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Quark-gluon transport theory
603c
NuclearPhysics A418 (1984) 603c-612~ North-Holland.Amsterdam
QUARK-GLUON
TRANSPORT
THEORY+)*)
Ulrich HEINZ') Institut fur Theoretische a. M. 11, WEST GERMANY
1.
Physik, Postfach
11 19 32, D-6000 Frankfurt
INTRODUCTION The discussion
about the possible
in high energy heavy ion collisions cated by the fact that suggested and the literature
signatures
quoted therein)
the system expands from hydrodynamical collisions
plasma phase
detection
is compli-
of this new phase (see refs. 1, 2
are affected
by its space-time
and cools down after the collision.
history. A very
or not the system
Nearly equally
An understanding
level requires
knowledge
The natural
port on an attempt
to formulate
non-Abelian
to correctly
In this
such a kinetic theory.
task since the plasma
gauge field theory
account very carefully.
to approach
functions.
2,556 .
part of the his-
tooter&
local equili-
phase even on a qualitative
of the transport
framework
theory for the plasma distribution
out not to be a trivial
by the approach
is the question
equilibrium
imply that a considerable
of that pre-equilibrium
an approximate
plasma.
important
is in local thermal and chemical
tory of the plasma will be characterized
quark-gluon
It has been estimated
calculations 3y4 $0 be of the order of 4-10 fm/c for U + U
at ~50 GeV/u c.m. energy.
The short time scales just mentioned
brium.
of a quark-gluon
role is played by the lifetime of the plasma which depends on how fast
important
whether
occurrence
and its experimental
properties
is a kinetic
contribution
I will re-
Conceptually,
interactions
(QCD), and gauge invariance
But also from the practical
of the
this problem
this turns
are governed
by a
has to be taken into
side it appears necessary
treat all the color degrees of freedom since in the plasma phase
color can move around freely, allowing
for the possibility
of macroscopic
color
fluctuations. On the conference (1982) I presented meantime, problems.
on ultrarelativistic
a classical
some progress
heavy ion collisions
in Bielefeld
kinetic theory for a colored plasma'.
could be made on a quantum
I will review these two approaches
(QCD) treatment
In the
of this
and add a few remarks on
+Work supported by Deutsche Forschungsgemeinschaft. *Talk given at the Third International Conference on Ultra-Relativistic NucleusNucleus Collisions (Quark Matter '83), Brookhaven Nat'l. Lab., Sept. 26-29, 1983. BPresent address: Department of Physics & Astronomy, Vanderbilt University, Nashville, TN 37235, USA.
037S-9474/84/$03.00 0 Elsevier Science Publishers B.V.
(North-Holland Physics Publishing Division)
604C
U, Heinz / Quark-Gluon Transport Theory
their further development
2.
CLASSICAL
KINETIC THEORY FOR A COLORED
The classical cal colored
and applications.
formulation
particles
that, due to exchange
moving
in an external
of color between
Q,(a=l,..., 8) of the particle being constants
of motion.
shown7'8
for classi-
These tell you
and field, the color charge
rotates in color space, with QaQa and dabc QaQbQC
into the definition
of the plasmal'.
and ?(x,p,Q)
of motion'
color field AZ(x),
particles
Hence Q, is a dynamical
and has to be included lI:cription
PLASMA
starts from the equations
The l-particle
for the classical
variable
distribution
functions
"quarks" and "antiquarks',
to obey the Vlasov-Boltzmann
like the ~mentum
of phase space in a statistical f(x,p,Q)
respectively,
were
equations
[P~~~~QaF~~(x)p~a~fabcpvA~(x)Qc~~~f(x,p,Q)
=
Ctf,~lfx,p,Q);
[p'aU-QaF;v(x)pV$+fabcP"A;(x)Qc$:(x,p,Q)
=
~[f,i+l(x,p,QI .
C and t are collision
terms, which
but were here assumed
to be of Boltzmann
in general
involve Z-particle
(la,b)
correlations,
type and hence to depend only on f and
f themselves. All the transport ductivity)
mary interest. purely classical
However,
In the plasma,
appears
-- here a thorough necessary
heat and color con-
therefore
are of prithese by
study in the framework
along the way to be outlined
the mean gluon field AZ(x) entering
of
below.
into (1) is determined
condition
f [a,,&,, - fabcA;(x)l
where ji is the quark-antiquark j:(x)
(viscosity,
terms, which
there is little hope to be able to estimate
the self-consistency
(D,F'v),(x)
of the plasma
by the collision
considerations
quantum chromodynamics
through
properties
are determined
Fr(x)
= j;(x)
color current
t
(2)
in the plasma: (3)
=~'Qa[f(x,p,Q) - f(x,p,Q)ldPdQ .
The measure
for the integration
over the color and momentum
sectors of phase
space in (3)‘is given by dP E 2e(p0)6(p2-mz)d'+p; dQ f a(QaQe-Q2)s(dabcQaQbQc-~3)daQ with d8Q being the invariant
group measure
,
(4)
for the octet representation
of
W(3). The kinetic equations an infinite hierarchy
(1) for the distribution
of equations
functions
are equivalent
for their color and mo~ntum
moments.
