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Structure of the QCD vacuum and excited hadronic matter
377c
Nuclear Physics A522 (1991) 377c-396~ North-Holland, Amsterdam
STRUCTURE
E.V.
OF THE
QCD
VACUUM
AND EXCITED
MATTER
Shuryak
Physics
Department,
Brookhaven
National
Laboratory,
This talk describes the latest development as in theoretical and experimental efforts quark-gluon
1.
HADRONIC
plasma
phase
by means
Upton,
New York
11973
in the theory of the QCD vacuum, as well to study its “melting” into the so-called
of high energy
collisions
of hadrons
and nuclei.
INTRODUCTION This
excited
talk includes hadronic
concerning
matter.
the topic
what we meant the coming moment
two large subjects: Before
one.
Strong
If one is interested journal
with
Planck
scale,
is assumed
this
decades
in the definition
of nuclear
i t includes
Although
physics,
papers
1 GeV. This definition
misleading:
interactions,
In the latter,
the period
toward
QCD
with
is that
changed
during
community
is at the
was observed, at these
the
keV
to
physics
lo-20
years
but now this dividing which
are becoming
splitting
between
line now
of people. one observes
typical
TeV
scale,
in hard
physics,
that
clear
and physics
and now the interests
physics.
from
and high energy
energies
works
nuclear
energies
consult
was indeed meaningful
QCD”
well,
with
nuclear
of “testing
the non-perturbative
here we find overlap
groups
community
with their
really
remarks
main point
he would probably
between
activity
it is exactly
different
in high energy
of electroweak
Perturbative
boundary
at this scale not so great
precisely,
Their
physics
dealing
about
for many
of highly
in this field.
to be somewhere
point
in 1990’s.
with a part of high energy
that
the focusing
and physics
is to be significantly
there,
completely
vacuum
let me make some general
Physics
it is explained
ago, when indeed
More
trends
Nuclear
in previous
convergence
name.
is becoming
shifted
physics
one of the main
of the QCD
we begin their discussion,
of this conference,
by nuclear
theory
processes
cases
seems
to come
of people
is, to 0.1-l
In some
of strong
GeV
are more
energy
it is so strong,
scale. that
physics
interaction. to the end. and more Certainly it becomes
This manuscript has been authored under contract number DE-AC02-76CH00016 with the U.S. Department of Energy. Accordingly, the U.S. Government retains a non-exclusive, royalty-free license to publish or reproduce the published form of this contribution, or allow others
to do so, for U.S.
Government
purposes.
03759474/91/$03.50 @ 1991 - Elsevier Science Publishers B.V. (North-Holland)
378~
E. K Shwyak / QCD vacuum and ercited hadmnic matter
completely
impossible
distributed
between
a completely
to say where Nuclear
illogical
works
Physics
should
be published.
As a result,
A and B ( as well as between
way, representing
author
background
Phys.
papers
Rev.
and position
are
C and D) in
rather
than
paper
cant ent . Scientific
communities
of different
problems.
Let me enumerate
specialised
conferences
1. traditional nuclei,
nuclear
working
excited
easy task,
heavy
systems,
common
interaction
between
so vast Starting
as QED
understand
physics
(section
breaking
the last
vacuum, few years
systems
both
spiration
of this
activity
high energy imental additional
density,
remarks
Then
come
plasma
reasons,
is logically
interaction
own
much
in the 1990’s,
making
lattice
I describe phase
to recent
the so-called
attention
quark-gluon
in the previous
of &CD”.
It is not an
speaking,
complete
(even
strong).
QCD
is the
celebrated
QED
I hope that
strong
and finally
QCD
the content
of this talk.
to concentrate
current
status
transition. progress
will play the same
ideas leading
I briefly
discuss
plasma
talk by Prof.
attempts
to
the latest
of new phase
lattice
symmetry
(section
of high
at high energies’.
(QGP)2.
of
chiral
at high temperature
manifestation
to studies
of the theoretical
in understanding
collisions
Considering
on a few new points.
was paid to production
to possible
large
one.
and have
and nuclear
was related
on them.
in
etc.
strictly
becomes
as well as its restoration
in hadronic
side are discussed
modification
for macroscopically
side, I first have tried to summarize
and then
hadronic
those
as “understanding
I would like to outline
of the corresponding
in the QCD
During
with their
in 1 GeV region.
looking
from other
where
be systematic
systems.
2),
nucleon
in particular
plays in the atomic
the introduction,
excited
forces,
into quark-gluon
which
will be fruitful
from the theoretical
macroscopic
results
field theories
I cannot
&CD,
community,
Apart
distances,
them
physics
subjects,
of people,
related
etc.;
can be formulated
be done.
at very small
on nuclear
and reactions
transition
aim, in short,
is deficient
Completing
hundreds
on very closely
experimentdists”);
ion collision
of quantum
role in nuclear
spectroscopy
phase
but it should
only example
matter
on nonperturbative
(“numerical
energy
(all include
working
of dense nuclear
calculations
Their
physicists,
doing hadronic
3. theorists
4. high
some of them
are now focused
etc.):
theory
2. people
backgrounds
3).
multiplicity
The
main
in-
of matter
at
Most news from the exper-
S. Nagamiya
so I make only short
379c
E. V. Shuryak / QCD vacuum and excited hadronic matter
Ironically attention
enough, hot hadronic
matter
(consisting
mainly
of pions) has attracted
little
in the past, and it was in most cases assumed to be just an ideal pion gas. Only
recently
it was realised, that it is more like some liquid, in which strong (momentum
dent) interaction
plays an important
is the existence surface.
of attractive
interaction
between its constituents,
This, in turn, makes it more difficult
present theoretical
and experimental
under consideration. soft puzzles”,
2. MELTING The
motto
which creates a kind of a
for the constituents
indications
to leave the system.
observed
OF THE
QCD
can explain
“three
in various reactions.
VACUUM
of this conference
does not contribute
We
that this is also true for the “pion liquid”
In section 5 we show, that these ideas presumably
recently
depen-
role. The main difference between any liquid and a gas
is “beauty
much to it. However,
even more in the spirit of Japan): above,
that the ultimate
Where
then have we to start from?
of the nucleus”,
but unfortunately
let me suggest a similar motto
“beauty
of the vacuum”.
aim of all strong interaction Certainly,
Indeed,
my talk
(which
I hope is
we have emphasised
physics is “understanding
of &CD”.
with the ground state, as we do for any other
quantum system. Even the ground state of QCD is a complicated quark fields. collective
Pions,
nucleons and all other low mass hadrons
excitations,
similar,
understanding
theory of their interaction
matter
spectroscopy
and scatterings.
them to temperatures
of the order of 200 MeV vacuum themself
else but their Certainly,
etc., but we cannot understand
solids from the very beginning,
comparable
we would hardly
The simpler way is, say, try to heat the
and see what other phases can be created.
nuclei exciting
gluonic and
of what solids (or nuclei) are made of.
Going further, if we want to understand start with phonon
are nothing
say, to phonons in solids (or nuclear vibrations).
we may make successful effective them without
matter, made of fluctuating
Analogously,
one may try to destroy
to nuclear binding energy.
Moreover,
(or, more precisely, energy densities few GeV/fm3)
which starts to be melted.
This phenomenon
at 2’
it is the QCD
is the central topic of the
present talk. Now I come to discussion of the latest lattice results concerning phase transitions temperature.
Certainly
are their technical comment
I am not able to discuss here how lattice calculations
limitations
that these “numerical
etc., or show many particular experiments”
at high
are made, what
results obtained.
Let me only
are rapidly reaching the level of ordinary
high
E.V. Shutyak j QCD vacuum and excited hadrtmic matter
38Oc energy experiments,
in terms of big and well organ&d
collaborations,
cost of the projects,
etc. Let me concentrate less answered recently.
on the following physical questions, which, I hope, are more or In the QCD vacuum we have two non-perturbative
confinement and cbiral symmetry breaking.
phenomena,
Are they related or not? Or, in more definite
way, are there two independent phase transitions on the phase diagram with different physics, or just one? T
tot4slo>
massive
0
states
Cl.1 % Figure 1: (a) Schematic phase diagram of hadronic matter for Nf > 2 on the plot quark mass m versus temperature. (b) Quark condensate versus temperature according to’.
Impressive amount of numerical studies done during the Iast few years has shown that the former alternative seems to be case. The resulting picture can be described as follows. Let all our Nf quarks have the same mass m, so we may plot simple phase diagram on the temperature-mass
plane, see Fig. l(a).
Roughly speaking, there are three different worlds,
with completely different features of the phase transition.
“Gluonic world” at the right has
only heavy quarks (m above 1 GeV, as if all quarks are charmed). strong first order deconflnement
transition.
It was shown to have
This means that the jump in energy density
Se = ep1asma- Eh&ronieis very large, actually several times more than eh&ronic by itself. Another extreme is the world of light quarks at the left. At zero mass we have chiral symmetry, which is to be discussed below in more details. Here there appears to be another strong first order transition
connected with chiral symmetry restoration3.
It is seen till
E.?! Shwyak f QCD vacuum and exited hadronic mutter mass is approximately
381~
100 MeV for Nf = 3,4..., while for NJC= 2 the transition is not
that strong and may be second order. If two masses are light and that of strange quark is changed, the last first order signal also disappears somewhere at m, = 100 MeV. (Is there deconfinement in this transition or not, one unfortunately cannot even ask in the rne~il~~~ way.) In the middle of Fig. l(a) there is the “intermediate mass world”, which attracted most attention and computer power during the last year, including e.g. “homemade” 16 Gigaflop 256 processor complex* at Columbia University. The resulting conclusion is actually the main news: no strong first order transition is seen here.
