QCD phenomenology from the lattice: Renormalisation of local operators

Nuclear Physics B (Proc. Suppl.) 9 (1989) 121-133 North-Holland, Amsterdam

121

QCD PHENOMENOLOGY FROM THE LATTICE: Renormalisation of Local Operators*

Christopher T. Sachrajda Department of Physics, The University,

Southampton,

S09 5NH, United Kingdom

The problem of extracting phenomenologically useful results from lattice measurements of operator matrix elements is reviewed. We start with a brief discussion of "lattice renormalisation schemes" and lattice perturbation theory. Then, by using the vector current as an example, it is demonstrated that the mixing of operators under renormalisation with other operators of higher mass dimension, an effect which disappears as the lattice spacing goes to zero, is nevertheless numerically significant at present values of p. It is also demonstrated that the power divergences (i.e. terms which diverge as inverse powers of the lattice spacing) which arise when the operators of interest can mix with others of lower dimension, must be subtracted non-perturbatively.

h

(in this talk I will use the MS scheme) whereas

I. INTRODUCTION In many phenomenological

applications of QCD

the non-perturbative physics is contained in

the lattice computations of the matrix elements are performed using some "lattice

matrix elements of local operators taken

renormalisation scheme",

between hadronic states.

depends on the lattice action being used).

During this confer-

ence we will hear about the latest (and in many

(the lattice scheme

cases the first) lattice computations of some

difference between the two schemes; this in-

of these matrix elements 1'2

volves performing a perturbative calculation

However, before

the results of these computations can be compared with experimental measurements,

It

is therefore necessary to bridge the

using Feynman rules derived from the lattice they

action which was used to compute the matrix

have to be combined with perturbative calcula-

elements.

tions of the contributions

which use lattice perturbation theory, in some

from the

short-distance or light cone regions of phase space,

(i.e. with the corresponding Wilson

coefficient function).

In general both the

perturbative calculations and the matrix

I will discuss these calculations,

detail in section 2. To illustrate the content of the opening paragraph let us consider deep inelastic structure functions and weak decay amplitudes.

elements depend on the way the local operators

In each case the result can be expressed as

have been renormalised

the matrix element of a bilocal operator

(i.e. on the

renormalisation scheme and on the

H(x,0) between hadronic states.

renormalisation scale).

inelastic electroproduction H is the product

The perturbative

In deep

calculations have generally been performed in

of two electromagnetic currents, one at x and

some standard continuum renormalisation scheme

the other at 0, whereas for weak decays H is the product of two weak (V-A) currents, convoluted with the W or Z propagator.

Plenary talk presented at the annual lattice conference, LATT88, Fermilab, September 1988

0920-5632/89/$03.50 © Elsevier Science Publishers B.V. (North-Holland Physics Publishing Division)

Using

the operator product expansion H is expanded as a series of local operators:

C.T. Sachrajda / QCD phenomenology from the lattice

122

other choices of the action, H(x,O)

= ~

C i (x;~) 0i(O; ~)

(I.I)

where ~ islthe renormalisation scale and the

For the structure functions in the

Bjorken limit we are interested in light-like separations

(x2~0) whereas for the weak decays

we are interested in the short distance limit, where each component of x is 0(I/Mw).

In each

(the operators

of lowest twist in the case of the structure functions and the operators of lowest dimension in the case of the weak decays).

The matrix

elements of H(x,0) are independent of ~ and of the renormalisation scheme used to define the renormalised operators 0i(O;~).

However,

it

is necessary to calculate the coefficient function C i in the same renormalisation scheme as that used to compute the matrix elements of Oi, a calculation which involves the use of

The plan for the remainder of this talk is In the next section I will

briefly review the use of lattice perturbation theory.

which are 0(a) in numerical calculations, this may lead to significant errors at present values of the lattice spacing a. In section 3, by using the renormalisation constant of the local vector current

example,

(which

I demonstrate that this is indeed

the case.

For the purposes of illustration I

will use the Wilson action for lattice QCD:

Generalisations

to other

operators are discussed. In section 4 I consider power divergences,

i.e. terms in the

renormalisation constants of operators which diverge as an inverse power of the lattice spacing (a), as a goes to 0.

These power

divergences are more severe on the lattice, since Euclidean symmetry is broken (as is chiral symmetry in the case of Wilson fermions).

