Then I got sidetracked by a fascinating Master's Thesis by a guy named Jared Stenson, who argues that we should really look at what the silver atoms do when they pass through a pure quadrupole field, instead of the traditional Stern Gerlach. Stenson claims, with some justification, that the beam of atoms then spreads into a donut. This is very different from the traditional Stern Gerlach where the beam simply splits in two.
Stenson did his analysis for an unpolarized beam, and last week I refined his analysis for the case of the polarized beam. I got a beautiful pattern of spin distributed about the donut. For an initial spin-up beam configuarion, this is the pattern at the detector screen:
Stenson points out that the original experiment was done, not with a pencil-shaped beam, but with a fan-shaped source. There never were two disrete dots representing "spin-up" and "spin-down". There were in fact two bands, representing the splitting of the fan-shaped beam. No, that's not eve right: the two bands came together at the ends, making an elongated ellipse. And isn't an elongated ellipse just another name for an elongated circle?
And what is the effect of the constant field on the beam of silver atoms? AB-SO-LUTE-LY nothing! Ok, to be fair, if the spin is lined up cross-wise to the field, there should be precession; but because the field is constant, any precession is also constant across the beam profile; so when it leaves the field, there is no shifting of phases which would tend to make the beam curve or bend. It just keeps going straight.
Any diffraction or bending of the beam can only come from the quadrupole component; and that's what we've calculated. The silver atoms don't suddenly jump into one of two possible states at all...they spread themselves around the axis of the beam in a symmetric pattern, showing all possible valuse of spin orientation. In the picture, I've shown the result for a polarized beam, where the circular distribution is skewed in the direction of the spin polarization. For the unpolarized beam, you get the uniform circular donut pattern.
Yes, there is a way you can set up the experiment so the spin appears to jump into one of two possible values: instead of using a pencil-shaped beam, you spread the beam out into a fan-shape. Then you get diffraction effects and interference so that the deposition pattern on the screen spreads out into an elongated ellipse, which, ignoring the endpoints, looks like two discreet bands. But that's not the Stern-Gerlach experiment the way the whole world talks about it. The real story is right here on this blog, and I just wonder if you can find this analysis ANYWHERE else.
6 comments:
Very interesting, thanks.
Have you refined your ideas since writing this blog?
Glad you like it, Mark. Have you read my posts on quantum siphoning?
http://marty-green.blogspot.ca/2014/12/wave-function-collapse-explained-by.html
Hi, check out the first slide here, you may like it:
http://www-bcf.usc.edu/~tbrun/Course/lecture02.pdf
Look at:
- the pattern on the screen,
- the legend below the figure.
That's brilliant. The slide shows a modified version of the elliptical tracde found in the actual Stern-Gerlach results, which they got by using a fan-shaped beam (from a slit aperture), not a pencil beam. But the text does not acknowledge this at all. It blithely continues as though the pencil-shaped beam had been split into two dots at the screen.
In the Stern—Gerlach experiment, it’s not a pure quadrupole, but at least the sum of a quadrupole and a constant field. If one treats the magnetic moment classically, the constant field induces a Larmor precession, so that the movement orthogonal to the field average out to 0. This leads to a vertical line and not a ring for unpolarized classical magnetic moments.
A complete quantum treatment uses spinors and wave-packet, and I haven’t done it. A simpler approximation, neglecting the quantum effects on the position (small λ de Broglie) consist in using the direction of the magnetic field as quantization axis. This leads to two points for a narrow beam.
Without an added global constant field, as in a pure quadrupolar field, I agree that it would lead to a ring for an unpolarized beam, but it is not the situation in the Stern–Gerlach experiment. Furthermore, if you send a fan beam to such a field, you will have the addition of many rings, not an elongated one, and this will remove the central hole. I do not see how a mixture of rings would explain the experimentally observed eye pattern.
Yes, Frederic, you've identified my error. The donut (ring) is what you get from a pure quadrupole field, but I assumed the addition of the DC field would have no effect. In fact, it causes a precession which disrupts the side-to-side effect, leaving only the up-and-down polarization.
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