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Lattice form factors: An update
524
Nuclear Physics B (Proc. Suppl.) 4 (1988) 524-530 North-Holland, Amsterdam
LATTICE FORM FACTORS: AN UPDATE* Terrence Draper and Richard Woloshyn TRIUMF, 4004 Wesbrook Mall, Vancouver, B.C., Canada V6T 2A3
Walter Wilcox Department of Physics, Baylor University, Waco, TX, USA 76798
Keh-Fei Liu Department of Physics, University of Kentucky, Lexington, KY, USA 40506
A calculation of the SU(3) pion electric form factor on an 103x29 lattice at 1~=5.9 using a technique that treats the zero momentum pion field as a secondary source is described. 1. INTRODUCTION Lattice hadron
the nonzero momentum
form
factors
internal
comparable
structure
with
a
useful
and
are
ultimately
In
previous
experiment.
publications,
systematic
SU(2)
pion
lattice
are
studies
form
of
probe
the
factor have
of
quenched
been carried
lattice two or three point
functions. We
will
next
explain
some
of
the
relevant
technical aspects of this study. This will be followed by
an
evaluation
discussion and
of
results
and
a
concluding
summary.
out for the Wilson 1 and staggered fermion 2,3 cases. We
report
quenched
here
on
SU(3)
some
pion
partial
form
results
factor
using
for
the
Since SST has been explained in other contexts5,
present
simply state how this technique has been applied.
fermions. There
2. TECHNICAL ASPECTS
Wilson
we will not elaborate on it further here, but will are
several
calculation besides
new
the use
aspects
to
of SU(3).
the
Since
it is
In
previous
workl'3, 7
an
actual
source
necessary to extract matrix elements of the lattice
exponentiation was carried out. That is, the current
charge
density
density,
one
must
devise
a
calculational
scheme to evaluate lattice three point functions. A technique
to
do
this
"exponentiation"
in
it here
sequential
as the
the
has
been
called
literature 4, but we refer to source technique (SST).
operator at
was
included
derivative three
explore higher momenta as well as to use a variety
momentum
of operators to probe the pion,
numerical
limit
ourselves to
examining the conserved vector
position
and
in the
of
the
fermion
two
points
action.
A numerical
function
was
then
taken with respect to a, which produced the desired
The manner in which we employ SST allows us to
although here we
some fixed time
spatial momentum, multiplied by a parameter a << 1,
point
exactly
function transfer. derivative
the
desired
at
a
SST
single
value
is
superior
method
since
combination
of
it
of
spatial to
this
produces two
point
charge density. Our method of analysis is also new
functions. The use of SST to simulate the effect of,
and reveals an unexpected and useful behavior of
for example, axial or vector current densities, has
* This research was supported in part by the Natural Sciences and Engineering Research Council of Canada and in pan by the U.S. Department of Energy under grant DE-FG05-84ER40154.
0920 5632/88/$03.50 © Elsevier Science Publishers B.V. (North-Holland Physics Publishing Division)
T. Draper et al. / Lattice form factors
the
advantage
of
hadronic
state,
functions
for
not
fixing
so that
the
one can
various
initial
or
final
form three point
interpolating
fields
from
525
>> tl >> 1, we have that6 Gnn(t;p) ~ Ns IC(p)I 2 e "Et
(3)
a
single set of quark propagators. On the other hand, it
limits
some
the
possible
largest
source
value
probe.
four momentum
and
These
fixes
the
limitations
transfer to
nature are
of
avoided
probes
then at
transfer.
reconstruct
any
Of
desired
course
one
the
effects
of
lattice
spatial
momentum
then
has
various
propagators
e'm(t2"tl)e-Etl
(4)
if
as the SST secondary source. In a separate analysis can
x
the
instead one uses the initial or final hadronic state
one
Gnjn(tl;q) ~ N 2 C(0)C*(q)
Our
method
is
based
upon
the
analysis
of
the
normalized two and three point functions: G~jn(tl;q) Gnn(t2;0)
_~'-~" e "(E'm)tl C~(0)
(5)
Gnn(t;p) Gnu(t;0) ~
C e_(E.m)t cC(~0) [2
(6)
in
which not the probe but one of the sources (and it's associated momentum) is fixed. We have chosen to examine the consequences of the use of SST in the latter
situation in order to explore lattice electric
Fitting
the
normalized propagator
data
to Eqs.(5)
form factors at higher momentum tranfers. In this
and (6) yields a value for the matrix element of the
study we do not necessarily expect to be in a regime
charge
density
where lattice artifacts are not detectable. However,
electric
form
we
continuum
hope
to
begin
to
understand
some
of
the
operator, factor
limit.
in
We
is
related
to
the
which
usual
manner
in
the
prefer
to
with
the
work
the
systematics involved in attempting to reach such a
normalized propagators since we will see that this
regime.
data is numerically quite well determined. In order
The
lattice
two
and three
point
functions that
to
guide
us
in
the
choice
of
the
two
point
propagator data to use in our fits, we define the
we measure are
local mass and energy by ' Gnn(t;p) = Z e -ip-x
<01T(0(x)0l(0))10>
(I)
x
Gnjn(tl;q)=
,'Gnn(t-1;0)X n ~ -)
(7)
• ~(t-1;p)-~ E(t) = m~'"~nn(t:p) ~
(8)
m(t) = l Z e - i q 'xl <01T(¢(x2)J4(xl)¢'l(0))10> Xl ,x2
(2)
Of course, the right hand side of Eq.(2) is also a function
of
t 2 , the
interpolation
time
field,
position
¢(x2),
but
of in
pion
and look for a time region where these quantities
present
have leveled off. An alternate measurement of the
the
the
t2 will be fixed. The spatial momentum
local energy minus mass, which we use to check
transfer in (2) is q, In calculating (2) on the lattice
consistency, is also available from the use of the
it is necessary to leave off the effect of current
normalized three point function, Eq.(5).
application
self-contractions, which
do
in
they
the
SU(3)
case
as
not do
necessarily for
SU(2).
vanish This
Our 103x20
original
quenched
configurations
were
and were calculated using the Monte Carlo
represents the interaction of the probe with a sea
Cabbibo-Marinari
rather than a valence quark. In the formal limit t2
fundamental Wilson action was used with periodic
p s e u d o h e a t b a t h 8.
