Singularities of the elastic S-matrix element,
No Thumbnail Available
Date
2008
Journal Title
Journal ISSN
Volume Title
Publisher
Faculty of Graduate Studies, University of Kelaniya
Abstract
It is well known that the standard conventional method of integral equations is not able to
explain the analyticity of the elastic S-matrix element for the nuclear optical potential
including the Coulomb potential. It has been shown[1],[2] that the cutting down of the
potential at a large distance is essential to get rid of the redundant poles of the S-matrix
element in case of an attractive exponentially decaying potential. This method has been
found [3] to be quite general and it does not change the physics of the problem. Using
this method , analiticity and the singularities of the S-matrix element is discussed.
Singularities of the elastic S-matrix element
Partial wave radial wave equation of angular momentum l corresponding to elastic
scattering is given by,
[ d2 - 2 /(/+ 1)] 2p [ . ] 2 + k - 2 u1(k,r)=-2 V(r)+ Vc(r)+ zW(r) u1(k,r)
M r n
(1)
where V (r) is the real part of nuclear potential, W (r) is the imaginary part of the
optical potential · (r) is the Coulomb potential, and k is the incident wave number.
Energy dependence of the optical potential is usually through laboratory energy E1ah and
hence it depend on k2 and therefore k2- 2
[V(r) + Vc(r) + i W(r)] is depending on k
n
through e . It is Well known that . (r) is independent Of k Jn Order tO make U 1 ( k, r) an
entire function of k , we impose k independent boundary condition at the origin . Now,
we can make use of a well known theorem of Poincare to deduce that the wave function
is an entire function of k2 and hence it is an entire function of k as well. We cut off the
exponential tails of the optical potential at sufficiently large Rm and use the relation
-1 --d u1 =.:u ;<--l -(k,-r)--s--'-r (--k,R--m----') u-'-;(+l--- ( k,-r)
u, dr u/-l(k ,r)-sr(k,Rm) uj+l(k,r)
(2)
to define St(k,Rm),where u,<-l(k,r) and u,<+l(k,r) stand for incoming and outgoing
Coulomb wave functions respectively which are given by
I
(±l(k )-+· [r(/+ l+i 17) ]2 [J[2"+iU+nJ w (-2 'u1 ,r - _l . e 1 1k r )
r(Z+I-z17) +i,,/+2 (3)
where Ware the Whittaker functions. In the limit Rm oo St (k,Rm) ,the nuclear part
of the S-matrix element , becomes St { k) and the redundant poles removed[1 ],[2].Now,
the nuclear S-matrix element , in terms of the Whittaker functions is given by
143
Proceedings of the Annual Research Symposium 2008- Faculty of Graduate Studies University of Kelaniya
where
w' 1 (2ikr)-(k,r) W I (2ikr)
IIJ, 1+-2 in'" 1+-2 , ,r 2 Rm
W. 1 (-2ikr)-(-k,r)W 1 (-2ikr)
-IIJ, I+-2 -ill ' 1+-2
P1(k,r) = u;(k,r)
,and St (k) has an essential singularity at k = 0, which
u1(k,r) ,
(4)
is
apparent from the Wister's definition of the Gamma function l(z) smce
z= l+ 1 ±i lJ .However, this singularity has no any physical meaning and is an outcome
of treating
21Jk
as well defined quantity for all k including k = 0 in the corresponding
r
Schrodinger equation .The infinite number of zeros and poles of S- matrix element due
to the Gamma functions associated with S - matrix element have to be interpreted
1
carefully. S;'(k)=O at the zeros of ----
f(l+1+i1J )
and then the total wave function
reduces to
[ . ] I J( '7 +i(/+I)ZZ"j uj-l(k,r)=-i f(l+1-'7)
e l 2 2 W (2ikr)
f(l+1+zlJ) i11,1+l2
which is also zero. Even though the corresponding energies of these states are negative
since the corresponding wave number is given by
?
k= z · z,z2 e- 2 n= 0' 1' 2 , ...
11 (n+l+1)
they are not physically meaningful bound states as found in[1],[2] long ago. These states
are unphysical since poles are redundant poles. This fact is clearly understood by the fact
that all these poles are absent in the physically meaningful total S - matrix element.
For large 1k1, Sin' (k) (- ) { e-21k r S(k), where S(k) = [-ik+(k)] • +2k
[ik-(-k)]. smce W = e- "
for large k. Therefore the S-matrix element has an essential singularity at infinity, which
is on the imaginary axis. It is clear that there are no redundant poles in the total S-matrix
element is free from redundant poles sinceSJ (k) =SeS t , where Se = f(l + 1 + i7J)
f(l+1-i1]) .
Description
Keywords
Citation
Jayasinghe, W.J.M.L.P. and Piyadasa, R.A.D., 2008. Singularities of the elastic S-matrix element, Proceedings of the Annual Research Symposium 2008, Faculty of Graduate Studies, University of Kelaniya, pp 143-144.