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- Formalism for going from the von Neumann equation to the Schrödinger equation
I was trying to show how to get Schrödinger’s equation from the von Neumann equation and I’m not quite confident enough in my grasp of the functional analysis formalism to believe my own explanation. Starting from
$$i\hbar\frac{\partial}{\partial t}\rho=[H,\rho]$$
We have
$$i\hbar\left(\frac{\partial |\psi\rangle}{\partial t}\langle \psi| +|\psi\rangle\frac{\partial \langle\psi|}{\partial t}\right) =H|\psi\rangle\langle\psi|-|\psi\rangle\langle\psi|H$$
Collecting bra and ket terms,
$$\left(i\hbar\frac{\partial |\psi\rangle}{\partial t}-H|\psi\rangle\right)\langle\psi|=|\psi\rangle\left(-i\hbar\frac{\partial\langle\psi|}{\partial t}-\langle\psi|H\right)$$
My hand-wavy explanation is to put everything on one side and zero on the other and claim that the bra and ket coefficients have to go to zero separately. If I just had any two independent vector spaces, this explanation would suffice, but is this still true when the bra space and ket space are dual to one another? Apologies if I’m missing something obvious.
$$i\hbar\frac{\partial}{\partial t}\rho=[H,\rho]$$
We have
$$i\hbar\left(\frac{\partial |\psi\rangle}{\partial t}\langle \psi| +|\psi\rangle\frac{\partial \langle\psi|}{\partial t}\right) =H|\psi\rangle\langle\psi|-|\psi\rangle\langle\psi|H$$
Collecting bra and ket terms,
$$\left(i\hbar\frac{\partial |\psi\rangle}{\partial t}-H|\psi\rangle\right)\langle\psi|=|\psi\rangle\left(-i\hbar\frac{\partial\langle\psi|}{\partial t}-\langle\psi|H\right)$$
My hand-wavy explanation is to put everything on one side and zero on the other and claim that the bra and ket coefficients have to go to zero separately. If I just had any two independent vector spaces, this explanation would suffice, but is this still true when the bra space and ket space are dual to one another? Apologies if I’m missing something obvious.