Holographic Cosmology - KICP Workshops · Holographic Cosmology Beyond Inflation Mark Trodden, U....
Transcript of Holographic Cosmology - KICP Workshops · Holographic Cosmology Beyond Inflation Mark Trodden, U....
Workshop: Status and Future of Inflationary Theory!University of Chicago, August 22-24, 2014
Holographic Cosmology Beyond Inflation?
Mark Trodden!University of Pennsylvania
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Questions
• To what extent should we worry about the initial conditions for inflation?!• How should we picture space, time, dimensions and field content prior to inflation?!• Within an effective field theory treatment, it may be that inflation requires
homogeneity over a large patch, or other unlikely conditions, to begin.!• This can make the probability low.!• If we have a UV complete theory (such as string theory) can we address this question?
Are there non-statistical answers? (Do we understand accelerating solutions even?)!• Possibly inflation itself can overcome this with sufficient volume enhancement.!• Expect (simple arguments; Dvali; Arkani-Hamed et al.) that there are
limits on the classical number of efolds. Does this affect this initial condition calculation?!
• Do we need eternal inflation?
Haven’t been thinking about inflation too much in recent years, but BICEP2 claim has rekindled my interest, like most people. Raises a number of old questions. !!Some are initial conditions questions (I’m surprised to see many people with related questions here):
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Eternal Inflation?
• Is eternal inflation a done-deal? Do we trust the naive intuition that it happens?!• In the usual picture, it involves a quantum fluctuation in the inflaton, up the
potential, over an extended region.!• When is this within the semiclassical approximation? (See Creminelli, Dubovsky,
Nicolis, Senatore & Zaldarriaga arXiv:0802.1067 [hep-th]).!• If not, is there a way to understand it within a Quantum Gravity model, such as
string theory? (Has implications beyond just the early universe).!• Recent evidence to the contrary in 1+1d (Martinec & Moore)!• How might we answer this generally?
q
V1
V2
V( )q
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Other Models?
• What do we really know about the space of theories that can simultaneously
• Solve the flatness and horizon problems?
• Generate the observed spectrum of density perturbations?
• Make predictions for upcoming measurements (such as B-modes)
Motivated by these questions, been trying to learn more about frameworks !in which might be useful to ask them. One possibility: holographic cosmology (using AdS/CFT).
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Possibilities for the Early Universe• When we think about early universe, we extrapolate GR coupled to sources back into
epochs of increasingly high curvature, and decreasing control.
• It is remarkable that we have fascinating possibilities to address our problems, and explain structure, such as inflation, in the regime in which we know how to calculate.
• Understanding the space of alternatives is difficult if we restrict ourselves to our perturbative, weakly-coupled description.
• Do we need the entire theory of quantum gravity to expand possibilities?
• One thing we’ve learned is that, in some cases, there exists a weak/strong coupling duality between gravity and field theory (AdS/CFT). Is there a way to use this to learn more?
• Obviously many people have considered this. One concrete proposal is to use the domain wall/cosmology connection (McFadden & Skenderis).
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Domain Wall Cosmology
Holographic!RG Flow
QFT (CFT)Cosmology
The domain wall/cosmology correspondence The AdS/CFT correspondence
Here, “domain wall” just means “having a radially-dependent profile in the bulk”.
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Domain Wall Cosmology
ds
2 = ⌘dz
2 + a(z)2�ijdxidx
j
In cosmology, used to seeing the metric
where and z representing the time coordinate.⌘ = �1
� = �(z)
⌘ = +1If we instead consider , then this describes a (Euclidean) “domain wall” (and if we made one of the x-coords timelike, it would be a Lorentzian one)
S = ⌘
Zd
4x
p|g|
� 1
22R+ (@�)2 + V (�)
�
So, for every flat FRW solution with potential V there exists a related domain-wall solution with potential −V
This holds, for both background solutions, and linear perturbations. These solutions their properties can then be, in principle, related to behavior of boundary field theory.
For inflationary cosmologies, has been used to relate power spectra and holographic 2-point functions (and, ultimately, higher-point functions).
