- Email: [email protected]
Quarks in nuclei
WORKSHOP
QUARKS
IN
II
NUCLEI
CONTRIBUTORS
J. Adam C. Chanfray A.E.L. Dieperink P. Gonzalez P.A.M. Guichon J-F. Mathiot G. Miller H.J. Pirner A.W. Schreiber A.W. Thomas E. Truhlik V. Vent0 K. Yazaki
237~
Nuclear Physics A497 (1989) 237c-246~ North-Holland, Amsterdam
QUARKS IN NUCLEI P.J. MULDERS Nations
Institute for Nuclear Physics and High-Energy section K (NIKHEF-K), P.O. Box 41882 1009 DB Amsterdam, The Netherlands
Physics,
1. INTRODUCTION In the 25 years that the quark model exists, understanding
flavor, flavor-spin
in the nonabelian
chromodynamics
(QCD) as the theory underlying
devoted
progress
to solving
gauge theories
led naturally
has been made in the
was on symmetries
and color. In the seventies the theoretical developments
and specifically
understanding
considerable
of the structure of hadrons. In the sixties the emphasis
in quantum field theories
to the emergence
the strong interactions.
QCD, of which lattice gauge theories
of models
that incorporate
confinement
and asymtotic
models. After confinement
freedom.
seem the most promising.
For the
followed route is the
a number of features of the basic theory, most notably
Well-known
examples
are quark potential
has been put in, the color magnetic
exchange interaction is responsible
of quantum
Many efforts have been
of the structure and properties of hadrons the most commonly
construction
such as
(spin-spin)
models and bag
part of the one gluon
for the hyperfine structure in the mass spectrum of baryons and
mesons. Another approach has been the construction of effective hadronic lagrangians such as in the Skyrme model. In the construction of the underlying
of effective lagrangians one attemps to preserve the symmetries
theory. For instance,
which is spontaneously
in the Skyrme model one incorporates
broken with the corresponding
chiral symmetry
appearance of the almost massless pions as
the Goldstone modes in the meson spectrum. At the basis of most of these theoretical developments instance
the measurements
were the experimental
developments,
for
of nuclear, proton and neutron form factors and the results of deep
inelastic electron scattering experiments
showing the existence of pointlike partons inside hadronic
matter. Although quarks and gluons unmis~ingly QCD is very probably degrees
of freedom
momentum excitations
the correct theory describing
for describing
transferred
the interactions
a nucleus strongly
among them, the relevant
depend on the probe and the energy and
to the nucleus. For instance in the description
of vibrational
and rotational
of the nucleus as a whole, states that are for instance excited in reactions between heavy
nuclei at the appropriate freedom,
are the underlying degrees of freedom in nuclei and
energies,
let alone their underlying
one does not even need the individual quark structure.
For higher energies
nucleon
degrees
and momenta
of
nucleons
generally provide a sufficiently accurate description of the nuclear aspects of the problem. Including moreover
the mesons,
notably the pions, and the delta as the lowest nucleon excitation
one can
obtain an accurate description of many processes involving nuclei. Nevertheless
one can pose a number of questions, some of which were addressed in the session
03X-9474j’89/$03.50 0 Elsevier Science Publishers B.V. (No~h.Holland Physics ~bIish~g Division)
‘quarks in nuclei’ at this workshop: 1. Can we understand
the existence
of nuclei with their ground state properties
dominated
by
themselves
as
nucleon degrees of freedom. 2. Could
quark effects
modifications
in low and intermediate
energy
processes
manifest
of intrinsic properties.
3. Can one learn more about the interactions between the quarks from nuclear systems. 4. How do nuclear effects enter in those cases that quarks provide the most natural description such as deep inelastic electron scattering. 5. Is it possible, examples
for instance,
of the transition
in going from low to high momentum from nucleon to quark degrees
transfer to indicate clear
of freedom as the most economic
description. 2. QCD
AND THE
STRUCTURE
A number of con~butions structure
of the hadrons.
interactions,
Few presently
doubt that QCD is the correct
with the quark and gluon theory to describe
the
although it is not yet possible to understand how the hadrons arise as the bound states
in this theory. responsible
OF HADRONS
at this workshop were directly concerned
Nevertheless
attemps
are underway
to try to really understand
how QCD is
for the structure of hadrons.
In the talk of Miller’ some prelimin~y (SCQCD) 2 were presented.
results of calculations
This is an expansion
using strong coupling
QCD
in inverse powers of the coupling constant g and
should be a valid guide to the low momentum-transfer
regime appropriate for nuclear physics where
g takes on larger values. These calculations in SCQCD are performed by treating three-dimensional space as a discrete lattice, while the time variable remains continuous. One finds a lattice hamiltonian H = HE + where
the electric
HQ
+
HM,
field contribution
(2.1) HE, the quark contribution
contribution HM are proportional to g2, 1 and gm2respectively. number of flux lines. The operator HQ is responsible
HQ and the magnetic
field
The operator HE basically counts the
for the quark kinetic energy and pair creation.
