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Gluon overlap factors extracted from Monte Carlo lattice calculations
Volume 258, n u m b e r 3,4
PHYSICS LETTERS B
11 April 1991
Gluon overlap factors extracted from Monte Carlo lattice calculations O. M o r i m a t s u Instttute for Nuclear Study, Umverstty of Tolcvo, Tokyo 188, Japan A.M. Green 2 Research Institute for Theoretical Physics, University of Helsmkt, SF-O0170 Helsmkt, Fmland and J. P a t o n 3 Department of Theoretical Physics, Umversltv of Oxford, Oxford OXI 3NP, UK Received 21 D e c e m b e r 1990, revised m a n u s c r i p t received 4 February 1991
A strategy is proposed for extracting gluon field overlap factors from Monte Carlo lattice calculatmns involving static ( q q ) (qdl) configurations This ~s d e m o n s t r a t e d by m e a n s of an existing lattice calculation that restricts the quarks and a n t l q u a r k s to a rectangular geometry The results are m q u a h t a t i v e agreement with weak coupling at short distances, but more definite conclusions could not be m a d e at this stage, since the a p p r o p r i a t e M o n t e Carlo calculations are - as yet - not suffioently precise.
1. Introduction In two recent papers [ 1,2 ] m e s o n - m e s o n scattermg has been formulated in an adtabatic basts for QCD in which " m e s o n " states [M (q,CtjG,:)) have quarks and antlquarks at fixed points and G,: represents the ground state of the gluon field h a m i l t o n l a n for these positions of q u a r k - a n t t q u a r k sources. Variational wave functions for states containing two quarks and two anUquarks are then made m terms of I A ) = IM ( q j c l 2 G t ~ ) M ( q 2 ( 1 4 G 2 a )
) ,
IB) = [M (qlft4Gaa)M(q2dI3G2~)) ,
( 1.1 )
as shown m fig. 1 In ref. [2] a third channel, with a different gluon configuration, was also introduced. But th~s has only a very m m o r effect on the main issue of interest here. Therefore, in this discussion the Bltnet address M O R I M A T U @ J P N U T I N S 2 Bltnet address G R E E N @ F I N U H C B 3 B~tnet address J A N E T % " P A T O N @ V 1 P H O X AC U K "
11 t a)
b)
Fig 1 The two-gluon configurations A and B o f r e f s [ 1,2] (a) The two meson state I A ) =M(q~ChG~3)M (q2q4G24)), (b) The two meson state I B ) = I M (ql~14G 14) M (q2q3G23) ) • =~ q u a r k × = ant~quark
formahsm will be illustrated only in the two channel case. In this varlattonal basts there are three dtstinct contributions to the scattertng, each of which preserves the two extreme limits of weak and strong coupling. ( 1 ) Non-orthogonahty effect. The states A and B are not orthogonal. In the weak coupling limit the offdiagonal matrix elements of the overlap matrix N have the form
0 3 7 0 - 2 6 9 3 / 9 1 / $ 03 50 © 1991 - Elsevier Science P u b h s h e r s B V ( N o r t h - H o l l a n d )
257
PHYSIC‘S LEl’TEKS
Volume 25X. numhcr 3.4
I I April
H
teal. which
IS coulomblc
at long distances. clcmcnts
= ‘/‘ 1
=(M(q,ql)M(q,qJ)IM(q,q,)
whereas.
In the strong
- as polntcd
(1 2)
coupling
Ilmlt
[ 3 1.
out In ref.
the quarks
ample.
IS Icro
result
lntcractlons
m a matrix
the off-diagonal
1’
matrix
I’. where.
elements
bcfor cx-
(weak
llmlt)
(strong
coupling
teals I’,, arc replaced
.
and
when
). The
lntcrquark
side of the second form
are close
1-O
limit
by the full
also on the right-hand
(1.6)
and antlquarks
coupling
( I .6 ) The complete
are
as
/.A)
+I when all quarks
togcthcr
are all far apart
( 2 ) D~w(Y /~~~ouc~/o~~. The gluon tween
1B)
(A
whcrc
and linear
the off-diagonal
.
(BI l/‘l.A) =,/< BI I’(wcak)
xM(qzS1) > = \ >
dlstanccs
hand.
I ‘arc wrlttcn
of .Y and
(HI:\)
at short
On the other
1991
proposed
they
potcn-
potcnttal equation
In
I IS,
for :I’ and
therefore. (AI
I’iB)
=(M((~,q,G,)M(q,qJCi?)lH,,lM(q,q,(i,) xM(q,cl~G,))
(1.3)
In the weak coupling
I has the form
llmlt
I ‘(weak )
In rcl’. mcnts whcrc
[ I].