Of
to
6052
U. Heinz / Quark-Gluon Transport Theory
practical
importance
b'(x) =Jp'(f ThiT(x)
are the following
and the color current tions which
(energy-momentum
- f)dPdQ (3).
These macroscopical
take the form of conservation
aPb'(x) = 0
of the distribution
(baryon number current)
- f)dPdQ
=lp'lp'(f
moments
function:
;
(5)
of matter);
densities
46)
obey hierarchy
equa-
laws
;
(7)
(D&‘),(x) = 0 ; = -ap
apThiT
T&(x)
and can be obtained terms reflected @(x,p,Q)
I -j:(x) F:"(x)
directly
from (1) using general symmetries
in the vanishing - $x,p,Q)ldPdQ
= 0
;
-
t(x,p,Q)ldPdQ = 0 ;
~P,[C(X,P,Q)
+
i(w,Q)ldPdQ
one truncates
thus arriving equations
Although
lar in view of equation
tion of the chrome-hydrodynamical
Before,
therefore,
derive the infinite
dx,p)
which
function,
higher moments
treatment
hierarchy
by
in particu-
still the definitions functions,
(3,
and in an evalua-
is usually done by expanding the collision
a la (10).
terms creep back
Thus the need to deter-
urgent also for the less de-
of the plasma.
going on to a QCD description
These will prove helpful kinetic theory.
equations,
terms from QCD remains equally
tailed chrome-hydrodynamical
is defined
that by doing this one has completely
distribution
distribution
in the form of non-vanishing
at this point,
of these equations,
terms, this is not true:
around a local equilibrium
equations
of chrome-hydrodynamicswhich
a naive inspection
the full, non-equilibrium
mine the collision
(lOa,b,c)
(l), would suggest
gotten rid of the collision 5,6) contain
=0 .
the infinite set of hierarchy
at the formalism
(2,7-g).
of the collision
of the following moments:
~Q,[C(X,P,Q)
In practice
(9)
,
of the problem,
of color moment equations
in understanding
equivalent
the color structure
let us
to (1).
of the quantum
To this end let us define the color moments
+fb,p,Q)
+ fb,-p,Q)ldQ
gabs) =jQ,[f(wQ) gab(x’p) =jQ,Qb[f(x,P,Q)
+ f(w,Q)ldQ
;
;
+ 7(x,-p,Q)ldQ;
etc.
(11)
U. Heinz / Quark-Ghm
606c
The corresponding
moment
equations
read
p'lapg = ~'Fzv a;ga +j[C(x,p,Q)
= PPF;~ P%,,sac- f,,,A;I P'[au6acbbd
- ~acfbmdA~
Trunsport Tkeory
+
h-p,Q)ldQ ;
a;g,b fJ
Qa[Cb,~.Q) + i(x,-p,Q)ldQ;
- 'amc~bdA~lgcd +
= p"FFV $g,bc
J
=
Q,Q,[C(X,P,Q) +
%w,Q)ldQ ;
etc.
3.
QUANTUM
KINETIC THEORY
PLASMA
analog of the one-particle
The quantum-~chanical generated
FOR A COLORED
by the following
distribution
function
(13)
1
<$X,P
is
operator
with j(y,z)
(14)
Here 6a = -ha/2 is the color charge operator,
and riisolves the QCD Dirac equa-
tion i7'[all + iGaA:(x)]i(x)
= m;(x).
(15)
The color indices A, B run from 1 to 3, the spin indices a, B from 1 to 4. path ordered
exponentials
have been included
under gauge transfor~tions the cancellation variants
like an operator
of gauge transformations
operators
tion of the Wigner
sitting
at point z.
in expectation
This leads to
values of gauge in-
6, cTr i 6,. and hence (13) is a gauge invariant Its expectation
operator I2 for quark fields.
is as close as one can get to a positive
definite
distribution
generaliza-
value
function
in quan-
tum mechanics. The Wigner operator
can be used to express
the macroscopical
bM, je and TV": b'(x) z <:~(x)~$(x):>
=J4p
= d'+p p' Jj:(x) 1 <:$(X)&~;(X):> =
J
TV F(x,p)>
+ spin terms
=Jd4p
d4p pp(Tr 3a F(x,p)>
The
in order to make j(y,z) transform
;
+ spin terms:
observables
U. Heinz / Quark-Glum
Transport Theory
60%
T;iT(x) 5 f <:;(x)~%~;(x) - $(x)b"'&(x):>
J
= d4p p' = I spin terms .
+
d4p p'lpv
fl6c)
Here, spin effects have been isolated through a Gordon decompositionas terms involving CT
and are henceforth neglected. They can be treated analogously to
the color d&ees
of freedom (see below), but there is no classical analogue to
them in the classical formulation of Section 2.
However, the latter can be
correspondinglygeneralized by using the classical equations of motion for colored, spinning particlesI to generate a Vlasov-Boltzmannequation for the classical distribution function ffx,p,s,Q) (s denoting spin). In fact, spincolor couplings may be important for the description of chromomagneticeffects in a colored plasma. Comparing equations (16) with (3,5,6) we recognize a similarity in structure, with the only differences being that in (16) the mo~ntum integrals are not on mass shell, and the color integrals of the classical theory have been replaced by sums over color indices. We will now discuss these differences in some more detail.
i can be split up in the following way:
F(x,p) = i(+)(x,p) +
F(-+X.P)
+ F(Zf(x,P)
(174
with
fw(x,p) i
e(~po)e(P2)i$x,Pl;
&+X,P)
s e(-p2G?x,p)
.