The magnetic term HM consists of plaquettes destroying and creating flux lines. One of the physical consequences
is the absence of quark exchange contributions
based on the
fact that the overlap between different flux lines is zero (see fig. 1). Only because of the action of plaquette operators and the fact that physical states are superpositions
of strings of different lengths
and shapes a nonzero exchange effect can arise. In SCQCD meson-meson caused by flux tube re~angement,
interactions
are thus not
but only the quark pair creation operator causes interactions,
much like resonance formation in TCX+ p -+ rcz
P.J. Mulders 1 Quarks in nuclei
Fig. 1: In SCQCD the overlap between diff~re~t~~
In order meson-nucleon
to discuss
nuclear
couplings
dynamics
239~
lines is zero
one only has to establish
and form factors
in reasonable
that SCQCD
agreement
leads to
with experiment.
The
preliminary results of some calculations presented by Miller indeed indicate a qualitative agreement. An attempt to study the consequences
of the QCD lagrangian
in the hadronic
regime was
described in the talk by Chanfray 3. The method, known as the color dielectric model 4, provides a method
to realize
con~g~ations
the transition
are responsible
from QCD to hadronic
for a polarizable
physics.
The short wavelength
medium with dielectric
gluon
constant E. The effective
hamiltonian,
L (Di2+ Hi’),
I;
E&f =
cw
i 2&
shows that color cannot survive in a region where E = 0 and so a (finite) domain with E f 0 will form around a color charge. Chanfray dielectric
showed
how one can extend the derivation
dielectric field x a color neutral vector field 8, appears. In mean field approximation are treated as classical remain,
of the color
theory from pure gluonic QCD in the SU(2) case to the SU(3) case. Besides the color fields the effective
where x and 6u
theory can be solved for baryons. Although problems
e.g. center of mass corrections,
the results seem promising.
The field turns out to be
surface peaked and it is expected to contribute to the repulsion in baryon-baryon
interactions.
The
model also enables one to consider the case of uniform quark nuclear matter. 3.
DEEP INELASTIC
SCATTERING
Deep inelastic scattering of leptons provides a direct picture of the quark and gluon distributions in the target. Through sum rules the connection with properties of the ground state, specifically the expectation
values of some operator is established.
In recent experiments
with
the focus has been on
the spin structure function gIN(x) 5. In his talk, Thomas 6 argued that in order to discuss the sum rules involving the spin structure function gI(x) one needs to consider models that incorporate intimately
connected
to the spin structure. For instance,
function the expectation value of the axial current enters
dx
slN(x) K
4
$0,
Qhl3rsvKQ
IN>
chiral symmetry,
as this symmetry is
in the first moment of the spin structure
P.J. Mulders / Quarks in nuclei
240~
While most of the strength is expected to come from the proton, the neutron contribution vanish. In the cloudy bag model the following nonvanishing
10 dxglN(x)
= - $Nrr
is found, where the quantities P,,
+
25
4
zpAC
-PNAn 9
considerable
result,
(3.2)
denote the probability of baryon-meson
is an interfernce term. Together with the modifications
does not
configurations
and PNA~
of the spin structure by one gluon exchange a
part (37 - 46 %) of the neutron contribution
to the Bjorken sum rule can be explained.
In a short contribution Jaffe outlined how one can calculate the structure functions for deep inelastic scattering
in the Skyrme model directly from the current communicator
in a way similar to the
derivation of the parton model from the free quark currents 7. 4. QUARKS
AND NUCLEAR
One of the fundamental
STRUCTURE
questions in the discussion of quarks in nuclei is the question how the
structure of the nucleus can be understood. shows that quark substructure
Guichon * sketched in his contribution
of nucleons
does not conflict
with the traditional
a scenario that picture of the
nucleus. His model for the nucleon is an M.I.T. bag. The bag in uniform nuclear matter is then studied in mean field approximation. scalar field (3 and an isoscalar-vector
The quarks inside the bags act as sources for an isoscalar field w, which are both treated as classical fields. A consistent
solution can be found with the correct nuclear binding energy at normal density by varying the coupling constants g,and
g, The bag radii that are considered range from 0.6 - 1.0 fm. The values
that are found for the scalar and vector potentials used in hadron field theories.
are roughly a factor three smaller than the ones
This is due to the fact that the relativistic
effect which produces
saturation is more efficient for quarks than for the nucleon. The saturation curve calculated in the model is very similar to usual nuclear matter calculations and is not much affected by corrections for Fermi motion and Pauli blocking
that have also been discussed
in the paper. The ground state
properties for nucleons at normal density such as axial charge and radius are not strongly modified in the nuclear medium. 5. QUARK
EXCHANGE
CONTRIBUTIONS
IN NUCLEI
The general starting point for the study of quark exchange
effects is a nuclear wave function
expressed in terms of quarks degrees of freedom that exhibits clustering into hadrons, i.e. colorless constituents.
The wave function is a resonating group type of wave function vab...(l,
2, 3; 4, 5, 6;...) = N-1/2 R [X(a, b,...)$,(l,
where a, b,... indicate the nucleon coordinates the CM of 1, 2, 3 constrained given by n
2, 3)&(4,
5, %.I
(5.1)
and 1, 2, 3 etc. indicate the quark coordinates
to a, etc. The antisymmetrizer,
= 1 - Z Pij, where the summation
which up to a normalization
is over all pairs of quarks, ensures
with
factor is the Pauli
241~
P.J. Mulders / Quarks in nuclei
principle at the quark level. The no~aliza~on N
of the wave function is given by
= N =,
(5.2)
kernel N ,
b’,...; a, b ,...)
as an intermediate
= <&&,L.