Thus, it is demonstrated that
deeonfinement and third restoration transitions do not even cross each other at our phase diagram.
~spectively,
the old idea that they are indeed two different phenomena has
obtained new support. The real world certainly corresponds to the light quark world, for u, d quarks have very small masses, of the order of few MeV only.
Also m, = 150 MeV is somewhere at the
threshold of the light quark region, so in QCD &Jf = 2.5 in some sense.
(Remarkably
enough, it seems to be close to the end of the transition line.) Now, at high energy collisions we are therefore iooking for chiral symmetry restoration. Unfortunately, it turns out to be very difficult to get some deep understanding based on lattice data concerning the underlying mechanism of these phase transitions (we discuss why it is so below) . Therefore, in the next section I switch to another approach, the theory of instantons.
3. RECENT PROGRESS IN WNDERSTA~DING BREAKING
OF CHIRAL SYMMETRY
AND RESTORATION
The classical papers from the early 60’s on the so--called sigma models, have considered pion and sigma fields and have explained how the latter obtains non-zero expectation value and the former becomes massless. Later Weinberg6 derived his famous Lagrangian, describing low energy pion interactions. This approach was used for hadronic matter, and in order to show that it is indeed fruitful let me present e.g. Fig. l(b) from recent paper7, where effect of the pion gas on the quark condensate was calculated using this interaction. in chiral perturbation theory. These results are very general and hold for small T/F= ratio, where F, = 93 MeV is the pion decay constant. However, the real understanding of physics of chiral symmetry restoration can only be reached if we consider the problem at the more fundamental level, starting from quarks Bnd
gluons. But in order to explain ah that, I have to come for a while into some discussion of the formalism involved. For example, s~ont~eous
magnetization
of iron is usu~ly discussed by the fo~iowing
sequence of steps. Due to rotational invariance, all states should be classified to total spin J.
Bowever, large systems may have such close levels with different J, that even infinitely
small magnetic field H can mix them up and create a (rotationally non-invariant)
state with
fixed orientation. Chiral symmetry is a consequence of the fact that in massless theory with vector interaction,
right and ieft-h~ded
quark fields are completely independent, so that di~ere~t
rotations can be made for them in flavor space, The quark mass m plays, in this problem, the same role as small magnetic field in the example above: it breaks the chiral symmetry and relates otherwise independent right and Ieft-handed
quarks. The question is again
whether it can produce the asymmetric vacuum, even for i&nitely
smd1 m.
The formalism used naw is somewhat different, so we have to explain at least the terminology. space-time,
Suppose we take the given ~o~gurat~on
usuahy in the so-called Euclidean (imaginary)
to average over all its possible indurations tion.)
of the gauge field Am,
where z is
time formalism. (Later we have
of the gauge field with the proper weight func-
Trying to understand quark behaviour in this case we may try to diagonal&e the
so-called Dirac operator ~~~(~)
= X$x(r)
where 6 = ~~fi8, +gA~(~)~a)
(Note that in Eu-
clidean time formalism there is no distinction between space and time coordinates.) call the states $x(s)
“the states with fixed virtuality” A. Using them one can easily compute
the quark propagator S = (B + QCD statistics
Let me
sum proportions
im)-r , or the weight of this gauge field configuration in the to detffi + in~)~f which comes from the integration over
all quark fields. Now, the nontrivial m -+ 5 limit (indicating third symmetry breaking) can exist only if there exist quark states with arbitrary small virtuality. In particular, one can see it from the following expression for the quark condensate:
(d$> = CA m/(X2 i- m2) which just fohows
from its definition as trace of the propagators taken at zero distance and averaged over all points. In the Iimit~m -+ 0 we get in the r.h.s. the density of eigenvaIues at zero. (Unfortunately,
it is exactly these small ~ge~v~ues
which are very di~cuit
to get 0x1
the lattice, due to finite size effects and other technical problems. Due to that, most lattice works are done for rather large quark masses, say 50 IvIeV or so. It is physically import~t~ say, the pion mass is in this ease about 500 MeV!)
383~
E. K Shuryak j QCD vacuum and excited hadrmic matter
_._ ..--.+
’ INSTANTON G$v=O &=O A;=0 A$#0 _-_--____ __““-----
(b)
0)
__“______
____-____
(cl
--_rx~~-L~-~~_--ErO ~ -
~ -
Figure 2: Schematic picture of the gluon field energy versus topological coordinate, Instanton is tunneling from one zero energy state to another, which is connected with rearrangements of occupations of light fermion states near the surface of the “Dirac sea”. Thus instanton can be considered as vertex emitting pairs of light quarksg.
Figure 3: Three possible phases of the instanton ensemble in the QCD vacuum: crystal, liquid and gas.
Now, what is the physical nature of these ““quark states -with zero virtuality”?
Do they
really correspond to some real process ? Can we understand their physics in the simpler way, without real evaluation of all eigenvalues for many gauge field configurations, as lattice people try to do? I hope the answer is “yes” and the reason for that is that we know specific types of gauge field configurations, instantons8.
which provide such small eigenvdues:
these are instantons
and anti-
Certainly I cannot now go into discussion of what they are, but only mention
that they describe tunneling from, say, naive classical vacuum A:(z)
= 0 to another one,
in which the field strength Gj&, is also zero, but the potential is non-zero and cannot be obtained from it by continuous gauge transformation.
Schematic picture is shown in Fig. 2.
If there are massbss fermions in the theory, instantons drive the axial anomaly. Physically it means, that tunneling does not change fermion states, but change their occupations, as shown in the lower part of Fig. 2. Thercfore, each instanton can be considered9 as the vertex with 2Nf fermionic lines. Chirality of quarks and anti-quarks cannot close them in loops in the massless theory.
are opposite, so one
Quarks and anti-quarks
the tunneling event shouId be absorbed elsewhere, for example by anti-instanton tunneling event).
produced by (backwaxd
384c
E. V. Shuryak / QCD vacuum and excited hadronic matter
Using this language made of instantons, a kind of a “crystal” symmetries.
one may say, that the QCD
connected
clusters (e.g.,
very small “virtualities”
breaking
of translational
(see Fig. 3b) in which all instantons are effectively
breaking of the chiral symmetry.
instanton-
is some complicated
anti-instanton
pairs, or molecules)
are there and therefore
from phenomenological
“instanton
we passed to developed
of the corresponding
statistical
correspondence
quantitative
sum12113. Results
remains unbroken.
to be in the liquid phase, breaking of the needed magnitude.
Further,
shown to break into separate molecules
theory based on computer
of
studies
are in remarkable
vacuum was indeed shown
and producing
T > T, (above
quark condensate
200 MeV)
(see Ref. 14) and chiral symmetry
Figure 4: Ratio of the correlation
was really
and simple approximations
The QCD
the chiral symmetry at temperatures
instantons
of these calculations
to what we observe in the reai world.
connected,
(see Fig. 3c), no states with
chiral symmetry
liquid model”‘e
the mean field type”
If it is
and color
Finally, if it is a “gas” made of finite
During the last few years the progress in the theory of interacting decisive:
matter
by quark lines. The question is what is its structure.
(see Fig. 3a), we get spontaneous
If it is a “liquid”
we have spontaneous
vacuum
this liquid is
becomes restored.
functions of currents with quantum num-
bers of corresponding mesons to those, corresponding to free quark propagation, versus the distance x between the currents. The points are from the instanton liquid calculation’“.
38%
E. K Shuyak / QCD vacuum and excited hmhnic matter
Moreover, mesonic correlation functions with different quantum numbers were recently calculatedr5.
They show different behaviour depending on quantum numbers (see Fig. 4 ).
The curve going up for pion means that it is light, while that for scalar channel going down means scalars are all heavy. Certainly here I cannot discuss details here, so I can only say that these curves agree with experiment,
sometimes with surprising accuracy . In many
respects, this theory works better than available lattice calculations (for which in principle all configurations
not only superpositions
of instantons)
are included, and it is orders of
magnitude simpler.
4. LOOKING
FOR QUA~I~-GLUON
PLASMA
The idea “to melt the &CD vacuum” is of course very attractive,
but many practical
questions can be asked, say, whether one csn really produce macroscopically in laboratory
large system
conditions, whether it may indeed become well thermalized, etc.
Addressing the former issue, let us say that now in CERN nuclear collision experiments with 0’6 and S3” beams up to several hundreds of pions are produced, and this number will be at least one order of magnitude larger for Pb beam to appear soon. This large “fireball” comes through diRerent stages of its evolution, with energy densities varying from l-3 GeV/fm3 at the beginning to those one order of magnitude smaller, at which final break-up into noninteracting
secondaries takes place. Pion interferometry
the breakup is about 7-10
tells us that the radius at
fm, so it is already larger than radii of the heaviest nuclei.
Let me also emphasize, that data for nuclear collisions are now s~~~plemented by those from Tevatron specialised experimentr6, (CM) energy proton-antiproton
triggering for high multiplicity events in 1.8 TeV
collisions. The corresponding energy density is of the order
of 10 GeV/fm3, but the system is of course not large (although they still has up to about 20 particles per unit rapidity). Transverse hydrodynamical collective phenomena. phase transition
flow was for a long time considered as the most obvious
However, it was emphasized long agoI
that as one approaches the
region, the equation of state becomes very “soft”, which means that by
increasing the energy density we do not increase pressure much.
This statement
is most
obvious for the so-called mixed phase, for which pressure is unchanged at all, but softness is more general prediction independent on the details of the phase tra,nsition. Only when the initial energy density becomes significantly larger than the critical one (above few GeV/fm3) some collective flow of quark-gluon plasma was predicted.