[4],
on the basis of strong f IS parametrized
CTIS the string
tension
as a free paramctcr where
I’,, IS the Interquark
gluon-eschange strong
where
(OGE).
coupling
I ‘(strong)
=
potential
0
energy since
vo1L.e static
quarks.
for
duced I’=
given
Interquark latcd
>.
the
A and B arc nonmatrix
[ I.?]
for the
for
wll
dIscusston
details. only
In-
wll not enter.
parametrizations
matrices
between above.
the
strong
In the same form the only
dlffercncc
potcntlal.
by lust replacing
the whole
and
weak
clcmcnts
introand
coupling of N and
m the two cxtrcmc they
practically Ilmlt.
as /, =exp( down
wcrc
I’,, b> the full lntcrquark
Ilmfor the
Intcrpopotcn-
meson-meson -/&‘
all
of
form
system.
check
value
prlnclplc.
InteractIon
such
this
form
with
as algcbralc
matrix.
out that Monte
of the above
.A strategy
kzl
regime
that can bc done
for the pure gauge system
the valIdIt\:
Carlo
lattice
can be used to
approach
and also to
Idea that IS csscntlally is outllncd from
cutpres-
.As In the case of./;.
In a separable
to point
I.C. the
In the transitional
for the scattering
[ 2 1.
In ref.
parametrized
of the SIX links
s~rnpl~c~t~cs
suggest the I‘orm off-an in r-cl: (41
to gcncrate
interaction.
of,/ leads to lntcgrals
11s attendant
calculations
~fcu IS > 0. I
too weak
~11th P=kr7/6
and results
WC here wish
back to that of the hand.
the average
seems to bc a t!,plcal
the
to be << 0.1.
convenlcncc,j‘is
_.,l ,)
ent In a (qq)(qq)
analytically
reverts
becomes
IS go\:crncd’by
area of the
Ilncs conncctmg
On the other
InteractIon
argu-currS).
CYIS treated
If CYIS chosen
for numerlcal
cxprcssions
IS the expression
Therefore.
and antiquarks
This latter
were
.Y=(X’IX)
The diagonal
by the straight
any significant
(XandX’areelthcrAorB)whlch
11m1ts glvcn 11s. where
see refs.
this term
quarks
mainly
Because
the present
[ I .3] simple
In refs
(1.5)
potential
operator.
bounded
weak coupling
there IS also a non-diagonal
llowever.
In the
=. I GcV/fm.
and S ts the mlnlmal
surface
then the model
(I,,AfL?J)
( 3) Krncv/c P/Ic,:~J~ /cm. kinetic
hand.
0
(L’l,+1’2.0
II,, is now a linear
orthogonal
the other
by onc-
1‘has the form
llmlt
(
On
- given
coupling
as f, =cxp(
for
“cxpcrlmental
glven
cxtractlng. data“
In
Volume 258, n u m b e r 3,4
meaning
Monte
Carlo
PHYSICS LETTERS B
lattice
calculations
for
(qCl) (qq) states. In the Monte Carlo lattice calculations for the pure gauge system the ground state energies o f the gluon field hamfltonlan are obtained for given q u a r k - a n t i quark sources. If the models proposed in refs. [ 1,2 ] a r e v a l i d , the lowest potential elgenvalues 2 o b t a m e d by solving det ( V - 2 N ) = 0, where N and V are gaven by eqs (1.7), should be c o m p a r e d with the corresponding ground state energies in lattice calculations.
2. Results At the present rime, almost the only data available for the above strategy is that o f ref. [ 5 ]. However, it should be noted that they are still far from being ideal for this purpose. In partacular, in a d d i t i o n to the statistical errors explicitly referred to m the following comparison, there as also a systematic error due to their use o f a small time-lattice i.e. the results do not correspond to the zero temperature h i l t . This could well mean that, even if we could obtain f it might differ to some extent from the zero t e m p e r a t u r e one In v~ew o f this, few definite statements can be drawn from the comparison with the present data These should be reserved until a calculation better than that o f r e f [ 5 ] has been carried out and m which the above objecnons have been confronted. In spite o f this the authors believe that the following qualitative mvesn g a n o n is worth making. In ref. [ 5 ] the two types of rectangular configuranons for (qCt) ( q q ) states shown in fig. 2 are consadered: ( a ) shows the antlparallel ( A P ) c o m b i n a t i o n as the two associated meson configuranons A and B and ( b ) shows the corresponding parallel ( P ) comblnanons. In this way, as a function o f d and m for
k A
B
a)
A
B
b)
Fig 2 (a) Annparallel (AP) combmanons glwng mesons of "'length" L=da and a d~stance apart ofR=ma A and B refer to the two meson configuranons of fig 1 (b) Parallel (P) comblnanons and the correspondmg meson configurations A, B
I 1 April 1991
d = 0 , 1, 2 and l ~ < m ~ 8 , a (qq)(qCl) potential V(d, m) was extracted, m umts o f 1/a, where a is the lattice spacing. Also in this reference, a Monte Carlo latrice calculation for qCl configuranons showed that, for a quark and antiquark a distance ra apart, ogo
av(r) = a a 2 r - - - - vo,
(2.1)
r
where aa2=0.088_+0.003, ao=0.30+001 and Vo= 1.04_+0.01, consistent with other d e t e r m m a tions. In eq (1.7) for the matrix V, the v,j are identified with the v(r) o f e q . (2 1 ) As can be seen from fig. 3 in ref. [5], the only values o f (d, m ) that lead to significantly non-zero potentials V(d, m ) are for (d, m ) = (1, 1), (2, 1 ) a n d (2, 2). A comparison is now m a d e between V(d, m ) , the (qcl) (qCl) potential o f ref. [ 5 ], and the lowest potential eigenvalues 2 (d, m ), i.e V(d, m ) <~ I?(d, m )
=2(d, rn)- [v13(d)+v2~(d)] .