The
SU(3)
T. Draper et al. / Lattice form factors
526
boundary
conditions
and
13 = 5.9. W e do not have
justification for this choice in that a certain type of
e n o u g h m a s s data yet to h a v e set the lattice scale or
total
measure
in
idea
K c r at this 13. However, in order to give an
o f the
physical
box
size,
although
we
realize
derivative
(9)
term c a n c e l s b e t w e e n
in the
combination
classical
we are not in a perturbative scaling regime, the 13 =
zero
6.0 results of Ref. 9 scaled to 5.9 give a w --- .12fm. The
s u p p o s e d l y located
g a u g e field was thermalized for 5000 s w e e p s after a cold
start
and
sweeps
10 c o n f i g u r a t i o n s
were
1/3Re,
saved. equals
Our
region
evolution
characteristics
configurations
in
In
which
were
by
average
.5822(2).
adequate
separated
of
plaquette,
order to
1000
to
have
examine
propagators,
lengthened
to
an
momentum
We
used
quark
were
by
criterion
103x29
gradient
we
gauge
At p r e s e n t
this
profile
at
current
we
demanded
technique
As
a
test
checked invariant
parameters. we
Also,
time
conserved
evaluation.
propagators accuracy.
local
conjugate
program
hopping
a
limit.
correct
exactly at time t.
the
propagator
these
the
for
computer
time
continuum
possesses
the two t e r m s
final
For
our
that
the
of
the
that
up
have
for
to
pion machine
results for two convergence
maximum
change
duplicating part o f the g a u g e fields in time. For the.
in the absolute s u m of squares o f the quark or SST
quarks
propagators
we u s e d periodic
spatial
directions
conditions,
boundary
and
which
conditions
"fixed"
consist
of
time
setting
the
couplings
across the time edge to zero.
boundary
conditions
exact,
and
this
inversion also
the
provides
algorithm.
preserve
propagators.
lattice
gauge check
These
exactly The
a
the
origin
of
With
on
the
fixed is
quark
conditions
condition
all
quark
invariance
boundary
CPT
in the
boundary
quark
on
quark
propagators
As
one
be
less
check
than
of
the
propagator origin
was
SST
lattice
seen
to
propagator
Ward
conservation
convergence
accuracy.
pion
jackknife
25.
We
that
far
from
nonvacuum In
these positions
lattice
time
are
sufficiently
boundaries
to
avoid
contaminations.
extracting
results
In
our
the
normalized
two
10
propagators
with
O(10-4).
an
origin
to
In addition,
the
responsible
is
with
another In
technique
fits
functions single
from
to
guarantees,
zero m o m e n t u m
the
secondary
for
our
charge boundary
conditions, that the pion charge is one. W e m e a s u r e which
expect
5 iterations.
agree
identity
1+O(1 0-4),
fixed at time site
SST
over
made possible by exact CPT, an origin to origin pion
was chosen to be at lattice time site 5; the secondary source was
5x10 5
of
over
all
for
cases
a
given
we
estimating
normalized
exponential
indication
two
time
and
interval,
chi-squared
of
the
used
the
error
bars.
three
point
we
used
a
fit. 1 1
3. RESULTS
and three point functions, it is n e c e s s a r y in the fits to
assign
time
to
the
location,
conserved time.
We
which
is
labelled lattice
tl
such
operator
in Eq.(2). density
of the
symmetrical
currents
density
charge
u s e a form a
nonlocal
charge
a unique
However, is
nonlocal
the in
vector current, j 4 ( t ) ,
combination
of
conserved
Some
of
presented referred
to
Figs.
at
that (9)
is defined t
and
t-l.
at sites t + l There
a consecutive
1 and 2 were
mass
from the two momentum
j+
of
this
investigation
1-8. R e s u l t s in these labelling
of
are
figures are lattice
time
useful
as a
guide
in our
choice o f propagator time data. T h e y show the local
j4(t) = 1/2( j+ + j-)
defined
results
sites from 1 to 29.
energy,
where
the
in Figs.
is
and
t and j- is
some
theoretical
energy
point
transfers
(~/5,n/5,n/5), equivalent
and
and lattice
minus
functions. were
mass
The
q values
the pion
measured
q = (n/5,0,0),
(2n/5,0,0).
for
We and
spatial
(n/5,n/5,0),
averaged
over
treated
the
T. Draper et al. / Lattice form factors
averaged
results as a single d a t u m
routines.
The
that
(E-m)
alone,
lower
is statistically
i.e.,
normalized The
portion
that two
(E-m)
point
also
place
examined
for
and
at both
allows us to reliably time
which
values
improves
the
from
site
9,
which
time
site
error
bar
8
onwards
in
these
relation
figures
results
for
m a s s e s for a 17 to 25 fit.
become
flat
individually.
