WEBVTT 99:59:59.999 --> 99:59:59.999 In 2009, two researchers ran a simple experiment. 99:59:59.999 --> 99:59:59.999 They took everything we know about our solar system and calculated 99:59:59.999 --> 99:59:59.999 where every planet would be up to 5 billion years in the future. 99:59:59.999 --> 99:59:59.999 To do so they ran over 2000 numerical simulations 99:59:59.999 --> 99:59:59.999 with the same exact initial conditions except for one difference: 99:59:59.999 --> 99:59:59.999 the distance between Mercury and the Sun, modified by less than a millimeter 99:59:59.999 --> 99:59:59.999 from one simulation to the next. 99:59:59.999 --> 99:59:59.999 Shockingly, in about 1 percent of their simulations, 99:59:59.999 --> 99:59:59.999 Mercury’s orbit changed so drastically that it could plunge into the Sun 99:59:59.999 --> 99:59:59.999 or collide with Venus. 99:59:59.999 --> 99:59:59.999 Worse yet, 99:59:59.999 --> 99:59:59.999 in one simulation it destabilized the entire inner solar system. 99:59:59.999 --> 99:59:59.999 This was no error; the astonishing variety in results 99:59:59.999 --> 99:59:59.999 reveals the truth that our solar system may be much less stable than it seems. 99:59:59.999 --> 99:59:59.999 Astrophysicists refer to this astonishing property of gravitational systems 99:59:59.999 --> 99:59:59.999 as the n-body problem. 99:59:59.999 --> 99:59:59.999 While we have equations that can completely predict the motions 99:59:59.999 --> 99:59:59.999 of two gravitating masses, 99:59:59.999 --> 99:59:59.999 our analytical tools fall short when faced with more populated systems. 99:59:59.999 --> 99:59:59.999 It’s actually impossible to write down all the terms of a general formula 99:59:59.999 --> 99:59:59.999 that can exactly describe the motion of three or more gravitating objects. 99:59:59.999 --> 99:59:59.999 Why? The issue lies in how many unknown variables an n-body system contains. 99:59:59.999 --> 99:59:59.999 Thanks to Isaac Newton, we can write a set of equations 99:59:59.999 --> 99:59:59.999 to describe the gravitational force acting between bodies. 99:59:59.999 --> 99:59:59.999 However, when trying to find a general solution for the unknown variables 99:59:59.999 --> 99:59:59.999 in these equations, 99:59:59.999 --> 99:59:59.999 we’re faced with a mathematical constraint: for each unknown, 99:59:59.999 --> 99:59:59.999 there must be at least one equation that independently describes it. 99:59:59.999 --> 99:59:59.999 Initially, a two-body system appears to have more unknown variables 99:59:59.999 --> 99:59:59.999 for position and velocity than equations of motion. 99:59:59.999 --> 99:59:59.999 However, there’s a trick: 99:59:59.999 --> 99:59:59.999 consider the relative position and velocity of the two bodies 99:59:59.999 --> 99:59:59.999 with respect to the center of gravity of the system. 99:59:59.999 --> 99:59:59.999 This reduces the number of unknowns and leaves us with a solvable system. 99:59:59.999 --> 99:59:59.999 With three or more orbiting objects in the picture, everything gets messier. 99:59:59.999 --> 99:59:59.999 Even with the same mathematical trick of considering relative motions, 99:59:59.999 --> 99:59:59.999 we’re left with more unknowns than equations describing them. 99:59:59.999 --> 99:59:59.999 There are simply too many variables for this system of equations 99:59:59.999 --> 99:59:59.999 to be untangled into a general solution. 99:59:59.999 --> 99:59:59.999 But what does it actually look like for objects in our universe 99:59:59.999 --> 99:59:59.999 to move according to analytically unsolvable equations of motion? 99:59:59.999 --> 99:59:59.999 A system of three stars–– 99:59:59.999 --> 99:59:59.999 like Alpha Centauri could come crashing into one another or, more likely, 99:59:59.999 --> 99:59:59.999 some might get flung out of orbit after a long time of apparent stability. 99:59:59.999 --> 99:59:59.999 Other than a few highly improbable stable configurations, 99:59:59.999 --> 99:59:59.999 almost every possible case is unpredictable on long timescales. 99:59:59.999 --> 99:59:59.999 Each has an astronomically large range of potential outcomes, 99:59:59.999 --> 99:59:59.999 dependent on the tiniest of differences in position and velocity. 99:59:59.999 --> 99:59:59.999 This behaviour is known as chaotic by physicists, 99:59:59.999 --> 99:59:59.999 and is an important characteristic of n-body systems. 99:59:59.999 --> 99:59:59.999 Such a system is still deterministic— meaning there’s nothing random about it. 99:59:59.999 --> 99:59:59.999 If multiple systems start from the exact same conditions, 99:59:59.999 --> 99:59:59.999 they’ll always reach the same result. 99:59:59.999 --> 99:59:59.999 But give one a little shove at the start, and all bets are off. 99:59:59.999 --> 99:59:59.999 That’s clearly relevant for human space missions, 99:59:59.999 --> 99:59:59.999 when complicated orbits need to be calculated with great precision. 99:59:59.999 --> 99:59:59.999 Thankfully, continuous advancements in computer simulations 99:59:59.999 --> 99:59:59.999 offer a number of ways to avoid catastrophe. 99:59:59.999 --> 99:59:59.999 By approximating the solutions with increasingly powerful processors, 99:59:59.999 --> 99:59:59.999 we can more confidently predict the motion of n-body systems on long time-scales. 99:59:59.999 --> 99:59:59.999 And if one body in a group of three is so light it exerts no significant force on the other two, 99:59:59.999 --> 99:59:59.999 the system behaves, with very good approximation, as a two-body system. 99:59:59.999 --> 99:59:59.999 This approach is known as the “restricted three-body problem.” 99:59:59.999 --> 99:59:59.999 It proves extremely useful in describing, for example, 99:59:59.999 --> 99:59:59.999 an asteroid in the Earth-Sun gravitational field, 99:59:59.999 --> 99:59:59.999 or a small planet in the field of a black hole and a star. 99:59:59.999 --> 99:59:59.999 As for our solar system, you’ll be happy to hear 99:59:59.999 --> 99:59:59.999 that we can have reasonable confidence in its stability 99:59:59.999 --> 99:59:59.999 for at least the next several hundred million years. 99:59:59.999 --> 99:59:59.999 Though if another star, launched from across the galaxy, is on its way to us, 99:59:59.999 --> 99:59:59.999 all bets are off.