The thinker said:
Are you saying that the new worlds are not actually new at all, just copies of the one world into different dimensions of the same universe? Like two 2-d worlds (pieces of paper for example) separated by a 3rd dimension (one is above the other).
Not quite like that. I'll try to explain. It would be easier if I could draw a picture, but I suck at making cool graphics so I'll just try to describe the mental picture I keep in my head when I think about these things.
We usually think of a measurement as a process that "collapses" the wave function, i.e. as a process that projects a superposition onto one of the eigenstates of the observable being measured. For example, if the system is a spin-1/2 particle in a superposition |\psi\rangle=a|+\rangle+b|-\rangle and we measure the z-component of the spin, the measurement changes the state of the particle into either |+\rangle or |-\rangle.
The "measurement problem" of quantum mechanics is the conflict between this description of a measurement and the claim that physical systems change with time according to the Schrödinger equation. Wave function collapse contradicts the Schrödinger equation, so it appears that we have two different types of time evolution in quantum mechanics, and no clear way to tell when we should use the first kind and when we should use the second kind.
This "problem" isn't really a problem if we adopt the view that quantum mechanics is
just an algorithm that we can use to predict the probabilities of the possible results of any experiment. This view is of course perfectly valid, but it's not the one that proponents of the MWI prefer. The MWI proponents believe that quantum mechanics isn't
just an algorithm that tells us probabilities of possibilites, but also an accurate
description of reality. In other words, they think that state vectors represent something that actually exists. The problem with this view is that it promotes the measurement problem into a real paradox...unless...the second kind of time evolution is really just a special case of the first.
So let's assume that
all physical systems evolve according to the Schrödinger equation and see where this takes us. (It will more or less force us to accept the existence of many worlds, if we also believe that quantum mechanics describes reality). If the assumption is correct, then the entire universe evolves according to the Schrödinger equation, and it makes sense to consider the wave function of the universe.
Now let's try to visualize the state of the universe.
The possible states of the universe are represented by vectors in a complex Hilbert space. Unfortunately, we can't really visualize complex dimensions, or a large number of real dimensions. The best we can do is to visualize three real dimensions, so let's do that. Imagine three axes, labeled x, y and z. We will let the x-y plane represent the spin state of a single spin-1/2 particle, and let the z direction represent the state of the rest of the universe (including other properties of that particle). Yeah, I know, we're omitting absurd amounts of information from this picture, but we don't really have a choice.
In this picture, |+\rangle is a unit vector in the x direction, and |-\rangle is a unit vector in the y direction, so an arbitrary linear combination |\psi\rangle=a|+\rangle+b|-\rangle is a vector in the x-y plane. (Note that even the picture of the x-y plane omits information, since a and b are really complex numbers). The vector that describes the state of the universe is a vector of the form |\phi\rangle|\psi\rangle, where |\phi\rangle represents the state of the rest of the universe.
Now suppose that we measure the spin of that particle. We know that we will always find the spin to be either "up" or "down", so the time evolution of the state of the universe is going to be approximately
|\phi\rangle|\psi\rangle\longrightarrow a|\phi_+\rangle|+\rangle + b|\phi_-\rangle|-\rangle
There are other terms on the right-hand side, but they are very small. I put a + or a - subscript on the state of the "rest of the universe" to indicate that it has also changed (since a measurement is a physical interaction between the system and the rest of the universe). The state |\phi_+\rangle includes the happy observer from my previous post, and |\phi_+\rangle includes the sad observer.
Now, here's the point I've been trying to make: The first term is a point in the x-z plane, and the second term is a point in the y-z plane. Those two planes are now the Hilbert spaces of possible states of two different worlds.
Note that the state vector of the universe isn't really projected onto one of these subspaces. It continues to evolve according to the Schrödinger equation, tracing out a curve in the x-y-z space, but after the measurement, there are two subspaces of the Hilbert space we started with that have a significance of their own. Those subspaces, weren't created by the interaction. They were always there. The interaction simply made them
relevant to physical systems that include brains.
We can't possibly represent the difference between |\phi_+\rangle, |\phi_-\rangle and |\phi\rangle in the picture we've made, so in the picture, the states of the two worlds are just the projections of the state vector of the universe onto two subspaces that were selected by the physical interaction that the observer thought of as a measurement.
, so I'll just post it here.
> + b|->|right>|
>