¥Flatness Problem ¥INITIAL CONDITIONS SOLVES ALL!!brian/A3002/lect12.pdf · 2006. 10. 23. ·...
Transcript of ¥Flatness Problem ¥INITIAL CONDITIONS SOLVES ALL!!brian/A3002/lect12.pdf · 2006. 10. 23. ·...
History of the Universe - according to the
standard big bang
• Radiaton dominated era
• Matter dominated era
• Decoupling - CMB emission
• Star and structure formation
• Successes
– Explains redshifts
– Explains CMB
– Explains creation of the lightelements
• Flatness Problem– Why is the universe flat? Unless born flat, it should
gradually move away from Flatness in thematter/radiation era.
• Horizon Problem– Why is the CMB The same temperature in all
directions?
• Structure Problem– What seeded the structures we see today?
• INITIAL CONDITIONS SOLVES ALL!!– The universe started out perfectly flat
– The universe started out all the same temperature
– The universe started with the seeds of structure
The Big Bang: problems
Inflation
creates
initial
conditions
Flatness
• Friedmann’s Equation
• Rearranged, !tot = "/"crit
• Fine tuning
problem,most of way,
Radiation dominated.
2
2
2
3
8
a
kcGH
tot!= "
#
2
2
22
2
1a
kc
aH
kctot
&==!" !
"crit
=3H
2
8#G
60
2
10)1(
)1(!""
#
$%%&
'=
()
()
Planck
now
Plancktot
nowtot
a
a
( ) 2/1602/1
60
43
17
42
10x3
10x310x1
10x3
=!"
==
""
#
#
Planck
now
planck
now
tot
a
ata
s
s
t
t
aH $
Universe is 60 orders of magnitude less
Flat than it was at the Planck time!
Flatness
2
2
22
2
1a
Kc
aH
Kc
tot&
==!"
• Solved by accelerating expansion
(not just increase in size)
Events we can have seenEvents we will be able to see
t =0
tend
us distance
Objects we can see at a particular time
Lig
ht c
one
Eve
nt h
oriz
on
tim
e
Part
icle
hor
izon
Our Universe
Hubble Deep Field
Our Universe
0
Horizon Problem
!
What is the Horizon length at epoch of CMB?
(t =100,000yrs)
dhorizonproper
= dproperlight
=a0
adcomovinglight
dcomovinglight
=a0cdt
a(t) a(t) = a0(2H0t)
1/ 2
0
105yr
"
How big does this horizon appear now?
# =L
dAto horizon
=dhorizonproper
dAto horizon
dA =dproper
(1+ z)
dproperCMB to present
=a0
a(t0)dcomovingCMB$ present
=1a0cdt
a(t) a(t) = a0(
3
2H0t)
2 / 3
105yr
9.3x109yr
"
# =L
dAlight
% .5o
#
dA
L=dproper (Horizon)
!
Relevant Equations from Earlier On...
ds2
= (cdt)2 " a2(t)dr
2
1" kr2+ r
2(d# 2+ sin2#d$ 2
%
& '
(
) *
ds = 0,d# = 0,d$ = 0
cdt+ =a(t)dr
1" kr2
%
& '
(
) *
0
r
+ = a(t)r (flat case)
dcomovinglight
= a0r =a0cdt
a(t)+
dproperlight (t0,r) =
a
a0
dcomovinglight
dAlight
=dproperlight
(1+ z)
Structure
Structure
• Quantum fluctuations are the seeds of structure
• Quantum fluctuations produce real fluctuations when
virtual particle pairs find themselves separated by more
than a Hubble distance
If the Universe is exponentially expanding, then this can
happen quite a lot!
!
"t # h /"E
Conditions for inflation
• Need accelerated expansion for inflation
• Negative pressure will accelerate the expansion
• The cosmological constant has negative pressure
Scalar fields and their potentials
• In particle physics, a scalar field is used to represent spin zero
particles.
– It transforms as a scalar (that is, it is unchanged) under coordinate transfor-
mations.
– In a homogeneous Universe, the scalar field is a function of time alone.
– In particle theories, scalar fields are a crucial ingredient for spontaneous
symmetry breaking. The most famous example is the Higgs field whichbreaks the electro-weak symmetry, whose existence is hoped to be verifiedat the Large Hadron Collider at CERN when it commences experiments.
– Any specific particle theory (eg GUTS, superstrings) contains scalar fields. ・No fundamental scalar field has yet been observed. ・
What drives inflation?
• Scalar Fields
– A potential that depends on one parameter only.
– It can depend on position but does not have a direction
– e.g. temperature, or potentials…
• Usually represented V(!), and !(t) is assumed
homogeneous, and associated with a “inflaton”
!
""
""
!
"
"
pw
Vp
V
=
#=
+=
)(2
)(22
2
&
&
Reheating
• Inflation cools down the universe - some mechanism is
needed for reheating and particle creation
– Decay of the particle responsible for inflation might create a
wealth of particles and energy.
So What does Inflation give
us…• Inflation invented to solve how the Cosmic Microwave Background
is uniform in temperature without seemingly ever having been incausal contact.
• It naturally predicts that the Universe should be observed to beexactly flat. (It was sort of designed to do this too). This has beenmeasured now.
• Predicts that the seeds of structure should be ~gaussian and ~scaleinvariant (that means equal power on all logarithmic scales).- scale independent density fluctuations measured by COBE+2dF/WMAP
• Very little more that it can predict… So is it a matter ofphilosophy now, rather than science? Is the above enough?
See Liddle article on inflation for a more complete Story on thecourse website.