Laplace equation only applies in limited regions ?

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SUMMARY

The discussion centers on the applicability of Laplace's equation, specifically why it is perceived to be limited to certain regions, while Poisson's equation can be utilized in unbounded domains. Participants clarify that Laplace's equation, defined by \(\nabla^2 f = 0\), can indeed apply outside limited regions, as evidenced by the function \(f = 1/r\) in the area outside a unit circle. The conversation also touches on the behavior of harmonic functions in spherical polar coordinates, particularly the divergence of \(r^l\) terms as \(r\) approaches infinity, which may contribute to misconceptions about the limitations of Laplace's equation.

PREREQUISITES
  • Understanding of Laplace's equation and Poisson's equation
  • Familiarity with harmonic functions and their properties
  • Knowledge of spherical polar coordinates
  • Basic grasp of Green's functions in the context of differential equations
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  • Study the properties of harmonic functions in various coordinate systems
  • Explore Green's functions for the Laplacian in unbounded domains
  • Investigate the implications of divergence in spherical coordinates
  • Learn about the applications of Poisson's equation in physics and engineering
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Mathematicians, physicists, and engineering students interested in differential equations, particularly those exploring the nuances of Laplace's and Poisson's equations in various domains.

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Why does laplace's equation only apply in limited regions, while Poisson's equation can apply in unbounded domains ?
 
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Where did you get the impression that Laplace's equation only applies in limited regions?

The function satisfying \nabla^2 f= 0, with f= 1 on the unit circle, in the region outside the circle is 1/r.
 
HallsofIvy said:
Where did you get the impression that Laplace's equation only applies in limited regions?

The function satisfying \nabla^2 f= 0, with f= 1 on the unit circle, in the region outside the circle is 1/r.



Thanks HallsofIvy:

I saw it in a book, but I agree with you that it doesn't seem to be true. However, I think 1/r may be the Green's function of the Laplacian in unbounded 3D domains.

Again, I agree with you that it seems strange, perhaps even untrue that Laplace equation would apply only to limited regions. If it turns out to be true, it may have something to do with the r^l terms in the harmonic functions in spherical polar coordinates. These terms diverge as r goes to infinity.

My above guess is unconvincing; especially since the r^{-(l+1)} terms will converge as r goes to infinity, and the divergent terms' coeffs can be chosen to decrease faster than the terms diverge. Any thoughts ?

BTW how is one able to write math expressions on this forum, such as the laplacian?
 
I'm now convinced it must be false. Consider the counter-example:

f(x) =x for x\in\Re,

then:

\nabla^{2}f(x)=0
 

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