"lattice perturbation theory".

as follows.

section 5).

is not conserved on the lattice) as an

case we need only keep a small number of operators in the sum in (I,I),

(see

Although it is usual to neglect terms

operators {0 i} form a complete set of local operators.

in particular

for that containing staggered quarks,

It is pointed out that the

power divergences must be subtracted non-perturbatively.

Section 5 contains a

brief review of the calculations which have been performed to date, which use lattice perturbation theory to extract phenomenologically meaningful results from

s : -

lattice computations. x

Section 6 contains a

summary and our conclusions.

^

+

+Ki(x+~)(l-y~lU

(x)¥(x)]-i(x),(x)) 2. LATTICE PERTURBATION THEORY

I

Tr[Up+U;?

(1.2)

Plaquettes

AS an example consider the local vector current V l°c = ~y~¥.

This current is not

where all colour,flavour and spin indices have

conserved in the lattice theory defined by

been omitted for simplicity.

the action (1.2).

parameter,

K is the hopping

~ m 6/g2o where go is the bare

We start by calculating

its renormalisation constant to one loop

coupling constant and Up is the product of

order, using perturbation theory.

links belonging to the elementary plaquette P.

Feynman rules required for this calculation

The discussion however, applies equally well to

are shown in fig,l (rules for other vertices and propagators can be found in 3.

The

Because

the theory is written in terms of links,

C.T. Sachrajda / QCD pheaomenology from the lattice

p,a

k Gluon Propagator

~2

123

~ab

~r

l~J ~'~sinka +½a~z 8ij

k Quark Propagator

a,p a

--21ia(p+q)~ " } T?. ,j •

j

J a,p

b,-J

-½g2os,. {co,½(p÷q), o P

-ija~(P~q2 )~ }{TQ, T b}jj

j

Quark- Gluon Vertices FIGURE I Feynman Rules required for the calculation of the one loop contribution to the renormalisation constant of the local vector current. ~ ~ 2/a sin (k#/2).

C.T. Sachrajda / QCD phenomenology from the lattice

124

(a)

(b)

(c)

FIGURE 2 One-loop diagrams which contribute to the renormalisation constant of the local vector current. rather than potentials,

there are additional

contribution comes from the "tadpole graph"

vertices to those in the continuum theory; e.g.

(fig.2(c)), which is a general feature of

the four point vertex in fig.l.

such computations.

The diagrams

which have to be evaluated are shown in fig.2.

In the next section I will report on the

These are evaluated numerically with the

results of lattice computations of Zvl°C,

results (in the Feynman gauge):

which will be compared to the expected result, i.e. that given in eqn. (2.3).

s CF

fig 2(a) -

[log

1

+ 7.26]

(2.1a)

In

general we are interested in computing the matrix element of some local operator 0

fig 2(b)

~ s CF

I-log

I

+

1.12] (21b)

between an initial state state

fig 2(c) - ~

S

If>.

li> and a final

Renormalising the operator by

using the lattice scheme we have: CF

12.24

(2.1c)

where I is an infrared cut-off introduced by


•

II>LATT =

0(o)[i +

modifying the denominator of the gluon propagator from ~2 t o ~2+ ~2,

factor

4 CF ~ g .

The u l t r a v i o l e t

and t h e c o l o u r

_ss

4, C-yIogC~2a2]

+

+ CLATT)

"'']

(2.4)

(and infrared)

whereas

by using the MS scheme we have

divergence cancels and we find ks zlOC 1 - s V = ~ C F 20.6

+

(2.2)

Taking p = 6.0 (i.e. g = I) as a typical value

2 ylog ~-+ ...]

(2.5)

of the coupling in current lattice where CLATT, c~-~ and the anomalous dimensions calculations gives, y are constants which can be determined from zlOC = 0.83 V

(2.3) one-loop perturbation theory.

The calculations are straightforward, although in general the loop integrals have to be performed numerically.

The largest

bare operator.

0 (°) is the

Thus the matrix elements in

the two renormalisation schemes are related by

C.T. Sachrajda / Q C D phenomenology from the lattice

125

momentum tensor.
Fi>~-~ = LATT (2.6)

states are proportional

S

( c ~ - CLATT?+...]