(17b)
The last term, containing spacelike momenta, is attributed to the Zitterbewegu~ and vanishes classically. ,(+) and ,c-) are usually peaked near the mass shell'* and classically correspond to 6(po)~(p2-m2)f(x,p,Q)and e(-p,)s(p2-m2)f(x,-p,Q),respectively. Thus we see the particle-antiparticle structure emerge from the quantum theory. This correspondenceshould become explicit in an* + 0 approximation. Next we discuss the color structure of P, neglecting the spin effects and taking the trace over spin indices. The color 3 x 3 matrix & as
with
dxd
'L
5
TrC ; +a(x9P) 9
may be expanded
608~
U. Heinz f Quark-G&on Transport Theory
Inserting
this expansion
dence between
the singlet
their classical g(x,p) -
za(x.p) -
function
higher ~ments
and octet quantum
eb,?lf(x,p,QMQ
1
Q, fbw,QNQ
@(PO)
J
(T)(x,p,Q).
distribution
and octet quantum
equation
(@AZ>
distribution
the following
equation
for
(204 terms.
(20b)
= I
of the path-ordered
in obtaining
mean non-Abelian
g ,(ab)
the correct
field.
6Ai and higher momentum into a form treatable
out and used for a computation
exponentials
terms in (20) involve
deviations
of i(x,p).
by Feynman diagrams
of transport
equations
the
They still
in order to be
coefficients.
a moment close our eyes for the SU(3) algebra transport
in (13, 14)
force terms due to the se'if-
The collision
have to be brought
p"
function8.
value and a fluctuating
functions:
gluon fluctuations
(redundant)
of the
terms:
(20) closes.
tet'sfor
dis-
the
with g(ab) in (20b) mean symmetrization:
Note that the introduction
and continue
for the higher color moments.
deriving
We find
- fame 6bd A: - 'ac fbmd AF % g(cd) I = pFI Fzv a~~((abjcJ
etc.
expectation
'ab - fame AC g = p" 'iv ai z(ab) + collision I %c
here proves crucial
worked
(19b)
their knowledge
for the QCD Wigner
= 0), we obtain
= p' Fiv .3; g + collision %a
consistent
.
of the classical
for-the h?gher ~ments
priori
The color algebra zan be used to express system
the Wigner-function,
the gluon field into its ensemble
The brackets
f
The reason is that quantum mechanically
exists a
the singlet
P'I
(1%)
function.
= AL(x) + e??(x)
%
g, ;a and 'L
etc. are related to g and g, via the SU(3) algebra,
part, am
p%,9
correspon-
;
i
+ e(-p,)ji,f(x.-p,9)dQ
specify
We wilf now derive a transport Splitting
functions
only the two lowest color moments
no such relationship
classical
distribution
f e(-po$b,-P.Q)dQ
g and g, completely
allows us to de?ermin$
whereas
i
6(p2-m2)
Thus, although
(16) reveals the following
counterparts:
6(p2-m2f
%
tribution
into expression
t collision
Up to the only partial symmetrization
is formally
identical
to the classical
of color indices,
analog
(2Ocl
terms,
(12).
this
hierarchy
In the quantum case the
hierarchy
is generated
by the color algebra, whereas
tion it is due to the non-Abelian
terms in (1).
This demonstrates
tance of this term and shows that the classical in a natural way to the correct QCD transport In view of this, two ways of proceeding to deduce the collision
Vlasov equation
Vlasov-Boltzmann
between both approaches
treated like a usual partial dependence
results
transport equation
fi)
equations (I) which
(2Qa,b).
equation,
whereas
twu types of distribution
Try
(20a,b) then re-
The major
is that in (i) the color dependence
differential
in considering
the impor-
(1) is related
further offer themselves:
mains to be solved; or (ii) work directly with equations difference
formula-
equation.
terms C, ?Z from the quantum
and insert them into the classical
in the classical
can be
in (ii) the color functions
(singlet
and octet),
which are coupled with each other, but contain no further color
variables.
I am not yet sure which approach will finally prove simpler.
the following
4.
section we will see an approximate
THE TWO-STREAM
the Vlasov equation
plasmas
can develop
modes are usually
found through an analysis
linearized
some given homogeneous
around
this procedure
i la method
fi),
INSTABILITY
From the theory of electrodynamic situations
treatment
In
it is known that for specific
unstable
solutions.
Such unstable
in which the Vlasov equation
background
configuration,
is
Applying
to our case, we set
(-) f (x,p,Q) = ($(,,Q) AZ(x) = AZ e-iksx;
+ (;;(p,Q)e*ik'x
(kU e (w, 1))
;
(21a
;
(21b)
where At and f (% ) are to be treated as perturbations. (21b) assumes that the 1 I background configuration should not contain a macroscopic color field, leading to the requirement (j:),(x)
"jQapp(fo-?,)dPdQ
For the purpose
= 0
(22)
.
of this chapter we will focus on the color eZe&ric
only by requiring
Ftj(x) = 0, which
now (21) into the coflisionless
in &X&X&
Vlasov equation
second order in the perturbations,
one finds
gauge yields i;" = 0, (If and neglecting
ssctor Inserting terms of
U. Heinz / Quark-Gluon Transport Theory
610~
Qa(k*p Ai aifo - po AZ k*anfo)
7, = -
&-
- i fabc P, Ai
Qa(k'p Ai ai?, - P, At k*apFo)
These expressions
can be used to eliminate
tion for A:, which
PC 3; f, ; I
f i fabc p, Ai Qc aa 7
(23)
Q oI *
fI and ?I from the Yang-Mills
equa-
in Coulomb gauge reads
.I- Q,Q,a~$l,(~.Q) I.