I&?/ $&t,...>,
step by integrating
(5.3)
over the quark coordinates.
This kernel is
in a direct term <&&,L..]~~c&&,...> and an exchange term %(a’, b’,...; a, b ,...)
In a microscopic
calculation
= &a,, &bh . . . f N,,(a’,
b’,...; a, b ,... ).
at the quark level x(a, b,...) is usually determined
(5.4) in a variational
approach after choosing a definite form for the quark wave functions in the nucleon clusters. At the quark level the electroweak
currents are simply given by the elementary vector and axial
currents for the quarks which are pointlike fermions.
The expectation
value of a one-body
quark
operator for the nuclear state described by w,
63
J = C
can be rewritten at the nucleon level which is convenient for nuclear ai~p~cations. This gives J =c
‘XI.iNIX>+
c
N=a,b,..
where &(a’;a)
=
+ ...
(5.6)
NN pairs
<$a’/t: jil4p,
(5.7)
(5.8)
8La,
8-.i-..- _-J_ a’
a--g’
b’
b
\
-7
b
--
--
b’
Fig. 2: One-body quark operators give rise to efsecrive one and two-body nucleon operators because of antisymmetrization
at the quark level.
242~
P.J. Mulders / Quarks in nuclei
are the effective one- and two-nucleon integrating
current operators (illustrated in fig. 2), again constructed by
over the quark coordinates.
The above
illustrates
the appearance
of two-body
contributions in the calculation of matrix elements. It are these contributions approximation
which do not satisfy the separability
properties
of the impulse
such as the factorization of the nuclear form factor in a body form factor and nucleon
form factor or the factorization
of the quasi-elastic
response functions in a scaling function and the
nucleon form factor squared. Examples of this were pointed out by Dicperink in his talk 8. It is, however, not so that quark exchange contributions are there several other conventional
mechanisms
are striking quark signatures. Not only
that also lead to two-body currents, for instance
meson exchange currents, but there is also the fact that the wave functions X(a, b,...) cannot directly be identified with a conventional As was already mentioned
nuclear wave function as was pointed out by Yazaki 9 in his talk.
x could be found from a variational calculation if the hamiltonian
H(l’, 2’, 3’; 4’, 5, 6’;...; 1, 2, 3; 4, 5, 6;...) is known at the quark level. However,
H =
for any but
the lightest nuclei this is not possible so one would rather take the nuclear wave function Xc(a,b,...) from a conventional
nuclear physics calculation.
However, it is not possible to directly identify x
with xc. In order to explain this we must realize that from wherever we got our nuclear quark wave function w = R[x $I @..I, it is assumed to be the best approximation
in the variational problem
~=~,
(5.9)
where H is the hamiltonian at the quark level. Rewriting this at the nucleon level one finds 6
(5.10)
= 0,
where ti(a’,b’,...; a,b,...) = <@a~~t,~../Hk&&,...>is the hamiltonian
at the nucleon level obtained by
integrating out the quark degrees of freedom analogous as done in the normalization kernel or for the currents. This can be rewritten as (5.11)
which shows that if we are using a conventional
wave function xc, the proper comparison with a
wave function x is NV2 x N-1/2 3y112 x =l/2
=
(5.12)
xc.
Yazaki argued that the true two-body effects are given by J -CqcljNIxc> N
= C+ NN
~(-)
243~
P.J. Mulders / Quarks in nuclei
=
$, - W’J)f
‘X
I{n, jN> 1X>)>
Using examples for the deuteron he illustrated the smallness of these true two-body effects among others in the form factor. Although small, the effects are not negligible. he suggests the detailed experimental
As an interesting
example
study of the 4He(e,e’n)jHe reaction.
In the talk by Dieperink 9 he stressed the deviations
from the impulse approximation
that arise
because of the two-body terms in Eq. (5.6). Although in principle drastic effects could occur 11 the effects in light nuclei turn out to be not dramatic, although they are of the same order of magnitude as meson exchange contributions.
Also in quasi-elastic
electron-nucleus
out to be small, at least for 4He, which shows a few percent
scattering the effects turn
increase
in the longitudinal
and
transverse response functions. Dieperink also pointed out that quark exchange effects give rise to a (small) effective three-body Coulomb interaction. Also in deep inelastic electron-nucleus
scattering quark exchange eFfects could be important. The
additional terms modify the quark momentum distributions in a nucleus in a way similar as observed experimentally
in the EMC measurements
In the contribution
**.
presented by Vento l3, he pointed out that there could be interesting places,
where socalled maximal Pauli effects can be expected. In ordinary (light) nuclei, the nuclear wave function
turns out to be dominated
by nucleon pairs that do not lead to dramatic Pauli effects.
Several non traditional nuclear systems such as dibaryons,
light hypemuclei
and delta-nuclei
have
been proposed as places where the quark Pauli principle is more important. Vento and collaborators have analyzed the delta-nuclei
and found sizable effects only for large momenta,
q > 4 fm-l. By
comparing
various channels, however, interesting effects at low energies might show up. They also
considered
the contributions
of quark exchange on the Coulomb energy. Energy differences
as 600 keV can occur in denser
system,
but many uncertainties
prevent
at present
as high a more
quantitative statement 14. 6.
MESON Mathiot
EXCHANGE l5 reviewed
CURRENTS
briefly the standard description
contributions
in the electromagnetic
contributions
expected
electromagnetic
current operator in nuclei and then discussed
from relativistic
corrections
in the constituent
current (MEC) successively
the
quark model, the role of
operators for six quark systems and some results from the Skyrme model.
