What Does Continuous Derivative Mean in Quantum Mechanics?

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Homework Help Overview

The discussion revolves around the concept of continuous derivatives in the context of quantum mechanics, specifically regarding wavefunctions and their behavior at boundaries defined by potential shapes.

Discussion Character

  • Conceptual clarification, Assumption checking

Approaches and Questions Raised

  • The original poster expresses confusion about the meaning of a continuous derivative in relation to wavefunctions and seeks clarification on the mathematical representation. Participants discuss the continuity conditions at boundaries between different potential regions and reference the Schrödinger equation.

Discussion Status

Some participants have provided insights into the continuity conditions of wavefunctions and their derivatives at boundary points. There appears to be a productive exchange of ideas, with references to specific equations and potential shapes being explored.

Contextual Notes

The original poster mentions difficulty in recalling the mathematical implications of continuous derivatives, indicating a potential gap in foundational understanding. The discussion includes references to specific potential shapes and the requirements for wavefunctions in quantum mechanics.

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In Quantum Mechanics the one of the constraints on the wavefunction is that its derivative is continuous, what I have a problem with is that I have forgotten what this actually means in terms of an equation.

ie

\frac{d\psi){dx}=?[\tex]<br /> <br /> This is driving me nutty and looked on the internet but not found what I am looking for! If some one can help me then that would be great!<br /> <br /> Thank you <br /> <br /> newo<br />
 
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Suppose we have this potential shape:

a, V = +inf at x < 0
b, V = - V_0 at 0 < x < a V_0 > 0
c, V = 0 at x > a

We get one wavefuntion at region b, call it psi_1(x) and one for region c, called psi_2(x), by solving the shrödinger equation.

Now psi_1(a) = psi_2(a)
and
d(psi_1(a))/dx = d(psi_2(a))/dx

and we have:

psi_1(a) / [d(psi_1(a))/dx ] = psi_2(a) / [d(psi_2(a))/dx]

was it this you were looking for?
 
Thats what i was looking for i remember now thanks!

malawi_glenn said:
Suppose we have this potential shape:

a, V = +inf at x < 0
b, V = - V_0 at 0 < x < a V_0 > 0
c, V = 0 at x > a

We get one wavefuntion at region b, call it psi_1(x) and one for region c, called psi_2(x), by solving the shrödinger equation.

Now psi_1(a) = psi_2(a)
and
d(psi_1(a))/dx = d(psi_2(a))/dx

and we have:

psi_1(a) / [d(psi_1(a))/dx ] = psi_2(a) / [d(psi_2(a))/dx]

was it this you were looking for?
 
hehe great, Good luck with the QM! =)

You can also check with the definitions and requriments of an continuous function in calcus books.
 

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