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toombs
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vinniewryan said:
First of all, it is not an induced spin, it is an induced change in spin. The former would imply the electron had no spin to start with, which isn't true.
A laser can change an electron's spin state because the energy of an electron in a magnetic field is a function of this state. This is one of the measurable consequences of spin. Despite what lasers can do to an electron's spin, the electron is definitely not spinning in the usual sense of a revolving mass. The reason is because the mathematical description of an electron's spin is much different from the description of that of a rotating mass and both kinds of system can be described in the mathematics of quantum physics. (Molecules are good examples of rotating masses.)
To understand what I mean completely, you'd need to look at the actual math, the most complete, accurate and unambiguous description of just what the hell is going on. For now, I'll just say that a spinning particle's total angular momentum squared has the form L^2 = h_bar^2 n(n+1) where n is a non-negative integer, but the total angular momentum of an electron squared is always L^2 = h_bar^2 1/2 (1/2 + 1) = h_bar^2 3/4! (an exclamation point; not a factorial.) The last statement means that it is impossible to try to get an electron to spin faster. It is impossible to try to stop an electron from spinning. This is very very unlike the behaviour of the rotating mass, for which both these things are possible. Just change n to change the total momentum squared and set it to zero for no total momentum. You'll also notice that for the electron, n = 1/2, something that the rotating mass cannot do.
Now, it seems spin is unimportant because the total spin doesn't change. Even in classical physics there is more to angular momentum than the total. Angular momentum also has a direction. Similarly, there is more to spin than the total spin. There is a direction involved here too. This is the spin state of the electron.
As a caveat, the above is not a completely accurate statement of just what the hell is going on either, but it's not bad. Unfortunately, the next most accurate description constitutes half of a third year undergraduate physics course and I don't care to repeat it all here in a single post. Our textbook was introductory quantum mechanics by Griffiths, otherwise known as Griffiths. It would do a better job of explaining things further than I could.
So like any situation where you don't know what's going on, do what we all do: RTFM. Ask questions later.
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