Precise measurements in Quantum Mechanics

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Discussion Overview

The discussion revolves around the concept of precise measurements in quantum mechanics, particularly focusing on the relationship between the expectation value postulate and the uncertainty principle. Participants explore the implications of wave functions being eigenstates of operators and the nature of measurement outcomes in quantum systems.

Discussion Character

  • Exploratory
  • Debate/contested
  • Technical explanation

Main Points Raised

  • Some participants assert that an observable can only be precisely measured if the wave function is an eigenfunction of the corresponding operator.
  • Others argue that while position and momentum cannot be simultaneously measured precisely, one can measure one property at the expense of the other, leading to a change in the wave function.
  • A participant questions the necessity of the eigenfunction condition by comparing it to rolling a die, suggesting that expectation values can differ from precise outcomes.
  • Another participant clarifies that "precise" may refer to "determinate," indicating that only eigenstates guarantee a specific measurement outcome.
  • One participant presents a hand-wavy analogy involving a die to illustrate the difference between expectation values and actual measurement outcomes, emphasizing the change in state upon measurement.

Areas of Agreement / Disagreement

Participants express differing views on the interpretation of precise measurements and the implications of the uncertainty principle. There is no consensus on how to reconcile these concepts, and the discussion remains unresolved.

Contextual Notes

Some limitations include the dependence on definitions of "precise" and "determinate," as well as the unresolved nature of how to apply classical analogies to quantum mechanics.

mpkannan
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It follows from the Expectation value postulate that an observable A, associated with the operator A^, can be precisely measured only if the wave function ψ of the system is an eigenfunction of A^ .

Accordingly, the position and momentum of a particle can never be precisely measured because the wave function (energy eigenfunction) is not an eigenfunction of the operators of these properties.

In the popular statement of the uncertainty principle, viz., the position and momentum of a particle cannot be measured precisely and simultaneously, it appears that one of these properties can be precisely measured sacrificing the other. Does it not contradict the above deduction from the expectation value postulate, that the wave function should be an eigenfunction of the operator of the property in order to measure the property precisely?
 
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A quantum state cannot be a simultaneous eigenfunction of position and momentum. Position eigenstates do exist, as do momentum eigenstates. You just can't be an eigenstate of both.

You may take an arbitrary state and measure its position, so that it becomes (collapses into) a position eigenstate. The state now has a determinate, known position. The probability that is a particular value is given by square of the projection of the original state onto the position basis (ie this is probably what you mean by the expectation value postulate). Note that, unless the original state was a position eigenstate, your new state is different; the act of measurement (the projection onto the new basis) has altered the state!

You may then take this position eigenstate and measure its momentum, so that it becomes a momentum eigenstate. The state has changed again; now it has determinate, known position.

If you had two commuting observables A and B (position and momentum are NOT commuting), you could take an eigenstate of A and then measure its B without changing the state. This is because commuting observables share an eigenbasis: the projection (the measurement) has no effect.
 
mpkannan said:
It follows from the Expectation value postulate that an observable A, associated with the operator A^, can be precisely measured only if the wave function ψ of the system is an eigenfunction of A^ .
Why should this follow? If I throw a standard dice, my expectation value is 3.5 but my measurement outcome is always "precisely" an integer between 1 and 6.
 
Precise measurements in QM

kith said:
Why should this follow? If I throw a standard dice, my expectation value is 3.5 but my measurement outcome is always "precisely" an integer between 1 and 6.

But, you cannot predict whether you get 1 or 2 or ...6 in each measurement you make. This leads to uncertainty.
 
I think that, by "precise", mpkannan means "determinate". If ψ is an eigenstate to begin with, we are guaranteed that its measurement will yield a particular value (the corresponding eigenvalue). Otherwise, we can't predict with certainty the outcome of the measurement.

"Precise" probably isn't the most appropriate term since it is typically used as kith used it.
 
kith said:
Why should this follow? If I throw a standard dice, my expectation value is 3.5 but my measurement outcome is always "precisely" an integer between 1 and 6.

In a VERY hand-wavy way (hand-wavy because I'm using ordinary uncertainty about the state of the die, a very different mathematical proposition than superposition of eigenfunctions)...

WARNING - hand-waving follows. Use at your own risk!

While the die is in the air the expectation is indeed 3.5. Once it lands on a flat surface and stops (that is, interacts with the measuring apparatus) it will settle into one of six states defined by which face is up; all six of these are very different from the state while it's in the air. When the die is in the in-the-air state, I cannot claim to have made any measurement of its value; all I can say is that if I made such a measurement the expectation value would be 3.5. After I've forced the die into one of the six resting-on-a-flat-surface states, I can read its value off the top face with absolute precision, and (because the die is in a different state) the expectation value of the next reading is not 3.5.

We could push the analogy to the breaking point (Hey - it's your analogy not mine! - don't blame me!) by saying that the in-the-air state is analogous to a superposition of the six on-a-flat-surface states which are analogous to eigenstates of the "value operator".

However, we can't push the analogy far enough to answer OP's question (How do we reconcile the uncertainty principle with the fact of precise values of observables in some eigenstates) because we'd need a second non-commuting observable, and dice don't have that.
 

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