1.0
0
LN A
dy
x PIONS o KAONS q ANTIPROTONS
5
15
10
20
B! dv
Figure 5: Mean transverse momenta of various secondaries versus ~AT/~~ (e&ctive energy density). (a) Hydrodynamics with phase tra.nsition’*; (b) FNAL data16. Detailed calculations in the hydra framework l8 have indeed suggested existence of some plateau in the < pt > versus dlVJdy plot (see Fig+ 5a). Such “plateau” was indeed observed by CERN experiments: the mean it is about the same, whatever number of secondaries is produced. But new Tevatron data are different (see Fig. 5b). As predicted, the rise is most pronounced in heavy secondaries, which is consistent with transverse Aow interpretation Let me now show the shape of mt = (m2 + pt2) r/z distributions for different secondaries, measured at CERN”g, Fig, 6a. Note that all of them have the same slope, which is 200 MeV. Nothing like that is seen neither at lower energies (AGS) nor at larger ones (Tevatron), wbere different secondaries have different slopes (see e.g. Fig. 5e again). I think here we see the m~ifestatio~
first
of the “‘mixed” phase, and the slope is nothing else but the critical temperature
T,, although many more studies are needed to make this statement really convincing+
150
225
300
T (MeV)
Figure 6: {a) Transverse mass spectra for various types of secondaries for SS collisions, NA35 ~OIlaboration. (b) Temperature profile function F(T) versus temperature (for comparison, each spectrum is normalized to one). The open and closed points correspond to WA80 and KELIOS data for reactions indicated, while stars represent pp data from ISR. Note now the concave shape of the pion md distribution at small ps: naively speaking this may lead to slopes as small as 50 MeV. Does it mean that so cold pion gas is indeed created? This point of view is not acceptable because of the following reasons: (if Breakup temperatures lower or about 100 MeV contradict our knowledge of the pion gas kinetics (see below): in this case practically no collisions between pions may take place. {ii) Even if some unknown mechanism can cool the pion system to lower temperatures, we then should observe the size of the emitting system to be essentially larger than 7-8 fm, measured by i~te~eromet~.
Thus, we have the so-called “soft pion puzzle” (to which we return later).
Let me now come to other topics, which are believed to be much better signals for quarkgluon plasma formation. The first idea’ was to use photons and lepton pairs because they are the “penetrating probes” without secondary interactions. Also their production rate in plasma phase is believed to be relatively easy to estimate. Unfort,unately, so far there is no data on direct photons in the kinematical region of interest, and the existing dilepton data from the NA38 collabora.tion at CERN are not yet completely analyzed.
388c
E. K SMyak
/ QCD VUCUU~and excited ha&&c
However, the NA38 experiment
matter
looking for dileptons have produced other surprising
data21, concerning production of vector mesons, especially 4, J/$.
The former is found
to be enhanced by the factor 3 in central nuclear collisions compared to f?p or peripheral collisions, while the latter is by the factor 2 suppressed. In first approximation this different behaviour can be understood from the fact that strange quarks are copiously produced in the plasma, while charmed ones are too heavy for this to be the case, and they a,re produced only in the initial hard collisions of gluons. Now there are strong debates on the exact origin of relative suppression of J/$ compared to dileptons with similar masses.
It may be due to charmed quark deconfinement in the
plasma (as suggested originally in Ref. 22)1 or due to J/$J splitting in hot hadronic matter23, or initial stage interaction
of colliding gluons in nuclei 24. The last idea got support from
recent FNAL experiment, where similar suppression in pA relative to np data wrasobserved. One may, in principle, use more information to understand all that. In particular, Karsch and Petronzio25 have suggested that J/$ can jump out of the “hot spot” if its pt is large enough. And indeed, at pt > 2 GeV this suppression disappears, and they concluded from it that the size of the spot is only1-Z fm, while if we assume strong suppression at the hadronic stage as well, we expect much larger size (remember, by interferometry beams.
size at breakup measured
is about 8 fm). Certainly, much will be clarified by experiments with Pb
In this case we certainly have much larger size of the system, even at the hottest
stage. If the Karsch-Petronzio
idea is right, suppression should be seen up to much higher
pb in this case. If the reason for more J/$ at larger pt is “initial stage res~attering” of the gluons, we will see no change while coming from #I6 to Pb beams.
5. NEWS ABOUT
NOT HADRONIC MATTER
The topic of this section is the closest one to nuclear physics of this talk: we consider a pion gas, with density of the order of that in nuclear matter. and with different (and quite specific) interaction. systems.
Of course, pions are bosons,
Also we do not of course have stable
On the other hand, high energy nuclear collisions produce hundreds (and soon
thousands) of pions, so these pionic systems can be much larger than even the heaviest nuclei. Our discussion below develops into two different directions. review of the theory, and here we introduce qu~iparti~les
The first one is a brief
with pion quantum number, the
“qnasipions”, following t,he experience of low temperature physics, especially that of liquid He*. Another part of this section is an attempt to explain few unexpected phenomena observed recently in various high energy reactions.
Their list includes in reticular:
‘I. enhanced production of pions at small pi found in nuclear collisions”“; 2. enhanced prod~lction of soft photons and low-mass dileptons in various hadronic reactions27; 3. an unexpectedly sharp two-pion annihilation threshold seen in the dilepton spectra at Berkeley28; 4. strong clustering of pions, produced in various hadronic reactions. Let us start with some general remarks about pions. are the lightest hadrons, so that if temperature
They are special because they
T is small enough, only pions are excited.
This fact is not occasional, but related to the specific nature of pions. In the chiral world they are massless, exactly for the same reason as e.g. acoustical phonons in solids: they are Goldstone modes, a remnant of the spontaneously
broken symmetry.
(Translational
symmetry for solids, chiral one for the QCD vacuum.) At small T the mean interparticle ideal gas approach is justified.
distances are large, l/T, so interaction is small and
Also discussion of massless pions makes the problem simpler,
so we start with this case. At small temperatures we get then simple formula for the energy density e(T) = (~z/~~)~4 Interaction
of pions is also quite specific and related to their Goldstone nature.
In the
chira1 world, pions with momenta Ic + 0 cannot interact with anything including themselves. (Exactly
because of this feature acoustical phonons propagate distances much larger than
molecule free paths, therefore we can hear each other.)
This feature makes this gas even
more ideal at small 2’. Accounting for momentums-dependent bation theory, considering T/F,
pion-pion interaction, one can use chiral pertur-
as a small parameter, while at so~s~~hat larger T one has
to include resonances. We summarized results on energy density in Fig. 7a, where e(T)/T4 is plotted versus T. For the ideal gas this ra.tin is close to one, until ~nteractior~ of pions makes some modifications
(see the dotted line). Much more dramatic things happen if one takes
into account nonzero pion mass and, even more important, becomes much more temperature-dependent
hadronic resonances.
The ratio
(see the solid line in Fig. ‘?a). We also show
simple paramete~zat~on
for the ~‘pion+reson~ces”
ago2*: e(T) = T”/T;,To
= 1~~~~~ wh’ICh is shown by the dashed line. One can see that
suggested by the author many years
E. JX Shutyak / QCD vacuum and excited hadronic matter
390~
: 1.5 -
j/+----
-e ‘,
1.0
I._Ix__.. -_/: .i’ / I : :
0.5 -
A
;/’
: ,,*’
~i .‘,’
,J
, 50
1W
150
m
T(MdY)
K/m,
Figure 7’: (a) Ratio of the energy density of excited hadronic matter e(T) to T4, versus temperature 2’. The dotted, dash-dotted and solid line are from3’ for interacting massless pions, massive pions and pions together with resonances, respectively. The dashed curve corresponds to par~etrisation~‘. (b) Qualitative picture of the modification of the pion dispersion curve in hot “pion liquid”. The “quasipion” with internal momentum corresponding to point A moves to point B as it goes out of the system. it approximately describes the energy density dependence on temperature over the whole interval. Summarising, above T around 100 MeV or so, corrections to the ideal pion gas energy become large. Now we come to kinetics in the pion matter. Again Goldstone nature of the pion plays an important role: apart from small effects related with scattering lengths, the r?r cross section is essentially proportional to pion momenta. Therefore mean time between collisions depend on T as follows2Q: rCOll= constF:/T”.
Goity and Leutwyler have recently made extensive
calculations3o supporting this expression and getting more accurate const=12. Note, that at ‘I’ = 200 MeV rC-,ais smali, .7 fm/c, b ut at our other extreme T = 100 MeV it is already about 25 fm/c, comparable to the lifetime of even the largest fireballs considered. Another useful way to look at rc-,nis to compare its inverse, the imaginary part of the pion energy Im E, = l/rc,ll, with its real part. The corresponding ratio can be estimated as follows Im E,f Re E, = .03(TfF,)4
It is still only about .1 at T = 140 MeV, but it is of
391c
E. K Shuyak / QCD vacuum and excited hudronic matter
the order I at Tc = 200 MeV.
Therefore,
in the former case the pions are still propagating
rather well, while in the latter case they are strongly
absorbed.