- i f,,de dQ
There the po-integretion
was already
Go (go) are the sum (difference) distribution Go6
functions
(24)
performed yielding
of the particle
p, = m,
and
and antiparticle
background
on mass shell:
;
(25a)
Qf 5 If,fp,Q) - ~o(~,Q)lpo=~~ .
(25b)
Q) 5 [fo(PsQ) + ?,(P,Q)I, =J" 0
so&
It is now easy to show that the last term in (24) does not contribute linearized
approximation:
from its color structure
(symmetrical
in the
in a and b) it
has to be of the form
= C+ibade+ C2dadnfnea J- QaQda&, s dQ
which
vanishes
dQ Q, 9, +
after contraction
first color integral J where
(26)
9
with fbde due to the constraint
(22).
The
is of the form
(27)
dQ QaQbGo(~,Q) = Gtifb,b + C3dabcpQ9, Go&Q) + ofA,) the second
configuration J-
o(Ao)
last term does not necessarily
is color neutral with respect
vanish.
Only if the background
to both particles
and antiparticles,
(281
dQ 9, f, =J-dQ Q, f. = 0 ,
this term vanishes,
too.
In order to be able to further analyse eq. (24) analy-
tically, we will here assume
(28).
indices and allows us to eliminate
This renders A:.
(24) diagonal
in the color
One finds the dispersion
relation
61IC
d3 c2 = +-it*?
I
P
!iT_. PO
p'
where G(c) is proportional persion
relation
(29)
G(+)
to f, + a
on mass shell
[see (25, 27)l.
is very similar
his famous discovery
to the non-relativistic 14 . of the so-called Landau damping
This dis-
one found by Landau in In general,
for real
l?, w need not be real:
w=w However,
r
(30)
+ iw.1 .
An analysis very similar to the only modes with wi 2 0 are stable. 14 reveals that unstable modes may develop plasmas
one known from electrodynamic when Gfff) is anisotropic Fig. 1 (independent
in mo~ntum
space with a double peak structure
like in
of px, py):
FIGURE 1 This is the well~known
W-stream
if in the plasma two streams instabiZity:
flow through each other, this configuration particles electric
and antiparticles, field.
all colors
through
growth
separation
increasing
of
(color-}
is only stopped when the nonlineari-
equations
its approximations
symmetrically,
against
which create an exponentially
(The exponential
ties of the Vlasov or Yang-Mills our treatment
is unstable
become important.)
(in particular
hence what we obtained
Unfortunately,
eq. (28)) has treated
is a complete Abelian
analogue
to the electrodynamic
case.
genuine color separation,
This unstable mode will therefore
but only to particle-antiparticle
this might happen in heavy ion collisions, other.
If I may speculate
nism might have something central
rapidity
not lead to
separation.
a little bit, it is even conceivable to do with the creation
region, but certainly
Still,
when the two nuclei fly through each that this mecha-
of the (baryon number poor)
a closer study is necessary
before this
can be finally decided.
ACKNOWLEDGEMENT I would Vanderbilt
like to thank the Department University,
of Physics and Astronomy
where this manuscript
was finished,
at
for their kind hos-
pitality,
REFERENCES I)
M. Gyulassy,
Signatures
2)
J. Rafelski, ference,
Strangeness
3)
G. Domokos and J. Goldman, Phys. Rev, D23 (198If 203.
4)
J. D. Bjorken,
5)
K. Kajantie, Hydrodynamics plasma, this conference.
6)
G. Baym, this conference.
7)
U. Heinz,
in:
of new phenomena, production
this conference.
in the quark-gluon
plasma,
this con-
Phys. Rev. D27 (1983) 140. and approach
Quark matter
Jacob and K. Satz
(tlorfd
Phys. Rev, Lett.
for~~i~~
Scientific,
to equilibrium
and heavy ion
Sinaapore.
in the quark-gluon
collisions,
eds. M,
1982). D. 439.
8)
8. Heinz,
9)
S. K. Wong, Nuovo Cimento 65A (1970) 689.
IO)
This was first pointed out by V. Moncrief
11)
3. M. Stewart, Non-equilibrium Notes in Physics 10 (Springer,
12)
S, R, de Groat, W, A. van Leeuwen, and Ch. G. van Wee&, Kinetic Theory (North-Ho~land~ Amsterdam, 1980).
IS)
H. Arod;, Phys.
14)
L. D. Landau, J. Phys. U.S.S.R. IO (1946) 25; R. Balescu$ Statistical Mechanics of Charged Particles (Interscience, London, 1963).
Lett.
51 (1983) 351.
