Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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20.5 THE DIFFUSION EQUATION


term is a little less obvious. It can be viewed as representing the accumulated


transverse displacement at positionxdue to the passage pastxof all parts of


the initial motion whose effects can reachxwithin a timet, both backward and


forward travelling.


The extension to the three-dimensional wave equation of solutions of the type

we have so far encountered presents no serious difficulty. In Cartesian coordinates


the three-dimensional wave equation is


∂^2 u
∂x^2

+

∂^2 u
∂y^2

+

∂^2 u
∂z^2


1
c^2

∂^2 u
∂t^2

=0. (20.32)

In close analogy with the one-dimensional case we try solutions that are functions


of linear combinations of all four variables,


p=lx+my+nz+μt.

It is clear that a solutionu(x, y, z, t)=f(p) will be acceptable provided that
(
l^2 +m^2 +n^2 −


μ^2
c^2

)
d^2 f(p)
dp^2

=0.

Thus, as in the one-dimensional case,fcan be arbitrary provided that


l^2 +m^2 +n^2 =μ^2 /c^2.

Using an obvious normalisation, we takeμ=±candl,m,nas three numbers

such that


l^2 +m^2 +n^2 =1.

In other words (l, m, n) are the Cartesian components of a unit vectornˆthat


points along the direction of propagation of the wave. The quantitypcan be


written in terms of vectors as the scalar expressionp=nˆ·r±ct, and the general


solution of (20.32) is then


u(x, y, z, t)=u(r,t)=f(nˆ·r−ct)+g(ˆn·r+ct), (20.33)

wherenˆisanyunit vector. It would perhaps be more transparent to writenˆ


explicitly as one of the arguments ofu.


20.5 The diffusion equation

One important class of second-order PDEs, which we have not yet considered


in detail, is that in which the second derivative with respect to one variable


appears, but only the first derivative with respect to another (usually time). This


is exemplified by the one-dimensional diffusion equation


κ

∂^2 u(x, t)
∂x^2

=

∂u
∂t

, (20.34)
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