[McFadden & Skenderis]
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
For Example
Asymptotically AdSDomain Walls
CFT w/ dual to scalar having a VEV
Asymptotically dSCosmology
The domain wall/cosmology correspondence The AdS/CFT correspondence
Different asymptotics & bulk slicings could probe (all?) other possible cosmologies
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Inflation
3M2PH = ⇢, ⇢ ⇡ cst
ds
2 = �dt
2 + e
Htd~x
2
so(1, 4) �! iso(3)
We think of inflation as a solution to GR coupled to a fluid or scalar field so that
with H approximately constant
If it was precisely de Sitter, then would have symmetry of dS group. But because quasi-dS, this is broken to the Poincaré algebra
We use the fact that the spaces are closely relateddS4, H4, AdS4
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Holographic Cosmology
ds2dS4=
H2
⌘2(�d⌘2 + �ijdx
idxj)
ds
2H4 =
L
2
z
2(dz2 + �ijdx
idx
j)
ds
2AdS4
=L
2
z
2(dz2 + ⌘µ⌫dx
µdx
⌫)
ds2dS4
L=iH,z=i⌘�������! ds2H4x1=ix0
����! ds2AdS4
O(1, 4) ���! O(1, 4) ���! O(2, 3)
�2 = 2M2P ✏
so(1, 4) �! iso(3)
These can be mapped into each other via
Corresponding symmetries
This allows us to model quasi-dS by a non-unitary Euclidean CFT deformed by relevant operators. In this picture, slow roll-parameters get related to field theory parameters; e.g.
Thus, in the boundary QFT (and hence in the bulk) this realizes the required pattern
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Can we Extend to Other Models?Are there dualities like this for any possible evolution of early universe? Might provide alternative way to probe uniqueness of inflation as solution to questions of early cosmos.
First example, is there a bulk (gravitational) dual to the Pseudo-Conformal Universe?
Works by SSB of conformal group in 4D to subalgebra isomorphic to dS isometries. Postulate early universe described by a CFT w/ scalar primary operators w/conformal dimensions in Minkowski space!!Assume operators develop t-dep VEVs of form
OI
�I
hOIi = cI(�t)�I
As required this breaks conformal group in 4D to subalgebra isomorphic to dS isometries.
so(2, 4) �! so(1, 4)
�1 < t < 0
Breaks down at late times near t=0, need reheating transition to radiation-domination
SSB pattern means spectator fields w/ vanishing conformal dimension acquire scale-invariant spectra
[K. Hinterbichler, J. Stokes and M.T., arXiv:1408.1955 [hep-th]]
[K. Hinterbichler & J. Khoury]
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
For duals to inflation, physics of interest is in bulk and dual is boundary CFT. Here, physics of interest is non-gravitational CFT on boundary, and dual is bulk gravitational theory.!!We’re constructing bulk dual to a CFT in the pseudo-conformal phase.
[arXiv:0909.0518]
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Holography of the PCU
so(2, 4) AdS5
so(2, 4) �! so(1, 4)
ds
2 = dr
2 + e
2r⌘µ⌫dx
µdx
⌫, L = 1, z = e
�r
Pµ = �@µ
Lµ⌫ = xµ@⌫ � x⌫@µ
Kµ = �x
2@µ + 2xµx
⌫@⌫ � z
2@µ + 2xµz@z
D = x
µ@µ + z@z
so(2, 4) �! iso(1, 3)
Pµ� = Lµ⌫� = 0 =) � = �(r)
We’re looking for a gravitational dual that realizes the breaking
Important point is, of course, that generators of and generators of are in one-to-one correspondence.
Start simply, with CFT in conformal vacuum. We know gravity dual is exact AdS space !
Killing vectors are!
If we turn on a constant VEV in the field theory, then this will break Bulk invariance under remaining symmetries then implies:!
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Which is in the slicing !
