Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(lu) #1

PDES: SEPARATION OF VARIABLES AND OTHER METHODS


21.2 A cube, made of material whose conductivity isk, has as its six faces the planes
x=±a,y=±aandz=±a, and contains no internal heat sources. Verify that
the temperature distribution


u(x, y, z, t)=Acos

πx
a

sin

πz
a

exp

(



2 κπ^2 t
a^2

)


obeys the appropriate diffusion equation. Across which faces is there heat flow?
What is the direction and rate of heat flow at the point (3a/ 4 ,a/ 4 ,a)attime
t=a^2 /(κπ^2 )?
21.3 The wave equation describing the transverse vibrations of a stretched membrane
under tensionTand having a uniform surface densityρis


T


(


∂^2 u
∂x^2

+


∂^2 u
∂y^2

)



∂^2 u
∂t^2

.


Find a separable solution appropriate to a membrane stretched on a frame of
lengthaand widthb, showing that the natural angular frequencies of such a
membrane are given by

ω^2 =

π^2 T
ρ

(


n^2
a^2

+


m^2
b^2

)


,


wherenandmare any positive integers.
21.4 Schrodinger’s equation for a non-relativistic particle in a constant potential region ̈
can be taken as



^2


2 m

(


∂^2 u
∂x^2

+


∂^2 u
∂y^2

+


∂^2 u
∂z^2

)


=i

∂u
∂t

.


(a) Find a solution, separable in the four independent variables, that can be
written in the form of a plane wave,

ψ(x, y, z, t)=Aexp[i(k·r−ωt)].
Using the relationships associated with de Broglie (p=k) and Einstein
(E=ω), show that the separation constants must be such that
p^2 x+p^2 y+p^2 z=2mE.

(b) Obtain a different separable solution describing a particle confined to a box
of sidea(ψmust vanish at the walls of the box). Show that the energy of
the particle can only take the quantised values

E=


^2 π^2
2 ma^2

(n^2 x+n^2 y+n^2 z),

wherenx,nyandnzare integers.

21.5 Denoting the three terms of∇^2 in spherical polars by∇^2 r,∇^2 θ,∇^2 φin an obvious
way, evaluate∇^2 ru, etc. for the two functions given below and verify that, in each
case, although the individual terms are not necessarily zero their sum∇^2 uis zero.
Identify the corresponding values ofandm.


(a) u(r, θ, φ)=

(


Ar^2 +

B


r^3

)


3cos^2 θ− 1
2

.


(b)u(r, θ, φ)=

(


Ar+

B


r^2

)


sinθexpiφ.

21.6 Prove that the expression given in equation (21.47) for the associated Legendre
functionPm(μ) satisfies the appropriate equation, (21.45), as follows.

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