How to Solve the Schrödinger Equation for Free Particles

There are plenty of free particles — particles outside any square well —in the universe, and quantum physics has something to say about them. The discussion starts with the Schrödinger equation:

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Say you’re dealing with a free particle whose general potential, V(x) = 0. In that case, you’d have the following equation:

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And you can rewrite this as

image2.png

where the wave number, k, is

image3.png

You can write the general solution to this Schrödinger equation as

image4.png

If you add time-dependence to the equation, you get this time-dependent wave function:

image5.png

That’s a solution to the Schrödinger equation, but it turns out to be unphysical. To see this, note that for either term in the equation, you can’t normalize the probability density,

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as long as A and B aren’t both equal to zero.

What’s going on here? The probability density for the position of the particle is uniform throughout all x! In other words, you can’t pin down the particle at all.

This is a result of the form of the time-dependent wave function, which uses an exact value for the wave number,

image7.png

So what that equation says is that you know E and p exactly. And if you know p and E exactly, that causes a large uncertainty in x and t — in fact, x and t are completely uncertain. That doesn’t correspond to physical reality.

For that matter, the wave function

image8.png

Marylouise, can you format the EQ above as a gif? Thanks, Alexa.

as it stands, isn’t something you can normalize. Trying to normalize the first term, for example, gives you this integral:

image9.png

EQ needs to be a gif.

Remember that the asterisk symbol (*) means the complex conjugate. A complex conjugate flips the sign connecting the real and imaginary parts of a complex number.

And for the first term of

image10.png

EQ needs to be a gif.

And the same is true of the second term in

image11.png
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