Here is a quote from Introduction to quantum mechanics by David J Griffiths:
- The general solution is a linear combination of separable solutions. As we're about to discover, the time-independent Schroedinger equation (Equation 2.5) yields an infinite collection of solutions ($\psi_1(x)$, $\psi_2(x)$, $\psi_3(x)$,...), each with its associated value of the separation constant ($E_1$, $E_2$, $E_3$,...); thus there is a different wave function for each allowed energy: $$\Psi_1(x, y) = \psi_1(x)e^{-iE_1 t/\hbar},\quad \Psi_2(x, y) = \psi_2(x)e^{-iE_2 t/\hbar}, \ldots.$$ Now (as you can easily check for yourself) the (time-dependent) Schroedinger equation (Equation 2.1) has the property that any linear combination5 of solutions is itself a solution. Once we have found the separable solutions, then, we can immediately construct a much more general solution, of the form $$\Psi(x, t) = \sum_{n = 1}^{\infty}c_n\psi_n(x)e^{-iE_n t/\hbar}\tag{2.15}$$
I am trying to understand it in this way.
...the time independent Schroedinger's equation $\hat H\psi = E\psi$
An eigenvalue equation $Ax = \lambda x$,
yields an infinite collection of solutions ($\psi_1(x)$, $\psi_2(x)$, $\psi_3(x)$, $\dots$)
has eigen vectors $x_1$, $x_2$, $x_3$, $\dots$
each with it's associated value of separation constant ($E_1$, $E_2$, $E_3$, $\dots$);
each with it's associated eigen value $\lambda_1$, $\lambda_2$, $\lambda_3$, $\dots$
thus there is a different wave function for allowed energy: $$\Psi_1(x,t) = \psi_1(x)e^{-iE_1t/\hbar},\quad\Psi_2(x,t) = \psi_2(x)e^{-iE_2t/\hbar}, \dots$$
have equations as $$Ax_1=\lambda_1x_1, \qquad Ax_2=\lambda_2x_2, \dots$$
Once we have found the separable solutions, then, we can immediately construct a much more general solution, of the form $$\Psi(x,t) = \sum_{n=1}^{\infty}c_n\psi_n(x)e^{-E_nt/\hbar}$$
(Forgetting the any other variable dependence) We can construct a more general solution of the form $$X = \sum_{n}c_n x_n$$
This last equation doesn't make any sense to me. There is nothing in linear algebra that says that this last equation logically precedes the previous equations. Trying to understand from linear algebra, what does the last equation mean? Why is the general solution of Schroedinger's equation a linear combination of the eigenfunctions?