Now we come to the central point of this section: matter,
but they interact
The main pion-pion potential modes.
interaction
is proportional
should grow with momentum Let us mention
strongly
with many particles
modified
directly
to pion momenta
examples
curve of elementary
by neutron scattering by Landau
respectively,
minimum
excitations
experiments.
curve is
is developed. in liquid He*, measured
Note the secondary minimum
and called the “roton”
minimum.
for phonon non-linear
interactions,
this curve, with accounting
our collective
of cases in which the dispersion
at larger L, so that even secondary
was suggested
in hot
and change their properties.
as well. Such a situation is common for all Goldstone
two well-known
1, The famous dispersion
pions are not only scattered
simultaneously
Modern
which
theory
of
can be found e.g.
in Ref. 31. 2. In Fig. 3 we show the pion dispersion ated theoretically (With
increasing
energy
Migdal
evalu-
(see e.g. Ref. 32 and references therein).
nuclear density,
modification
may reach zero at some critical
rearrangement
curve in cold dense nuclear matter,
and spontaneous
pion condensation.
of pions may become
momentum
production
&.
so strong
that their
If so, it should lead to vacuum
of the pion field. This phenomenon
We are not going to discuss here whether
is known as
these calculations
are
reliable or not at such high densities.) The
expected
qualitative
behaviour
“pseudopotential”
is slightly
repulsive
of the dispersion
curve is shown in Fig.
at small momenta
but becomes
attractive
7b:
the
at larger
ones. We do not want to have many free parameters,
so we do not speculate
secondary
for the modified pion dispersion curve
w(k)
minima and assume simple parametrisation
= (m;
+ u(T)%~)‘/~
m t ro d ucing the temperature-dependent
It is close to one till about T = 150A4eV, Now we return to “soft pion puzzle”, nuclear collisions Goldstone
theorem,
Therefore,
pion interactions
spectra
compared
slope parameter
u(T).
and then rapidly decreases. or enhancement
to pp, or peripheral
in any type of kinetic
the experimental opposite
compared
about possible
of soft pion production
collisions.
It is puzzling
in central
because,
due to
should be small for soft pions for all types of processes.
calculations
one might
to the thermal
expect
at low momenta
ones, while experiments
a dip in
show quite the
trend!
However, quantitative
pion modification explanation
phenomenon
discussed above can provide
of the soft pion component
at least a semi-
at small pt (see Fig. 8a).
Climbing
392c
2.6 i
2.4 2.2 2.0 1.8 1.6 R 1.4
t
1.2
t
1.0 0.8 0.6 0.4 0.2 0
1.6 0.8 Pt (GeVlc)
2.4
"0
200
400
600
Pt (MeV)
Figure 8: (a) The ratio of the pt spectra of X-Oin central and peripheral OW collisions (WA80) (points), while the shaded area is the ratio of x- HELIOS spectra for SS collisions to pp ones. (b) The ratio of the spectra calculated in the quasipion model with and without modification of the dispersion curve. out of the attractive potential well, the outgoing pion reduce its momenta (see Fig. 7b). If the dispersion curve is flat at low momenta, rather large phase space in terms of internal momenta corresponds to soft outgoing pions. It leads to very effective production of nearly stopping pions33(see Fig. 8b), which seems to explain the data. Another consequence of the pion modification is that some of them are reflected from the boundary which presumably makes the system lifetime longer. The second striking phenomenon observed in high energy collisions during the last years is observation27 of an excess of the produced soft photons over the theoretical expectations (see Fig, 9). The reason this is disturbing is that emission of the soft photons is described by the classicai electrodynamics,
which demands the simple bremsstrahlung
to be the main
effect, provided photon energies w are small compared to inverse lifetime of the radiating system. Attempts to describe these data in conventional models of the collisions has failed, (see e.g. Ref. 34) in which the Lund version of the string model was used. The results obtained
E. K Shutyak / QCD vacuum and excited hadronic matter
I N,
393c
= 400
I N, = 400 I N,=
10
I
1000
100
10
Pt( MeV1 Figure 9:
The ratio of the observed
photon
yield
to bremsstrahhmg
pre-
dictions, versus p\t. The dashed area shows predictions of the Lund mode134, while solid and dashed curves are for the quasipion model with and without pion modificat ion33.
with such space-time momenta,
picture more or less reproduce
production
was evaluated
in the “quasipion”
shown in Fig. 9 show indeed much stronger in the Lund model.
cancellation
final scattering Comparing
observe
that at intermediate
of scattering
describe
observed
experimental
contribution,
than, say,
several times
photon momenta
there
and at low w all but the
between
the coherent
seems that we can naturally
data shown in Fig.
excess for low pt < 30 MeV
effects of the pion modification
region
Recently,
from the b~msstrahlun~
becomes irrelevant.
cannot
transition
Interesting,
in the amplitude
these results with
strong
deviations
model in Ref. 33. The results
The main reason for that is that pions are rescattered
before they come out of the system.
definitely
in wide range of
up to those of the order of few hundreds MeV (see the shaded region in Fig. 9).
Soft photon
partial
low energy theorem
on the photon
and incoherent
regimes
9, one notes that we
or so.
However,
we do
radiation,
especially
in the
of radiation.
Moreover,
it
explain the data shown by solid points in Fig. 9).
first dilepton experiments
at Berkeley2* have studied the lepton pair production
at energies as low as 4.9 GeV for proton-nucleus
and about 1 GeV/N
in Ca Ca collisions.
The data are well described by known sources except for the peak above two pion mass. One may think about n+rr-
annihilation,
and in fact s-dependence
of this peak is consistent with
E. K Shutyak / QCD vacuum and excited hudrmic matter
394c
that for pion pair production.
However, attempts
to ascribe it to pion annihilation meet
certain problems. First of $11, production of two soft pions is suppressed by smallness of the phase space.
Second, the annihilation of soft pions into a virtual photon is suppressed at
threshold because it takes place in the P wave. Let us emphasize that conditions of this experiment
are quite different from nuclear
collisions at CERN. There are no hundreds of pions in a fireball, but just one pair of them. However, kinematics are now such that pions are produced snd ~nj~lated
in nuclear matter,
Gale and Kapusta 32 have used this fact, suggesting that pion dispersion curve is modified so strongly in the compressed nuclear matter, that secondary ~nimum
in w(k) is developed. If
so, annihilation of two “quasipions” leads to a peak in the dilepton spectrum, corresponding to the diiepton mass equal to twice the minimum value of w(k). with the double-pion
It may well be mixed
threshold, and now there is no suppression mentioned above because
momentum is now far from zero value. It may we11be that the peak seen in these experiments is indeed of this nature.
6. SUMMARY 1. Latest results of numerical experiments with lattice gauge theory have shown that deconfinement
transition
is strong first order, but it exists only in the
“Lgluonic worid” , or for quark masses roughly above 1 GeV. For small masses (and for real &CD) chiral symmetry restoration is the main phenomenon, strong f&t-order
Again
transition seems to take place between hadronic gas and quark-
gluon plasma. However, in the inte~ediate
mass region (roughly 0.1-1 GeV) no
first order phase transition is seen, which means that deconfinement and chiral restoration are in fact two different phenomena. 2. Much progress was made in understanding of chiral symmetry breaking in the QCD vacuum and its restoration interacting instantons. gas transition,
at high temperatures
based on the theory of
The phase transition is understood as liquid - molecular
with some details in striking correlation to what people see OR
the lattice. In particular, it explains why at such small quark masses as 50-100 MeV one finds strong changes of the chiral symmetry physics. Also the theory of inst~tons
proved to be very effective in predicting properties of mesonic
correlation functions.
E. V; Shwyak / QCD vacutun ad
excited hadronk matter
395c
3. Various high energy collisions are now used fur search of the superdense hadronic matter. There is evidence that for energy density of the order of 1-3
GeV/fm3
the equation of state is soft, which is expected near the phase transition.
At
larger energy density some collective flow may be observed at Tevatron. Maybe we have some first evidence for appearance of the “mixed phase’* from CERN experiments.
Suppression of J/d
and enhancement of Q; found by NA38 ex-
periment in GERN are discussed at various angles. Let me finish this section, reminding you once more of the long-standing statement: looking for dileptons with pt (or invariant masses M) about 14
GeV we probabiy have a chance
to see dileptons produced in the plasma phase, above hadronic production and Drell-Yan contribution. 4. Hadronic matter at ‘I’ = 100 - 200 MeV is not an ideal pion gas, but rather a liquid in which strong attractive interaction between pions is important.
In
particular, it modifies the pion dispersion curve. Also, it makes it difficult for the pion to leave the system, and presumably explains the excess of soft pions observed in CERN nuclear collisions. Other “soft puzzles” also can be related to these phenomena. REFERENCES 1.
Proceedings of Quark mattez-88, Nordkirhen, 2. Phys. C. 38 (1988); Proceedings of Quark ~a~~er-~9, Lenox, Nucl. Phys. A498 (1989); Proceedings of Quark matter-96, , Nucl. Phys. (in press)..
2.
E.V. Shuryak, Phys. Lett. 78B (1978) 150, Yad. Fis. 28 (1978) 796. The &CD Vacuum, Hadrons and the Superdeme Matter, World Scientific 1988; D.J. Gross, R.D. Pisarsky and L.G. Yaffe, Rev. Mod. Phys. 53 (1981) 43; B. Muller, Lecture Notes in Physics 225, {Sprjnger-Verla~ 1985); J. Cleymans, R.V. Gavai and E, Suchonen. Phys. Rep. Cl30 (1986) 217.
3.
J.B. Kogut et at, Phys. Rev. D39 (1989) 636 S. Gottlieb et oL, Phys. Rev. D40 (1989) 2389 M.P. Grady et al., Nucl. Phys. IX00 (1988) 149.
4.
N.H. Crist, Columbia preprint CU-TP-447 S. Qhta, Columbia preprint CU-tp-446.
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M. Gell-Mann and M. Levy, Nuovo Cimento 16 (1960) 705..
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J. Gasser and H. Leutwyler, Phys. Rep. 87 (1982) 79..
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A.A. Belavin, A.M. Polyakov, A.A. Schwartz and Yu. S. Tyupkin. (1975) 35.
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G. ‘t Hooft, Phys. Rev. D14 (1976) 3432.
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Phys. Lett. B59
E.V. Shuryak, Nucl. Phys. I3203 (1982) 93, 116,I4~.H243 (1983) 231.
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D.I. Dyakonov and V. Yu. Petrov, Nucl. Phys. B245 (1984) 259, I3272 (1986) 457.