This
to
transfers values.
or
m
It
individually,
estimates.
that
lines
dispersion
mass. Table 1 gives the results for the pion and rho
In
all
of
results are seen to plateau at
means
horizontal
out.
parameter
for E
The
continuum
cancel
to
momentum
than
the
the
seen
hopping
show
in
tend
all
individually.
E
fit the n o r m a l i z e d f u n c t i o n s at
our g r a p h s the (E-m) time
are
show than E
fluctuations
s o o n e r than E or m
took
graphs
determined
functions
behavior
smaller
these
better
statistical
results
significantly
of
in the j a c k k n i f e
527
the p r o p a g a t o r falls
like
a
data single
exponential. W e selected time steps 8 through
and
(E-m)
given
the
lattice
result
for
the pion
Figs. 3 and 4 s h o w the local (E-m) v a l u e s from the
time
Eq.(4). the
two
aspect
behavior
of
the
three
point
function,
T h e s e v a l u e s are seen to be c o n s i s t e n t with point
function
o f the
results.
normalized
A
three
quite
point
remarkable
function
seen
in these figures is the fact that it falls like a single exponential
from
time
site
6 onwards
in all cases.
(Remember, time site 5 is the location of one of the local pion fields.) T h u s , an 8 to 12 fit of this data is quite
12 in
conservative
A
as far as e s t i m a t i n g error bars.
comparison
of
lattice
and
continuum
all of our exponential fits of the normalized two and
dispersion,
three point
functions, is carried out in Figs. 5 and 6. Since we
functions, Eqs.(5)
and (6).
One can see
using
the
8 to
12
time
fit
two
point
in Figs. 1 and 2 that such a time interval would not
find
be
determined than E alone, we have plotted (E-m) as a
appropriate
if
we
were
to
fit
E
and
m
I I I I I I I I I I 1 1 1
2.6
that
(E-m)
Eolol
2.6
oo
K=O. 140
2.4-
t
2.4-
D
2.01.8 1.6
0 A
0 °
•
Es- ~
o E a
•
E2- ~
n
•
Ej-~
Re o E~
I
2.0-
1.6-
t
I
I
I
I
and
I
reliably
1
I
E a
K=0.148
c
o
~0
easily
o •
Ea-.vn,
c
A
Ee-~ ~
a
* E~ m
n o~
1.8-
r.q 1.4
I
2.2-
O~
0
more
ao ao o
2.2-
is
o Eo=132
u~
zx o
1.4-
~
T
nZ~I~
~ 1.2
a; 1.o
~4 1.0 0.8--
0.8
0.6--
0.6
0.4--
0.4
•
0.2 -' 0.0
I
I
3 5
[
I
I
I
I
I
I
I
I
7 9 11131517192123252729 TIME SLICE
FIGURE 1 T h e local e n e r g y , m a s s and e n e r g y m i n u s m a s s in lattice u n i t s f r o m the n o r m a l i z e d pion two p o i n t function as a function of time for K=.140.
0.0
I 3
I 5
I 7
I 9
I I 1 I I I I I I 1113151719212325272~ TIME SLICE
FIGURE 2 Same as Fig.1 but for K=.148.
--
Re o E, --
528
T. Draper et al. / Lattice f o r m factors
.8
[
[
.7-
I
[
[
[
I
I
I
K=0.140
I
[
[
I
• Es-rre
1 f
.8
-
*7 --
-
.6-
I
I
I
[
L I
I
K=0.148
I
t
I
• E3--TTb
• Ee-va
• E2-,tre .6-
I
• Et-,rn
,5
E1--m
•
--
~.4-
.3
,~
-
- t
,2
-
--
1][
.0
I
I
E
I
I
I
I
I
I
I
I
J
.0
I
I
FIGURE 3 L o c a l e n e r g y m i n u s m a s s f r o m the n o r m a l i z e d p i o n three point f u n c t i o n as a f u n c t i o n o f t i m e for K=.140. .8
.6 -
I
[
I
I
I
I
I
I
I
I
I
I
I
I
I
L
1
I
3 5 7 9 11131517192123252729 TIME SLICE
3 5 7 9 11f31517192123252729 TIME SLICE
FIGURE 4 S a m e as Fig. 3 but for K=.148.
]
.8
K=O.140
I
.6 -
~.4-
I
[
I
I
I
I
1
K=0.148
~.4-
r
.2
.19 T I t 0.0 0.2 0 . 4 0 . 6 0 . 8
I 1.0
p/m
I I 1.2 1.4
I 1.6
.0 L8
FIGURE 5 Pion energy minus mass versus momentum, both s c a l e d by m a s s f r o m the 8 to 12 t i m e fit of the n o r m a l i z e d two p o i n t f u n c t i o n at K = . 1 4 0 . T h e p i o n m a s s w a s m e a s u r e d s e p a r a t e l y in a 17 to 25 t i m e fit o f the zero m o m e n t u m two point function.
-
-
I
I
[
I
0.0 0.2 0 . 4 0 . 6 0 . 8
I
I
I
l
1.0
1.2
1.4
1.6
FIGURE 6 S a m e as Fig. 5 but for K=.148.
