is produced in the big bang and is present today in sufficient numbers to ..... of the early Universe offer a possible mechanism for the generation of the baryon ...
Fermi National Accelerator
Laboratory FERMILAB-Conf-85119-A January 1985
PRODUCTION OF INOS IN THE BIG BANG Edward W. Kolb Theoretical Astrophysics National Accelerator Laboratory Batavia, IL 60510 U.S.A.
Fermi
Astronomy and Astrophysics The University of Chicago Chicago, IL 60637 U.S.A.
ABSTRACT The
production
("ino")
is
numbers
to contribute
of
production
I.
produced
dark
in the
in
the
possibility
that
big
bang and is
present
mass density
is
illustrated
with
axions
big
bang
some elementary
overall
matter
the
today
in
particle sufficient
of the Universe several
is
in the The
examples.
and baryons
are covered
of galaxies
reveals
in detail.
INTRODUCTION
component
of
of the the
structure
total not
the
of the
local
larger
vicinity
systems,
clusters
of galaxies,
by Universities
Research
galaxy
in galactic
Only
such as
of the
mass
seems to be present
Operated
particles
to the
of neutrinos,
The study
s
elementary
In particular,
discussed.
form
of
solar
system.
binary
Association
in the
that
halos,
small Universe
Inc. under contract
presence
but
also
in the disk
is also
groups
of
a
Dark matter
is dark.
Dark matter
galaxies,
and perhaps
the
of
as a whole.
present
in in
galaxies, 1.1
with the United States Department
01 Energy
2 It
is not
solution.
It
the
dark
clear
in
baryons,
clusters
be
interest
in the
the
of the
In this in
the
given
paper
big
for
pyrgons
the particles mass the and
if
is
been remarkably In this Universe. of the
big
candidates since will ino
it then
in
in Table
neutrinos
I
and
range
same than
the
dark
clear
whether
jupiters,
etc.
cosmological
of
dark
particle,
matter
or ino,
iS
which
review
I.
I will
that
baryons
neutrinos,
since
in Table of about fact
iS
the
are
examples
I will of
of fact
of the from
masses
ino
physicists
inos
from
have
the
of
then "hot"
early
standard
model
several
to do with baryons,
the
in
the production
have something than
to
One striking
of
production
other
axions
inos.
results
review
are
fraction
particle
production
first
matter
abundances
33 in possible
is that
the
for
The relic
I. 10
particles
ino dark
10 -5eV
candidate
we know exists.
axions
for
from
some general discuss
of elementary
a significant
in providing
will
Table
I that
component
candidates
given
striking
reviewing
discuss
not
holes,
monopoles.
is a range
I will
is obvious
is also
the production
masses
are also
generous
bang,
than
Of particular
of some elementary
discuss
Another
After
matter.
the
is different
different
It
some
have
disk
black
are to contribute
there
paper
dark
or Kaluza-Klein
they
abundances.
is
etc.
that
Possible
that
in the
in turn
Some proposed
of the Universe table
problems
bang.
bang."* I.
matter
of primordial
of the
I will
in Table
1028eV
form
form
big
dark
matter
galaxies,
all)
in the
dark
which
possibility
non-baryonic, a remnant
the
of
some (or is
the
in the halo,
either
could
all
may be that
matter
matter
if
they
discuss and tqcold"
of
the
of baryons, galaxies. are
I
the only
axiOnS. dark
The matter
respectively. TABLE I SOME IN0 CANDIDATES FOR DARK MATTER Candidate
Present Abundance
Mass
Axion Neutrinos Gravitino/Photino
10m5eV
10gcm -3
1OeV
lO*cm -3
1 03eV
1 cme3
1O'eV
10+cme3
Sneutrino/Photino
1OlleV
10~'cm -3
GUT Monopoles
1 Oz5eV
1 0-22cm-3
1028eV
10-25cm-3
Baryons
Pyrgons/K.-K.
II.
Monopoles
THE BIG BANG MODEL Although
structure
is
the
structure
seems
scales,
background. they
are correlated.
two-point excess F,(r)
Galaxies
correlation probability galaxies
>> 1,
distributed
as spread
r.
If
that
P,(r)
E(r)
MN, where MN is
the
if
it
the Universe
the
falls
of the Universe
3.2 0'
Universe
the baryon
nucleon number,
from matter
this
Furthermore,
when the
temperature If
mass. nN = ni,
we
number density
is
of would
when T me, the cross
a(e+e-
++
V.“. 1-1)
where G is Fermi’s F electrons
iS
the
neutrino
section
for
family,
e,~,
neutrino
or T (or
production
possibly
more).
is
= G;E2
(4.1)
constant.
given
When
by ne - T3,
E
>
so the
me,
the
production
number rate
density
of
of neutrinos
is
(EST)
r
This T2/m
P
= no = T3G2E2 = GgT* F
rate
is
to be compared
.
(4.2)
with
the
expansion
rate
of the Universe
TE =
Pl
- rP rE
= G2T3m F Pl (4.3) = O(1)
When
the
[T/1MeV13
temperature
iz much greater
than
they
are destroyed.
rest
of the matter
Universe
iz
neutrinos
“freeze
equilibrate
less
with
.
of the Universe
is greater
than
about
one and neutrinos
interact;
they
are
The neutrinos in
the
than out.” the rest
would
Universe.
about After
1 MeV,
freeze-out
of the Universe.
then
1 MeV, fP/rE created
be in equilibrium
When
the
they
no
with
the
of
the
temperature
!YP/rE is much less longer
A more detailed
and
than
one and
interact calculation
and
18 can be done by solving neutrino
annihilation
If at
Eq. crosz
we azsume that
freeze
at freeze
out
(T=T~)
number density
(3/4)
The
at freeze
because
T; = (3/4)
neutrinos density
entropy
in e+e-
(since
neutrino
haz
a fraction
Rvi = 0.01
If
h = l/2,
fivi
5 1, then
the present
relativistic
(plus
antineutrinos)
(4.4)
and n y is the number
pairs
nvo,
is
a
mazz
of the
is
mvi,
closure
density
by a factor
decoupled). (per
The
into
of
photons
but the
Therefore
not
number
family)
.
then
(4.5)
the
relic
neutrinos
would
density
(4.6)
The limit
bounds
e+e-
(11/4)“3
.
mvi as low as 25eV could mvi ( 100h2eV.
annihilation.
converted
nYo = 110cmm3
(mvi/eV)hm2
experimental
e+etemperature
have
today,
(4/11)
contribute
total
ny
before
neutrinos
“0 = (314)
the
be
will
of neutrinos
neutrinos
the neutrino
of neutrinos
n
If
decouple
increases the
the
out.
neutrinos
annihilation
oA[vl
be
where we have assumed 2-component of photons
with
neutrinos 4.1
section.
would
n v = (s(3)/n2)
for
mu tu)
important
physics
usual
the
theory
of strong
interactions,
QCD, it
is possible
to add to
Lagrangian
Lo = -(l/4)
G,:
Gap”
,
(5.1)
20 where G a = a Aa - a Aa ilv
Le = (e/32~~~)
pu
where express can
L
is e
the
be discarded
odd
under
contribution
(W32r2)
There
L e has the
coup1 ing
form
it
can have physical
- eE’*8’, it
neutron
electric
dipole
dipole
e
a contribution
the
than
of
the
due to
P and T, hence L8 term would
be a
moment.
The fact
of order
10 -19 e cm requires
to 8. The quarks
a vacuum expectation the
quarks
to have the
that
the
iz
value
neither
mass
real
matrix
receive
