Commuting Pauli Matrices: A Tricky Homework Challenge

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SUMMARY

The discussion focuses on the challenge of commuting Pauli matrices, specifically the product involving σy and σz. The key takeaway is that the exponentials of these matrices do not combine to yield the identity matrix due to their non-commuting nature, as indicated by the relation \left[\sigma^z,\sigma^x\right]\neq0. The solution involves expressing the exponential as a series to properly handle the matrices. This exercise emphasizes the importance of understanding matrix exponentiation in quantum mechanics.

PREREQUISITES
  • Understanding of Pauli matrices (σx, σy, σz)
  • Familiarity with matrix exponentiation
  • Knowledge of commutation relations in quantum mechanics
  • Basic skills in series expansion of functions
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  • Study the properties of Pauli matrices in quantum mechanics
  • Learn about matrix exponentiation techniques
  • Investigate the implications of non-commuting operators
  • Explore series expansions in the context of quantum mechanics
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Students and professionals in quantum mechanics, physicists dealing with quantum computing, and anyone interested in advanced linear algebra concepts related to matrix operations.

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Homework Statement



Express the product

where σy and σz are the other two Pauli matrices defined above.

commutatorpauli1.png



Homework Equations





The Attempt at a Solution



I'm not sure if this is a trick question, because right away both exponentials combine to give 1, where the result is simply σx

commutatorpauli2.png
 
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That's the whole point of the exercise, to see that the exponentials do not combine to give 1. To do such a thing, you would have to pass exp(i\alpha\sigma^z) to the other side of \sigma^x. But \left[\sigma^z,\sigma^x\right]\neq0 so that you can't simply commute them.

Hint: express the exponential as a series.
 
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kevinferreira said:
That's the whole point of the exercise, to see that the exponentials do not combine to give 1. To do such a thing, you would have to pass exp(i\alpha\sigma^z) to the other side of \sigma^x. But \left[\sigma^z,\sigma^x\right]\neq0 so that you can't simply commute them.

Hint: express the exponential as a series.

Ah, I see what you mean, as the sum is a matrix and not a number. Silly me.
 
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