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Non-congruence of liquid-gas phase transition of asymmetric nuclear matter
T. Maruyama (JAEA) & T. Tatsumi (Kyoto U)
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• Mixed phase at first-order phase transitions. • Its non uniform structures. • Its equation of state.
T. Maruyama, N. Yasutake and T. Tatsumi, Prog. Theor. Phys. Suppl. 186, 69 (2010)
T. Tatsumi, N. Yasutake, T. Maruyama, arXiv:1107.0804
M. Okamoto, T. Maruyama, K. Yabana, T. Tatsumi, arXiv:1106.3407
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Phase transitions in nuclear matter
In stellar objects, there are many phase transitions considered:
liquid-gas, neutron drip, meson condensation, hyperon mixture,
quark deconfinement, color super-conductivity, etc.
Some of them are the first-order mixed phase
EOS of mixed phase
• Single component congruent
(e.g. water)
Maxwell construction satisfies the
Gibbs cond. TI=TII, PI=PII, mI=mII.
• Many components non-congruent
(e.g. water+ethanol)
Gibbs cond. TI=TII, PiI=Pi
II, miI=mi
II.
No Maxwell construction !
• Many charged components (nuclear matter)
Gibbs cond. TI=TII, miI=mi
II.
No Maxwell construction !
No constant pressure !
r
rU
dr
dP iii
;
3
129Xe + Sn at 50 MeV/u AMD A.Ono et al. PRC 66, 014603(2002)
Collision Hot matter Gas Cool down Free nucleons
+ Liquid clusters
First-order phase transition mixed phase. Clustering of low-density nuclear matter may be the result of mixed phase.
• Multi fragmentation in heavy-ion collisions
Liquid-gas phase transition at T>0
dilute phase + dense phase (fragments)
Formation of
fragments
Finite system
Mechanical instability is important !
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Depending on the density, geometrical structure of mixed phase changes from droplet, rod, slab, tube and to bubble
configuration. [Ravenhall et al, PRL 50 (1983) 2066]
•Matter in the collapsing stage of supernova
Liquid-gas phase transition at T>0
dilute phase + dense phase
• Neutron star crust
Neutron drip at T~0
neutron phase + nuclear phase
Formation
of “Pasta”
structures
Macroscopic system (matter in the stellar objects)
Chemical instability
Mechanical & chemical instability
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Stability condition
3 3
3
2
2
2 2
2
3
2 2
2
3 3
,
0
0
p n p n
f P
f
f f
f f
m m
Mechanical stability + chemical stability (congruence)
,
, ,
0
0, or 0
pT Y
p n
p pT P T P
P
Y Y
m m
Theoretical model for nuclear matter
Relativistic Mean Field (RMF) model: Lorentz-covariant Lagrangian L with baryon densities, meson fields , , , electron density and the Coulomb potential, is determined.
Local density approx for Fermions: Thomas-Fermi model for baryons and electron
Consistent treatment for potentials and densities: Coulomb screening by charged particles
[T.M. et al,PRC72(2005)015802; Rec.Res.Dev.Phys,7(2006)1]
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* 3
2 2 2 2 2
*
1
2
1 1 1 1 1 1( ) ( )
2 2 4 2 4 2
1(
4
1, ( )
3
,
,
, )
N M e
N N N N
M
e e e e
N N N
L L L L
L i m g g b e V
L m U m R R m R R
L V V i m e V F F F
m m g U bm
m m m mm m m m
m m m mm m m m m
m m mm m m m m m
3 41( ) ( )
4N N Ng c g
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Choice of parameters -- Properties of uniform matter and nuclei--
Symmetric matter:
Energy minimum at B=0.16 fm3
and E/A=16 MeV
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Bulk calculation of phase coexistence in nuclear matter
Gibbs conditions:
TI=TII
PiI=Pi
II
miI=mi
II. should be fulfilled
among two nuclear
matter with different
densities.
coexistence curve
bary
on p
ressure
proton fraction
Results ---
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Bulk calculation of phase coexistence in nuclear matter
When the system enters the forbidden region, it
splits into 2 phases with different components.
Gibbs conditions:
TI=TII
PiI=Pi
II
miI=mi
II. should be fulfilled
among two nuclear
matter with different
densities.
coexistence curve
forbidden
proton fraction
bary
on p
ressure
Results ---
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Yp-PB phase diagram of matter
congruent
non congruent
non congruent
Yp Dependence of the Congruence
• Symmetric nuclear matter is congruent and
has constant value of Yp=0.5.
Maxwell construction.
• In general cases, liquid and gas phases are
not congruent and have different values of Yp.
• In the case of small Yp, the retrograde
transition (gas-mix-gas) may occur.