El + ~ In this

way t h e m a t r i x e l e m e n t d e f i n e d

continuum renormaIisation from that

in the hadron. Among the diagrams contribut-

in a

ing to the renormalisation

scheme i s o b t a i n e d

The corresponding

Of course if we calculate all the

higher order terms on the right hand side then

As the lattice and MS definitions

of ~s

Indeed the contributions

Thus in this example c ~

correction

In practice

to the

the lattice coupling is

This is natural for the example of the

tends to be

For other operators

CLATT > c~[~

for n=O

(2.8a)

CLATT ~ c~-~

for n=l

(2.8b)

CLATT < CM-~

for n~2

(2.8c)

derivatives

are due to lattice

in the operator.

this is not the

case, however the large contributions c~

represents a negligibly small

to the measured value of .

where n is the number of covariant

local vector current given above since c ~ = 0 , and all the corrections effects.

- CLATT is small,

the dominant one it is usually the case that

the one loop term in (2.6) is sensitive

used.

from the two

Since the tadpole contribution

(2.7)

~LATT(~ )

choice.

loop integral is identical

to that for the tadpole graph in fig (2.c).

and eqn.(2.6)

differ c o n s i d e r a b l y 3 ' 4

at ~ ~ 2GeV,

(3).

tadpole graphs are equal and opposite.

the result would not depend on the choice of

2.7

of this operator

is the one loop graph drawn in figure

Which definition of ~s should we use in

~s"

to , the average

fraction of momentum carried by the quarks

m e a s u r e d on t h e l a t t i c e .

eqn.(2.6)?

Forward matrix elements

of this operator between single hadron

to

- CLATT still come from lattice effects.

Thus although

it is not possible

to say that

the use of the lattice coupling is a better approximation

than a continuum definition,

without calculating

higher order corrections,

this is indeed the expectation above observation

that the one loop contribu-

tion comes predominantly I have mentioned contributions

from lattice effects.

above that the tadpole FIGURE 3

to the wave function

renormalisation contribution

based on the

constant

is the largest

to the one loop term in eqn.(2,2),

A "tadpole" diagram which contributes to the renormalisation constant of the energy momentum tensor, and hence .

and generally gives the dominant contribution. Tadpole graphs also arise from the expansion of the link variables

in covariant derivatives

in

is the quark contribution

to the energy

In lattice computations

it is usual to

neglect terms which vanish as the lattice

operators which contain such derivatives. Consider for example the operator ~ygDV~,

3. 0(a) CORRECTIONS

which

spacing goes to zero. attempts

to "improve"

There have been some the calculations

including some of these terms, notably

by

C.T. Sachrajda/ QCD phenomenology from the lattice

126

Symanzik's

program 5,6, but in practice

terms are not kept in phenomenological tions.

these

Here I would like to demonstrate,

means of a numerical neglecting

computation,

where

applicaby

that

four-momentum p.

this matrix

lattice at ~=6.0 we

when the particle is a pion8:

errors.

The example which I will use is again that of the local vector current VB l°c = ~y~¥.

is not conserved

= 0.99 ± 0.05

for K=0.1515

~v = 1.00 ± 0.05

for K=O.1530

= I.II ± 0,06

for K=0.1545

In

the previous section we have seen that this operator

Computing

element on a 20xlO2x40

obtain the following very precise results

terms which are O(a) can lead to

significant

I p > is a meson or baryon state with

in the theory defined

(3.4)

by the action (1.2) and that we should expect its renormalisation 6.0.

constant

The computation

The chiral limit corresponds

to be ~ 0.83 at

to a value of

the hopping parameter K=0.1564(2) 8'9.

of Zvl°C is made

simpler by the existence of a conserved vector For the proton the results are still

current in the theory defined by (1.2)7: 1

~= ~ ~(x) (y-1)u (x)v(x+~) + ~ (x+~) (v+l) U+(x),(x)] The renormalisation ~

consistent with one but are a little

(3.1)

precise.

constant of the operator

(3.1) separately

_loc ZV can be readily

is precisely one.

for the two cases when the

quark, q, is an up quark or a down quark. We find I0

determined by taking ratios of matrix elements, _loc

In this case we compute the matrix

elements of the conserved vector current

~V = 0.87 ± 0.15

for K=0.1515

and q=up

~V = 0.92 ± 0.10

for K=0.1515

and q=down

=

ZV

(3.2)



and = ratio of corresponding functions. zlOC has been computed using both two and V three point correlation

(2.5)

correlation

~V = 0.89 ± 0.29

for K=0.1530 and q=up

~V = 1.08 ± 0.16

for K=0.1530

functions and I will For both the pion and proton,

now discuss these results.

had three-momentum a) 3-Point Correlation Before presenting

Functions.

the results for Zvl°C,

constant of the conserved vector current,

I

a

In this way we check the precision of

any information

(without of course gaining

about the physics content).

