Reflection coefficient of the step function potential

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Homework Statement


Consider the step function potential: [tex]V(x) = \{ \begin{array}{*{20}c}<br /> {0,(x \le 0)} \\<br /> {V_0 ,(x > 0)} \\<br /> \end{array}[/tex],Caculate the reflection coefficient,for the case E<V0,and comment on the answer


Homework Equations


[tex]- \frac{{\hbar ^2 }}{{2m}}\frac{{d^2 \psi }}{{dx^2 }} + V_0 \psi = E\psi[/tex]


The Attempt at a Solution


when x<=0,let [tex]k = \frac{{\sqrt {2mE} }}{\hbar }[/tex],then [tex]\psi (x) = Ae^{kxi} + Be^{ - kxi}[/tex],if x>0,then let [tex]l = \frac{{\sqrt {2m(V_0 - E)} }}{\hbar }[/tex],and [tex]\psi (x) = De^{ - lx}[/tex]


Then how do we explain it?The funtion is real in the right
 
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In the book,if psi(x) is not real in the right and left,then we can find the transmission and reflection coefficient.But in this question,it's not all complex.

definition of the reflection coefficient?You must know Quantum Tunneliing.it that one
 
I know what the reflection coefficient is. It's not clear to me that you did from your initial post.

It doesn't matter if all the solutions are not complex. The next step is the same: match the wavefunction and its derivative at the boundary.
 
Thanks very much.But why?how should we think about it?