(2 2)
Here the second term simply removes the energies o f the two mesons as R ( m ) ~ and ensures 17(d, rn) -~0 in this limit. Results are shown in table 1 for f = 1, 0.9 and 0.5 as the gluon field overlap factor defined by eq. ( 1.6 ) Thas selectaon o f f ' s is chosen since: (a) The value f = 1 corresponds to no cut-down due to the overlap and so maxamlzes the absolute value of the potentml I?(d, m ) . ( b ) F r o m the above defimtlons off~,2 for a ~ 0 . 1 , k~½ the value o f f - - 0.9 occurs roughly at (d, m) = (2, 2). It is therefore selected as a typical value in the transitional regime for the range of (d, m) o f interest. For this estimate, a lattice spacing of 0.15 fm ~s used as m ref. [ 5 ]. (c) The numbers for f = 0.5 are quoted smce they a p p r o x i m a t e l y correspond to the choaces a and k ~ 1 which are representatives of strong cut-down factors. Further results are shown m fig. 3 for the two extremes f = 1 and f = 0 , but treating R as a continuous variable. Several poants should be noted. ( 1 ) All the numbers are in quahtatlve agreement with the " d a t a " of ref. [5] p r o v l d l n g f ~ 1. Thas implies that the range o f (d, m ) stays m the weak coupling regime. 259
Volume 258, number 3,4
PHYSICS LETTERS B
1 l April 1991
Table 1 Column 1 the values of (d, m) corresponding to significantly non-zero potenuals m ref [5] Column 2 a representauve selectmn of gluon field overlap factors/defined by eq ( 1 6) Columns 3 and 4 the (qq) (qq) potenUal a V(d, m ) defined by eq (2 2 ) for the two quark configuratmns, anUparallel (AP) and parallel (P), shown in figs 2a and 2b, respecuvely Columns 5 and 6 the corresponding potenual values read from fig 3 o f r e f [5] (dm )
(1,1)
(2,1)
(2,2)
/
a V(d, m )
"'Experimental" data
AP
P
AP
10 09 05
-00621 - 0 0574 - 0 0355
-00311 - 0 0246 - 0 00710
-0
I0 09 05
- 0 477 -0477 - 0 476
- 0 224 -0187 - 0 0734
-048+001
10 09 05
- 0 0584 - 0 0539 - 0 0333
- 0 0292 - 0 0231 - 0 00668
(2) Even though there is quahtatlve agreement, m detail the results are not what was expected, since some of the "data" from ref. [5] appear to be larger In magnttude than the above numbers even for the case w~th f = 1 It is not clear whether this should be taken too seriously at this stage m view of the present accuracy of Monte Carlo lattice calculations. (3) In the (d, m ) = ( 2 , 1) case, the constancy of the anttparallel results with appreciable magnitude, asfdecreases, is an artifice of the definition of 17(d, m) by eq. (2.2), since asymptotically the state correspondmg to ( 1, 2) - B m fig. 2a - has a lower energy than the one corresponding to (2, 1 ) - the state The most part of 12(2, 1 ), thus, comes from the difference of asymptotic quark-antxquark potentials m two states, i e . (t,12~-~/)23) - ( u 1 3 - ] - v 2 4 ) . After removing thts "trivial" part, the rest becomes - 0 0012 equal to that for ( 1, 2) A stmllar problem does not arise with the parallel results, since there state B always has a higher energy because the q u a r k - a n t i quark distances are always larger In the state B - as seen m fig. 2b - and the lnterquark potential is monotonically increasing. This suggests that the antlparallel configurations with d > tn are less useful in the present strategy for extracting f 's. (4) One definite conclusion that can already be seen from fig 3 Is that even for f= 1 - l e. no cut down due to exphclt gluon effects - there is still a rapid decrease in the mteractlon as R increases In ref [5] 260
P
-005±001
1 ±001
-027±001
~-008+005
thts Is interpreted as due to colour charge shielding. However, the above calculation shows that th~s rapid decrease ts already present when using the conventional two-body potential ofeq. (2.1). This is one of the reasons why tt did not prove possible to extract f from the results ofref. [ 5 ] with their present accuracy. Several questtons can be asked concerning the stablhty and completeness of the above analysts and also its feastblhty with the present data from ref. [ 5 ]. ( 1 ) Since the qq potential ofeq. (2.1) plays a crucial role, it was checked that variations of the parameters o~a2 and e~o within the quoted error bars did not make significant changes. For example, using a a 2 = - 0 091 and c%=0.31 changed I?(2, 1 ) from - 0 . 1 8 7 to - 0 . 1 9 4 1 e. an increase of less than 5%. (2) As discussed in ref [ 2 ], exotic q2q2 states can be introduced However, these make a rather small contribution at the values of (d, m ) of interest here. Thts ~s because, m the weak coupling hmlt, states A and B form a complete set for descrtbmg the scatterrag. If the Monte Carlo calculations were extended for the positions of q u a r k - a n t i q u a r k sources beyond the weak couphng regime, to where an e x o t t c q2Ct2 state has an energy which ~s either the lowest or comparable to the lowest, it would probably be necessary to also include these exotic states in the complete analysis.