Defining this renormalisation < p I ~

[ p >

=l_ 2pp ~v

and the matrix

index ~ chosen to be I.

The results are

consistent with ZV = 1 and we also have some

quantity for which we know the exact result to

the numerical work,

(I/10,0,0)

the hadron

elements were computed with the Lorentz

will present those for the renormalisation

be I.

and q=down

constant by (3.3)

indication of the precision of lattice computations

involving three-point

tion functions.

correla-

The results in (3.4) and

(3.5) were obtained using 15 gauge field configurations.

C. T. Sachrajda / QCD phenomenology

from

the lattice

127

We have confirmed these results on our K 0.1515 0.1530 0.1545

K 0.1515 0.1530

larger

PION = 4 0.76 0.73 0.71

~= 1 0.73 0.71 0.71

lattice 12.

These results are

clearly inconsistent,

the results obtained using the three-point correlation function,

PROTON q = up ~ = 4 0.76 0.73

not only with the

perturbative result of 0.83, but also with

~ = 1 0.72(3) 0.74(10)

(see table I).

What is the reason for the discrepancy between the results obtained using two-point and three-point correlation functions?

K 0.1515 0.1530

It

is not due to the quenched approximation,

PROTON q = dow~ ~ = 4 0.76 0.73

~ = 1 0.73 0.73(4)

since this would affect both computations equally. Moreover,

the one-loop contribution

to Zvl°C does not contain any quark loops Table I. Values of ZvL°C obtained by

anyway.

computing three point correlation functions

being due to the fact that V l°c mixes with

containlng the operator qy~q.

operators of higher dimension with coeffi-

The error is

We interpret the discrepancies as

less than one on the last digit unless

cients which vanish as the lattice spacing

otherwise stated.

goes to zero,

This effect is neglected in

all calculations, In table one we present the results of our

but the numerical results

presented above seem to indicate that it can

calculations of ZV l°c, obtained by taking the

lead to significant errors.

This interpre-

ratio of the three-point correlation functions

tation is supported by the fact that at

with the local and conserved currents

~=6.2 (for which the inverse lattice spacing

(eqn.(3.2)).

is about 3 GeV), Zvl°C increases to a value

The correlation functions were

evaluated at zero momentum transfer. that the statistical

0.6513 .

Notice

Here I have demonstrated,

errors on the ratios are

by using V l°c

tiny, they are generally less than 1 in the

as

second digit.

of higher dimension can lead to significant

The results do depend on the

quark mass, albeit very mildly.

They differ a

an example, that mixing with operators

errors,

(~ 40%?) on the numerical evaluation

little from the one-loop perturbative result of

of matrix elements.

0.83, but in itself this could be accounted for

particularly simple because of the knowledge

by higher order corrections to the perturbative

that the renormalisation constant of the

prediction.

conserved current is precisely I.

What is more significant however

is that the results differ from those obtained

Our example was

For other

operators we do not know the exact value of the renormalisation constant, however, by

using two-point correlation functions. b) Two-Point Correlation Functions

computing the ratio of the matrix elements

Using two-point correlation functions, on a

of two different lattice definitions of the

I03x20 lattice at ~=6.0, Maiani and

same continuum operator, and comparing the

Martinelli II obtained the results

result to the perturbative prediction for

Zvl°C = 0.57 ± 0.01

for K=0.1515

ZvI°C = 0.57 ± 0.01

for K=0.1530

Zvl°C = 0.58 ± 0.02

for K=0 1545

this ratio, one can get some idea of the (3.6)

systematic problems.

