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| classes:2009:fall:phys4101.001:q_a_1030 [2009/11/01 22:11] – cwu | classes:2009:fall:phys4101.001:q_a_1030 [2009/11/30 16:32] (current) – youmans | ||
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| ===Hardy 11:20 - 11/ | ===Hardy 11:20 - 11/ | ||
| I also have a hard time to understanding the math inside this equation. It turns out to be equivalent to the proof of equation [3.31] in our textbook. I think the technique used in the proof must be very tricky and just a matter of math. | I also have a hard time to understanding the math inside this equation. It turns out to be equivalent to the proof of equation [3.31] in our textbook. I think the technique used in the proof must be very tricky and just a matter of math. | ||
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| + | ===Blackbox 2:10 - 11/ | ||
| + | Yes, it' a kind of Fourier trick. If you look at the equation 2.144, then you would understand how this proof has been made. | ||
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| + | === Can 10:48 11/06/09 === | ||
| + | For Chap < | ||
| ====ralph - 11:10AM 10/ | ====ralph - 11:10AM 10/ | ||
| In problem 3.13 we had to show three parts. | In problem 3.13 we had to show three parts. | ||
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| ====ralph - 11:10AM 10/ | ====ralph - 11:10AM 10/ | ||
| Now that I'm getting a better understanding of the new notation, can someone explain to me if it's possible to have multiple eigenvalues for the same state? | Now that I'm getting a better understanding of the new notation, can someone explain to me if it's possible to have multiple eigenvalues for the same state? | ||
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| ===Hardy - 11:30 - 11/01/09=== | ===Hardy - 11:30 - 11/01/09=== | ||
| I think it can't be possible for a same state to have multiple eigenvalues. Because the state is determined by | I think it can't be possible for a same state to have multiple eigenvalues. Because the state is determined by | ||
| - | < | + | < |
| + | ===Andromeda 10:51 11/ | ||
| + | the degenerate states of some operator share the same eigenvalues. for example in an atom two or more different configuration of electrons can have the same energy. | ||
| ====ralph - 11:10AM 10/ | ====ralph - 11:10AM 10/ | ||
| My understanding is that the space-momentum uncertainty principle is analogous to the time-energy one. What are the implications of this? Should I change my understanding of how momentum and energy are related? | My understanding is that the space-momentum uncertainty principle is analogous to the time-energy one. What are the implications of this? Should I change my understanding of how momentum and energy are related? | ||
| + | ===Andromeda 10:59 11/ | ||
| + | i think i might be overthinking this too but i am having trouble understanding the whole explanation of how energy time form of the uncertainty principle is a " | ||
| + | == prest121 23:10 11/1/2009 == | ||
| + | I think the point Griffiths is trying to make is that the momentum-position uncertainty principle resembles the energy-time uncertainty principle, primarily because the uncertainty for both is < | ||
| + | ====Dagny==== | ||
| + | What is a good method for finding the determinant of an nxn matrix? Do you think we will need to be able to find such a determinant in this class? Why or why not? | ||
| - | + | ====Jake22 4:30 11/ | |
| - | + | Must all non-degenerate energy eigenfunctions be parity eigenfunctions? | |
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| -------------------------------------- | -------------------------------------- | ||
| **Return to Q&A main page: [[Q_A]]**\\ | **Return to Q&A main page: [[Q_A]]**\\ | ||
| **Q&A for the previous lecture: [[Q_A_1028]]**\\ | **Q&A for the previous lecture: [[Q_A_1028]]**\\ | ||
| **Q&A for the next lecture: [[Q_A_1102]]** | **Q&A for the next lecture: [[Q_A_1102]]** | ||
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