1000 Solved Problems in Modern Physics

(Romina) #1

3.3 Solutions 179


α^2 a^2 =

2 mEa^2
^2

=

n^2 π^2
4

E=
n^2 π^2 ^2
8 ma^2

(neven)

ThusE=

n^2 π^2 ^2
8 ma^2

,n= 1 , 2 , 3 ...

3.28 From problem 3.27,


αcotαa=−β= 0
Thefirstsolutionisαa=π/2, for the ground state.
The second solution,αa= 3 π/2, will correspond to the first excited state
(withl=0). This will give
α^2 a^2 = 9 π^2 / 4
Let the excited states be barely bound so thatW=0. Then,
α^2 = 2 mE/^2 = 9 π^2 / 4 a^2

E=V 1 = 9 V 0
a value which is not possible. Thus, the physical reason why bound excited
states are not possible is that deuteron is a loose structure as the binding energy
(2.225 MeV) is small. The same conclusion is reached for higher excited states
includingl= 1 , 2 ...

3.29 The inside wave functionu 1 =Asinkris maximum atr≈R. Therefore


kR=

π
2

ork^2 =

M(V 0 −W)R^2

^2

=

π^2
4

orV 0 =

(

π^2 ^2 c^2
4 Mc^2 R^2

)

+W

Substitutingc= 197 .3MeV−fm,Mc^2 =940 MeV,R= 1 .5 fm andW=
2 .2 Mev, we findV 0 ≈47 MeV

3.30 Schrodinger’s equation in one dimension


(a)d

(^2) ψ
dx^2 +
( 2 m
^2


)

(E−V)ψ= 0
Region 1: (x<0)V=0;d

(^2) ψ
dx^2 +k
2
1 ψ=^0
wherek^21 =^2 mE 2 Solution:ψ 1 =exp(ik 1 x)+Aexp(−ik 1 x)
Region 2: (0<x<a)V=Vb;d
(^2) ψ
dx^2 −k
2
2 ψ=^0
wherek^22 =
( 2 m
^2


)

(Vb−E)
Solution:ψ 2 =Bexp(k 2 x)+Cexp(−k 2 x)
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