The important

question which now arises is whether it is

C.T. Sachrajda/ QCD phenomenology from the lattice

128

possible to include some of the O(a) correc-

the 4 operators 0 3 D ~

transform as the

tions by hand, and hence to reduce the

vector representation

((~,~) in the notation

systematic

of ref (16) where the character table for

error?

This problem is currently

the hypercubic

being studied.

group can be found).

vector current ~ y ~ 4.

POWER DIVERGENCES

transforms

The

in the same

way and the operator 03~D~ mixes with the vector current under renormalisation.

In the previous section we discussed the problem of operators mixing under renormalisation

mixing coefficient

diverges

Hence in the computations

with other operators

of higher

elements of 0 3 ~ ,

The

like I/a 2.

of the matrix

the leading term is this

dimension.

This effect was found to be

mixing term of O(I/a2), which is a lattice

numerically

significant

artefact of no phenomenological

at current values of

the lattice spacing a, but becomes important as a gets smaller.

interest.

This power divergence must be subtracted

less

In this section

before we can extract useful results from

we discuss mixing with operators of lower

lattice calculations.

dimension;

case this is possible by choosing the

in this case the mixing coeffi-

In this particular

cients diverge as inverse powers of a. This

Lorentz indices appropriately.

problem is more severe on the lattice because

the combination

Lorentz

(or Euclidean)

symmetry

invariance

and chiral

(in the case of Wilson fermions)

not symmetries

of the lattice.

renormalisation

schemes,

prevent the existence

transform as different of the Lorentz group.

these symmetries

often

operators may

tensor representations As will be demonstrated

below, the power divergences non-perturbatively

are

must be subtracted

before meaningful

results

can be obtained from the lattice computations. To illustrate divergences 03~vP m ~ Lorentz

indices.

operators

the existence of power

Matrix elements of these

are proportional

tions of hadrons

(4.1)

like the eight dimensional

representation

of the hypercubic

group and

does not mix with operators of lower dimension.

Thus it is possible to evaluate

the matrix elements of 03~vP with the power divergence

removed but at a two-fold price.

First of all the subtraction removes the component

in eqn.(4.1)

in 03411 which

like the (~,~) representation

i.e. it removes the power divergence.

D p ~, symanetrised over the

to the second

moment of the deep inelastic structure

transforms

transforms

consider the operators

y~ D v

03411 - ~ (03422 + 03433 )

In continuum

of power divergences,

since e.g. the corresponding

For example

leads to a considerable

tion with the corresponding precision.

func-

(when the forward matrix

numerical

Secondly,

This

cancella-

loss of

when we take the

matrix element of 0~ vp we are interested the "leading twist" component,

which is the

element between the single hadron states is

term proportional

computed 8'I0,14)

momentum of the hadron. Thus the matrix

or the quark distribution

to p~pVpp, where p is the

amplitude of the pion (when the matrix element

element of the operator in eqn,(4.1)

between the pion and the vacuum is computedlS).

vanishes

Under transformations

non-zero three-momentum.

of the hypercubic

group

possible

in

trivially unless the hadron has a

to evaluate

It is not

the matrix elements of

C.T. Sachrajda / QCD phenomenology from the lattice 0~ vp with the hadron at rest.

129

Power divergences must be subtracted

Note that it would not be possible to avoid

non-perturbatively.

the large numerical cancellations by choosing all 3 Lorentz indices to be different (e.g. by

For the field strength tensor F ~v on the lattice, the definition 19

using the operator 0~ 12 which transforms like the ( ~ )

representation and again does not mix

with operators of lower dimension).

Fgv~ !

4a 2

However

~

4 plaquettes in ~,v plane

1 U + 2i~UpP ~ (4.3)

the symmetrisation over the Lorentz indices which is implicit in the definition of 0~ 12,

has the advantage that it transforms like

again involves the cancellation of power

the ( I , 0 ) ~

divergences.

representation of the hypercubic group.

Moreover using 0~ 12 we would

need to give the hadron two non-zero components

F ~v is defined using a single plaquette,

the ~,v plane as in eqn. (4.3), then it

To illustrate the large numerical cancellations consider Figure 4, where the three-point correlation functions of the operators 0~ 11 and 0~ II - ~ (0~22 + 0~ 33) between pion states with momentum (~/I0,0,0) The subtraction of the power

divergences reduces the result by an order of magnitude.

If

rather than summing over all 4 plaquettes in

of three momentum.

are presented 14.