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E.V. Shuryak, Nucl, Phys. B302 (1988) 559,574,599,621.
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E. K Slwyak
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E.V. Shuryak and J.J.M. Verbaarschot, CERN-TH-5492/89,
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E.M. Ilgenfritz and E.V. Shuryak, Nucl. Phys. B319 (1989) 511.
Nucl. Phys. in press,
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E.V. Shuryak, Nucl. Phys. B319 (1989) 521,541; B328 (1989) 85,102.
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T. Alexopoulos et al., Phys. Rev. Lett. 64 (1990) 991; F. Turkot, Talk at Quark Matter-Q& Menton, 1990.
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E.V. Shuryak and O.V. Zhirov, Phys. Lett. 89B (1980) 253.
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M. Kataja, P.V. Ruuskanen, L.D. McLerran and H. van Gersdorff, Phys. Rev. D34 (1986) 2755.
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G. Odyniec (NA35), Talk at Workshop on Relativistic aspects of Nuclear Physics, Rio de Janeiro, 1989 (WSPC, Singapore, in press).
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C. Baglin et al., (NA38 ~011.) Phys. Lett. 220B (1989) 471; 3. Varela, Talk at Quark hatter-Q~, Menton.
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26.
R. Albrecht et a&, (WA80 ~011.) Phys. Lett. Bf19 (1987) 297.; A. Bamberger et al., (NA35 ~011.) Phys. Lett. B184 (1987) 271.; A. Sandoval et ak., (HELIOS ~011)Nud. Phys. A 4655 (1987).
27.
P.V. Chliapnikov et al., Phys. Lett. 141B (1984) 276; U. Gurlach, (HELIOS ~011.) Proc. of 24-th Int. Conf. High. Energy Phys., Munich 1988; W.J. Willis, Nucl. Phys. A478 (1988) 151C; J. Schukraft, (HELIOS ~011.) Talk at 7th Int. Conf. Quark ,vatter-88, Lenox, Massachusetts 1988.
28.
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29.
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33.
E.V. Shuryak, Pion modi~~ation in hot hadronic matter and %sltrasoft” phenomena in high energy collisions. CERN-TH-5386189 and “L. Van Hove Festschrift”, World Scientific, (1990). Physics of the pion liquid. BNL-44522, 1990..
34.
B. Andersson et al., Preprint LUTP 88-1, Lund 1988.
Nuclear Physics A522 (1991) 377c-396~ North-Holland, Amsterdam
STRUCTURE
E.V.
OF THE
QCD
VACUUM
AND EXCITED
MATTER
Shuryak
Physics
Department,
Brookhaven
National
Laboratory,
This talk describes the latest development as in theoretical and experimental efforts quark-gluon
1.
HADRONIC
plasma
phase
by means
Upton,
New York
11973
in the theory of the QCD vacuum, as well to study its “melting” into the so-called
of high energy
collisions
of hadrons
and nuclei.
INTRODUCTION This
excited
talk includes hadronic
concerning
matter.
the topic
what we meant the coming moment
two large subjects: Before
one.
Strong
If one is interested journal
with
Planck
scale,
is assumed
this
decades
in the definition
of nuclear
i t includes
Although
physics,
papers
1 GeV. This definition
misleading:
interactions,
In the latter,
the period
toward
QCD
with
is that
changed
during
community
is at the
was observed, at these
the
keV
to
physics
lo-20
years
but now this dividing which
are becoming
splitting
between
line now
of people. one observes
typical
TeV
scale,
in hard
physics,
that
clear
and physics
and now the interests
physics.
from
and high energy
energies
works
nuclear
energies
consult
was indeed meaningful
QCD”
well,
with
nuclear
of “testing
the non-perturbative
here we find overlap
groups
community
with their
really
remarks
main point
he would probably
between
activity
it is exactly
different
in high energy
of electroweak
Perturbative
boundary
at this scale not so great
precisely,
Their
physics
dealing
about
for many
of highly
in this field.
to be somewhere
point
in 1990’s.
with a part of high energy
that
the focusing
and physics
is to be significantly
there,
completely
vacuum
let me make some general
Physics
it is explained
ago, when indeed
More
trends
Nuclear
in previous
convergence
name.
is becoming
shifted
physics
one of the main
of the QCD
we begin their discussion,
of this conference,
by nuclear
theory
processes
cases
seems
to come
of people
is, to 0.1-l
In some
of strong
GeV
are more
energy
it is so strong,
scale. that
physics
interaction. to the end. and more Certainly it becomes
This manuscript has been authored under contract number DE-AC02-76CH00016 with the U.S. Department of Energy. Accordingly, the U.S. Government retains a non-exclusive, royalty-free license to publish or reproduce the published form of this contribution, or allow others
to do so, for U.S.
Government
purposes.
03759474/91/$03.50 @ 1991 - Elsevier Science Publishers B.V. (North-Holland)
378~
E. K Shwyak / QCD vacuum and ercited hadmnic matter
completely
impossible
distributed
between
a completely
to say where Nuclear
illogical
works
Physics
should
be published.
As a result,
A and B ( as well as between
way, representing
author
background
Phys.
papers
Rev.
and position
are
C and D) in
rather
than
paper
cant ent . Scientific
communities
of different
problems.
Let me enumerate
specialised
conferences
1. traditional nuclei,
nuclear
working
excited
easy task,
heavy
systems,
common
interaction
between
so vast Starting
as QED
understand
physics
(section
breaking
the last
vacuum, few years
systems
both
spiration
of this
activity
high energy imental additional
density,
remarks
Then
come
plasma
reasons,
is logically
interaction
own
much
in the 1990’s,
making
lattice
I describe phase
to recent
the so-called
attention
quark-gluon
in the previous
of &CD”.
It is not an
speaking,
complete
(even
strong).
QCD
is the
celebrated
QED
I hope that
strong
and finally
QCD
the content
of this talk.
to concentrate
current
status
transition. progress
will play the same
ideas leading
I briefly
discuss
plasma
talk by Prof.
attempts
to
the latest
of new phase
lattice
symmetry
(section
of high
at high energies’.
(QGP)2.
of
chiral
at high temperature
manifestation
to studies
of the theoretical
in understanding
collisions
Considering
on a few new points.
was paid to production
to possible
large
one.
and have
and nuclear
was related
on them.
in
etc.
strictly
becomes
as well as its restoration
in hadronic
side are discussed
modification
for macroscopically
side, I first have tried to summarize
and then
hadronic
those
as “understanding
I would like to outline
of the corresponding
in the QCD
During
with their
in 1 GeV region.
looking
from other
where
be systematic
systems.
2),
nucleon
in particular
plays in the atomic
the introduction,
excited
forces,
into quark-gluon
which
will be fruitful
from the theoretical
macroscopic
results
field theories
I cannot
&CD,
community,
Apart
distances,
them
physics
subjects,
of people,
related
etc.;
can be formulated
be done.
at very small
on nuclear
and reactions
transition
aim, in short,
is deficient
Completing
hundreds
on very closely
experimentdists”);
ion collision
of quantum
role in nuclear
spectroscopy
phase
but it should
only example
matter
on nonperturbative
(“numerical
energy
(all include
working
of dense nuclear
calculations
Their
physicists,
doing hadronic
3. theorists
4. high
some of them
are now focused
etc.):
theory
2. people
backgrounds
3).
multiplicity
The
main
in-
of matter
at
Most news from the exper-
S. Nagamiya
so I make only short
379c
E. V. Shuryak / QCD vacuum and excited hadronic matter
Ironically attention
enough, hot hadronic
matter
(consisting
mainly
of pions) has attracted
little
in the past, and it was in most cases assumed to be just an ideal pion gas. Only
recently
it was realised, that it is more like some liquid, in which strong (momentum
dent) interaction
plays an important
is the existence surface.
of attractive
interaction
between its constituents,
This, in turn, makes it more difficult
present theoretical
and experimental
under consideration. soft puzzles”,
2. MELTING The
motto
which creates a kind of a
for the constituents
indications
to leave the system.
observed
OF THE
QCD
can explain
“three
in various reactions.
VACUUM
of this conference
does not contribute
We
that this is also true for the “pion liquid”
In section 5 we show, that these ideas presumably
recently
depen-
role. The main difference between any liquid and a gas
is “beauty
much to it. However,
even more in the spirit of Japan): above,
that the ultimate
Where
then have we to start from?
of the nucleus”,
but unfortunately
let me suggest a similar motto
“beauty
of the vacuum”.
aim of all strong interaction Certainly,
Indeed,
my talk
(which
I hope is
we have emphasised
physics is “understanding
of &CD”.
with the ground state, as we do for any other
quantum system. Even the ground state of QCD is a complicated quark fields. collective
Pions,
nucleons and all other low mass hadrons
excitations,
similar,
understanding
theory of their interaction
matter
spectroscopy
and scatterings.
them to temperatures
of the order of 200 MeV vacuum themself
else but their Certainly,
etc., but we cannot understand
solids from the very beginning,
comparable
we would hardly
The simpler way is, say, try to heat the
and see what other phases can be created.
nuclei exciting
gluonic and
of what solids (or nuclei) are made of.
Going further, if we want to understand start with phonon
are nothing
say, to phonons in solids (or nuclear vibrations).
we may make successful effective them without
matter, made of fluctuating
Analogously,
one may try to destroy
to nuclear binding energy.
Moreover,
(or, more precisely, energy densities few GeV/fm3)
which starts to be melted.
This phenomenon
at 2’
it is the QCD
is the central topic of the
present talk. Now I come to discussion of the latest lattice results concerning phase transitions temperature.
Certainly
are their technical comment
I am not able to discuss here how lattice calculations
limitations
that these “numerical
etc., or show many particular experiments”
at high
are made, what
results obtained.