1.0
T. Draper et aL / Lattice form factors
529
function of the momentum, both scaled by mass. We
higher m o m e n t u m transfers.
see that the K=.140
found
violate
result seems to
continuum
dispersion.
systematically
However,
the
In so doing,
we have
a useful behavior of normalized lattice
and three point
two
functions. This behavior allows us
comparison has significantly improved at K=.148, as
to
one would
The error bars on the form factor data are also seen
expect for lower lattice mass, with the
exception of the highest m o m e n t u m point. Our
final
results
for
the
pion
reliably
check
the
lattice
dispersion
relation.
to be quite reasonable.
electric
form
We have
seen that
the form
factor results are
factor as a function of Minkowski four m o m e n t u m
systematically higher than would
squared are given in Table 1 and shown in Figs. 7
vector dominance. This is not surprising at K=.140
and
where our accurate (E-m) measurements allow us to
8.
results
Also
shown
from
are
vector
the
dominance
expected using
monopole the
lattice
be expected
from
see a significant violation of continuum dispersion,
measurement of the rho meson mass. The accuracy
but is more puzzling for
of our form factor determinations allows us to see
dispersion seems to
that the lattice
larger error bars. A violation in the same direction
results are probably deviating from
vector dominance by being systematically too high.
One
of
demonstrate
the
major
the
implementation
in
goals
in
this
of
the
I
1.2
1.0
1
(which
form
study
was
present
factor
data
to
SST at
I
are
consistent
single
monopole
1,0
0.8
0.8
0,6
r~ 0.6
0.4
0.4
0.0
where
respected,
spatially
continuum albeit with
form.
vector q=n/5
Of
doubled
spatial
course,
103x20
m o m e n t u m points
dominance, point
lies
restoration
I
but
the
above
the
(within
I
--
--
}(=0.140
0.0
a
with
calculated
1.2
\
0,2 -
uses
lattice) where the q=n/10
usefulness extracting
K=.148
well
also appears in the SU(2) Wilson form factor data of Ref.
4. SUMMARY AND DISCUSSION
be
K=0.148
fit: 8-12
fit: 8-12
0.2
[
I
0.5
1.0
&
0,0 1.5
FIGURE 7 The pion electric form factor as a function of lattice four m o m e n t u m transfer at K=.140.
I
0.0
0.5
[
qe
FIGURE 8 The same as Fig. 7 but for K=.148.
1.0
1,5
T. Draper et al. / Lattice form factors
530
TABLE 1 masses
momenta
K
mn
mp
(n/5,0,0)
(n/5,n/5,0)
(n/5,n/5,n/5) (2n/5,0,0)
.140 .148
1.121(10) .797(13)
1.139(12) .829(16)
.83(2) .73(3)
.73(3) .62(6)
.68(4) .58(6)
.59(5) .42(8)
error bars) of the physical dispersion relation does not
guarantee
that
the
measured
form factors
are
also physical. However, we think it more likely that the
K=. 148
fortuitous
dispersion
and
violation
that
results
we
really
of both
continuum
for
range
dominance
our
are
have
somewhat
a
factor
results
at quite
the
dispersion and vector
of momentum
two
K
similar.
values,
By
which
delving
transfer,
improvement.
The
there
pion
to
should
vector
be
dominance
However,
we
have
also
an
We
have on
succeeded form
in
reducing
factors
and
the
lattice
seen
that
statistical dispersion
enough for it to be apparent where future efforts must be directed.
One can probe to smaller four
momentum transfer on the present size lattices by choosing
the
current
density
(at
lowest
boosting
statements
the
concerning
pion.
Of
course
the
usual
improved
results
on
larger
lattices apply as well. We intend to investigate these matters
further
in
future
publications.
We thank George Hockney for providing us with a copy of his SU(3) gauge field Monte Carlo code. One of us (WW) would also like to thank the theory group
at
SLAC,
where
Lattice Gauge Theory: A Challenge in Large-Scale C o m p u t i n g , eds. B. Bunk, K.H. Mutter and K. Schilling (Plenum, New York, 1986) pp. 199-207. 6. W. Wilcox and Keh-Fei Liu, Phys. Rev. D35 (1987) 2056. 7. W. Wilcox and R.M. Woloshyn, "Lattice Hadron Structure and the Electric Form Factor," in: Advances in Lattice Gauge Theory, eds. D.W. Duke and J.F. Owens (World Scientific, Singapore, 1985) pp. 136-147. 8. N. Cabibbo and E. Marinari, Phys. Lett. l 1 9 B (1982) 387. 9. H.W. Hamber, Phy. Lett. B178 (1986) 277.
ACKNOWLEDGEMENTS
performed,
5. T. Draper, "Lattice Evaluation o f Strong Corrections to Weak Matrix Elements -- AI=I/2 Rule," Ph.D. thesis, University of California, Los Angeles, 1984 (unpublished); C. Bernard, T. Draper, G. Hockney, and A. Soni, "Calculation of Weak Matrix Elements: Some Technical Aspects," in:
spatial
momentum) as the secondary SST source and then Lorentz
4. C. Bernard, "Lattice Calculation of Hadronic Weak Matrix Elements: The AI=l/2 Rule," in: Gauge Theory on a Lattice: 1984, eds. C. Zachos, W. Celmaster, E. Kovacs, and D. Sivers (National Technical Information Service, Springfield, VA) pp. 85-101.
result
statistical errors increase in this direction.
errors
3. W. Wilcox and R.M. Woloshyn, Phys. Rev. Lett. 54 (1985) 2653
look
smaller
may indeed be recovered, and this would be quite dramatic.
2. R.M. Woloshyn and A.M. Kobos, Phys. Rev. D33 (1986) 222.
transfers.
lattice hadron mass, and therefore also smaller four momentum
1. R.M. Woloshyn, Phys. Rev. D34 (1986) 605.
systematic
This is suggested also by a comparison of the form qualitatively
REFERENCES
part
for their hospitality.
of
this
work
was
10. B. Efron, SIAM Rev. 21 (1979) 460. 11. We used the CURFIT program from: P.R. Bevington, Data Reduction and Error Analysis for the Physical Sciences (McGraw-Hill, New York, 1969).