Volume 258, number 3,4
PHYSICS LETTERS B
aC/(d=l,R) 08
15 R/a
0
)
//
-005
/i/I p ,,/
-0 10 f = 0 "/'1
/'%" f = 1
AP
aV (d =2,R) 05 I
10 i
~
I
~
I
15 i
i
i
~
]
20 L
i
i
I
/
R/a
I
11 April 1991
t r a c t m g f t h e g l u o n field o v e r l a p . I n t h e a p p h c a U o n to t h e d a t a c u r r e n t l y a v a i l a b l e , t h e results are m q u a l i t a t i v e a g r e e m e n t w i t h w e a k c o u p l i n g at s h o r t distances. H o w e v e r , a m o r e d e f i n i t e e x t r a c t i o n c o u l d n o t b e a c h i e v e d at present, s i n c e t h i s d a t a , in effect, is so f a r o n l y r e s t r i c t e d to s h o r t d i s t a n c e s a n d also suffers f r o m t h e use o f a s m a l l U m e - l a t t l c e as d i s c u s s e d earher. T h e r e f o r e , t h e r e is a g o o d case for p e r f o r m i n g m o r e M o n t e C a r l o latUce c a l c u l a U o n s m t h e q2C12 syst e m u s i n g l a m c e s t h a t are a b l e to yield (qCl) (qCt) pot e n t i a l s V(d, m ) t h a t are s i g n i f i c a n t l y d i f f e r e n t f r o m z e r o a n d yet n o t in t h e w e a k c o u p l i n g regime. Bec a u s e o f t h e dlfficulUes m e n t i o n e d e a r h e r , for n u m e r i c a l r e a s o n s it is p r o b a b l y b e t t e r to c o n c e n t r a t e such calculations on quark configurations which a v o i d i n c l u d i n g a large " t n w a l " c o m p o n e n t as ~s p r e s e n t in t h e a n U p a r a l l e l case w i t h d > m
Acknowledgement -05-
P/
//""
/ "
/
O n e o f t h e a u t h o r s ( O . M . ) w i s h e s to t h a n k t h e Res e a r c h I n s t i t u t e for T h e o r e t i c a l Physics, H e l s m k i , for t h e i r h o s p i t a l i t y d u r i n g w h i c h txme m o s t o f t h i s w o r k w a s c a r r i e d out.
-10-
b Fig 3 The potential ~2(d, m), m units of a, defined by eq (2 2), for (a) d = 1 and (b) d = 2 and with continuous values for R/a Solid lines: the antlparallel (AP) combmauon of (qcl)(qCl) m fig 2a with f=0, 1 Dashed line the parallel (P) combination m fig 2b with f= 1, the f = 0 potential being always zero In (a) the two points at R/a = 1 were read from fig. 3 of ref [ 5 ] and correspond to the AP(O ) and P( × ) combinations In (b) the point ([]) at R/a = 2 as read from ref [ 5 ] cannot d]stlngmsh between AP and P
3. Conclusion In t h e a b o v e , a s t r a t e g y h a s b e e n o u t l i n e d f o r ex-
References [ 1 ] c Alexandrou, T Karaplpens and O Monmatsu, Nucl Phys A 518 (1990) 723. [2 ] B Masud, J Paton, A M Green and G Q Llu, A model for quark exchange m chromodynamlcs illustrated by a description of meson-meson scattering, Helslnk~ preprmt HU-TFT-90-67, Nucl Phys A 527 (1991), to appear [3] D Robson, Phys Rev D 35 (1986) 1029, G A Miller, Phys Rev D 37 (1988)2431, Phys Rev C 39 (1989) 1563 [4] O Monmatsu, Nucl Phys A 505 (1989) 655 [ 5 ] S Ohta, M. Fukugna and A Ukawa, Phys Lett B 173 (1986) 15
261
PHYSICS LETTERS B
11 April 1991
Gluon overlap factors extracted from Monte Carlo lattice calculations O. M o r i m a t s u Instttute for Nuclear Study, Umverstty of Tolcvo, Tokyo 188, Japan A.M. Green 2 Research Institute for Theoretical Physics, University of Helsmkt, SF-O0170 Helsmkt, Fmland and J. P a t o n 3 Department of Theoretical Physics, Umversltv of Oxford, Oxford OXI 3NP, UK Received 21 D e c e m b e r 1990, revised m a n u s c r i p t received 4 February 1991
A strategy is proposed for extracting gluon field overlap factors from Monte Carlo lattice calculatmns involving static ( q q ) (qdl) configurations This ~s d e m o n s t r a t e d by m e a n s of an existing lattice calculation that restricts the quarks and a n t l q u a r k s to a rectangular geometry The results are m q u a h t a t i v e agreement with weak coupling at short distances, but more definite conclusions could not be m a d e at this stage, since the a p p r o p r i a t e M o n t e Carlo calculations are - as yet - not suffioently precise.