In the standard correspond
of the meson-exchange
description
the main contribution
to two-body parts in the electromagnetic
with the continuity equation. Smaller contributions
to the meson
exchange
contributions
operator coming from the constraint associated arise from gauge invariant processes
e.g. those
involving pxy couplings and relativistic terms in the current that enter Fatthe same order as MBCs. Mathiot notes that in the constituent important contributions
quark model relativistic
corrections
in the current give
to the nucleon charge radius which have not yet been seriously investigated.
Although in bag models the quarks are treated relativistically,
many problems remain if one tries to
244~
P.J. Mulders / Quarks in nuclei
use an effective describing
With such a separation
six quark current for short distances.
the long range interactions
and quarks describing
between
hadrons
the shott range interactions
a careful
check of the continuity of the current in the transition region is necessary. In the Skyrme model the isoscalar part of the electromagnetic the Wess-Zumino
operator is proportional
term in the effective langrangian
to the baryon current which arises from
and this is connected
QCD. At present, a technical limitation for a better understanding using the Skyrme model 16 is formed by the poor knowledge
to the chiral anomaly in
of isoscalar exchange currents,
of the soliton structure for baryon
numbers larger than one. In his contribution, disintegration. equation
Truhlik
17 studied
in backward
deuteron
Calculations of MBCs in leading order in l/M satisfying the nonrelativistic
continuity
show a strong sensitivity
corrections
and short
range
meson
to the choice
phenomena.
exchange
currents
of the nucleon
For the study
form factors,
of the structure
to relativistic
of the isovector
electromagnetic
MBC Truhlik starts with a lagrangian for the nucleons and the R, p, and Al mesons
that is locally
chiral invariant
dominance.
and as such naturally
The effects of other heavy meson exchanges
are also included as well as relativistic
corrections
incorporates
the idea of vector
meson
(co, 6, rb 6) as used in the Bonn potential
to the current. From the calculations
one can
conclude that the contributions appearing due to the chiral invariance can contribute significantly and should not be omitted. Moreover, it is important to consider relativistic: effects and the con~butions of heavy mesons. 7
CONCLUSIONS It is clear that the session
mentioned
in the introduction.
understanding
of the strong interactions
theoretical considerations.
answers
to the questions
it indicates interest in a better and more fundamental
in nuclei. These questions
However, for understanding
of quantum chromodynamics 8
quarks in nuclei did not give definite Nevertheless,
cannot be answered
and modelling
the nonperturbative
only by aspects
the theoretical efforts are undispensable.
ACKNOWLEDGEMENT This work is part of the research program of the National Institute for Nuclear Physics
High-Energy the Foundation
Physics (NIKHEF, section K), Amsterdam, for Fundamental
and
made possible by financial support from
Research on Matter (FOM) and the Netherlands
Organization
Scientific Research (NWO).
9. REFERENCES 1)
G.A. Miller, ‘Strong coupling QCD and the nucleus’, contribution
2)
I. Kogut and L. Susskind, Phys. Rev. Dll (1975) 395; M. Bander, Phys. Rep. 75 (1981)
to this conference.
for
P.J. Mulders / Quarks in nuclei
24%
206; N. Isgur and J. Paton, Phys. Rev. D31 (1985) 2910. 3)
G. Chanfray, J.F. Mathiot and H.J. Pirner, ‘Color dielectric approach to the nucleon and nuclear matter’, contribution
4)
to this conference.
H.B. Nielsen and A. Patkos, Nucl. Phys. B195 (1982) 137; G. Mack, Nucl. Phys. B235 (1981) 197; H.J. Pirner, J. Wroldsen andM. Ilgenfritz, Nucl. Phys. B294 (1987) 905.
5)
EMC Collaboration,
6)
A.W. Schreiber and A.W. Thomas, ‘Corrections to the Ellis-Jaffe
J. Ashman et al., Phys. Lett. B 206 (1988) 364. sum rule’, contribution
to
this conference. 7)
R.L. Jaffe, ‘Debosonization’,
contribution
to this conference;
R.L. Jaffe, Nucl. Phys. A478
(1988) 3c.
8)
P.A.M. Guichon, ‘Quarks and the saturation of nuclear matter’, contribution conference;
9)
A.E.L. Dieperink and P.J. Mulders, ‘Quark exchange effects in electron-nucleus contribution
10)
to this
P.A.M. Guichon, Phys. Lett. 200B (1988) 235. scattering’,
to this conference.
K. Yazaki, ‘Quark exchange currents within the quark cluster model’, contribution
to this
conference.
11)
T. de Forest and P.J. Mulders, Phys. Rev. D35 (1987) 2849.
12) P. Hoodbhoy and R.L. Jaffe, Phys. Rev. D35 (1987) 113 13)
P. Gonzalez and V. Vento, ‘Quarks in light nuclei’, contribution
to this conference.
14)
F. Wang and C.W. Wong, Nucl. Phys. A432 (1985) 619; F. Wang, C.W. Wong and S. Lu, Nucl. Phys. A480 (1988) 480.
15)
J.-F. Mathiot, ‘Few-body form factors: mesonic or quark degrees of freedom’, contribution to this conference.