Nuclear Physics B (Proc. Suppl.) 4 (1988) 524-530 North-Holland, Amsterdam
LATTICE FORM FACTORS: AN UPDATE* Terrence Draper and Richard Woloshyn TRIUMF, 4004 Wesbrook Mall, Vancouver, B.C., Canada V6T 2A3
Walter Wilcox Department of Physics, Baylor University, Waco, TX, USA 76798
Keh-Fei Liu Department of Physics, University of Kentucky, Lexington, KY, USA 40506
A calculation of the SU(3) pion electric form factor on an 103x29 lattice at 1~=5.9 using a technique that treats the zero momentum pion field as a secondary source is described. 1. INTRODUCTION Lattice hadron
the nonzero momentum
form
factors
internal
comparable
structure
with
a
useful
and
are
ultimately
In
previous
experiment.
publications,
systematic
SU(2)
pion
lattice
are
studies
form
of
probe
the
factor have
of
quenched
been carried
lattice two or three point
functions. We
will
next
explain
some
of
the
relevant
technical aspects of this study. This will be followed by
an
evaluation
discussion and
of
results
and
a
concluding
summary.
out for the Wilson 1 and staggered fermion 2,3 cases. We
report
quenched
here
on
SU(3)
some
pion
partial
form
results
factor
using
for
the
Since SST has been explained in other contexts5,
present
simply state how this technique has been applied.
fermions. There
2. TECHNICAL ASPECTS
Wilson
we will not elaborate on it further here, but will are
several
calculation besides
new
the use
aspects
to
of SU(3).
the
Since
it is
In
previous
workl'3, 7
an
actual
source
necessary to extract matrix elements of the lattice
exponentiation was carried out. That is, the current
charge
density
density,
one
must
devise
a
calculational
scheme to evaluate lattice three point functions. A technique
to
do
this
"exponentiation"
in
it here
sequential
as the
the
has
been
called
literature 4, but we refer to source technique (SST).
operator at
was
included
derivative three
explore higher momenta as well as to use a variety
momentum
of operators to probe the pion,
numerical
limit
ourselves to
examining the conserved vector
position
and
in the
of
the
fermion
two
points
action.
A numerical
function
was
then
taken with respect to a, which produced the desired
The manner in which we employ SST allows us to
although here we
some fixed time
spatial momentum, multiplied by a parameter a << 1,
point
exactly
function transfer. derivative
the
desired
at
a
SST
single
value
is
superior
method
since
combination
of
it
of
spatial to
this
produces two
point
charge density. Our method of analysis is also new
functions. The use of SST to simulate the effect of,
and reveals an unexpected and useful behavior of
for example, axial or vector current densities, has
* This research was supported in part by the Natural Sciences and Engineering Research Council of Canada and in pan by the U.S. Department of Energy under grant DE-FG05-84ER40154.
0920 5632/88/$03.50 © Elsevier Science Publishers B.V. (North-Holland Physics Publishing Division)
T. Draper et al. / Lattice form factors
the
advantage
of
hadronic
state,
functions
for
not
fixing
so that
the
one can
various
initial
or
final
form three point
interpolating
fields
from
525
>> tl >> 1, we have that6 Gnn(t;p) ~ Ns IC(p)I 2 e "Et
(3)
a
single set of quark propagators. On the other hand, it
limits
some
the
possible
largest
source
value
probe.
four momentum
and
These
fixes
the
limitations
transfer to
nature are
of
avoided
probes
then at
transfer.
reconstruct
any
Of
desired
course
one
the
effects
of
lattice
spatial
momentum
then
has
various
propagators
e'm(t2"tl)e-Etl
(4)
if
as the SST secondary source. In a separate analysis can
x
the
instead one uses the initial or final hadronic state
one
Gnjn(tl;q) ~ N 2 C(0)C*(q)
Our
method
is
based
upon
the
analysis
of
the
normalized two and three point functions: G~jn(tl;q) Gnn(t2;0)
_~'-~"
(5)
Gnn(t;p) Gnu(t;0) ~
C e_(E.m)t cC(~0) [2
(6)
in
which not the probe but one of the sources (and it's associated momentum) is fixed. We have chosen to examine the consequences of the use of SST in the latter
situation in order to explore lattice electric
Fitting
the
normalized propagator
data
to Eqs.(5)
form factors at higher momentum tranfers. In this
and (6) yields a value for the matrix element of the
study we do not necessarily expect to be in a regime
charge
density
where lattice artifacts are not detectable. However,
electric
form
we
continuum
hope
to
begin
to
understand
some
of
the
operator, factor
limit.
in
We
is
related
to
the
which
usual
manner
in
the
prefer
to
with
the
work
the
systematics involved in attempting to reach such a
normalized propagators since we will see that this
regime.
data is numerically quite well determined. In order
The
lattice
two
and three
point
functions that
to
guide
us
in
the
choice
of
the
two
point
propagator data to use in our fits, we define the
we measure are
local mass and energy by ' Gnn(t;p) = Z e -ip-x
<01T(0(x)0l(0))10>
(I)
x
Gnjn(tl;q)=
,'Gnn(t-1;0)X n ~ -)
(7)
• ~(t-1;p)-~ E(t) = m~'"~nn(t:p) ~
(8)
m(t) = l Z e - i q 'xl <01T(¢(x2)J4(xl)¢'l(0))10> Xl ,x2
(2)
Of course, the right hand side of Eq.(2) is also a function
of
t 2 , the
interpolation
time
field,
position
¢(x2),
but
of in
pion
and look for a time region where these quantities
present
have leveled off. An alternate measurement of the
the
the
t2 will be fixed. The spatial momentum
local energy minus mass, which we use to check
transfer in (2) is q, In calculating (2) on the lattice
consistency, is also available from the use of the
it is necessary to leave off the effect of current
normalized three point function, Eq.(5).
application
self-contractions, which
do
in
they
the
SU(3)
case
as
not do
necessarily for
SU(2).
vanish This
Our 103x20
original
quenched
configurations
were
and were calculated using the Monte Carlo
represents the interaction of the probe with a sea
Cabbibo-Marinari
rather than a valence quark. In the formal limit t2
fundamental Wilson action was used with periodic
p s e u d o h e a t b a t h 8.
