202 3 Quantum Mechanics – II
Br^2 =x (8)
Substitute (8) in (7) and simplify, to obtain
xd^2 v
dx^2+
dv
dx(C−x)−Av=0(9)which is the familiar confluent hyper geometric equation whose solution
which is regular atx=0is;V(A,C,x)=α 0[
1 +
Ax
C+
A(A+1)x^2
C(C+1)2!+
A(A+1)(A+2)x^3
C(C+1)(C+2)3!+···.
]
V(A,C,Br^2 )=α 0[
1 +
ABr^2
C+
A(A+1)B^2 r^4
C(C+1)2!+A(A+1)(A+2)B^3 r^6
C(C+1)(C+2)3!+···
]
The asymptotic solutionV(r)→0, whiler→∞implies that the series
must break off for finite powers ofBr^2 sinceα 0
=0. This means thatAmust
equal a negative integer−p; wherep= 0 , 1 , 2 , 3 ...
Therefore− 4 p= 2 l+ 3 −^2 ω(V 0 +E)
Where we have used the definition ofA(Eq. 6) from this we find, the energy
eigen values,Ep,l=−V 0 +ω(
2 p+l+3
2
)
(p= 0 , 1 , 2 ,....)
Settingn= 2 p+l
En=−V 0 +ω(
n+^32)
(which is different from one-dimensional harmonic
oscillator)
E 0 =−V 0 +^3 2 ωcorresponds to ground state.
It is a single state (not degenerate)
sincen=0 can be formed only by the combinationl= 0 ,p=0.3.54 When the oscillator is in the lowest energy state
<H>=<V+T>=(
mω^2
2)
<x^2 >+(
1
2 m)
<P^2 >
Now, ifa, bandcare three real numbers such thata+b=c, thenab=c^2
4−
(
a−b
2) 2
orab≤c^2
4
Apply this inequality to(
mω^2
2)
<x^2 >,( 1
2 m)
<p^2 >and 2 ω<Δx>^2 =<x^2 >−<x>^2 =<x^2 >and <x>= 0