1. Introduction In two recent papers [ 1,2 ] m e s o n - m e s o n scattermg has been formulated in an adtabatic basts for QCD in which " m e s o n " states [M (q,CtjG,:)) have quarks and antlquarks at fixed points and G,: represents the ground state of the gluon field h a m i l t o n l a n for these positions of q u a r k - a n t t q u a r k sources. Variational wave functions for states containing two quarks and two anUquarks are then made m terms of I A ) = IM ( q j c l 2 G t ~ ) M ( q 2 ( 1 4 G 2 a )
) ,
IB) = [M (qlft4Gaa)M(q2dI3G2~)) ,
( 1.1 )
as shown m fig. 1 In ref. [2] a third channel, with a different gluon configuration, was also introduced. But th~s has only a very m m o r effect on the main issue of interest here. Therefore, in this discussion the Bltnet address M O R I M A T U @ J P N U T I N S 2 Bltnet address G R E E N @ F I N U H C B 3 B~tnet address J A N E T % " P A T O N @ V 1 P H O X AC U K "
11 t a)
b)
Fig 1 The two-gluon configurations A and B o f r e f s [ 1,2] (a) The two meson state I A ) =M(q~ChG~3)M (q2q4G24)), (b) The two meson state I B ) = I M (ql~14G 14) M (q2q3G23) ) • =~ q u a r k × = ant~quark
formahsm will be illustrated only in the two channel case. In this varlattonal basts there are three dtstinct contributions to the scattertng, each of which preserves the two extreme limits of weak and strong coupling. ( 1 ) Non-orthogonahty effect. The states A and B are not orthogonal. In the weak coupling limit the offdiagonal matrix elements of the overlap matrix N have the form
0 3 7 0 - 2 6 9 3 / 9 1 / $ 03 50 © 1991 - Elsevier Science P u b h s h e r s B V ( N o r t h - H o l l a n d )
257
PHYSIC‘S LEl’TEKS
Volume 25X. numhcr 3.4
I I April
H
teal. which
IS coulomblc
at long distances. clcmcnts
= ‘/‘ 1
=(M(q,ql)M(q,qJ)IM(q,q,)
whereas.
In the strong
- as polntcd
(1 2)
coupling
Ilmlt
[ 3 1.
out In ref.
the quarks
ample.
IS Icro
result
lntcractlons
m a matrix
the off-diagonal
1’
matrix
I’. where.
elements
bcfor cx-
(weak
llmlt)
(strong
coupling
teals I’,, arc replaced
.
and
when
). The
lntcrquark
side of the second form
are close
1-O
limit
by the full
also on the right-hand
(1.6)
and antlquarks
coupling
( I .6 ) The complete
are
as
/.A)
+I when all quarks
togcthcr
are all far apart
( 2 ) D~w(Y /~~~ouc~/o~~. The gluon tween
1B)
(A
whcrc
and linear
the off-diagonal
.
(BI l/‘l.A) =,/< BI I’(wcak)
xM(qzS1) > = \ >
dlstanccs
hand.
I ‘arc wrlttcn
of .Y and
(HI:\)
at short
On the other
1991
proposed
they
potcn-
potcnttal equation
In
I IS,
for :I’ and
therefore. (AI
I’iB)
=(M((~,q,G,)M(q,qJCi?)lH,,lM(q,q,(i,) xM(q,cl~G,))
(1.3)
In the weak coupling
I has the form
llmlt
I ‘(weak )
In rcl’. mcnts whcrc
[ I].