The
SU(3)
T. Draper et al. / Lattice form factors
526
boundary
conditions
and
13 = 5.9. W e do not have
justification for this choice in that a certain type of
e n o u g h m a s s data yet to h a v e set the lattice scale or
total
measure
in
idea
K c r at this 13. However, in order to give an
o f the
physical
box
size,
although
we
realize
derivative
(9)
term c a n c e l s b e t w e e n
in the
combination
classical
we are not in a perturbative scaling regime, the 13 =
zero
6.0 results of Ref. 9 scaled to 5.9 give a w --- .12fm. The
s u p p o s e d l y located
g a u g e field was thermalized for 5000 s w e e p s after a cold
start
and
sweeps
10 c o n f i g u r a t i o n s
were
1/3Re
saved. equals
Our
region
evolution
characteristics
configurations
in
In
which
were
by
average
.5822(2).
adequate
separated
of
plaquette,
order to
1000
to
have
examine
propagators,
lengthened
to
an
momentum
We
used
quark
were
by
criterion
103x29
gradient
we
gauge
At p r e s e n t
this
profile
at
current
we
demanded
technique
As
a
test
checked invariant
parameters. we
Also,
time
conserved
evaluation.
propagators accuracy.
local
conjugate
program
hopping
a
limit.
correct
exactly at time t.
the
propagator
these
the
for
computer
time
continuum
possesses
the two t e r m s
final
For
our
that
the
of
the
that
up
have
for
to
pion machine
results for two convergence
maximum
change
duplicating part o f the g a u g e fields in time. For the.
in the absolute s u m of squares o f the quark or SST
quarks
propagators
we u s e d periodic
spatial
directions
conditions,
boundary
and
which
conditions
"fixed"
consist
of
time
setting
the
couplings
across the time edge to zero.
boundary
conditions
exact,
and
this
inversion also
the
provides
algorithm.
preserve
propagators.
lattice
gauge check
These
exactly The
a
the
origin
of
With
on
the
fixed is
quark
conditions
condition
all
quark
invariance
boundary
CPT
in the
boundary
quark
on
quark
propagators
As
one
be
less
check
than
of
the
propagator origin
was
SST
lattice
seen
to
propagator
Ward
conservation
convergence
accuracy.
pion
jackknife
25.
We
that
far
from
nonvacuum In
these positions
lattice
time
are
sufficiently
boundaries
to
avoid
contaminations.
extracting
results
In
our
the
normalized
two
10
propagators
with
O(10-4).
an
origin
to
In addition,
the
responsible
is
with
another In
technique
fits
functions single
from
to
guarantees,
zero m o m e n t u m
the
secondary
for
our
charge boundary
conditions, that the pion charge is one. W e m e a s u r e which
expect
5 iterations.
agree
identity
1+O(1 0-4),
fixed at time site
SST
over
made possible by exact CPT, an origin to origin pion
was chosen to be at lattice time site 5; the secondary source was
5x10 5
of
over
all
for
cases
a
given
we
estimating
normalized
exponential
indication
two
time
and
interval,
chi-squared
of
the
used
the
error
bars.
three
point
we
used
a
fit. 1 1
3. RESULTS
and three point functions, it is n e c e s s a r y in the fits to
assign
time
to
the
location,
conserved time.
We
which
is
labelled lattice
tl
such
operator
in Eq.(2). density
of the
symmetrical
currents
density
charge
u s e a form a
nonlocal
charge
a unique
However, is
nonlocal
the in
vector current, j 4 ( t ) ,
combination
of
conserved
Some
of
presented referred
to
Figs.
at
that (9)
is defined t
and
t-l.
at sites t + l There
a consecutive
1 and 2 were
mass
from the two momentum
j+
of
this
investigation
1-8. R e s u l t s in these labelling
of
are
figures are lattice
time
useful
as a
guide
in our
choice o f propagator time data. T h e y show the local
j4(t) = 1/2( j+ + j-)
defined
results
sites from 1 to 29.
energy,
where
the
in Figs.
is
and
t and j- is
some
theoretical
energy
point
transfers
(~/5,n/5,n/5), equivalent
and
and lattice
minus
functions. were
mass
The
q values
the pion
measured
q = (n/5,0,0),
(2n/5,0,0).
for
We and
spatial
(n/5,n/5,0),
averaged
over
treated
the
T. Draper et al. / Lattice form factors
averaged
results as a single d a t u m
routines.
The
that
(E-m)
alone,
lower
is statistically
i.e.,
normalized The
portion
that two
(E-m)
point
also
place
examined
for
and
at both
allows us to reliably time
which
values
improves
the
from
site
9,
which
time
site
error
bar
8
onwards
in
these
relation
figures
results
for
m a s s e s for a 17 to 25 fit.
become
flat
individually.
