How do spin measurements of particles relate to complex amplitudes?

AI Thread Summary
The discussion focuses on the relationship between spin measurements of particles and complex amplitudes. It begins with a specific state for measuring the spin in the x-direction, expressed as a superposition of spin states. The goal is to determine the amplitudes for measuring spin in the z-direction, questioning why the phase angle φ is set to zero. The conversation highlights that multiplying an eigenstate by a complex number does not change the eigenstate, but emphasizes the importance of the ratio of complex amplitudes for different spin measurements. Ultimately, the calculations reveal that the ratio for measuring s_z yields a value of 1, while for s_y, it results in i.
Grand
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Homework Statement


Say we want to fiddle with spin of a particle.

The state in which a measurement of s_x is certain to yield +1/2 is:
|+,x\rangle=\sin{\frac{\pi}{4}}e^{i 0}|-\rangle+\cos{\frac{\pi}{4}}e^{-i 0}|+\rangle=\frac{1}{\sqrt{2}}(|-\rangle+\+|+\rangle)

Now, for this state, we want to find the amplitude for measuring s_z to be either 1/2 or -1/2. We have to apply the bra
\langle+,s_z|=sin0e^{i\phi/2}\langle-|+cos0e^{i\phi/2}\langle+|

What I want to ask about is why in here \phi=0 as well - it is the z direction, which is determined only by \theta=0.
 
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Hi Grand! :wink:

If you multiply any eigenstate by an ordinary complex number, don't you get the same eigenstate?
 
Yes, we do. The probability is computed as mod squared of the amplitude. But here we have to show that the ratio of the complex amplitudes to measure the momentum s_z to be 1/2 and -1/2 is 1 and for the same calculation, but for y it is i.
 
Thread 'Variable mass system : water sprayed into a moving container'

Thread 'Variable mass system : water sprayed into a moving container'

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