(0,I) 6 dimensional, reducible

Fortunately the correlations in the

results for 0~ II and ~ (0~22 + 0~ 33) are strong and even after the subtraction there is still a significant signal,

(the situation is

somewhat worse in the case of the quark distribution amplitudel5). For the structure function of the pion the results in fig. 4 give

transforms like a 24 dimensional reducible representation and there is more scope for operators containing F ~v to be able to mix with operators of lower dimension.

For

example, using the single plaquette definition of F ~ ,

the gluonic contribution

to the energy-momentum tensor, F~VF ~p, contains a hypercubic group singlet and mixes with the unit operator under renormalisaiton,

(we have verified numeri-

cally that the vacuum expectation value of F~VF ~p does not vanish when the single plaquette definition of F ~v is usedl2). Hence care has to be taken to choose an



=

0.18 ± 0.05

(4.2)

appropriate lattice definition of F ~V to avoid power divergences, and eqn. (4.3) is

at a scale of about 7 GeV, where experimental data is available.

Unfortunately not all power divergences

In this example even after

the subtraction of power divergences the error is reasonable, but this is not so in some other

can

be removed by using the transformation

properties of operators under the hypercubic group, and choosing the Lorentz indices

cases. It has been suggested that it may be reasonable to subtract the power divergences perturbatively 17.

frequently found to be the optimal choice.

Perturbation theory at ~ = 6 . 0

appropriately.

An important example appears

in the computation of weak matrix elements in the study of the ~I = ~ rule (in

generally gives a small contribution for these

particular when evaluating matrix elements

divergences 17'18, whereas we have

between single meson states).

seen that the full non-perturbative subtraction changes the result drastically.

~±

The operators

=

[SLY d L ULY~UL ± SLY u L ULY~dL ] - u ~ (4.4)

c

C.T. Sachrajda / QCD phenomenology from the lattice

130

I

I

I

C(tx= 15,fy)x 10"l

I

1

[

K = 0.1530

Operator n" 3~11(y)

Operator O~'~ (y)-½(O~ ,,(y)+ O~"(y)) 100 90 80 70 60 50 -4,0--

3020100 0

5

6

7

8

I

I

9

10

FIGURE 4: Three-point correlation functions of the operators 0~ II and 0~ II(0~ 22 + 0~aa). The difference is due to the subtraction of power divergences.

C.T. Sachrajda/ QCD phenomenology from the lattice

131 +

Thus in order to determine combination

which have mass dimension six, mix under renormalisation

of matrix elements

with the scalar density sd, +

which has dimension

3; specifically

A+ = Z± ^± + + O~E N [0LATT + S60- + S5 O- +

C±

+


+


(4.5)

operators with which O± mix.

do not contain any power divergences,

These

(the GIM

The power divergence

of

the

in c-.

In the SU(3) limit, using

chiral perturbation

of the AI = ~ amplitude, configurations 1,20,21.

even with 30

For this reason the amplitudes

(which

do not suffer from these power divergences) directly may seem to be the natural way to

is

+

contained

for the 100%

errors which still exist in the evaluation

evaluation of the K + ~

that the extra mass

factor in 850± is the mass

charm quark).

of power divergences

in eqn. (4.10) is responsible

renormalisation

S60± and S50± are other six and five

dependent

I sd I K+(g) > (4.10)

The subtraction

mechanism guarantees

IO~ERTI K+(O)>

- <~+(O)



where Z is the diagonal

dimensional

+

IO~ERTIK (R)>

sd]

+ ± Z- [0pERT + c ± sd]

constant,

y- we need the

theory to reduce out a pion

study the AI = ~ rule, however in this case one first has to understand

from the K + I~ matrix element, we find that

scalar particle

<~+(k)

coefficients

the role of the

pole 20'21.

We note in passing that in this case, the 10;m N IK+(H)> = y~k.q + gem 2

(4.6) +

where +the K + I~ amplitude Thus y- is given by

c ± obtained non-

perturbatively,

is given by y-.

using the procedure

described above, agree approximately with those obtained in perturbation

[E(q) - m] my ± = <~+(0)

I~;ENI

- <~+(O)

IO~ENI

theory.