This
to
transfers values.
or
m
It
individually,
estimates.
that
lines
dispersion
mass. Table 1 gives the results for the pion and rho
In
all
of
results are seen to plateau at
means
horizontal
out.
parameter
for E
The
continuum
cancel
to
momentum
than
the
the
seen
hopping
show
in
tend
all
individually.
E
fit the n o r m a l i z e d f u n c t i o n s at
our g r a p h s the (E-m) time
are
show than E
fluctuations
s o o n e r than E or m
took
graphs
determined
functions
behavior
smaller
these
better
statistical
results
significantly
of
in the j a c k k n i f e
527
the p r o p a g a t o r falls
like
a
data single
exponential. W e selected time steps 8 through
and
(E-m)
given
the
lattice
result
for
the pion
Figs. 3 and 4 s h o w the local (E-m) v a l u e s from the
time
Eq.(4). the
two
aspect
behavior
of
the
three
point
function,
T h e s e v a l u e s are seen to be c o n s i s t e n t with point
function
o f the
results.
normalized
A
three
quite
point
remarkable
function
seen
in these figures is the fact that it falls like a single exponential
from
time
site
6 onwards
in all cases.
(Remember, time site 5 is the location of one of the local pion fields.) T h u s , an 8 to 12 fit of this data is quite
12 in
conservative
A
as far as e s t i m a t i n g error bars.
comparison
of
lattice
and
continuum
all of our exponential fits of the normalized two and
dispersion,
three point
functions, is carried out in Figs. 5 and 6. Since we
functions, Eqs.(5)
and (6).
One can see
using
the
8 to
12
time
fit
two
point
in Figs. 1 and 2 that such a time interval would not
find
be
determined than E alone, we have plotted (E-m) as a
appropriate
if
we
were
to
fit
E
and
m
I I I I I I I I I I 1 1 1
2.6
that
(E-m)
Eolol
2.6
oo
K=O. 140
2.4-
t
2.4-
D
2.01.8 1.6
0 A
0 °
•
Es- ~
o E a
•
E2- ~
n
•
Ej-~
Re o E~
I
2.0-
1.6-
t
I
I
I
I
and
I
reliably
1
I
E a
K=0.148
c
o
~0
easily
o •
Ea-.vn,
c
A
Ee-~ ~
a
* E~ m
n o~
1.8-
r.q 1.4
I
2.2-
O~
0
more
ao ao o
2.2-
is
o Eo=132
u~
zx o
1.4-
~
T
nZ~I~
~ 1.2
a; 1.o
~4 1.0 0.8--
0.8
0.6--
0.6
0.4--
0.4
•
0.2 -' 0.0
I
I
3 5
[
I
I
I
I
I
I
I
I
7 9 11131517192123252729 TIME SLICE
FIGURE 1 T h e local e n e r g y , m a s s and e n e r g y m i n u s m a s s in lattice u n i t s f r o m the n o r m a l i z e d pion two p o i n t function as a function of time for K=.140.
0.0
I 3
I 5
I 7
I 9
I I 1 I I I I I I 1113151719212325272~ TIME SLICE
FIGURE 2 Same as Fig.1 but for K=.148.
--
Re o E, --
528
T. Draper et al. / Lattice f o r m factors
.8
[
[
.7-
I
[
[
[
I
I
I
K=0.140
I
[
[
I
• Es-rre
1 f
.8
-
*7 --
-
.6-
I
I
I
[
L I
I
K=0.148
I
t
I
• E3--TTb
• Ee-va
• E2-,tre .6-
I
• Et-,rn
,5
E1--m
•
--
~.4-
.3
,~
-
- t
,2
-
--
1][
.0
I
I
E
I
I
I
I
I
I
I
I
J
.0
I
I
FIGURE 3 L o c a l e n e r g y m i n u s m a s s f r o m the n o r m a l i z e d p i o n three point f u n c t i o n as a f u n c t i o n o f t i m e for K=.140. .8
.6 -
I
[
I
I
I
I
I
I
I
I
I
I
I
I
I
L
1
I
3 5 7 9 11131517192123252729 TIME SLICE
3 5 7 9 11f31517192123252729 TIME SLICE
FIGURE 4 S a m e as Fig. 3 but for K=.148.
]
.8
K=O.140
I
.6 -
~.4-
I
[
I
I
I
I
1
K=0.148
~.4-
r
.2
.19 T I t 0.0 0.2 0 . 4 0 . 6 0 . 8
I 1.0
p/m
I I 1.2 1.4
I 1.6
.0 L8
FIGURE 5 Pion energy minus mass versus momentum, both s c a l e d by m a s s f r o m the 8 to 12 t i m e fit of the n o r m a l i z e d two p o i n t f u n c t i o n at K = . 1 4 0 . T h e p i o n m a s s w a s m e a s u r e d s e p a r a t e l y in a 17 to 25 t i m e fit o f the zero m o m e n t u m two point function.
-
-
I
I
[
I
0.0 0.2 0 . 4 0 . 6 0 . 8
I
I
I
l
1.0
1.2
1.4
1.6
FIGURE 6 S a m e as Fig. 5 but for K=.148.