(private communication).
relativistic kinetic theory, New York, 1971).
in: Lecture
Relativistic
1168 (1982) 251.
NuclearPhysics A418 (1984) 603c-612~ North-Holland.Amsterdam
QUARK-GLUON
TRANSPORT
THEORY+)*)
Ulrich HEINZ') Institut fur Theoretische a. M. 11, WEST GERMANY
1.
Physik, Postfach
11 19 32, D-6000 Frankfurt
INTRODUCTION The discussion
about the possible
in high energy heavy ion collisions cated by the fact that suggested and the literature
signatures
quoted therein)
the system expands from hydrodynamical collisions
plasma phase
detection
is compli-
of this new phase (see refs. 1, 2
are affected
by its space-time
and cools down after the collision.
history. A very
or not the system
Nearly equally
An understanding
level requires
knowledge
The natural
port on an attempt
to formulate
non-Abelian
to correctly
In this
such a kinetic theory.
task since the plasma
gauge field theory
account very carefully.
to approach
functions.
2,556 .
part of the his-
tooter&
local equili-
phase even on a qualitative
of the transport
framework
theory for the plasma distribution
out not to be a trivial
by the approach
is the question
equilibrium
imply that a considerable
of that pre-equilibrium
an approximate
plasma.
important
is in local thermal and chemical
tory of the plasma will be characterized
quark-gluon
It has been estimated
calculations 3y4 $0 be of the order of 4-10 fm/c for U + U
at ~50 GeV/u c.m. energy.
The short time scales just mentioned
brium.
of a quark-gluon
role is played by the lifetime of the plasma which depends on how fast
important
whether
occurrence
and its experimental
properties
is a kinetic
contribution
I will re-
Conceptually,
interactions
(QCD), and gauge invariance
But also from the practical
of the
this problem
this turns
are governed
by a
has to be taken into
side it appears necessary
treat all the color degrees of freedom since in the plasma phase
color can move around freely, allowing
for the possibility
of macroscopic
color
fluctuations. On the conference (1982) I presented meantime, problems.
on ultrarelativistic
a classical
some progress
heavy ion collisions
in Bielefeld
kinetic theory for a colored plasma'.
could be made on a quantum
I will review these two approaches
(QCD) treatment
In the
of this
and add a few remarks on
+Work supported by Deutsche Forschungsgemeinschaft. *Talk given at the Third International Conference on Ultra-Relativistic NucleusNucleus Collisions (Quark Matter '83), Brookhaven Nat'l. Lab., Sept. 26-29, 1983. BPresent address: Department of Physics & Astronomy, Vanderbilt University, Nashville, TN 37235, USA.
037S-9474/84/$03.00 0 Elsevier Science Publishers B.V.
(North-Holland Physics Publishing Division)
604C
U, Heinz / Quark-Gluon Transport Theory
their further development
2.
CLASSICAL
KINETIC THEORY FOR A COLORED
The classical cal colored
and applications.
formulation
particles
that, due to exchange
moving
in an external
of color between
Q,(a=l,..., 8) of the particle being constants
of motion.
shown7'8
for classi-
These tell you
and field, the color charge
rotates in color space, with QaQa and dabc QaQbQC
into the definition
of the plasmal'.
and ?(x,p,Q)
of motion'
color field AZ(x),
particles
Hence Q, is a dynamical
and has to be included lI:cription
PLASMA
starts from the equations
The l-particle
for the classical
variable
distribution
functions
"quarks" and "antiquarks',
to obey the Vlasov-Boltzmann
like the ~mentum
of phase space in a statistical f(x,p,Q)
respectively,
were
equations
[P~~~~QaF~~(x)p~a~fabcpvA~(x)Qc~~~f(x,p,Q)
=
Ctf,~lfx,p,Q);
[p'aU-QaF;v(x)pV$+fabcP"A;(x)Qc$:(x,p,Q)
=
~[f,i+l(x,p,QI .
C and t are collision
terms, which
but were here assumed
to be of Boltzmann
in general
involve Z-particle
(la,b)
correlations,
type and hence to depend only on f and
f themselves. All the transport ductivity)
mary interest. purely classical
However,
In the plasma,
appears
-- here a thorough necessary
heat and color con-
therefore
are of prithese by
study in the framework
along the way to be outlined
the mean gluon field AZ(x) entering
of
below.
into (1) is determined
condition
f [a,,&,, - fabcA;(x)l
where ji is the quark-antiquark j:(x)
(viscosity,
terms, which
there is little hope to be able to estimate
the self-consistency
(D,F'v),(x)
of the plasma
by the collision
considerations
quantum chromodynamics
through
properties
are determined
Fr(x)
= j;(x)
color current
t
(2)
in the plasma: (3)
=~'Qa[f(x,p,Q) - f(x,p,Q)ldPdQ .
The measure
for the integration
over the color and momentum
sectors of phase
space in (3)‘is given by dP E 2e(p0)6(p2-mz)d'+p; dQ f a(QaQe-Q2)s(dabcQaQbQc-~3)daQ with d8Q being the invariant
group measure
,
(4)
for the octet representation
of
W(3). The kinetic equations an infinite hierarchy
(1) for the distribution
of equations
functions
are equivalent
for their color and mo~ntum
moments.
