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[NOTES/QM-09001] Unitary Operator for Time Evolution

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That assumption that the superposition principle be preserved under time evolution leads to unitary nature of the  them evolution operator. The state vector satisfies  differential equation, the Schrodinger equation, with Hamiltonian as the generator of time evolution.

The description of state of a quantum mechanical system at one time is by a  vector, called state vector, in a Hilbert space. As the system evolves this state vector will change.We will see that  general requirements  lead to time evolution governed by unitary operator and for short times by a hermitian operator \(H\) which will be identified with Hamiltonian of the system.

Unitary nature of time evolution

Let $\ket{\psi t_0}$ represent the state of system at time $t_0$ and $\ket{\psi t}$ represent the state at time $t$. We assume that $\ket{\psi t_0}$ determines the state at time $t$ completely. The principle of superposition should apply at these two times $t_0$ and $t$. If we have a relation at time $t_0$ \begin{equation}\label{EQ02} \ket{\psi t_0} = \alpha\ket{\chi t_0} + \beta\ket{\phi t_0} \end{equation}
between three possible states,$\ket{\psi}, \ket{\chi}, \ket{\phi}$, the same relation must hold at all times $t > t_0$ when the system is left undisturbed \begin{equation}\label{EQ03} \ket{\psi (t)} = \alpha \ket{\chi t} + \beta\ket{\phi t} \end{equation}
Thus if we write
\begin{equation}\label{EQ03A} \ket{\psi t} = U(t,t_0)\ket{\psi t_0}\qquad\mbox{etc.} \end{equation}
Then $U(t,t_0)$ must be a linear operator independent of $\psi$. Obviously $U$ must reduce to the identity operator at time $t=t_0$ \begin{equation} U(t_0,t_0) = I\,\,\,. \end{equation}
Next we demand that the norm of vector $\ket{\psi t}$ should not change with time and hence \begin{equation}\label{EQ05} \innerproduct{\psi t}{\psi t} = \innerproduct{\psi t_0}{\psi t_0} \qquad\mbox{for all $t$} \end{equation}
The above requirements \eqref{EQ02} and \eqref{EQ05}, respectively, imply
\begin{equation} \matrixelement{\psi t_0}{U^\dagger U}{\psi t_0} = \innerproduct{\psi t_0}{\psi t_0} \qquad\mbox{ for all } \ket{\psi t_0} \end{equation}
It, therefore, follows that the operator $U$ must be must be a unitary unitary operator.
\begin{equation} UU^\dagger = U^\dagger U = I \end{equation}

Differential Equation for time evolution

We shall now derive a differential equation satisfied by the state vector at time $t$. We, therefore, compute \begin{eqnarray} {d\over dt} \ket{\psi t} &=& \lim_{\Delta t\to 0}{ \ket{\psi t+\Delta t)} - \ket{\psi t}\over\Delta t}\nonumber\\ &=& \lim_{\Delta t\to 0} {(U(t+\Delta t,t)-I) \over\Delta t} \ket{\psi t}\\ \mbox{or}~~{d\over dt} \ket{\psi t} &=& \hat{X}\ket{\psi t} \label{EQ08}\end{eqnarray}
where 
\begin{equation} \hat{X}(t) = \lim_{\Delta t\to 0} {U(t+\Delta t,t)-I\over\Delta t}= {d\over dt} U(t,t^\prime)|_{t^\prime=t} \end{equation}
The operator $\hat{X}$ can be shown to be anti-hermitian. Hence with notation \( (i\hbar) X \equiv H(t)\), the operator \(H(t)\) will be hermitian. We therefore write \eqref{EQ08} as \begin{equation} i\hbar{d\over dt} \ket{\psi t} = \hat{H}(t)\ket{\psi t} \end{equation} where \begin{equation} \hat{H}(t) ={1\over i\hbar} \dd{t} U(t,t^\prime)|_{t^\prime=t} \end{equation}
Thus the time evolution of a quantum system is governed by the equation
\begin{equation}\label{EQ17} i\hbar {\partial\over\partial t}\ket{\psi t} = \hat{H}(t)\ket{\psi t} \end{equation} Using correspondence with classical mechanics, Dirac shows that the operator $\hat{H}$ represents the energy,  i.e. the Hamiltonian, of the system. Using \eqref{EQ03A} in \eqref{EQ17} we get
\begin{equation} i\hbar\pp{t} U(t,t_0)\ket{\psi t_0} = \hat{H}(t)U(t,t_0)\ket{\psi t_0} \end{equation}
This equation must hold for all vectors $|\psi t_0\rangle$. Hence the time evolution operator $U$ must satisfy the differential equation
\begin{equation} i\hbar \pp{t} U(t,t_0) = \hat{H}(t)U(t,t_0) \,\,\,. \end{equation} It may be remarked that that \eqref{EQ17} has a wide applicability to all quantum systems, and not just quantum mechanics of point particles, a fact  not emphasized in most text books.

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