Translation operator problem: Difference between revisions

Source: Problem: The translation operator for a finite (spatial) displacement is given by , where p is the momentum operator. ${\displaystyle T(\mathbf {l} )=exp(-{\frac {i\mathbf {p} .\mathbf {l} }{\hbar }})}$

a. Evaluate ${\displaystyle [x_{i},T(\mathbf {l} ))]}$ b. Using (a) (or otherwise), demonstrate how the expectation value ${\displaystyle <\mathbf {x} >}$ changes under translation.

Solution: a) ${\displaystyle [x_{i},T(\mathbf {l} ))]=i\hbar {\frac {\partial T(\mathbf {l} )}{\partial p_{i}}}=i\hbar (-i{\frac {l_{i}}{\hbar }})exp(-{\frac {i\mathbf {p} .\mathbf {l} }{\hbar }})}$

${\displaystyle \Rightarrow =[x_{i},T(\mathbf {l} ))]=l_{i}T(\mathbf {l} )}$

b) ${\displaystyle <x_{i}>=<\alpha \mid x_{i}\mid \alpha >}$ ,${\displaystyle \mid \alpha >}$ is a general ket

${\displaystyle <\alpha \mid \ T^{+}(\mathbf {l} )[x_{i},T(\mathbf {l} ))]\mid \alpha >=<\alpha \mid T^{+}(\mathbf {l} )l_{i}T(\mathbf {l} )\mid \alpha >=l_{i}}$

${\displaystyle <\alpha \mid \ T^{+}(\mathbf {l} )[x_{i},T(\mathbf {l} ))]\mid \alpha >=<\alpha \mid T^{+}x_{i}T\mid \alpha \ >-<\alpha \mid T^{+}Tx_{i}\mid \alpha >}$

${\displaystyle \Rightarrow <x_{i}>_{translated}=<x_{i}>+l_{i}\Rightarrow <\mathbf {x} >_{translated}=<\mathbf {x} >+\mathbf {l} }$