Of
to
6052
U. Heinz / Quark-Gluon Transport Theory
practical
importance
b'(x) =Jp'(f ThiT(x)
are the following
and the color current tions which
(energy-momentum
- f)dPdQ (3).
These macroscopical
take the form of conservation
aPb'(x) = 0
of the distribution
(baryon number current)
- f)dPdQ
=lp'lp'(f
moments
function:
;
(5)
of matter);
densities
46)
obey hierarchy
equa-
laws
;
(7)
(D&‘),(x) = 0 ; = -ap
apThiT
T&(x)
and can be obtained terms reflected @(x,p,Q)
I -j:(x) F:"(x)
directly
from (1) using general symmetries
in the vanishing - $x,p,Q)ldPdQ
= 0
;
-
t(x,p,Q)ldPdQ = 0 ;
~P,[C(X,P,Q)
+
i(w,Q)ldPdQ
one truncates
thus arriving equations
Although
lar in view of equation
tion of the chrome-hydrodynamical
Before,
therefore,
derive the infinite
dx,p)
which
function,
higher moments
treatment
hierarchy
by
in particu-
still the definitions functions,
(3,
and in an evalua-
is usually done by expanding the collision
a la (10).
terms creep back
Thus the need to deter-
urgent also for the less de-
of the plasma.
going on to a QCD description
These will prove helpful kinetic theory.
equations,
terms from QCD remains equally
tailed chrome-hydrodynamical
is defined
that by doing this one has completely
distribution
distribution
in the form of non-vanishing
at this point,
of these equations,
terms, this is not true:
around a local equilibrium
equations
of chrome-hydrodynamicswhich
a naive inspection
the full, non-equilibrium
mine the collision
(lOa,b,c)
(l), would suggest
gotten rid of the collision 5,6) contain
=0 .
the infinite set of hierarchy
at the formalism
(2,7-g).
of the collision
of the following moments:
~Q,[C(X,P,Q)
In practice
(9)
,
of the problem,
of color moment equations
in understanding
equivalent
the color structure
let us
to (1).
of the quantum
To this end let us define the color moments
+fb,p,Q)
+ fb,-p,Q)ldQ
gabs) =jQ,[f(wQ) gab(x’p) =jQ,Qb[f(x,P,Q)
+ f(w,Q)ldQ
;
;
+ 7(x,-p,Q)ldQ;
etc.
(11)
U. Heinz / Quark-Ghm
606c
The corresponding
moment
equations
read
p'lapg = ~'Fzv a;ga +j[C(x,p,Q)
= PPF;~ P%,,sac- f,,,A;I P'[au6acbbd
- ~acfbmdA~
Trunsport Tkeory
+
h-p,Q)ldQ ;
a;g,b fJ
Qa[Cb,~.Q) + i(x,-p,Q)ldQ;
- 'amc~bdA~lgcd +
= p"FFV $g,bc
J
=
Q,Q,[C(X,P,Q) +
%w,Q)ldQ ;
etc.
3.
QUANTUM
KINETIC THEORY
PLASMA
analog of the one-particle
The quantum-~chanical generated
FOR A COLORED
by the following
distribution
function
(13)
1
<$X,P
is
operator
with j(y,z)
(14)
Here 6a = -ha/2 is the color charge operator,
and riisolves the QCD Dirac equa-
tion i7'[all + iGaA:(x)]i(x)
= m;(x).
(15)
The color indices A, B run from 1 to 3, the spin indices a, B from 1 to 4. path ordered
exponentials
have been included
under gauge transfor~tions the cancellation variants
like an operator
of gauge transformations
operators
tion of the Wigner
sitting
at point z.
in expectation
This leads to
values of gauge in-
6, cTr i 6,. and hence (13) is a gauge invariant Its expectation
operator I2 for quark fields.
is as close as one can get to a positive
definite
distribution
generaliza-
value
function
in quan-
tum mechanics. The Wigner operator
can be used to express
the macroscopical
bM, je and TV": b'(x) z <:~(x)~$(x):>
=J4p
= d'+p p'
J
TV F(x,p)>
+ spin terms
=Jd4p
d4p pp(Tr 3a F(x,p)>
The
in order to make j(y,z) transform
;
observables
U. Heinz / Quark-Glum
Transport Theory
60%
T;iT(x) 5 f <:;(x)~%~;(x) - $(x)b"'&(x):>
J
= d4p p'
+
d4p p'lpv
fl6c)
Here, spin effects have been isolated through a Gordon decompositionas terms involving CT
and are henceforth neglected. They can be treated analogously to
the color d&ees
of freedom (see below), but there is no classical analogue to
them in the classical formulation of Section 2.
However, the latter can be
correspondinglygeneralized by using the classical equations of motion for colored, spinning particlesI to generate a Vlasov-Boltzmannequation for the classical distribution function ffx,p,s,Q) (s denoting spin). In fact, spincolor couplings may be important for the description of chromomagneticeffects in a colored plasma. Comparing equations (16) with (3,5,6) we recognize a similarity in structure, with the only differences being that in (16) the mo~ntum integrals are not on mass shell, and the color integrals of the classical theory have been replaced by sums over color indices. We will now discuss these differences in some more detail.
i can be split up in the following way:
F(x,p) = i(+)(x,p) +
F(-+X.P)
+ F(Zf(x,P)
(174
with
fw(x,p) i
e(~po)e(P2)i$x,Pl;
&+X,P)
s e(-p2G?x,p)
.