Let me only
are rapidly reaching the level of ordinary
high
E.V. Shutyak j QCD vacuum and excited hadrtmic matter
38Oc energy experiments,
in terms of big and well organ&d
collaborations,
cost of the projects,
etc. Let me concentrate less answered recently.
on the following physical questions, which, I hope, are more or In the QCD vacuum we have two non-perturbative
confinement and cbiral symmetry breaking.
phenomena,
Are they related or not? Or, in more definite
way, are there two independent phase transitions on the phase diagram with different physics, or just one? T
tot4slo>
massive
0
states
Cl.1 % Figure 1: (a) Schematic phase diagram of hadronic matter for Nf > 2 on the plot quark mass m versus temperature. (b) Quark condensate versus temperature according to’.
Impressive amount of numerical studies done during the Iast few years has shown that the former alternative seems to be case. The resulting picture can be described as follows. Let all our Nf quarks have the same mass m, so we may plot simple phase diagram on the temperature-mass
plane, see Fig. l(a).
Roughly speaking, there are three different worlds,
with completely different features of the phase transition.
“Gluonic world” at the right has
only heavy quarks (m above 1 GeV, as if all quarks are charmed). strong first order deconflnement
transition.
It was shown to have
This means that the jump in energy density
Se = ep1asma- Eh&ronieis very large, actually several times more than eh&ronic by itself. Another extreme is the world of light quarks at the left. At zero mass we have chiral symmetry, which is to be discussed below in more details. Here there appears to be another strong first order transition
connected with chiral symmetry restoration3.
It is seen till
E.?! Shwyak f QCD vacuum and exited hadronic mutter mass is approximately
381~
100 MeV for Nf = 3,4..., while for NJC= 2 the transition is not
that strong and may be second order. If two masses are light and that of strange quark is changed, the last first order signal also disappears somewhere at m, = 100 MeV. (Is there deconfinement in this transition or not, one unfortunately cannot even ask in the rne~il~~~ way.) In the middle of Fig. l(a) there is the “intermediate mass world”, which attracted most attention and computer power during the last year, including e.g. “homemade” 16 Gigaflop 256 processor complex* at Columbia University. The resulting conclusion is actually the main news: no strong first order transition is seen here.
Thus, it is demonstrated that
deeonfinement and third restoration transitions do not even cross each other at our phase diagram.
~spectively,
the old idea that they are indeed two different phenomena has
obtained new support. The real world certainly corresponds to the light quark world, for u, d quarks have very small masses, of the order of few MeV only.
Also m, = 150 MeV is somewhere at the
threshold of the light quark region, so in QCD &Jf = 2.5 in some sense.
(Remarkably
enough, it seems to be close to the end of the transition line.) Now, at high energy collisions we are therefore iooking for chiral symmetry restoration. Unfortunately, it turns out to be very difficult to get some deep understanding based on lattice data concerning the underlying mechanism of these phase transitions (we discuss why it is so below) . Therefore, in the next section I switch to another approach, the theory of instantons.
3. RECENT PROGRESS IN WNDERSTA~DING BREAKING
OF CHIRAL SYMMETRY
AND RESTORATION
The classical papers from the early 60’s on the so--called sigma models, have considered pion and sigma fields and have explained how the latter obtains non-zero expectation value and the former becomes massless. Later Weinberg6 derived his famous Lagrangian, describing low energy pion interactions. This approach was used for hadronic matter, and in order to show that it is indeed fruitful let me present e.g. Fig. l(b) from recent paper7, where effect of the pion gas on the quark condensate was calculated using this interaction. in chiral perturbation theory. These results are very general and hold for small T/F= ratio, where F, = 93 MeV is the pion decay constant. However, the real understanding of physics of chiral symmetry restoration can only be reached if we consider the problem at the more fundamental level, starting from quarks Bnd
gluons. But in order to explain ah that, I have to come for a while into some discussion of the formalism involved. For example, s~ont~eous
magnetization
of iron is usu~ly discussed by the fo~iowing
sequence of steps. Due to rotational invariance, all states should be classified to total spin J.
Bowever, large systems may have such close levels with different J, that even infinitely
small magnetic field H can mix them up and create a (rotationally non-invariant)
state with
fixed orientation. Chiral symmetry is a consequence of the fact that in massless theory with vector interaction,
right and ieft-h~ded
quark fields are completely independent, so that di~ere~t
rotations can be made for them in flavor space, The quark mass m plays, in this problem, the same role as small magnetic field in the example above: it breaks the chiral symmetry and relates otherwise independent right and Ieft-handed
quarks. The question is again
whether it can produce the asymmetric vacuum, even for i&nitely
smd1 m.
The formalism used naw is somewhat different, so we have to explain at least the terminology. space-time,
Suppose we take the given ~o~gurat~on
usuahy in the so-called Euclidean (imaginary)
to average over all its possible indurations tion.)
of the gauge field Am,
where z is
time formalism. (Later we have
of the gauge field with the proper weight func-
Trying to understand quark behaviour in this case we may try to diagonal&e the
so-called Dirac operator ~~~(~)
= X$x(r)
where 6 = ~~fi8, +gA~(~)~a)
(Note that in Eu-
clidean time formalism there is no distinction between space and time coordinates.) call the states $x(s)
“the states with fixed virtuality” A. Using them one can easily compute
the quark propagator S = (B + QCD statistics
Let me
sum proportions
im)-r , or the weight of this gauge field configuration in the to detffi + in~)~f which comes from the integration over
all quark fields. Now, the nontrivial m -+ 5 limit (indicating third symmetry breaking) can exist only if there exist quark states with arbitrary small virtuality. In particular, one can see it from the following expression for the quark condensate:
(d$> = CA m/(X2 i- m2) which just fohows
from its definition as trace of the propagators taken at zero distance and averaged over all points. In the Iimit~m -+ 0 we get in the r.h.s. the density of eigenvaIues at zero. (Unfortunately,
it is exactly these small ~ge~v~ues
which are very di~cuit
to get 0x1
the lattice, due to finite size effects and other technical problems. Due to that, most lattice works are done for rather large quark masses, say 50 IvIeV or so. It is physically import~t~ say, the pion mass is in this ease about 500 MeV!)
383~
E. K Shuryak j QCD vacuum and excited hadrmic matter
_._ ..--.+
’ INSTANTON G$v=O &=O A;=0 A$#0 _-_--____ __““-----
(b)
0)
__“______
____-____
(cl
--_rx~~-L~-~~_--ErO ~ -
~ -
Figure 2: Schematic picture of the gluon field energy versus topological coordinate, Instanton is tunneling from one zero energy state to another, which is connected with rearrangements of occupations of light fermion states near the surface of the “Dirac sea”. Thus instanton can be considered as vertex emitting pairs of light quarksg.
Figure 3: Three possible phases of the instanton ensemble in the QCD vacuum: crystal, liquid and gas.
Now, what is the physical nature of these ““quark states -with zero virtuality”?
Do they
really correspond to some real process ? Can we understand their physics in the simpler way, without real evaluation of all eigenvalues for many gauge field configurations, as lattice people try to do? I hope the answer is “yes” and the reason for that is that we know specific types of gauge field configurations, instantons8.
which provide such small eigenvdues:
these are instantons
and anti-
Certainly I cannot now go into discussion of what they are, but only mention
that they describe tunneling from, say, naive classical vacuum A:(z)
= 0 to another one,
in which the field strength Gj&, is also zero, but the potential is non-zero and cannot be obtained from it by continuous gauge transformation.
Schematic picture is shown in Fig. 2.
If there are massbss fermions in the theory, instantons drive the axial anomaly. Physically it means, that tunneling does not change fermion states, but change their occupations, as shown in the lower part of Fig. 2. Thercfore, each instanton can be considered9 as the vertex with 2Nf fermionic lines. Chirality of quarks and anti-quarks cannot close them in loops in the massless theory.
are opposite, so one
Quarks and anti-quarks
the tunneling event shouId be absorbed elsewhere, for example by anti-instanton tunneling event).
produced by (backwaxd
384c
E. V. Shuryak / QCD vacuum and excited hadronic matter
Using this language made of instantons, a kind of a “crystal” symmetries.
one may say, that the QCD
connected
clusters (e.g.,
very small “virtualities”
breaking
of translational
(see Fig. 3b) in which all instantons are effectively
breaking of the chiral symmetry.
instanton-
is some complicated
anti-instanton
pairs, or molecules)
are there and therefore
from phenomenological
“instanton
we passed to developed
of the corresponding
statistical
correspondence
quantitative
sum12113. Results
remains unbroken.
to be in the liquid phase, breaking of the needed magnitude.
Further,
shown to break into separate molecules
theory based on computer
of
studies
are in remarkable
vacuum was indeed shown
and producing
T > T, (above
quark condensate
200 MeV)
(see Ref. 14) and chiral symmetry
Figure 4: Ratio of the correlation
was really
and simple approximations
The QCD
the chiral symmetry at temperatures
instantons
of these calculations
to what we observe in the reai world.
connected,
(see Fig. 3c), no states with
chiral symmetry
liquid model”‘e
the mean field type”
If it is
and color
Finally, if it is a “gas” made of finite
During the last few years the progress in the theory of interacting decisive:
matter
by quark lines. The question is what is its structure.
(see Fig. 3a), we get spontaneous
If it is a “liquid”
we have spontaneous
vacuum
this liquid is
becomes restored.
functions of currents with quantum num-
bers of corresponding mesons to those, corresponding to free quark propagation, versus the distance x between the currents. The points are from the instanton liquid calculation’“.
38%
E. K Shuyak / QCD vacuum and excited hmhnic matter
Moreover, mesonic correlation functions with different quantum numbers were recently calculatedr5.