16) E.M. Nyman and D.O. Riska, Nucl. Phys. A468 (1987) 473. 17)
E. Truhlik and J. Adam, ‘The chiral and relativistic effects in the backward deuteron disintegration’,
contribution
to this conference.
QUARKS
IN
II
NUCLEI
CONTRIBUTORS
J. Adam C. Chanfray A.E.L. Dieperink P. Gonzalez P.A.M. Guichon J-F. Mathiot G. Miller H.J. Pirner A.W. Schreiber A.W. Thomas E. Truhlik V. Vent0 K. Yazaki
237~
Nuclear Physics A497 (1989) 237c-246~ North-Holland, Amsterdam
QUARKS IN NUCLEI P.J. MULDERS Nations
Institute for Nuclear Physics and High-Energy section K (NIKHEF-K), P.O. Box 41882 1009 DB Amsterdam, The Netherlands
Physics,
1. INTRODUCTION In the 25 years that the quark model exists, understanding
flavor, flavor-spin
in the nonabelian
chromodynamics
(QCD) as the theory underlying
devoted
progress
to solving
gauge theories
led naturally
has been made in the
was on symmetries
and color. In the seventies the theoretical developments
and specifically
understanding
considerable
of the structure of hadrons. In the sixties the emphasis
in quantum field theories
to the emergence
the strong interactions.
QCD, of which lattice gauge theories
of models
that incorporate
confinement
and asymtotic
models. After confinement
freedom.
seem the most promising.
For the
followed route is the
a number of features of the basic theory, most notably
Well-known
examples
are quark potential
has been put in, the color magnetic
exchange interaction is responsible
of quantum
Many efforts have been
of the structure and properties of hadrons the most commonly
construction
such as
(spin-spin)
models and bag
part of the one gluon
for the hyperfine structure in the mass spectrum of baryons and
mesons. Another approach has been the construction of effective hadronic lagrangians such as in the Skyrme model. In the construction of the underlying
of effective lagrangians one attemps to preserve the symmetries
theory. For instance,
which is spontaneously
in the Skyrme model one incorporates
broken with the corresponding
chiral symmetry
appearance of the almost massless pions as
the Goldstone modes in the meson spectrum. At the basis of most of these theoretical developments instance
the measurements
were the experimental
developments,
for
of nuclear, proton and neutron form factors and the results of deep
inelastic electron scattering experiments
showing the existence of pointlike partons inside hadronic
matter. Although quarks and gluons unmis~ingly QCD is very probably degrees
of freedom
momentum excitations
the correct theory describing
for describing
transferred
the interactions
a nucleus strongly
among them, the relevant
depend on the probe and the energy and
to the nucleus. For instance in the description
of vibrational
and rotational
of the nucleus as a whole, states that are for instance excited in reactions between heavy
nuclei at the appropriate freedom,
are the underlying degrees of freedom in nuclei and
energies,
let alone their underlying
one does not even need the individual quark structure.
For higher energies
nucleon
degrees
and momenta
of
nucleons
generally provide a sufficiently accurate description of the nuclear aspects of the problem. Including moreover
the mesons,
notably the pions, and the delta as the lowest nucleon excitation
one can
obtain an accurate description of many processes involving nuclei. Nevertheless
one can pose a number of questions, some of which were addressed in the session
03X-9474j’89/$03.50 0 Elsevier Science Publishers B.V. (No~h.Holland Physics ~bIish~g Division)
‘quarks in nuclei’ at this workshop: 1. Can we understand
the existence
of nuclei with their ground state properties
dominated
by
themselves
as
nucleon degrees of freedom. 2. Could
quark effects
modifications
in low and intermediate
energy
processes
manifest
of intrinsic properties.
3. Can one learn more about the interactions between the quarks from nuclear systems. 4. How do nuclear effects enter in those cases that quarks provide the most natural description such as deep inelastic electron scattering. 5. Is it possible, examples
for instance,
of the transition
in going from low to high momentum from nucleon to quark degrees
transfer to indicate clear
of freedom as the most economic
description. 2. QCD
AND THE
STRUCTURE
A number of con~butions structure
of the hadrons.
interactions,
Few presently
doubt that QCD is the correct
with the quark and gluon theory to describe
the
although it is not yet possible to understand how the hadrons arise as the bound states
in this theory. responsible
OF HADRONS
at this workshop were directly concerned
Nevertheless
attemps
are underway
to try to really understand
how QCD is
for the structure of hadrons.
In the talk of Miller’ some prelimin~y (SCQCD) 2 were presented.
results of calculations
This is an expansion
using strong coupling
QCD
in inverse powers of the coupling constant g and
should be a valid guide to the low momentum-transfer
regime appropriate for nuclear physics where
g takes on larger values. These calculations in SCQCD are performed by treating three-dimensional space as a discrete lattice, while the time variable remains continuous. One finds a lattice hamiltonian H = HE + where
the electric
HQ
+
HM,
field contribution
(2.1) HE, the quark contribution
contribution HM are proportional to g2, 1 and gm2respectively. number of flux lines. The operator HQ is responsible
HQ and the magnetic
field
The operator HE basically counts the
for the quark kinetic energy and pair creation.