[4],
on the basis of strong f IS parametrized
CTIS the string
tension
as a free paramctcr where
I’,, IS the Interquark
gluon-eschange strong
where
(OGE).
coupling
I ‘(strong)
=
potential
0
energy since
vo1L.e static
quarks.
for
duced I’=
given
Interquark latcd
>.
the
A and B arc nonmatrix
[ I.?]
for the
for
wll
dIscusston
details. only
In-
wll not enter.
parametrizations
matrices
between above.
the
strong
In the same form the only
dlffercncc
potcntlal.
by lust replacing
the whole
and
weak
clcmcnts
introand
coupling of N and
m the two cxtrcmc they
practically Ilmlt.
as /, =exp( down
wcrc
I’,, b> the full lntcrquark
Ilmfor the
Intcrpopotcn-
meson-meson -/&‘
all
of
form
system.
check
value
prlnclplc.
InteractIon
such
this
form
with
as algcbralc
matrix.
out that Monte
of the above
.A strategy
kzl
regime
that can bc done
for the pure gauge system
the valIdIt\:
Carlo
lattice
can be used to
approach
and also to
Idea that IS csscntlally is outllncd from
cutpres-
.As In the case of./;.
In a separable
to point
I.C. the
In the transitional
for the scattering
[ 2 1.
In ref.
parametrized
of the SIX links
s~rnpl~c~t~cs
suggest the I‘orm off-an in r-cl: (41
to gcncrate
interaction.
of,/ leads to lntcgrals
11s attendant
calculations
~fcu IS > 0. I
too weak
~11th P=kr7/6
and results
WC here wish
back to that of the hand.
the average
seems to bc a t!,plcal
the
to be << 0.1.
convenlcncc,j‘is
_.,l ,)
ent In a (qq)(qq)
analytically
reverts
becomes
IS go\:crncd’by
area of the
Ilncs conncctmg
On the other
InteractIon
argu-currS).
CYIS treated
If CYIS chosen
for numerlcal
cxprcssions
IS the expression
Therefore.
and antiquarks
This latter
were
.Y=(X’IX)
The diagonal
by the straight
any significant
(XandX’areelthcrAorB)whlch
11m1ts glvcn 11s. where
see refs.
this term
quarks
mainly
Because
the present
[ I .3] simple
In refs
(1.5)
potential
operator.
bounded
weak coupling
there IS also a non-diagonal
llowever.
In the
=. I GcV/fm.
and S ts the mlnlmal
surface
then the model
(I,,AfL?J)
( 3) Krncv/c P/Ic,:~J~ /cm. kinetic
hand.
0
(L’l,+1’2.0
II,, is now a linear
orthogonal
the other
by onc-
1‘has the form
llmlt
(
On
- given
coupling
as f, =cxp(
for
“cxpcrlmental
glven
cxtractlng. data“
In
Volume 258, n u m b e r 3,4
meaning
Monte
Carlo
PHYSICS LETTERS B
lattice
calculations
for
(qCl) (qq) states. In the Monte Carlo lattice calculations for the pure gauge system the ground state energies o f the gluon field hamfltonlan are obtained for given q u a r k - a n t i quark sources. If the models proposed in refs. [ 1,2 ] a r e v a l i d , the lowest potential elgenvalues 2 o b t a m e d by solving det ( V - 2 N ) = 0, where N and V are gaven by eqs (1.7), should be c o m p a r e d with the corresponding ground state energies in lattice calculations.
2. Results At the present rime, almost the only data available for the above strategy is that o f ref. [ 5 ]. However, it should be noted that they are still far from being ideal for this purpose. In partacular, in a d d i t i o n to the statistical errors explicitly referred to m the following comparison, there as also a systematic error due to their use o f a small time-lattice i.e. the results do not correspond to the zero temperature h i l t . This could well mean that, even if we could obtain f it might differ to some extent from the zero t e m p e r a t u r e one In v~ew o f this, few definite statements can be drawn from the comparison with the present data These should be reserved until a calculation better than that o f r e f [ 5 ] has been carried out and m which the above objecnons have been confronted. In spite o f this the authors believe that the following qualitative mvesn g a n o n is worth making. In ref. [ 5 ] the two types of rectangular configuranons for (qCt) ( q q ) states shown in fig. 2 are consadered: ( a ) shows the antlparallel ( A P ) c o m b i n a t i o n as the two associated meson configuranons A and B and ( b ) shows the corresponding parallel ( P ) comblnanons. In this way, as a function o f d and m for
k A
B
a)
A
B
b)
Fig 2 (a) Annparallel (AP) combmanons glwng mesons of "'length" L=da and a d~stance apart ofR=ma A and B refer to the two meson configuranons of fig 1 (b) Parallel (P) comblnanons and the correspondmg meson configurations A, B
I 1 April 1991
d = 0 , 1, 2 and l ~ < m ~ 8 , a (qq)(qCl) potential V(d, m) was extracted, m umts o f 1/a, where a is the lattice spacing. Also in this reference, a Monte Carlo latrice calculation for qCl configuranons showed that, for a quark and antiquark a distance ra apart, ogo
av(r) = a a 2 r - - - - vo,
(2.1)
r
where aa2=0.088_+0.003, ao=0.30+001 and Vo= 1.04_+0.01, consistent with other d e t e r m m a tions. In eq (1.7) for the matrix V, the v,j are identified with the v(r) o f e q . (2 1 ) As can be seen from fig. 3 in ref. [5], the only values o f (d, m ) that lead to significantly non-zero potentials V(d, m ) are for (d, m ) = (1, 1), (2, 1 ) a n d (2, 2). A comparison is now m a d e between V(d, m ) , the (qcl) (qCl) potential o f ref. [ 5 ], and the lowest potential eigenvalues 2 (d, m ), i.e V(d, m ) <~ I?(d, m )
=2(d, rn)- [v13(d)+v2~(d)] .