K+(R)>

K+(O)>

(4.7)

5. PERTURBATIVE

CALCULATIONS

In this section I briefly review the The factor in square brackets on the left hand side of eqn.(4.7) fluctuations

is small and subject to large

hence reducing

the evaluation

of y±.

cient c ± is determined condition

the precision

The divergent

in

coeffi-

once a renormalisation

is imposed on the operators 0 ±, for

example

calculations

(or are nearing completion),

from those computed on the lattice: i)

Bilinear Operators

of

the sixteen matrices of Dirac theory).

For these operators ± I~RENI K+(O)> = 0

(4.8)

+

± c

<~ (9) = -

condition c- is

the perturbative

have been performed both for

The calculations

include the

cases in which the lattice operators are

+

extended over two lattice sites (connected

10pERTI K+(9 )> (4.9)

+


(~r~ where F is one

Wilson fermioms 22,23 and staggered fermions 24.

+

With this renormalisation given by:

which enable

one to determine continuum matrix elements

calculations <~+(9)

which have been done to date

I sd I

K+(O) >

by the appropriate

link variable so as to

preserve gauge invariance), operators of the form ~ F D ~ ,

so that where D is the

C.T. Sachrajda / QCD phenomenology from the lattice

132

covariant

derivative

ii) Four-fermion

are also included.

operators

and ~I = 3/2 weak decays. cients the calculation whereas for staggered

relevant

2)

for AI =

lattice spacing,

For Wilson coeffi-

is complete 25'26,27, fermions

The corrections

of O(a), where a is the

can be significant.

In

section 3 we presented an explicit example in which this was the case.

it is almost

3)

Power divergences,

i.e. terms which

complete 28,29, but the mixing with the dimen-

diverge as inverse powers of a as a ~ O,

sion five operator

must be subtracted non-perturbatively,

(SsO± in eqn. 4.5)) has

still not been worked out. fermions the corrections

For staggered

are frequently very

large (in some cases the one loop perturbative correction can change the measured

ACKNOWLEDGEMENTS

result by

It is a pleasure to thank my colleagues

over 50%28).

of the European Lattice Collaboration

iii) Lowest twist operators inelastic

structure

relevant for deep

functions.

For Wilson

fermions these have been computed 17. the coefficients

see

section 4.

Phenomenology.

However

tabulated in tables VI and

Particular

thanks goes to

Guido Martinelli with whom many of the ideas and calculations

VII 17 are wrong 3 0 ' 2 3 , 1 4 .

for an

education in so many aspects of Lattice

described

in this talk were

developed.

iv) Lowest dimension and lowest twist baryonic operators.

These operators are relevant for

REFERENCES

proton decay matrix elements and the quark distribution

amplitudes

of nucleons.

Wilson fermions the coefficients

For

v) Renormalisation

of fB' (the decay constant

of the B-mesons).

Eichten 32 has proposed an

approach to the computation

and the corresponding heavy quark propagator

B-parameter,

these proceedings.

2.

G. Martinelli,

3.

H. Kawai, R. Nakayama and K. Seo, Nucl.Phys. B189 (1981) 40.

4.

A. Hasenfratz and P. Hasenfratz, Phys.Lett. 93B (1980) 165.

5.

K. Symanzik, ibid, 205.

6.

J-P. Ma and W. Wetzel, (1986) 441.

7.

L.H. Karseten and J.H. Smit, Nucl.Phys. B183 (1981) 103.

8.

G. Martinelli and C.T. Sachrajda, Phys. B306 (1988) 865.

9.

M.B. Gavela et al, Nucl. Phys. B306 (1988) 677.

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in which the

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C, Bernard,

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c o m p u t e d 31 .

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calculation

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6. SUMMARY AND CONCLUSIONS

Nucl.

The three main points raised in this talk are : 1)

Matrix

be r e l a t e d

elements

m e a s u r e d on t h e

to

defined

those

lattice

by using

renormalisation

schemes in perturbation

see section 2.

The corrections

significant

see section 5.

I0. G. Martinelli and C.T. Sachrajda, preprint TH.5042/88.

Cern

theory,

are often

and sometimes very large.

such calculations

can

continuum

II. L. Maiani and G. Martinelli, B178 (1986) 265.

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Many

have been or are being done,

12. G. Martinelli unpublished.

and C.T. Sachrajda,

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133