Domain Wall Cosmology for the PCU
ds
2 = dr
2 + e
2A(r)⌘µ⌫dx
µdx
⌫, � = �(r)
A(r) �! r r �! 1
x = t/z
Pi� = Lij� = D� = 0 =) � = �(x)
ds
2 =dx
2
x
2� 2
dx dt
xt
+1
t
2
⇥(1� x
2)dt2 + x
2�ijdx
idx
j⇤
ds
2 = d⇢
2 + sinh2 ⇢
�d⌘
2 + �ijdxidx
j
⌘
2
�
AdS5 dS4
So a constant VEV corresponds to a domain wall spacetime!
This will be asymptotically AdS if as!
Consider a VEV that breaks!so(2, 4) �! so(1, 4)
D, Pi, Lij , KiThere is a dS subalgebra of AdS, spanned by!
Metric can then be written!
Which can be diagonalized as!
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Penrose Diagrams
t = 0
t = 1
t = �1⌘ = �1
⌘ = 0
z=
0
z=1
⇢=
1
⇢=0
t = 0
t = �1
t = 1
Global AdS cylinder; dS slice coordinate region is bounded from above by lightcone running downward from t=0, and from below by slanted ellipse, also marking lower boundary of Poincaré patch (upper slanted ellipse is upper boundary of Poincaré patch).
2d slice down axis of AdS cylinder; thin lines are Poincaré lines of constant z and t, thick lines de Sitter slice lines of constant and⇢ ⌘
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Check
pi = �@i
jij = xi@j � xj@i,
ki = �~x
2@i + 2xix
j@j + ⌘
2@i + 2xi⌘@⌘
d = x
i@i + ⌘@⌘
K+ =
1
⌘
@⇢ + coth ⇢@⌘
K� =
1
⌘
(�⌘
2+ ~x
2)@⇢ + (⌘
2+ ~x
2) coth ⇢@⌘ + 2⌘ coth ⇢x
i@i
Ki =1
⌘
xi@⇢ + xi coth ⇢@⌘ + ⌘ coth ⇢@i
Killing vectors for in the slicingAdS5 dS4
pi , jij , ki , d generateso(1, 4)
� = �(⇢) =) pi� = jij� = ki� = d� = 0Ansatz preserves dS isometries
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
We want a domain wall with leaves in asymptotic !
Including Back-Reaction
ds2 = d⇢2 + e2A(⇢)ds2dS4, � = �(⇢)
S =
Zd
5x
p�g
1
4R� 1
2g
MN@M�@N�� V (�)
�+
1
2
Zd
4x
phK
V = �3 +1
2m2�2 +O(�3)
�00(⇢) + 4A0(⇢)�0(⇢) =@V
@�
3A0(⇢)2 � 3e�2A(⇢) =1
2�0(⇢)2 � V
More generally, a metric consistent with the unbroken symmetries is!
Where asymptotic AdS requires! A(⇢) ! log sinh ⇢ as ⇢ ! 1AdS5dS4
Action is!
Give scalar potential a negative extremum at the origin!
Background fields then obey!
-0.2 0.2 0.4 0.6 0.8 f-3.14-3.12-3.10-3.08-3.06-3.04-3.02-3.00
VHfL
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
�0(⇢) = ce�4A(⇢), A0(⇢)2 = 1 + e�2A(⇢) + be�8A(⇢)
u = e�2A(⇢)ds
2 =du
2
4u2(1 + u+ bu
4)+
1
u
�d⌘
2 + d~x
2
⌘
2
�b = c2/6
�(⇢) ' ↵+ �e�4⇢
0.0 0.5 1.0 1.5 2.0 2.5 3.0 r
2
4
6
8
10fHrL
0.5 1.0 1.5 2.0 2.5 3.0 r
-2
-1
1
2AHrL
Simplest thing we could do is merely to choose V=-3. EOMs become!
Metric can be written as!
Asymptotically:!
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
1-Point Functions etc.
Want to determine VEVs of the stress energy tensor and the operator dual to the scalar field.!!Correlation functions of gauge invariant operators can be extracted from asymptotics of bulk solutions.!!Or, given correlation functions of dual operators, can reconstruct asymptotic solutions. To perform holographic computations need some knowledge of structure of asymptotic solutions of field equations.