(2 2)
Here the second term simply removes the energies o f the two mesons as R ( m ) ~ and ensures 17(d, rn) -~0 in this limit. Results are shown in table 1 for f = 1, 0.9 and 0.5 as the gluon field overlap factor defined by eq. ( 1.6 ) Thas selectaon o f f ' s is chosen since: (a) The value f = 1 corresponds to no cut-down due to the overlap and so maxamlzes the absolute value of the potentml I?(d, m ) . ( b ) F r o m the above defimtlons off~,2 for a ~ 0 . 1 , k~½ the value o f f - - 0.9 occurs roughly at (d, m) = (2, 2). It is therefore selected as a typical value in the transitional regime for the range of (d, m) o f interest. For this estimate, a lattice spacing of 0.15 fm ~s used as m ref. [ 5 ]. (c) The numbers for f = 0.5 are quoted smce they a p p r o x i m a t e l y correspond to the choaces a and k ~ 1 which are representatives of strong cut-down factors. Further results are shown m fig. 3 for the two extremes f = 1 and f = 0 , but treating R as a continuous variable. Several poants should be noted. ( 1 ) All the numbers are in quahtatlve agreement with the " d a t a " of ref. [5] p r o v l d l n g f ~ 1. Thas implies that the range o f (d, m ) stays m the weak coupling regime. 259
Volume 258, number 3,4
PHYSICS LETTERS B
1 l April 1991
Table 1 Column 1 the values of (d, m) corresponding to significantly non-zero potenuals m ref [5] Column 2 a representauve selectmn of gluon field overlap factors/defined by eq ( 1 6) Columns 3 and 4 the (qq) (qq) potenUal a V(d, m ) defined by eq (2 2 ) for the two quark configuratmns, anUparallel (AP) and parallel (P), shown in figs 2a and 2b, respecuvely Columns 5 and 6 the corresponding potenual values read from fig 3 o f r e f [5] (dm )
(1,1)
(2,1)
(2,2)
/
a V(d, m )
"'Experimental" data
AP
P
AP
10 09 05
-00621 - 0 0574 - 0 0355
-00311 - 0 0246 - 0 00710
-0
I0 09 05
- 0 477 -0477 - 0 476
- 0 224 -0187 - 0 0734
-048+001
10 09 05
- 0 0584 - 0 0539 - 0 0333
- 0 0292 - 0 0231 - 0 00668
(2) Even though there is quahtatlve agreement, m detail the results are not what was expected, since some of the "data" from ref. [5] appear to be larger In magnttude than the above numbers even for the case w~th f = 1 It is not clear whether this should be taken too seriously at this stage m view of the present accuracy of Monte Carlo lattice calculations. (3) In the (d, m ) = ( 2 , 1) case, the constancy of the anttparallel results with appreciable magnitude, asfdecreases, is an artifice of the definition of 17(d, m) by eq. (2.2), since asymptotically the state correspondmg to ( 1, 2) - B m fig. 2a - has a lower energy than the one corresponding to (2, 1 ) - the state The most part of 12(2, 1 ), thus, comes from the difference of asymptotic quark-antxquark potentials m two states, i e . (t,12~-~/)23) - ( u 1 3 - ] - v 2 4 ) . After removing thts "trivial" part, the rest becomes - 0 0012 equal to that for ( 1, 2) A stmllar problem does not arise with the parallel results, since there state B always has a higher energy because the q u a r k - a n t i quark distances are always larger In the state B - as seen m fig. 2b - and the lnterquark potential is monotonically increasing. This suggests that the antlparallel configurations with d > tn are less useful in the present strategy for extracting f 's. (4) One definite conclusion that can already be seen from fig 3 Is that even for f= 1 - l e. no cut down due to exphclt gluon effects - there is still a rapid decrease in the mteractlon as R increases In ref [5] 260
P
-005±001
1 ±001
-027±001
~-008+005
thts Is interpreted as due to colour charge shielding. However, the above calculation shows that th~s rapid decrease ts already present when using the conventional two-body potential ofeq. (2.1). This is one of the reasons why tt did not prove possible to extract f from the results ofref. [ 5 ] with their present accuracy. Several questtons can be asked concerning the stablhty and completeness of the above analysts and also its feastblhty with the present data from ref. [ 5 ]. ( 1 ) Since the qq potential ofeq. (2.1) plays a crucial role, it was checked that variations of the parameters o~a2 and e~o within the quoted error bars did not make significant changes. For example, using a a 2 = - 0 091 and c%=0.31 changed I?(2, 1 ) from - 0 . 1 8 7 to - 0 . 1 9 4 1 e. an increase of less than 5%. (2) As discussed in ref [ 2 ], exotic q2q2 states can be introduced However, these make a rather small contribution at the values of (d, m ) of interest here. Thts ~s because, m the weak coupling hmlt, states A and B form a complete set for descrtbmg the scatterrag. If the Monte Carlo calculations were extended for the positions of q u a r k - a n t i q u a r k sources beyond the weak couphng regime, to where an e x o t t c q2Ct2 state has an energy which ~s either the lowest or comparable to the lowest, it would probably be necessary to also include these exotic states in the complete analysis.