They show different behaviour depending on quantum numbers (see Fig. 4 ).
The curve going up for pion means that it is light, while that for scalar channel going down means scalars are all heavy. Certainly here I cannot discuss details here, so I can only say that these curves agree with experiment,
sometimes with surprising accuracy . In many
respects, this theory works better than available lattice calculations (for which in principle all configurations
not only superpositions
of instantons)
are included, and it is orders of
magnitude simpler.
4. LOOKING
FOR QUA~I~-GLUON
PLASMA
The idea “to melt the &CD vacuum” is of course very attractive,
but many practical
questions can be asked, say, whether one csn really produce macroscopically in laboratory
large system
conditions, whether it may indeed become well thermalized, etc.
Addressing the former issue, let us say that now in CERN nuclear collision experiments with 0’6 and S3” beams up to several hundreds of pions are produced, and this number will be at least one order of magnitude larger for Pb beam to appear soon. This large “fireball” comes through diRerent stages of its evolution, with energy densities varying from l-3 GeV/fm3 at the beginning to those one order of magnitude smaller, at which final break-up into noninteracting
secondaries takes place. Pion interferometry
the breakup is about 7-10
tells us that the radius at
fm, so it is already larger than radii of the heaviest nuclei.
Let me also emphasize, that data for nuclear collisions are now s~~~plemented by those from Tevatron specialised experimentr6, (CM) energy proton-antiproton
triggering for high multiplicity events in 1.8 TeV
collisions. The corresponding energy density is of the order
of 10 GeV/fm3, but the system is of course not large (although they still has up to about 20 particles per unit rapidity). Transverse hydrodynamical collective phenomena. phase transition
flow was for a long time considered as the most obvious
However, it was emphasized long agoI
that as one approaches the
region, the equation of state becomes very “soft”, which means that by
increasing the energy density we do not increase pressure much.
This statement
is most
obvious for the so-called mixed phase, for which pressure is unchanged at all, but softness is more general prediction independent on the details of the phase tra,nsition. Only when the initial energy density becomes significantly larger than the critical one (above few GeV/fm3) some collective flow of quark-gluon plasma was predicted.
1.0
0
LN A
dy
x PIONS o KAONS q ANTIPROTONS
5
15
10
20
B! dv
Figure 5: Mean transverse momenta of various secondaries versus ~AT/~~ (e&ctive energy density). (a) Hydrodynamics with phase tra.nsition’*; (b) FNAL data16. Detailed calculations in the hydra framework l8 have indeed suggested existence of some plateau in the < pt > versus dlVJdy plot (see Fig+ 5a). Such “plateau” was indeed observed by CERN experiments: the mean it is about the same, whatever number of secondaries is produced. But new Tevatron data are different (see Fig. 5b). As predicted, the rise is most pronounced in heavy secondaries, which is consistent with transverse Aow interpretation Let me now show the shape of mt = (m2 + pt2) r/z distributions for different secondaries, measured at CERN”g, Fig, 6a. Note that all of them have the same slope, which is 200 MeV. Nothing like that is seen neither at lower energies (AGS) nor at larger ones (Tevatron), wbere different secondaries have different slopes (see e.g. Fig. 5e again). I think here we see the m~ifestatio~
first
of the “‘mixed” phase, and the slope is nothing else but the critical temperature
T,, although many more studies are needed to make this statement really convincing+
150
225
300
T (MeV)
Figure 6: {a) Transverse mass spectra for various types of secondaries for SS collisions, NA35 ~OIlaboration. (b) Temperature profile function F(T) versus temperature (for comparison, each spectrum is normalized to one). The open and closed points correspond to WA80 and KELIOS data for reactions indicated, while stars represent pp data from ISR. Note now the concave shape of the pion md distribution at small ps: naively speaking this may lead to slopes as small as 50 MeV. Does it mean that so cold pion gas is indeed created? This point of view is not acceptable because of the following reasons: (if Breakup temperatures lower or about 100 MeV contradict our knowledge of the pion gas kinetics (see below): in this case practically no collisions between pions may take place. {ii) Even if some unknown mechanism can cool the pion system to lower temperatures, we then should observe the size of the emitting system to be essentially larger than 7-8 fm, measured by i~te~eromet~.
Thus, we have the so-called “soft pion puzzle” (to which we return later).
Let me now come to other topics, which are believed to be much better signals for quarkgluon plasma formation. The first idea’ was to use photons and lepton pairs because they are the “penetrating probes” without secondary interactions. Also their production rate in plasma phase is believed to be relatively easy to estimate. Unfort,unately, so far there is no data on direct photons in the kinematical region of interest, and the existing dilepton data from the NA38 collabora.tion at CERN are not yet completely analyzed.
388c
E. K SMyak
/ QCD VUCUU~and excited ha&&c
However, the NA38 experiment
matter
looking for dileptons have produced other surprising
data21, concerning production of vector mesons, especially 4, J/$.
The former is found
to be enhanced by the factor 3 in central nuclear collisions compared to f?p or peripheral collisions, while the latter is by the factor 2 suppressed. In first approximation this different behaviour can be understood from the fact that strange quarks are copiously produced in the plasma, while charmed ones are too heavy for this to be the case, and they a,re produced only in the initial hard collisions of gluons. Now there are strong debates on the exact origin of relative suppression of J/$ compared to dileptons with similar masses.
It may be due to charmed quark deconfinement in the
plasma (as suggested originally in Ref. 22)1 or due to J/$J splitting in hot hadronic matter23, or initial stage interaction
of colliding gluons in nuclei 24. The last idea got support from
recent FNAL experiment, where similar suppression in pA relative to np data wrasobserved. One may, in principle, use more information to understand all that. In particular, Karsch and Petronzio25 have suggested that J/$ can jump out of the “hot spot” if its pt is large enough. And indeed, at pt > 2 GeV this suppression disappears, and they concluded from it that the size of the spot is only1-Z fm, while if we assume strong suppression at the hadronic stage as well, we expect much larger size (remember, by interferometry beams.
size at breakup measured
is about 8 fm). Certainly, much will be clarified by experiments with Pb
In this case we certainly have much larger size of the system, even at the hottest
stage. If the Karsch-Petronzio
idea is right, suppression should be seen up to much higher
pb in this case. If the reason for more J/$ at larger pt is “initial stage res~attering” of the gluons, we will see no change while coming from #I6 to Pb beams.
5. NEWS ABOUT
NOT HADRONIC MATTER
The topic of this section is the closest one to nuclear physics of this talk: we consider a pion gas, with density of the order of that in nuclear matter. and with different (and quite specific) interaction. systems.
Of course, pions are bosons,
Also we do not of course have stable
On the other hand, high energy nuclear collisions produce hundreds (and soon
thousands) of pions, so these pionic systems can be much larger than even the heaviest nuclei. Our discussion below develops into two different directions. review of the theory, and here we introduce qu~iparti~les
The first one is a brief
with pion quantum number, the
“qnasipions”, following t,he experience of low temperature physics, especially that of liquid He*. Another part of this section is an attempt to explain few unexpected phenomena observed recently in various high energy reactions.
Their list includes in reticular:
‘I. enhanced production of pions at small pi found in nuclear collisions”“; 2. enhanced prod~lction of soft photons and low-mass dileptons in various hadronic reactions27; 3. an unexpectedly sharp two-pion annihilation threshold seen in the dilepton spectra at Berkeley28; 4. strong clustering of pions, produced in various hadronic reactions. Let us start with some general remarks about pions. are the lightest hadrons, so that if temperature
They are special because they
T is small enough, only pions are excited.
This fact is not occasional, but related to the specific nature of pions. In the chiral world they are massless, exactly for the same reason as e.g. acoustical phonons in solids: they are Goldstone modes, a remnant of the spontaneously
broken symmetry.
(Translational
symmetry for solids, chiral one for the QCD vacuum.) At small T the mean interparticle ideal gas approach is justified.
distances are large, l/T, so interaction is small and
Also discussion of massless pions makes the problem simpler,
so we start with this case. At small temperatures we get then simple formula for the energy density e(T) = (~z/~~)~4 Interaction
of pions is also quite specific and related to their Goldstone nature.
In the
chira1 world, pions with momenta Ic + 0 cannot interact with anything including themselves. (Exactly
because of this feature acoustical phonons propagate distances much larger than
molecule free paths, therefore we can hear each other.)
This feature makes this gas even
more ideal at small 2’. Accounting for momentums-dependent bation theory, considering T/F,
pion-pion interaction, one can use chiral pertur-
as a small parameter, while at so~s~~hat larger T one has
to include resonances. We summarized results on energy density in Fig. 7a, where e(T)/T4 is plotted versus T. For the ideal gas this ra.tin is close to one, until ~nteractior~ of pions makes some modifications
(see the dotted line). Much more dramatic things happen if one takes
into account nonzero pion mass and, even more important, becomes much more temperature-dependent
hadronic resonances.
The ratio
(see the solid line in Fig. ‘?a). We also show
simple paramete~zat~on
for the ~‘pion+reson~ces”
ago2*: e(T) = T”/T;,To
= 1~~~~~ wh’ICh is shown by the dashed line. One can see that
suggested by the author many years
E. JX Shutyak / QCD vacuum and excited hadronic matter
390~
: 1.5 -
j/+----
-e ‘,
1.0
I._Ix__.. -_/: .i’ / I : :
0.5 -
A
;/’
: ,,*’
~i .‘,’
,J
, 50
1W
150
m
T(MdY)
K/m,
Figure 7’: (a) Ratio of the energy density of excited hadronic matter e(T) to T4, versus temperature 2’. The dotted, dash-dotted and solid line are from3’ for interacting massless pions, massive pions and pions together with resonances, respectively. The dashed curve corresponds to par~etrisation~‘. (b) Qualitative picture of the modification of the pion dispersion curve in hot “pion liquid”. The “quasipion” with internal momentum corresponding to point A moves to point B as it goes out of the system. it approximately describes the energy density dependence on temperature over the whole interval. Summarising, above T around 100 MeV or so, corrections to the ideal pion gas energy become large. Now we come to kinetics in the pion matter. Again Goldstone nature of the pion plays an important role: apart from small effects related with scattering lengths, the r?r cross section is essentially proportional to pion momenta. Therefore mean time between collisions depend on T as follows2Q: rCOll= constF:/T”.
