Physics/Chaos: The Science of the Butterfly Effect
Chaos: The Science of the Butterfly Effect

Chaos: The Science of the Butterfly Effect

Veritasium12 minDec 6, 2019
The butterfly effect is the idea that tiny causes, like a flap of a butterfly's wings in Brazil, can have huge effects, like setting off a tornado in Texas
11 chapters
  • Introduction to the Butterfly Effect(0'001'06)
    The butterfly effect has inspired 61 movies, TV episodes, and short films on IMDB, plus prominent references in Jurassic Park, songs, books, and memes
    In pop culture, the butterfly effect means that even tiny, seemingly insignificant choices can have huge consequences later in life
    People are fascinated by the butterfly effect because it addresses a fundamental question: how well can we predict the future?
    Examine the science behind the butterfly effect to answer the question of future predictability
  • Classical Determinism and Laplace's Demon(1'062'24)
    After Newton's laws of motion and universal gravitation in the late 1600s, everything seemed predictable
    • Explained the motions of all planets and moons • Predicted eclipses and comet appearances with pinpoint accuracy centuries in advance
    Pierre-Simon Laplace imagined a super-intelligent being (Laplace's demon) that knew everything about the universe's current state, concluding the future would be entirely determined and predictable
    The view that the future is already fixed; we just have to wait for it to manifest itself
  • Phase Space and Pendulum Dynamics(2'244'04)
    A 2D plot representing every possible state of a system, with position on one axis and velocity on another
    The pendulum slows down over time, creating an inward spiral in phase space toward a fixed point attractor where it hangs at rest
    The pendulum swings back and forth at the same amplitude, creating a closed loop in phase space that indicates periodic, predictable motion
    Curves never cross in phase space because each point uniquely identifies the complete system state with only one possible future
  • The Three-Body Problem and Early Chaos(4'044'46)
    While calculating Earth and Sun's motion was simple, adding a third body like the Moon made the problem virtually impossible
    Newton told his friend Halley that the theory of the Moon's motions made his head ache and kept him awake so often that he would think of it no more
    Two hundred years later, Henri Poincaré realized there was no simple solution to the three-body problem and glimpsed what became known as chaos
    The three-body problem revealed fundamental limitations in predicting complex systems using Newton's laws
  • Lorenz's Atmospheric Discovery(4'465'57)
    Meteorologist Ed Lorenz created a computer simulation of Earth's atmosphere with 12 equations and 12 variables representing temperature, pressure, humidity, and other factors
    When Lorenz re-entered numbers from a previous printout as a shortcut, the new run initially followed the old one but then diverged into completely different weather patterns
    The printer rounded to three decimal places while the computer calculated with six, creating a difference of less than one part in a thousand that produced totally different results
    Lorenz's system displayed sensitive dependence on initial conditions, the hallmark of chaos, where tiny input differences create dramatically different outcomes
  • Understanding Chaos Through Simplification(5'576'22)
    Lorenz reduced his equations to just three equations and three variables representing a toy model of convection in a 2D slice of atmosphere
    • System is completely deterministic, identical to the pendulum in this regard • Identical initial conditions produce identical results • Any tiny difference in initial conditions gets amplified to totally different final states
    The system is both deterministic and unpredictable because in practice you could never know initial conditions with perfect accuracy
    This explains why even today with huge supercomputers, weather forecasts become no better than historical averages after eight days
  • Phase Space Visualization of Chaos(6'228'08)
    With three variables, Lorenz's phase space can be plotted in three dimensions to visualize how the system evolves
    Three closely spaced initial states initially evolve together but then start to diverge, ending up on totally different trajectories
    Unlike simple systems, the chaotic system never revisits the same exact state and doesn't move toward fixed attractors or repeating loops
    You could never release a double pendulum or similar chaotic system and make it behave the same way twice; its motion remains forever unpredictable
  • Chaos in Multiple Systems(8'089'38)
    • Double pendulum: two simple pendulums connected together • Fidget spinners with repelling magnets: five spinners that appear regular but have strange motions
    Simulations of our solar system for a hundred million years found it behaves chaotically with a characteristic time of about four million years
    Within 10 to 15 million years, some planets or moons may have collided or been flung out of the solar system entirely
    Even the system we think of as the model of order is unpredictable on modest timescales
  • Fundamental Limits on Prediction(9'3810'06)
    The further into the future you try to predict, the harder it becomes, with predictions eventually becoming no better than guesses
    The same applies when looking into the past of chaotic systems and trying to identify initial causes
    Like a fog that sets in the further we try to look into the future or past, chaos puts fundamental limits on what we can know
    Chaos limits what we can know about the future of systems and what we can say about their past
  • The Lorenz Attractor and Structure(10'0611'02)
    Despite chaos limiting individual predictions, there is underlying structure in chaotic systems
    When multiple initial conditions evolve together, they move toward a butterfly-shaped object called the Lorenz attractor
    • Paths traced never cross or form loops • Each path is an infinite curve in finite space • All trajectories converge to the attractor shape
    Though you cannot predict individual states, you can describe how collections of states evolve into recognizable patterns like the butterfly shape
  • Conclusion and LastPass Sponsorship(11'0212'51)
    The science reveals that the butterfly effect is not just about unpredictability but also shows deep and beautiful structure underlying system dynamics
    While you cannot predict how any individual state evolves, you can describe how collections of states evolve into recognizable patterns
    LastPass helps manage passwords by generating strong, unique codes for each website and auto-filling them, eliminating the need to remember or reuse passwords
    Having chaotic passwords is actually beneficial for security, unlike chaotic systems where unpredictability limits our understanding