(17b)
The last term, containing spacelike momenta, is attributed to the Zitterbewegu~ and vanishes classically. ,(+) and ,c-) are usually peaked near the mass shell'* and classically correspond to 6(po)~(p2-m2)f(x,p,Q)and e(-p,)s(p2-m2)f(x,-p,Q),respectively. Thus we see the particle-antiparticle structure emerge from the quantum theory. This correspondenceshould become explicit in an* + 0 approximation. Next we discuss the color structure of P, neglecting the spin effects and taking the trace over spin indices. The color 3 x 3 matrix & as
with
dxd
'L
5
TrC
may be expanded
608~
U. Heinz f Quark-G&on Transport Theory
Inserting
this expansion
dence between
the singlet
their classical g(x,p) -
za(x.p) -
function
higher ~ments
and octet quantum
eb,?lf(x,p,QMQ
1
Q, fbw,QNQ
@(PO)
J
(T)(x,p,Q).
distribution
and octet quantum
equation
(@AZ>
distribution
the following
equation
for
(204 terms.
(20b)
= I
of the path-ordered
in obtaining
mean non-Abelian
g ,(ab)
the correct
field.
6Ai and higher momentum into a form treatable
out and used for a computation
exponentials
terms in (20) involve
deviations
of i(x,p).
by Feynman diagrams
of transport
equations
the
They still
in order to be
coefficients.
a moment close our eyes for the SU(3) algebra transport
in (13, 14)
force terms due to the se'if-
The collision
have to be brought
p"
function8.
value and a fluctuating
functions:
gluon fluctuations
(redundant)
of the
terms:
(20) closes.
tet'sfor
dis-
the
with g(ab) in (20b) mean symmetrization:
Note that the introduction
and continue
for the higher color moments.
deriving
We find
- fame 6bd A: - 'ac fbmd AF % g(cd) I = pFI Fzv a~~((abjcJ
etc.
expectation
'ab - fame AC g = p" 'iv ai z(ab) + collision I %c
here proves crucial
worked
(19b)
their knowledge
for the QCD Wigner
= 0), we obtain
= p' Fiv .3; g + collision %a
consistent
.
of the classical
for-the h?gher ~ments
priori
The color algebra zan be used to express system
the Wigner-function,
the gluon field into its ensemble
The brackets
f
The reason is that quantum mechanically
exists a
the singlet
P'I
(1%)
function.
= AL(x) + e??(x)
%
g, ;a and 'L
etc. are related to g and g, via the SU(3) algebra,
part, am
p%,9
correspon-
;
i
+ e(-p,)ji,f(x.-p,9)dQ
specify
We wilf now derive a transport Splitting
functions
only the two lowest color moments
no such relationship
classical
distribution
f e(-po$b,-P.Q)dQ
g and g, completely
allows us to de?ermin$
whereas
i
6(p2-m2)
Thus, although
(16) reveals the following
counterparts:
6(p2-m2f
%
tribution
into expression
t collision
Up to the only partial symmetrization
is formally
identical
to the classical
of color indices,
analog
(2Ocl
terms,
(12).
this
hierarchy
In the quantum case the
hierarchy
is generated
by the color algebra, whereas
tion it is due to the non-Abelian
terms in (1).
This demonstrates
tance of this term and shows that the classical in a natural way to the correct QCD transport In view of this, two ways of proceeding to deduce the collision
Vlasov equation
Vlasov-Boltzmann
between both approaches
treated like a usual partial dependence
results
transport equation
fi)
equations (I) which
(2Qa,b).
equation,
whereas
twu types of distribution
Try
(20a,b) then re-
The major
is that in (i) the color dependence
differential
in considering
the impor-
(1) is related
further offer themselves:
mains to be solved; or (ii) work directly with equations difference
formula-
equation.
terms C, ?Z from the quantum
and insert them into the classical
in the classical
can be
in (ii) the color functions
(singlet
and octet),
which are coupled with each other, but contain no further color
variables.
I am not yet sure which approach will finally prove simpler.
the following
4.
section we will see an approximate
THE TWO-STREAM
the Vlasov equation
plasmas
can develop
modes are usually
found through an analysis
linearized
some given homogeneous
around
this procedure
i la method
fi),
INSTABILITY
From the theory of electrodynamic situations
treatment
In
it is known that for specific
unstable
solutions.
Such unstable
in which the Vlasov equation
background
configuration,
is
Applying
to our case, we set
(-) f (x,p,Q) = ($(,,Q) AZ(x) = AZ e-iksx;
+ (;;(p,Q)e*ik'x
(kU e (w, 1))
;
(21a
;
(21b)
where At and f (% ) are to be treated as perturbations. (21b) assumes that the 1 I background configuration should not contain a macroscopic color field, leading to the requirement (j:),(x)
"jQapp(fo-?,)dPdQ
For the purpose
= 0
(22)
.
of this chapter we will focus on the color eZe&ric
only by requiring
Ftj(x) = 0, which
now (21) into the coflisionless
in &X&X&
Vlasov equation
second order in the perturbations,
one finds
gauge yields i;" = 0, (If and neglecting
ssctor Inserting terms of
U. Heinz / Quark-Gluon Transport Theory
610~
Qa(k*p Ai aifo - po AZ k*anfo)
7, = -
&-
- i fabc P, Ai
Qa(k'p Ai ai?, - P, At k*apFo)
These expressions
can be used to eliminate
tion for A:, which
PC 3; f, ; I
f i fabc p, Ai Qc aa 7
(23)
Q oI *
fI and ?I from the Yang-Mills
equa-
in Coulomb gauge reads
.I- Q,Q,a~$l,(~.Q) I.