1.0
T. Draper et aL / Lattice form factors
529
function of the momentum, both scaled by mass. We
higher m o m e n t u m transfers.
see that the K=.140
found
violate
result seems to
continuum
dispersion.
systematically
However,
the
In so doing,
we have
a useful behavior of normalized lattice
and three point
two
functions. This behavior allows us
comparison has significantly improved at K=.148, as
to
one would
The error bars on the form factor data are also seen
expect for lower lattice mass, with the
exception of the highest m o m e n t u m point. Our
final
results
for
the
pion
reliably
check
the
lattice
dispersion
relation.
to be quite reasonable.
electric
form
We have
seen that
the form
factor results are
factor as a function of Minkowski four m o m e n t u m
systematically higher than would
squared are given in Table 1 and shown in Figs. 7
vector dominance. This is not surprising at K=.140
and
where our accurate (E-m) measurements allow us to
8.
results
Also
shown
from
are
vector
the
dominance
expected using
monopole the
lattice
be expected
from
see a significant violation of continuum dispersion,
measurement of the rho meson mass. The accuracy
but is more puzzling for
of our form factor determinations allows us to see
dispersion seems to
that the lattice
larger error bars. A violation in the same direction
results are probably deviating from
vector dominance by being systematically too high.
One
of
demonstrate
the
major
the
implementation
in
goals
in
this
of
the
I
1.2
1.0
1
(which
form
study
was
present
factor
data
to
SST at
I
are
consistent
single
monopole
1,0
0.8
0.8
0,6
r~ 0.6
0.4
0.4
0.0
where
respected,
spatially
continuum albeit with
form.
vector q=n/5
Of
doubled
spatial
course,
103x20
m o m e n t u m points
dominance, point
lies
restoration
I
but
the
above
the
(within
I
--
--
}(=0.140
0.0
a
with
calculated
1.2
\
0,2 -
uses
lattice) where the q=n/10
usefulness extracting
K=.148
well
also appears in the SU(2) Wilson form factor data of Ref.
4. SUMMARY AND DISCUSSION
be
K=0.148
fit: 8-12
fit: 8-12
0.2
[
I
0.5
1.0
&
0,0 1.5
FIGURE 7 The pion electric form factor as a function of lattice four m o m e n t u m transfer at K=.140.
I
0.0
0.5
[
qe
FIGURE 8 The same as Fig. 7 but for K=.148.
1.0
1,5
T. Draper et al. / Lattice form factors
530
TABLE 1 masses
momenta
K
mn
mp
(n/5,0,0)
(n/5,n/5,0)
(n/5,n/5,n/5) (2n/5,0,0)
.140 .148
1.121(10) .797(13)
1.139(12) .829(16)
.83(2) .73(3)
.73(3) .62(6)
.68(4) .58(6)
.59(5) .42(8)
error bars) of the physical dispersion relation does not
guarantee
that
the
measured
form factors
are
also physical. However, we think it more likely that the
K=. 148
fortuitous
dispersion
and
violation
that
results
we
really
of both
continuum
for
range
dominance
our
are
have
somewhat
a
factor
results
at quite
the
dispersion and vector
of momentum
two
K
similar.
values,
By
which
delving
transfer,
improvement.
The
there
pion
to
should
vector
be
dominance
However,
we
have
also
an
We
have on
succeeded form
in
reducing
factors
and
the
lattice
seen
that
statistical dispersion
enough for it to be apparent where future efforts must be directed.
One can probe to smaller four
momentum transfer on the present size lattices by choosing
the
current
density
(at
lowest
boosting
statements
the
concerning
pion.
Of
course
the
usual
improved
results
on
larger
lattices apply as well. We intend to investigate these matters
further
in
future
publications.
We thank George Hockney for providing us with a copy of his SU(3) gauge field Monte Carlo code. One of us (WW) would also like to thank the theory group
at
SLAC,
where
Lattice Gauge Theory: A Challenge in Large-Scale C o m p u t i n g , eds. B. Bunk, K.H. Mutter and K. Schilling (Plenum, New York, 1986) pp. 199-207. 6. W. Wilcox and Keh-Fei Liu, Phys. Rev. D35 (1987) 2056. 7. W. Wilcox and R.M. Woloshyn, "Lattice Hadron Structure and the Electric Form Factor," in: Advances in Lattice Gauge Theory, eds. D.W. Duke and J.F. Owens (World Scientific, Singapore, 1985) pp. 136-147. 8. N. Cabibbo and E. Marinari, Phys. Lett. l 1 9 B (1982) 387. 9. H.W. Hamber, Phy. Lett. B178 (1986) 277.
ACKNOWLEDGEMENTS
performed,
5. T. Draper, "Lattice Evaluation o f Strong Corrections to Weak Matrix Elements -- AI=I/2 Rule," Ph.D. thesis, University of California, Los Angeles, 1984 (unpublished); C. Bernard, T. Draper, G. Hockney, and A. Soni, "Calculation of Weak Matrix Elements: Some Technical Aspects," in:
spatial
momentum) as the secondary SST source and then Lorentz
4. C. Bernard, "Lattice Calculation of Hadronic Weak Matrix Elements: The AI=l/2 Rule," in: Gauge Theory on a Lattice: 1984, eds. C. Zachos, W. Celmaster, E. Kovacs, and D. Sivers (National Technical Information Service, Springfield, VA) pp. 85-101.
result
statistical errors increase in this direction.
errors
3. W. Wilcox and R.M. Woloshyn, Phys. Rev. Lett. 54 (1985) 2653
look
smaller
may indeed be recovered, and this would be quite dramatic.
2. R.M. Woloshyn and A.M. Kobos, Phys. Rev. D33 (1986) 222.
transfers.
lattice hadron mass, and therefore also smaller four momentum
1. R.M. Woloshyn, Phys. Rev. D34 (1986) 605.
systematic
This is suggested also by a comparison of the form qualitatively
REFERENCES
part
for their hospitality.
of
this
work
was
10. B. Efron, SIAM Rev. 21 (1979) 460. 11. We used the CURFIT program from: P.R. Bevington, Data Reduction and Error Analysis for the Physical Sciences (McGraw-Hill, New York, 1969).