How does one prove the anti-commutation of the operators $$e^{\hat{y}} , \hat{P}_y^2 $$ where $\hat{y}$ and $\hat{P}_y$ are the standard position operator and translation generator operator in quantum mechanics, respectively. $\hbar=1$
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What have you tried? – Davide Morgante Mar 27 '21 at 13:42
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Use definition of exponential of operator, employ the 'uncertainty relation' for each term such that I get an error term for each exponential term. E.g, for the cube term of the exponential, $$\hat{P}_y^2\hat{y}^3 = \hat{y}^3\hat{P}_y^2-3i[\hat{y}^2\hat{P}_y+\hat{P}_y\hat{y}^2]$$ We know that $$[\hat{y}^2\hat{P}_y+\hat{P}_y\hat{y}^2]=2\hat{P}_y\hat{y}^2-2i\hat{y}$$ and thus bracket term in first equation is non zero, this is true for all terms in the series for the exponential. – TheDawg Mar 27 '21 at 13:55
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Do you know what the commutator of $p$ with a function of $x$ is? Maybe this could help you. – Tobias Fünke Mar 27 '21 at 15:23
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I know that expression, but that is commutation involving operator $\hat{p}$, while I have $\hat{p}^2$ – TheDawg Mar 27 '21 at 16:08
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Well, there are some other useful relations regarding cases like $[AB,C]= \ldots$ Write down the commutator and then you should see how to rewrite $[p^2, f(x)]$ in terms of $[p,f(x)]$. – Tobias Fünke Mar 27 '21 at 16:15
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The exponential is the Lagrange shift operator for momenta, i.e. $$ e^{-ia \hat y} f(\hat p) e^{ia \hat y}= e^{ a \partial_p} f(\hat p) e^{-a \partial_p} = f(\hat p + a). $$ If you wish to focus on your stated particular case, $f(x)= x^2$, $a=i$, $$ e^{ \hat y} \hat p ^2 e^{ -\hat y}= (\hat p +i)^2,~~~\leadsto \\ e^{ \hat y} \hat p ^2 + \hat p ^2e^{ \hat y} =( (\hat p+i)^2+ \hat p^2 )e^{\hat y} . $$ It's hard to see why you'd need this partial result.
Cosmas Zachos
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The two operators are part of some Hamiltonian which, I want to prove, can not be diagonalized, that is, the time propagator being the exponential of the hamiltonian, sandwiched between position bra and momentum ket, can not be written as the exponential of some scalar value multiplied by the position bra momentum ket. – TheDawg Mar 28 '21 at 09:32
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