The magnetic term HM consists of plaquettes destroying and creating flux lines. One of the physical consequences
is the absence of quark exchange contributions
based on the
fact that the overlap between different flux lines is zero (see fig. 1). Only because of the action of plaquette operators and the fact that physical states are superpositions
of strings of different lengths
and shapes a nonzero exchange effect can arise. In SCQCD meson-meson caused by flux tube re~angement,
interactions
are thus not
but only the quark pair creation operator causes interactions,
much like resonance formation in TCX+ p -+ rcz
P.J. Mulders 1 Quarks in nuclei
Fig. 1: In SCQCD the overlap between diff~re~t~~
In order meson-nucleon
to discuss
nuclear
couplings
dynamics
239~
lines is zero
one only has to establish
and form factors
in reasonable
that SCQCD
agreement
leads to
with experiment.
The
preliminary results of some calculations presented by Miller indeed indicate a qualitative agreement. An attempt to study the consequences
of the QCD lagrangian
in the hadronic
regime was
described in the talk by Chanfray 3. The method, known as the color dielectric model 4, provides a method
to realize
con~g~ations
the transition
are responsible
from QCD to hadronic
for a polarizable
physics.
The short wavelength
medium with dielectric
gluon
constant E. The effective
hamiltonian,
L (Di2+ Hi’),
I;
E&f =
cw
i 2&
shows that color cannot survive in a region where E = 0 and so a (finite) domain with E f 0 will form around a color charge. Chanfray dielectric
showed
how one can extend the derivation
dielectric field x a color neutral vector field 8, appears. In mean field approximation are treated as classical remain,
of the color
theory from pure gluonic QCD in the SU(2) case to the SU(3) case. Besides the color fields the effective
where x and 6u
theory can be solved for baryons. Although problems
e.g. center of mass corrections,
the results seem promising.
The field turns out to be
surface peaked and it is expected to contribute to the repulsion in baryon-baryon
interactions.
The
model also enables one to consider the case of uniform quark nuclear matter. 3.
DEEP INELASTIC
SCATTERING
Deep inelastic scattering of leptons provides a direct picture of the quark and gluon distributions in the target. Through sum rules the connection with properties of the ground state, specifically the expectation
values of some operator is established.
In recent experiments
with
the focus has been on
the spin structure function gIN(x) 5. In his talk, Thomas 6 argued that in order to discuss the sum rules involving the spin structure function gI(x) one needs to consider models that incorporate intimately
connected
to the spin structure. For instance,
function the expectation value of the axial current enters
dx
slN(x) K
4
$0,
Qhl3rsvKQ
IN>
chiral symmetry,
as this symmetry is
in the first moment of the spin structure
P.J. Mulders / Quarks in nuclei
240~
While most of the strength is expected to come from the proton, the neutron contribution vanish. In the cloudy bag model the following nonvanishing
10 dxglN(x)
= - $Nrr
is found, where the quantities P,,
+
25
4
zpAC
-PNAn 9
considerable
result,
(3.2)
denote the probability of baryon-meson
is an interfernce term. Together with the modifications
does not
configurations
and PNA~
of the spin structure by one gluon exchange a
part (37 - 46 %) of the neutron contribution
to the Bjorken sum rule can be explained.
In a short contribution Jaffe outlined how one can calculate the structure functions for deep inelastic scattering
in the Skyrme model directly from the current communicator
in a way similar to the
derivation of the parton model from the free quark currents 7. 4. QUARKS
AND NUCLEAR
One of the fundamental
STRUCTURE
questions in the discussion of quarks in nuclei is the question how the
structure of the nucleus can be understood. shows that quark substructure
Guichon * sketched in his contribution
of nucleons
does not conflict
with the traditional
a scenario that picture of the
nucleus. His model for the nucleon is an M.I.T. bag. The bag in uniform nuclear matter is then studied in mean field approximation. scalar field (3 and an isoscalar-vector
The quarks inside the bags act as sources for an isoscalar field w, which are both treated as classical fields. A consistent
solution can be found with the correct nuclear binding energy at normal density by varying the coupling constants g,and
g, The bag radii that are considered range from 0.6 - 1.0 fm. The values
that are found for the scalar and vector potentials used in hadron field theories.
are roughly a factor three smaller than the ones
This is due to the fact that the relativistic
effect which produces
saturation is more efficient for quarks than for the nucleon. The saturation curve calculated in the model is very similar to usual nuclear matter calculations and is not much affected by corrections for Fermi motion and Pauli blocking
that have also been discussed
in the paper. The ground state
properties for nucleons at normal density such as axial charge and radius are not strongly modified in the nuclear medium. 5. QUARK
EXCHANGE
CONTRIBUTIONS
IN NUCLEI
The general starting point for the study of quark exchange
effects is a nuclear wave function
expressed in terms of quarks degrees of freedom that exhibits clustering into hadrons, i.e. colorless constituents.
The wave function is a resonating group type of wave function vab...(l,
2, 3; 4, 5, 6;...) = N-1/2 R [X(a, b,...)$,(l,
where a, b,... indicate the nucleon coordinates the CM of 1, 2, 3 constrained given by n
2, 3)&(4,
5, %.I
(5.1)
and 1, 2, 3 etc. indicate the quark coordinates
to a, etc. The antisymmetrizer,
= 1 - Z Pij, where the summation
which up to a normalization
is over all pairs of quarks, ensures
with
factor is the Pauli
241~
P.J. Mulders / Quarks in nuclei
principle at the quark level. The no~aliza~on N
of the wave function is given by
= N =
(5.2)
kernel N ,
b’,...; a, b ,...)
as an intermediate
= <&&,L.
