Spin probability of a particle state

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Zack K
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Homework Statement
Suppose that a measurement of ##S_x## is carried out on a particle in the state ##|\textbf{+n}\rangle##. What is the probability that the measurement yields (i) ##\frac{\hbar}{2}## (ii) ##\frac{-\hbar}{2}##?
Relevant Equations
##|\textbf{+n}\rangle = cos\frac{\theta}{2}|+\textbf{z}\rangle + e^{i\phi}sin\frac{\theta}{2}|-\textbf{z}\rangle##
Starting with finding the probability of getting one of the states will make finding the other trivial, as the sum of their probabilities would be 1.

Some confusion came because I never represented the states ##|\pm \textbf{z}\rangle## as a superposition of other states, but I guess you would not need to.

My attempt:$$\langle+\textbf{x}|+\textbf{n}\rangle=cos\frac{\theta}{2}\langle+\textbf{x}|+\textbf{z}\rangle + e^{i\phi}sin\frac{\theta}{2}\langle+\textbf{x}|-\textbf{z}\rangle$$

Since ##|\textbf{x}\rangle = \frac{1}{\sqrt{2}}|+\textbf{z}\rangle + \frac{1}{\sqrt{2}}|-\textbf{z}\rangle## has only real parts, the bra vector coefficients look the same so then ## \langle+\textbf{x}|\pm\textbf{z}\rangle =\frac{1}{\sqrt{2}}##. Therefore we get

$$\langle+\textbf{x}|+\textbf{n}\rangle=\frac{1}{\sqrt{2}}cos\frac{\theta}{2} + \frac{1}{\sqrt{2}}e^{i\phi}sin\frac{\theta}{2}$$

The probability is this expression squared, which expands into

$$\frac{1}{2}\left(cos^2\frac{\theta}{2}+sin(2\theta)cos(\phi)+sin^2\frac{\theta}{2}cos(2\theta)+i(sin^2\frac{\theta}{2}sin(2\phi)+sin(2\theta)sin(\phi))\right)$$

The answer is given as ##\frac{1}{2}(1+sin(\theta)cos(\phi))##

I have plugged in some values of theta and phi and my answer and that of the textbook evaluated to the same answer, though I am still skeptical on my answer. I cannot see how I could reduce this, I have tried using wolframalpha to no luck. Though I am more interested in knowing if my steps were correct.
 
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Zack K said:
Homework Statement:: Suppose that a measurement of ##S_x## is carried out on a particle in the state ##|\textbf{+n}\rangle##. What is the probability that the measurement yields (i) ##\frac{\hbar}{2}## (ii) ##\frac{-\hbar}{2}##?
Relevant Equations:: ##|\textbf{+n}\rangle = cos\frac{\theta}{2}|+\textbf{z}\rangle + e^{i\phi}sin\frac{\theta}{2}|-\textbf{z}\rangle##

Starting with finding the probability of getting one of the states will make finding the other trivial, as the sum of their probabilities would be 1.

Some confusion came because I never represented the states ##|\pm \textbf{z}\rangle## as a superposition of other states, but I guess you would not need to.

My attempt:$$\langle+\textbf{x}|+\textbf{n}\rangle=cos\frac{\theta}{2}\langle+\textbf{x}|+\textbf{z}\rangle + e^{i\phi}sin\frac{\theta}{2}\langle+\textbf{x}|-\textbf{z}\rangle$$

Since ##|\textbf{x}\rangle = \frac{1}{\sqrt{2}}|+\textbf{z}\rangle + \frac{1}{\sqrt{2}}|-\textbf{z}\rangle## has only real parts, the bra vector coefficients look the same so then ## \langle+\textbf{x}|\pm\textbf{z}\rangle =\frac{1}{\sqrt{2}}##. Therefore we get

$$\langle+\textbf{x}|+\textbf{n}\rangle=\frac{1}{\sqrt{2}}cos\frac{\theta}{2} + \frac{1}{\sqrt{2}}e^{i\phi}sin\frac{\theta}{2}$$

The modulus squared of a complex number ##w## is given by ##|w|^2 = ww^*##, where ##w^*## is the complex conjugate. The resulting expression is real and cannot have a factor of ##i## in it.

What is the complex conjugate of
$$\frac{1}{\sqrt{2}}cos\frac{\theta}{2} + \frac{1}{\sqrt{2}}e^{i\phi}sin\frac{\theta}{2}$$
 
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