shifts

01:09

okay so that means Earth is kind of

01:13

jiggling like this as the moon goes

01:15

around gotta that's their Center of mass

01:18

all right this is the two- body problem

01:20

it is perfectly solved using equations

01:23

of gravity right and mechanics makes

01:25

sense perfectly solved yeah Isaac Newton

01:27

solved it okay my boy that's your man so

01:30

that worked then Isaac applied the

01:32

equations to the Earth Moon system going

01:35

around the Sun okay okay that worked too

01:39

so in that system Let's ignore the moon

01:41

for the moment it's earth going around

01:42

it's another two- body system two system

01:44

all right but then he worried he said

01:47

every time Earth comes around the

01:51

backstretch and Jupiter's out there

01:54

right Jupiter about tug on it a little

01:56

bit a lot of gravity a little bit tug on

01:58

it as we com around back to the other

02:00

side what's up Earth all right and then

02:02

it comes around again tugs on it again

02:04

what's up earth right and of course

02:06

everybody's moving in the same direction

02:08

around the Sun so the Earth would have

02:09

to go a little farther in its orbit to

02:11

be aligned again with Jupiter but it's

02:13

going to tug on it right okay he looked

02:15

at all these little tugs and he says I'm

02:17

worried that the solar system will go

02:20

unstable right because it keeps tugging

02:23

on it it keeps pulling it away and the

02:25

previously stable orbit would just Decay

02:28

into chaos okay okay he was worried

02:30

about this you know what he said but I

02:32

know my stuff works and it's been and

02:34

it's looks stable to me right so clearly

02:37

it is stable even though it looks like

02:39

maybe it wouldn't be stable you know

02:40

what he says he said every now and then

02:42

God fixes things well there you go

02:44

that's the answer even Isaac

02:47

Newton wow look at that when in doubt

02:50

went in doubt just just let God figure

02:53

it out right I can't figure it out God

02:55

Did It clearly we're all still here and

02:57

we haven't been yanked out of orbit by

02:59

Jupiter right but Jupiter is pulling on

03:01

us so it's a god correction God God

03:03

correction okay this this is the first

03:06

hint that a third

03:09

body is messing with you right okay in

03:12

some way that maybe is harder to

03:14

understand fast forward

03:17

113 years oh right we get to uh

03:22

llas he studied this problem right okay

03:28

and he developed I don't think he

03:30

invented but he

03:32

developed a new branch of calculus oo

03:35

called perturbation Theory aha okay

03:40

unknown to Newton even though Newton

03:42

invented calculus right he invented

03:44

calculus right all right so he could

03:46

have done it he could have said in order

03:49

to solve this problem let me invent more

03:51

calcul more calcul just need more calcul

03:53

I just need more do do it didn't do it

03:56

so LL develops perturbation Theory and

04:00

it comes down to we have two bodies the

04:02

Sun and the Earth in this case and the

04:04

third one the tug is small but it's

04:07

repeating it's not a big Jupiter's not

04:10

sitting right here it's way way out

04:12

there it's just a little tug and so you

04:14

can run the equations in such a way and

04:17

realize that a two body system that is

04:22

tugged Often by something small that it

04:26

all cancels out in the end gotcha okay

04:29

okay so when it's out here the tug is a

04:31

little bit that way but now it's over

04:33

here and the tug is less right all right

04:37

and then sometimes it's tugging you in

04:39

this direction when that's the

04:41

configuration you add it all up it all

04:43

cancels out Newton could not have known

04:45

that without this new branch of calculus

04:47

okay okay pertubation Theory so that

04:49

took care of that third body gotcha

04:52

where solar system is basically stable

04:55

okay for the foreseeable future in ways

04:57

that Newton had not imagined in ways

04:59

that Newton required God right okay oh

05:02

by the way just a quick aside this is

05:04

now we're up to the year 1800 uh you

05:07

know who summoned up these books to read

05:09

them immediately because the there a

05:11

series of books called Celestial

05:12

mechanics okay Napoleon ah na am

05:17

Napoleon Napoleon who read all the books

05:20

he could on physics and engineering and

05:23

metalurgy look at that okay it wasn't

05:25

just a tyrant right he was like he was a

05:27

smart Tyrant smart Tyrant was all right

05:30

so he summons up the book doesn't need

05:32

doesn't have to be translated because

05:34

they're both in French right he reads it

05:36

goes to llas and says Monier this is a

05:39

beautiful piece of work brilliant but

05:41

you make no mention of the architect of

05:45

the system he's referring to God and

05:46

llas replied sir I had no need for that

05:50

hypothesis oo that's a mic drop oh that

05:54

is tough

05:57

man you that's a dig on Napoleon and on

06:01

new Newton yeah and on Newton I have oh

06:05

man look at that yeah all right so let's

06:08

keep going go ahead so now let's say we

06:11

have not just the planet and one of its

06:14

moons but let's say we have a star and

06:17

another star double star system famously

06:19

portrayed in what film uh Star Wars Star

06:22

Wars yeah all right of course so those

06:25

two suns and the planet is stable and

06:28

I'll tell you why in a minute mhm but if

06:30

you take a third sun and put it there

06:33

about approximately the same size then

06:35

what kind of orbits will they have give

06:39

me two fists here okay so I'm feeling

06:42