But by surface tension and the Coulomb
interaction, it might be suppressed.
how 2 phases are
chemically same.
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Symmetry-potential dependence of phase-coexistence curve
Narrower region with
weak symmetry-potential.
Strong attraction
between p and n
non-congruence of
nuclear matter
Only symmetric nuclear
matter can be congruent.
(normal x 0.1)
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Temperature dependence of the phase-coexistence curve
At higher temperatures, the region of
mixed phase becomes narrow, and
the congruence is enhanced.
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2 2 ( ) ( )
2 20 0
2 20 0
2 2ch ch
( ) ( ) ( ) ( ( ) ( )),
( ) ( ) ( ( ) ( )),
( ) ( ) ( ( ) (
From 0, ( , , , , ),
)),
( ) 4 ( ), ( (
( )
) ( )
s sN n p
N p n
N p n
C p
dUm g
d
m g
R m R g
V e
R V
m m m
mm
r r r r r
r r r r
r r r r
r r r r
L L
( ))e r
12 * 2
,
1
3 3
,3 30 0
( ; , ) 1 e
For fermions, we em
xp ( ) ( ) ,
( ; , ) 1 exp ( ( ))
( ) 2 ( ; , ), ( ) 2 ( ;(
ploy Thomas-Fermi
2 ) (
approx. at finite
2 )
i n p i N i
e e e C
e e e i p n i
T
f p m T
f p V T
d p d pf f
m
m m
m
r p r r
r p r
r r p r r p
0 0 0 0
, )
( ) ( ) ( ), ( ) ( ) ( ) ( ),
i
n n N N p p N N Cg g R g g R V
m
m m r r r r r r r
Chemical equilibrium fully
consistent with all the density
distributions and fields.
EOM to be solved
Mixed phase with finite-size effects (“pasta” matter)
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Numerical calculation of mixed-phase
• Assume regularity in structure: divide whole space into equivalent and neutral cells with a geometrical symmetry (3D: sphere, 2D : cylinder, 1D: plate). Wigner-Seitz cell approx. • Give a geometry (Unif/Dropl/Rod/...) and a baryon density B. • Solve the field equations numerically. Optimize the cell size (choose the energy-minimum). • Choose an energy-minimum geometry among 7 cases (Unif (I), droplet, rod, slab, tube, bubble, Unif (II)).
WS-cell
Density profiles in WS cell
Pasta structures in matter (case of fixed Yp)
Yp=0.5 T=0
Yp=0.1 T=0
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In the case of symmetric (Yp=0.5)
nuclear matter,
p(r) and n(r) are almost equal.
e(r) is approximately independent.
p & n are congruent.
Maxwell construction may be
possible for pn matter with uniform e.
But baryon and electron are not
congruent.
Maxwell constr. of pne matter is
impossible.
Yp=0.5 T=0
Case of symmetric nuclear matter
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Yp=0.1 T=0
In the case of asymmetric (Yp<0.5)
nuclear matter,
p(r) and n(r) are different.
e(r) is approximately independent.
p & n are non-congruent
Maxwell constr does not satisfy
Gibbs cond.
Case of asymmetric nuclear matter
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EOS with pasta structures in nuclear matter at T 0
Symmetric matter Yp=0.5
Asymmetric matter Yp=0.3
Pasta structure appear at T 10 MeV
coexistence region (Maxwell for Yp=0.5 and bulk Gibbs for Yp<0.5) is meta-
stable. Uniform matter is allowed in some coexistence region due to finite-size
effects.
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EOS with pasta structures in nuclear matter at T 0
Symmetric matter Yp=0.5
Asymmetric matter Yp=0.3
Pasta structure appear at T 10 MeV
coexistence region (Maxwell for Yp=0.5 and bulk Gibbs for Yp<0.5) is meta-
stable. Uniform matter is allowed in some coexistence region due to finite-size
effects.
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Summary
We have studied liquid-gas phase transition of nuclear matter. [Bulk calculation] •The non-congruence of nuclear matter comes from strong symmetry potential. • Symmetric nuclear matter behaves like single-component matter, while asymmetric matter does not. [Considering matter structures] • Pasta structures appear in liquid-gas transition. • The region of pasta is narrower than the phase-coexistence region due to the finite-size effects (surface and Coulomb).
Future
• More understanding of pasta matter in stellar objects. • Its implications to stellar phenomena.
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Pasta structures at T=10 MeV vs T=0
Mixed phase of liquid
and gas.
The surface is more
vague than T=0 case.
weaker surface
tension
smaller size
Electron distribution is
more uniform.
less screening
smaller size
T=10 MeV T=0
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