Goity and Leutwyler have recently made extensive
calculations3o supporting this expression and getting more accurate const=12. Note, that at ‘I’ = 200 MeV rC-,ais smali, .7 fm/c, b ut at our other extreme T = 100 MeV it is already about 25 fm/c, comparable to the lifetime of even the largest fireballs considered. Another useful way to look at rc-,nis to compare its inverse, the imaginary part of the pion energy Im E, = l/rc,ll, with its real part. The corresponding ratio can be estimated as follows Im E,f Re E, = .03(TfF,)4
It is still only about .1 at T = 140 MeV, but it is of
391c
E. K Shuyak / QCD vacuum and excited hudronic matter
the order I at Tc = 200 MeV.
Therefore,
in the former case the pions are still propagating
rather well, while in the latter case they are strongly
absorbed.
Now we come to the central point of this section: matter,
but they interact
The main pion-pion potential modes.
interaction
is proportional
should grow with momentum Let us mention
strongly
with many particles
modified
directly
to pion momenta
examples
curve of elementary
by neutron scattering by Landau
respectively,
minimum
excitations
experiments.
curve is
is developed. in liquid He*, measured
Note the secondary minimum
and called the “roton”
minimum.
for phonon non-linear
interactions,
this curve, with accounting
our collective
of cases in which the dispersion
at larger L, so that even secondary
was suggested
in hot
and change their properties.
as well. Such a situation is common for all Goldstone
two well-known
1, The famous dispersion
pions are not only scattered
simultaneously
Modern
which
theory
of
can be found e.g.
in Ref. 31. 2. In Fig. 3 we show the pion dispersion ated theoretically (With
increasing
energy
Migdal
evalu-
(see e.g. Ref. 32 and references therein).
nuclear density,
modification
may reach zero at some critical
rearrangement
curve in cold dense nuclear matter,
and spontaneous
pion condensation.
of pions may become
momentum
production
&.
so strong
that their
If so, it should lead to vacuum
of the pion field. This phenomenon
We are not going to discuss here whether
is known as
these calculations
are
reliable or not at such high densities.) The
expected
qualitative
behaviour
“pseudopotential”
is slightly
repulsive
of the dispersion
curve is shown in Fig.
at small momenta
but becomes
attractive
7b:
the
at larger
ones. We do not want to have many free parameters,
so we do not speculate
secondary
for the modified pion dispersion curve
w(k)
minima and assume simple parametrisation
= (m;
+ u(T)%~)‘/~
m t ro d ucing the temperature-dependent
It is close to one till about T = 150A4eV, Now we return to “soft pion puzzle”, nuclear collisions Goldstone
theorem,
Therefore,
pion interactions
spectra
compared
slope parameter
u(T).
and then rapidly decreases. or enhancement
to pp, or peripheral
in any type of kinetic
the experimental opposite
compared
about possible
of soft pion production
collisions.
It is puzzling
in central
because,
due to
should be small for soft pions for all types of processes.
calculations
one might
to the thermal
expect
at low momenta
ones, while experiments
a dip in
show quite the
trend!
However, quantitative
pion modification explanation
phenomenon
discussed above can provide
of the soft pion component
at least a semi-
at small pt (see Fig. 8a).
Climbing
392c
2.6 i
2.4 2.2 2.0 1.8 1.6 R 1.4
t
1.2
t
1.0 0.8 0.6 0.4 0.2 0
1.6 0.8 Pt (GeVlc)
2.4
"0
200
400
600
Pt (MeV)
Figure 8: (a) The ratio of the pt spectra of X-Oin central and peripheral OW collisions (WA80) (points), while the shaded area is the ratio of x- HELIOS spectra for SS collisions to pp ones. (b) The ratio of the spectra calculated in the quasipion model with and without modification of the dispersion curve. out of the attractive potential well, the outgoing pion reduce its momenta (see Fig. 7b). If the dispersion curve is flat at low momenta, rather large phase space in terms of internal momenta corresponds to soft outgoing pions. It leads to very effective production of nearly stopping pions33(see Fig. 8b), which seems to explain the data. Another consequence of the pion modification is that some of them are reflected from the boundary which presumably makes the system lifetime longer. The second striking phenomenon observed in high energy collisions during the last years is observation27 of an excess of the produced soft photons over the theoretical expectations (see Fig, 9). The reason this is disturbing is that emission of the soft photons is described by the classicai electrodynamics,
which demands the simple bremsstrahlung
to be the main
effect, provided photon energies w are small compared to inverse lifetime of the radiating system. Attempts to describe these data in conventional models of the collisions has failed, (see e.g. Ref. 34) in which the Lund version of the string model was used. The results obtained
E. K Shutyak / QCD vacuum and excited hadronic matter
I N,
393c
= 400
I N, = 400 I N,=
10
I
1000
100
10
Pt( MeV1 Figure 9:
The ratio of the observed
photon
yield
to bremsstrahhmg
pre-
dictions, versus p\t. The dashed area shows predictions of the Lund mode134, while solid and dashed curves are for the quasipion model with and without pion modificat ion33.
with such space-time momenta,
picture more or less reproduce
production
was evaluated
in the “quasipion”
shown in Fig. 9 show indeed much stronger in the Lund model.
cancellation
final scattering Comparing
observe
that at intermediate
of scattering
describe
observed
experimental
contribution,
than, say,
several times
photon momenta
there
and at low w all but the
between
the coherent
seems that we can naturally
data shown in Fig.
excess for low pt < 30 MeV
effects of the pion modification
region
Recently,
from the b~msstrahlun~
becomes irrelevant.
cannot
transition
Interesting,
in the amplitude
these results with
strong
deviations
model in Ref. 33. The results
The main reason for that is that pions are rescattered
before they come out of the system.
definitely
in wide range of
up to those of the order of few hundreds MeV (see the shaded region in Fig. 9).
Soft photon
partial
low energy theorem
on the photon
and incoherent
regimes
9, one notes that we
or so.
However,
we do
radiation,
especially
in the
of radiation.
Moreover,
it
explain the data shown by solid points in Fig. 9).
first dilepton experiments
at Berkeley2* have studied the lepton pair production
at energies as low as 4.9 GeV for proton-nucleus
and about 1 GeV/N
in Ca Ca collisions.
The data are well described by known sources except for the peak above two pion mass. One may think about n+rr-
annihilation,
and in fact s-dependence
of this peak is consistent with
E. K Shutyak / QCD vacuum and excited hudrmic matter
394c
that for pion pair production.
However, attempts
to ascribe it to pion annihilation meet
certain problems. First of $11, production of two soft pions is suppressed by smallness of the phase space.
Second, the annihilation of soft pions into a virtual photon is suppressed at
threshold because it takes place in the P wave. Let us emphasize that conditions of this experiment
are quite different from nuclear
collisions at CERN. There are no hundreds of pions in a fireball, but just one pair of them. However, kinematics are now such that pions are produced snd ~nj~lated
in nuclear matter,
Gale and Kapusta 32 have used this fact, suggesting that pion dispersion curve is modified so strongly in the compressed nuclear matter, that secondary ~nimum
in w(k) is developed. If
so, annihilation of two “quasipions” leads to a peak in the dilepton spectrum, corresponding to the diiepton mass equal to twice the minimum value of w(k). with the double-pion
It may well be mixed
threshold, and now there is no suppression mentioned above because
momentum is now far from zero value. It may we11be that the peak seen in these experiments is indeed of this nature.
6. SUMMARY 1. Latest results of numerical experiments with lattice gauge theory have shown that deconfinement
transition
is strong first order, but it exists only in the
“Lgluonic worid” , or for quark masses roughly above 1 GeV. For small masses (and for real &CD) chiral symmetry restoration is the main phenomenon, strong f&t-order
Again
transition seems to take place between hadronic gas and quark-
gluon plasma. However, in the inte~ediate
mass region (roughly 0.1-1 GeV) no
first order phase transition is seen, which means that deconfinement and chiral restoration are in fact two different phenomena. 2. Much progress was made in understanding of chiral symmetry breaking in the QCD vacuum and its restoration interacting instantons. gas transition,
at high temperatures
based on the theory of
The phase transition is understood as liquid - molecular
with some details in striking correlation to what people see OR
the lattice. In particular, it explains why at such small quark masses as 50-100 MeV one finds strong changes of the chiral symmetry physics. Also the theory of inst~tons
proved to be very effective in predicting properties of mesonic
correlation functions.
E. V; Shwyak / QCD vacutun ad
excited hadronk matter
395c
3. Various high energy collisions are now used fur search of the superdense hadronic matter. There is evidence that for energy density of the order of 1-3
GeV/fm3
the equation of state is soft, which is expected near the phase transition.
At
larger energy density some collective flow may be observed at Tevatron. Maybe we have some first evidence for appearance of the “mixed phase’* from CERN experiments.
Suppression of J/d
and enhancement of Q; found by NA38 ex-
periment in GERN are discussed at various angles. Let me finish this section, reminding you once more of the long-standing statement: looking for dileptons with pt (or invariant masses M) about 14
GeV we probabiy have a chance
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