The holographic dictionary!!• There exists a 1-1 correspondence: local gauge invariant operators of boundary QFT
bulk modes. !• Bulk metric corresponds to energy momentum tensor of boundary theory.!• Bulk scalar fields correspond to scalar operators in boundary theory.!• Can obtain correlation functions of gauge invariant operators from
asymptotics of bulk solutions. !
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Fefferman-Graham Expansion
ds
2 =dz
2 + gµ⌫(x, z)dxµdx
⌫
z
2
gµ⌫(x, z) = g(0)µ⌫(x) + z
2g(2)µ⌫(x) + z
4g(4)µ⌫(x) + h(4)µ⌫(x)z
4log z
2+ · · · .
�(x, z) = �(0)(x) + z
4�(4)(x) + · · ·
he�Rd
4xO(x)�0(x)i = e�Istring[�0]
���on-shell
hOi = (4� 2�)�(4), hTµ⌫i = g(4)µ⌫
Any asymptotically AdS space admits expansion of form!
(massless scalar)!
The GKPW prescription is!
� = 2 +p
4 +m2
Dual operator marginal!
� = 4m=0!
Holographic renormalization (most of the paper) gives 1-point functions!
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
How Does This Work?
ds
2 =du
2
4u2(1 + u+ bu
4)+
1
u
�d⌘
2 + d~x
2
⌘
2
�
p1 + u+ bu
4 =tp
t
2 � z
2+ bf1(x) +O(b2)
⌘ =pt
2 � z
2 + bzf2(x) +O(b2)
f1(x) =xC1
(1� x
2)
3/2+
2 + 9x
2 � 6x
4 � 6x
2��1 + x
2�2
log
⇥�1 +
1x
2
⇤
8x (�1 + x
2)
7/2
f2(x) =1
4
p�1 + x
2
17� 42x
2+ 24x
4
6 (�1 + x
2)
3 � 4iC1
�1 + x
2+ 4C2 + 4 log
1� 1
x
2
�+
3 log
⇥�1 +
1x
2
⇤
�1 + x
2
!
Can put our metric!
in FG form. e.g. for b non-zero define!
with!
Then transformed metric is of FG form to leading order in b!
ds
2 =dz
2⇥1 +O(b2)
⇤+⇥�1 + bc3(x) +O(b)2
⇤dt
2 +⇥1 + bc4(x) +O(b)2
⇤d~x
2
z
2
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
FG Form Again
gtt(z/t) = �1 +b
8
⇣zt
⌘8+O �
(z/t)10�
g11(z/t) = 1� b
8
⇣zt
⌘8+O �
(z/t)10�
hTµ⌫i = 0
Form is fixed by unbroken O(1,4) symmetry!
Scalar equation is solved in FG coordinates by!
� = �(0) � c
4
⇣zt
⌘4+O �
(z/t)6�
� = 4Setting yields!
hOi = �4�(4) =c
t4
which is correct form required by O(1,4) symmetry:! hOIi = cIt�I
[N.B. similar to interface CFT’s which break using ]O(2, 4) ! O(2, 3) hOIi = cIy�I
Holographic Cosmology Beyond Inflation Mark Trodden, U. Penn
Conclusions & Comments• Have shown how to get a gravitational dual to one suggested alternative to inflation.!• Should also be possible to calculate other correlators (doing that now)
hO(x)O(y)i hTµ⌫(x)O(y)i hTµ⌫(x)T⇢�(y)i
• Ward identities (Justin’s talk) have been computed, should be able to check them.!• Admits a supergravity embedding. !• Could consider holographic dual to turning on 4D gravity in boundary theory. !
• Dynamical gravity could be incorporated in boundary by moving boundary slightly into bulk, to a cut-off surface. !
• Local counter-terms now regarded as finite kinetic terms for graviton.!• Was just an example of how dualities extend beyond the usual application to
inflation. A hope is that they might provide a route to understanding other possible early universe models.
See poster by James Stokes at COSMO-2014
Thank you for listening…!… and a big thank you to our organizers