this one but now I feel that where's my

06:44

gravitational allegiance to go am I

06:47

going to come through but then am I

06:49

going to go that that way or this way so

06:52

I'm coming into the system and do I go

06:55

to you in orbit but wait you're still

06:57

coming around here now I feel this

07:00

and so it turns out the orbits of a

07:04

three-body problem are mathematically

07:07

chaotic yes I was about to say that did

07:09

not seem very stable SS has to give well

07:13

this is this is in the series what talk

07:16

something I don't I haven't seen the

07:17

series I'm just saying something has to

07:19

give that's all two of these are going

07:20

to collide one is going to get ejected

07:23

right okay that is the classical three

07:27

body problem three objects of a

07:29

approximately similar mass trying to

07:32

maintain a stable orbit and it goes

07:34

chaotic with just three objects look at

07:37

that it is an unsolvable you can let me

07:40

say that differently you can calculate

07:43

incrementally what's happening and track

07:45

it until the system dies right or splits

07:49

apart or whatever but you cannot

07:52

analytically predict the future of the

07:54

three-body system because what chaos

07:57

will do for you in your mathematical

07:59

model is if you change the initial

08:01

conditions by a little bit right a

08:03

little bit the solution diverges further

08:06

down the line that goes crazy it's not

08:09

just a little bit different later on

08:10

down line it is exponentially

08:13

exponentially different correct with the

08:14

with the smallest increment of distance

08:17

so I'll say I'll move you in this

08:19

direction in this model and then in a

08:22

slightly different direction than the

08:23

other model it goes chaotic that's what

08:25

we mean by chaos right okay it's

08:27

mathematically defined Okay so now

08:30

there's something called the restricted

08:31

three body problem all right okay okay

08:34

the restricted three body problem never

08:35

heard you have give me your two your two

08:38

things back two plan you got that okay

08:40

two bodies you got your two bodies now

08:43

the third body is little ah now you two

08:46

will orbit each other right okay and

08:49

then and then this it's not messing with

08:52

them right so so there restricted three

08:55

body problem we have two masses of

08:57

approximately equal and one that's much

08:59

less than the other two that is solvable

09:02

right it's called the restricted three

09:03

body problem gotcha in the Star Wars

09:07

case that's the restricted three body

09:09

problem right because you have the two

09:11

stars and you have the little planet the

09:13

little planet deal and it's even better

09:16

because the planet is so far away that

09:18

it only really saw one merged gravity of

09:22

the two stars right okay you're far

09:26

enough away that that difference is not

09:28

really mattering to you you maintain one

09:31

stable orbit around them both around

09:33

both stars both Stars okay now if it got

09:37

really close then you'll have issues

09:40

because then ites again gravitational

09:42

Allegiance matters the stars are not

09:44

going to care but you will cuz you

09:46

you'll get eat you don't know where to

09:47

go you don't know where to go I'm in

09:48

love with two stars and I don't know

09:50

what to do which way do I

09:52

turn so anyhow I so so the three body

09:56

problem the takeaway here is it's

09:59

unsolvable yes not just because we don't

10:02

know how to do it yet because it's

10:03

mathematically UNS bu into the system

10:05

the system is chaotic yeah okay unless

10:09

you make certain assumptions about the

10:12

system that you would then invoke so

10:15

that you can solve it and so one of them

10:18

is a small object around bigger ones

10:20

another one oh by the way in this

10:22

solution with Jupiter out there slightly

10:24

tugging right yes it turns out over a

10:27

very long time scale this is chaotic

10:30

but much longer time skill than Newton

10:32

ever imagined okay okay because yes we

10:34

are small compared to the Sun but

10:36

Jupiter isn't all right and we're trying

10:38

to orbit between them right right so

10:41

that's that's all it's not deeper than

10:42

that it's not yeah right I could have

10:44

said the four body problem but this

10:47

problem begins at the three body problem

10:48

right right because you're going to have

10:50

the same thing in four bodies or five

10:51

bodies it's going to be the same we have

10:53

star clusters with thousands of stars in

10:55

them and they're all just orbiting we

10:57

have to we can model it but cannot

11:00

predict with Precision where everybody's

11:01

going to be at any given time okay CU

11:03

it's chaotic the're chaotic so it's

11:05

basically it's about the chaos it's

11:06

about the chaos it's all about the chaos

11:08

yeah so what we do is we model the chaos

11:10

right right we say this will be

11:11

statistically looking like this over

11:14

time you're not going to track one

11:15

object through the system exactly for

11:17

eternity that's not going to work that's

11:19

so cool yeah all right that is so cool

11:21

there it is all right another explainer

11:23

slipped in from torn from the pages of

11:27

Science Fiction yes just the just a

11:29

simple description of the three body

11:31

problem until next time keep looking up

11:37

[Music]

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関連タグ
AstronomyChaos TheoryNewtonThree-BodyCelestial MechanicsPerturbationJupiterSolar SystemStar WarsGod CorrectionMathematical Chaos
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