I&?/ $&t,...>,
step by integrating
(5.3)
over the quark coordinates.
This kernel is
in a direct term <&&,L..]~~c&&,...> and an exchange term %(a’, b’,...; a, b ,...)
In a microscopic
calculation
= &a,, &bh . . . f N,,(a’,
b’,...; a, b ,... ).
at the quark level x(a, b,...) is usually determined
(5.4) in a variational
approach after choosing a definite form for the quark wave functions in the nucleon clusters. At the quark level the electroweak
currents are simply given by the elementary vector and axial
currents for the quarks which are pointlike fermions.
The expectation
value of a one-body
quark
operator for the nuclear state described by w,
63
J = C
can be rewritten at the nucleon level which is convenient for nuclear ai~p~cations. This gives J =c
‘XI.iNIX>+
c
N=a,b,..
where &(a’;a)
=
+ ...
(5.6)
NN pairs
<$a’/t: jil4p,
(5.7)
(5.8)
8La,
8-.i-..- _-J_ a’
a--g’
b’
b
\
-7
b
--
--
b’
Fig. 2: One-body quark operators give rise to efsecrive one and two-body nucleon operators because of antisymmetrization
at the quark level.
242~
P.J. Mulders / Quarks in nuclei
are the effective one- and two-nucleon integrating
current operators (illustrated in fig. 2), again constructed by
over the quark coordinates.
The above
illustrates
the appearance
of two-body
contributions in the calculation of matrix elements. It are these contributions approximation
which do not satisfy the separability
properties
of the impulse
such as the factorization of the nuclear form factor in a body form factor and nucleon
form factor or the factorization
of the quasi-elastic
response functions in a scaling function and the
nucleon form factor squared. Examples of this were pointed out by Dicperink in his talk 8. It is, however, not so that quark exchange contributions are there several other conventional
mechanisms
are striking quark signatures. Not only
that also lead to two-body currents, for instance
meson exchange currents, but there is also the fact that the wave functions X(a, b,...) cannot directly be identified with a conventional As was already mentioned
nuclear wave function as was pointed out by Yazaki 9 in his talk.
x could be found from a variational calculation if the hamiltonian
H(l’, 2’, 3’; 4’, 5, 6’;...; 1, 2, 3; 4, 5, 6;...) is known at the quark level. However,
H =
for any but
the lightest nuclei this is not possible so one would rather take the nuclear wave function Xc(a,b,...) from a conventional
nuclear physics calculation.
However, it is not possible to directly identify x
with xc. In order to explain this we must realize that from wherever we got our nuclear quark wave function w = R[x $I @..I, it is assumed to be the best approximation
in the variational problem
~
(5.9)
where H is the hamiltonian at the quark level. Rewriting this at the nucleon level one finds 6
(5.10)
= 0,
where ti(a’,b’,...; a,b,...) = <@a~~t,~../Hk&&,...>is the hamiltonian
at the nucleon level obtained by
integrating out the quark degrees of freedom analogous as done in the normalization kernel or for the currents. This can be rewritten as (5.11)
which shows that if we are using a conventional
wave function xc, the proper comparison with a
wave function x is NV2 x N-1/2 3y112 x =
=
(5.12)
xc.
Yazaki argued that the true two-body effects are given by J -CqcljNIxc> N
= C
~(
243~
P.J. Mulders / Quarks in nuclei
=
$,
‘X
I{n, jN> 1X>)>
Using examples for the deuteron he illustrated the smallness of these true two-body effects among others in the form factor. Although small, the effects are not negligible. he suggests the detailed experimental
As an interesting
example
study of the 4He(e,e’n)jHe reaction.
In the talk by Dieperink 9 he stressed the deviations
from the impulse approximation
that arise
because of the two-body terms in Eq. (5.6). Although in principle drastic effects could occur 11 the effects in light nuclei turn out to be not dramatic, although they are of the same order of magnitude as meson exchange contributions.
Also in quasi-elastic
electron-nucleus
out to be small, at least for 4He, which shows a few percent
scattering the effects turn
increase
in the longitudinal
and
transverse response functions. Dieperink also pointed out that quark exchange effects give rise to a (small) effective three-body Coulomb interaction. Also in deep inelastic electron-nucleus
scattering quark exchange eFfects could be important. The
additional terms modify the quark momentum distributions in a nucleus in a way similar as observed experimentally
in the EMC measurements
In the contribution
**.
presented by Vento l3, he pointed out that there could be interesting places,
where socalled maximal Pauli effects can be expected. In ordinary (light) nuclei, the nuclear wave function
turns out to be dominated
by nucleon pairs that do not lead to dramatic Pauli effects.
Several non traditional nuclear systems such as dibaryons,
light hypemuclei
and delta-nuclei
have
been proposed as places where the quark Pauli principle is more important. Vento and collaborators have analyzed the delta-nuclei
and found sizable effects only for large momenta,
q > 4 fm-l. By
comparing
various channels, however, interesting effects at low energies might show up. They also
considered
the contributions
of quark exchange on the Coulomb energy. Energy differences
as 600 keV can occur in denser
system,
but many uncertainties
prevent
at present
as high a more
quantitative statement 14. 6.