- i f,,de dQ
There the po-integretion
was already
Go (go) are the sum (difference) distribution Go6
functions
(24)
performed yielding
of the particle
p, = m,
and
and antiparticle
background
on mass shell:
;
(25a)
Qf 5 If,fp,Q) - ~o(~,Q)lpo=~~ .
(25b)
Q) 5 [fo(PsQ) + ?,(P,Q)I, =J" 0
so&
It is now easy to show that the last term in (24) does not contribute linearized
approximation:
from its color structure
(symmetrical
in the
in a and b) it
has to be of the form
= C+ibade+ C2dadnfnea J- QaQda&, s dQ
which
vanishes
dQ Q, 9, +
after contraction
first color integral J where
(26)
9
with fbde due to the constraint
(22).
The
is of the form
(27)
dQ QaQbGo(~,Q) = Gtifb,b + C3dabcpQ9, Go&Q) + ofA,) the second
configuration J-
o(Ao)
last term does not necessarily
is color neutral with respect
vanish.
Only if the background
to both particles
and antiparticles,
(281
dQ 9, f, =J-dQ Q, f. = 0 ,
this term vanishes,
too.
In order to be able to further analyse eq. (24) analy-
tically, we will here assume
(28).
indices and allows us to eliminate
This renders A:.
(24) diagonal
in the color
One finds the dispersion
relation
61IC
d3 c2 = +-it*?
I
P
!iT_. PO
p'
where G(c) is proportional persion
relation
(29)
G(+)
to f, + a
on mass shell
[see (25, 27)l.
is very similar
his famous discovery
to the non-relativistic 14 . of the so-called Landau damping
This dis-
one found by Landau in In general,
for real
l?, w need not be real:
w=w However,
r
(30)
+ iw.1 .
An analysis very similar to the only modes with wi 2 0 are stable. 14 reveals that unstable modes may develop plasmas
one known from electrodynamic when Gfff) is anisotropic Fig. 1 (independent
in mo~ntum
space with a double peak structure
like in
of px, py):
FIGURE 1 This is the well~known
W-stream
if in the plasma two streams instabiZity:
flow through each other, this configuration particles electric
and antiparticles, field.
all colors
through
growth
separation
increasing
of
(color-}
is only stopped when the nonlineari-
equations
its approximations
symmetrically,
against
which create an exponentially
(The exponential
ties of the Vlasov or Yang-Mills our treatment
is unstable
become important.)
(in particular
hence what we obtained
Unfortunately,
eq. (28)) has treated
is a complete Abelian
analogue
to the electrodynamic
case.
genuine color separation,
This unstable mode will therefore
but only to particle-antiparticle
this might happen in heavy ion collisions, other.
If I may speculate
nism might have something central
rapidity
not lead to
separation.
a little bit, it is even conceivable to do with the creation
region, but certainly
Still,
when the two nuclei fly through each that this mecha-
of the (baryon number poor)
a closer study is necessary
before this
can be finally decided.
ACKNOWLEDGEMENT I would Vanderbilt
like to thank the Department University,
of Physics and Astronomy
where this manuscript
was finished,
at
for their kind hos-
pitality,
REFERENCES I)
M. Gyulassy,
Signatures
2)
J. Rafelski, ference,
Strangeness
3)
G. Domokos and J. Goldman, Phys. Rev, D23 (198If 203.
4)
J. D. Bjorken,
5)
K. Kajantie, Hydrodynamics plasma, this conference.
6)
G. Baym, this conference.
7)
U. Heinz,
in:
of new phenomena, production
this conference.
in the quark-gluon
plasma,
this con-
Phys. Rev. D27 (1983) 140. and approach
Quark matter
Jacob and K. Satz
(tlorfd
Phys. Rev, Lett.
for~~i~~
Scientific,
to equilibrium
and heavy ion
Sinaapore.
in the quark-gluon
collisions,
eds. M,
1982). D. 439.
8)
8. Heinz,
9)
S. K. Wong, Nuovo Cimento 65A (1970) 689.
IO)
This was first pointed out by V. Moncrief
11)
3. M. Stewart, Non-equilibrium Notes in Physics 10 (Springer,
12)
S, R, de Groat, W, A. van Leeuwen, and Ch. G. van Wee&, Kinetic Theory (North-Ho~land~ Amsterdam, 1980).
IS)
H. Arod;, Phys.
14)
L. D. Landau, J. Phys. U.S.S.R. IO (1946) 25; R. Balescu$ Statistical Mechanics of Charged Particles (Interscience, London, 1963).
Lett.
51 (1983) 351.
(private communication).
relativistic kinetic theory, New York, 1971).
in: Lecture
Relativistic
1168 (1982) 251.