Calculate expectation value of entangled 2 state system?

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SUMMARY

The discussion focuses on calculating the expectation value of an entangled two-state system using the operator C with eigenstates |B⟩ and |R⟩. The projection operator P_R = |R⟩⟨R| is utilized to derive the probability of measuring the states, resulting in an expectation value of 0. This indicates that over a large number of measurements, the average result will yield 0, reflecting the balance between the eigenvalues of 1 and -1. The distinction between expectation values and projection operators is clarified, emphasizing their roles in quantum measurements.

PREREQUISITES
  • Understanding of quantum mechanics concepts, specifically eigenstates and operators.
  • Familiarity with projection operators and their mathematical representation.
  • Knowledge of calculating expectation values in quantum systems.
  • Basic proficiency in linear algebra, particularly with column vectors.
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  • Study the mathematical formulation of quantum measurement theory.
  • Learn about the implications of eigenvalues in quantum mechanics.
  • Explore the role of projection operators in quantum state manipulation.
  • Investigate the concept of entanglement and its effects on measurement outcomes.
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Students and researchers in quantum mechanics, physicists working with quantum systems, and anyone interested in the mathematical foundations of quantum measurement and entanglement.

ianmgull
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Homework Statement



Image_1.jpg

Homework Equations


I know that there are two eigenstates of the operator C:

|B> = (1 0) as a column vector with eigenvalue 1
|R> = (0 1) also a column vector with eigenvalue -1

The Attempt at a Solution


My work is shown here:

IMG_3540.jpg


If anyone could point me in the right direction, I'd greatly appreciate it. I've been stuck for hours and just can't figure out what I'm doing wrong.

thanks

Ian
 

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Use a projection operator. A projector on the red basis would look like P_R = |R\rangle\langle R|. Then (dropping 1 and 2 subscripts, and assuming orthogonal states):

<br /> Prob_R =\frac{1}{2} (\langle B|\langle R| - \langle R|\langle B|)|R\rangle\langle R|(|B\rangle|R\rangle -|R\rangle|B\rangle )=\frac{1}{2}<br />

The expectation value of C is the probability that the measurement produces either 1 or -1, so the average result will be 0.
 
I just worked it out and that makes much more sense.

I'm still a little unclear on (conceptually) what meaning I should attribute to taking the expectation value of an operator (like above) vs a projection operator.

Thanks so much!
 
The eigenvalues are what can be measured in a lab; an expectation value will give you the average result that will be obtained over a large number of measurements, in this case 0. A projection operator projects the state onto a basis (red or blue) according to a probability, 1/2 here.
 
Awesome.

THANK YOU
 

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