MESON Mathiot
EXCHANGE l5 reviewed
CURRENTS
briefly the standard description
contributions
in the electromagnetic
contributions
expected
electromagnetic
current operator in nuclei and then discussed
from relativistic
corrections
in the constituent
current (MEC) successively
the
quark model, the role of
operators for six quark systems and some results from the Skyrme model.
In the standard correspond
of the meson-exchange
description
the main contribution
to two-body parts in the electromagnetic
with the continuity equation. Smaller contributions
to the meson
exchange
contributions
operator coming from the constraint associated arise from gauge invariant processes
e.g. those
involving pxy couplings and relativistic terms in the current that enter Fatthe same order as MBCs. Mathiot notes that in the constituent important contributions
quark model relativistic
corrections
in the current give
to the nucleon charge radius which have not yet been seriously investigated.
Although in bag models the quarks are treated relativistically,
many problems remain if one tries to
244~
P.J. Mulders / Quarks in nuclei
use an effective describing
With such a separation
six quark current for short distances.
the long range interactions
and quarks describing
between
hadrons
the shott range interactions
a careful
check of the continuity of the current in the transition region is necessary. In the Skyrme model the isoscalar part of the electromagnetic the Wess-Zumino
operator is proportional
term in the effective langrangian
to the baryon current which arises from
and this is connected
QCD. At present, a technical limitation for a better understanding using the Skyrme model 16 is formed by the poor knowledge
to the chiral anomaly in
of isoscalar exchange currents,
of the soliton structure for baryon
numbers larger than one. In his contribution, disintegration. equation
Truhlik
17 studied
in backward
deuteron
Calculations of MBCs in leading order in l/M satisfying the nonrelativistic
continuity
show a strong sensitivity
corrections
and short
range
meson
to the choice
phenomena.
exchange
currents
of the nucleon
For the study
form factors,
of the structure
to relativistic
of the isovector
electromagnetic
MBC Truhlik starts with a lagrangian for the nucleons and the R, p, and Al mesons
that is locally
chiral invariant
dominance.
and as such naturally
The effects of other heavy meson exchanges
are also included as well as relativistic
corrections
incorporates
the idea of vector
meson
(co, 6, rb 6) as used in the Bonn potential
to the current. From the calculations
one can
conclude that the contributions appearing due to the chiral invariance can contribute significantly and should not be omitted. Moreover, it is important to consider relativistic: effects and the con~butions of heavy mesons. 7
CONCLUSIONS It is clear that the session
mentioned
in the introduction.
understanding
of the strong interactions
theoretical considerations.
answers
to the questions
it indicates interest in a better and more fundamental
in nuclei. These questions
However, for understanding
of quantum chromodynamics 8
quarks in nuclei did not give definite Nevertheless,
cannot be answered
and modelling
the nonperturbative
only by aspects
the theoretical efforts are undispensable.
ACKNOWLEDGEMENT This work is part of the research program of the National Institute for Nuclear Physics
High-Energy the Foundation
Physics (NIKHEF, section K), Amsterdam, for Fundamental
and
made possible by financial support from
Research on Matter (FOM) and the Netherlands
Organization
Scientific Research (NWO).
9. REFERENCES 1)
G.A. Miller, ‘Strong coupling QCD and the nucleus’, contribution
2)
I. Kogut and L. Susskind, Phys. Rev. Dll (1975) 395; M. Bander, Phys. Rep. 75 (1981)
to this conference.
for
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24%
206; N. Isgur and J. Paton, Phys. Rev. D31 (1985) 2910. 3)
G. Chanfray, J.F. Mathiot and H.J. Pirner, ‘Color dielectric approach to the nucleon and nuclear matter’, contribution
4)
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H.B. Nielsen and A. Patkos, Nucl. Phys. B195 (1982) 137; G. Mack, Nucl. Phys. B235 (1981) 197; H.J. Pirner, J. Wroldsen andM. Ilgenfritz, Nucl. Phys. B294 (1987) 905.
5)
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A.W. Schreiber and A.W. Thomas, ‘Corrections to the Ellis-Jaffe
J. Ashman et al., Phys. Lett. B 206 (1988) 364. sum rule’, contribution
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R.L. Jaffe, ‘Debosonization’,
contribution
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R.L. Jaffe, Nucl. Phys. A478
(1988) 3c.
8)
P.A.M. Guichon, ‘Quarks and the saturation of nuclear matter’, contribution conference;
9)
A.E.L. Dieperink and P.J. Mulders, ‘Quark exchange effects in electron-nucleus contribution
10)
to this
P.A.M. Guichon, Phys. Lett. 200B (1988) 235. scattering’,
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K. Yazaki, ‘Quark exchange currents within the quark cluster model’, contribution
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11)
T. de Forest and P.J. Mulders, Phys. Rev. D35 (1987) 2849.
12) P. Hoodbhoy and R.L. Jaffe, Phys. Rev. D35 (1987) 113 13)
P. Gonzalez and V. Vento, ‘Quarks in light nuclei’, contribution
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14)
F. Wang and C.W. Wong, Nucl. Phys. A432 (1985) 619; F. Wang, C.W. Wong and S. Lu, Nucl. Phys. A480 (1988) 480.
15)
J.-F. Mathiot, ‘Few-body form factors: mesonic or quark degrees of freedom’, contribution to this conference.
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E. Truhlik and J. Adam, ‘The chiral and relativistic effects in the backward deuteron disintegration’,
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