Volume 258, number 3,4
PHYSICS LETTERS B
aC/(d=l,R) 08
15 R/a
0
)
//
-005
/i/I p ,,/
-0 10 f = 0 "/'1
/'%" f = 1
AP
aV (d =2,R) 05 I
10 i
~
I
~
I
15 i
i
i
~
]
20 L
i
i
I
/
R/a
I
11 April 1991
t r a c t m g f t h e g l u o n field o v e r l a p . I n t h e a p p h c a U o n to t h e d a t a c u r r e n t l y a v a i l a b l e , t h e results are m q u a l i t a t i v e a g r e e m e n t w i t h w e a k c o u p l i n g at s h o r t distances. H o w e v e r , a m o r e d e f i n i t e e x t r a c t i o n c o u l d n o t b e a c h i e v e d at present, s i n c e t h i s d a t a , in effect, is so f a r o n l y r e s t r i c t e d to s h o r t d i s t a n c e s a n d also suffers f r o m t h e use o f a s m a l l U m e - l a t t l c e as d i s c u s s e d earher. T h e r e f o r e , t h e r e is a g o o d case for p e r f o r m i n g m o r e M o n t e C a r l o latUce c a l c u l a U o n s m t h e q2C12 syst e m u s i n g l a m c e s t h a t are a b l e to yield (qCl) (qCt) pot e n t i a l s V(d, m ) t h a t are s i g n i f i c a n t l y d i f f e r e n t f r o m z e r o a n d yet n o t in t h e w e a k c o u p l i n g regime. Bec a u s e o f t h e dlfficulUes m e n t i o n e d e a r h e r , for n u m e r i c a l r e a s o n s it is p r o b a b l y b e t t e r to c o n c e n t r a t e such calculations on quark configurations which a v o i d i n c l u d i n g a large " t n w a l " c o m p o n e n t as ~s p r e s e n t in t h e a n U p a r a l l e l case w i t h d > m
Acknowledgement -05-
P/
//""
/ "
/
O n e o f t h e a u t h o r s ( O . M . ) w i s h e s to t h a n k t h e Res e a r c h I n s t i t u t e for T h e o r e t i c a l Physics, H e l s m k i , for t h e i r h o s p i t a l i t y d u r i n g w h i c h txme m o s t o f t h i s w o r k w a s c a r r i e d out.
-10-
b Fig 3 The potential ~2(d, m), m units of a, defined by eq (2 2), for (a) d = 1 and (b) d = 2 and with continuous values for R/a Solid lines: the antlparallel (AP) combmauon of (qcl)(qCl) m fig 2a with f=0, 1 Dashed line the parallel (P) combination m fig 2b with f= 1, the f = 0 potential being always zero In (a) the two points at R/a = 1 were read from fig. 3 of ref [ 5 ] and correspond to the AP(O ) and P( × ) combinations In (b) the point ([]) at R/a = 2 as read from ref [ 5 ] cannot d]stlngmsh between AP and P
3. Conclusion In t h e a b o v e , a s t r a t e g y h a s b e e n o u t l i n e d f o r ex-
References [ 1 ] c Alexandrou, T Karaplpens and O Monmatsu, Nucl Phys A 518 (1990) 723. [2 ] B Masud, J Paton, A M Green and G Q Llu, A model for quark exchange m chromodynamlcs illustrated by a description of meson-meson scattering, Helslnk~ preprmt HU-TFT-90-67, Nucl Phys A 527 (1991), to appear [3] D Robson, Phys Rev D 35 (1986) 1029, G A Miller, Phys Rev D 37 (1988)2431, Phys Rev C 39 (1989) 1563 [4] O Monmatsu, Nucl Phys A 505 (1989) 655 [ 5 ] S Ohta, M. Fukugna and A Ukawa, Phys Lett B 173 (1986) 15
261