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Inflation, Inflation, String String y y Landscape Landscape and Anthropic Principle and Anthropic Principle

Linde lecturesmunich3

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Page 1: Linde lecturesmunich3

Inflation, Inflation, StringStringyy LandscapeLandscapeand Anthropic Principleand Anthropic Principle

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Inflation in String TheoryInflation in String TheoryThe volume stabilization problem:

A potential of the theory obtained by compactification instring theory of type IIB:

The potential with respect to X and Y is very steep, these fields rapidly rundown, and the potential energy V vanishes. We must stabilize these fields.

Volume stabilization: KKLT constructionKachru, Kallosh, A.L., Trivedi 2003

X and Y are canonically normalized field corresponding to the dilaton fieldand to the volume of the compactified space; φ is the field driving inflation

Dilaton stabilization: Giddings, Kachru, Polchinski 2001

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Basic steps of the KKLT scenario:Basic steps of the KKLT scenario:

AdS minimumAdS minimum Metastable dS minimumMetastable dS minimum

1) Start with a theory with runaway potential discussed above2) Bend this potential down due to nonperturbative quantum

effects3) Uplift the minimum to the state with a positive vacuum

energy by adding a positive energy of an anti-D3 brane inwarped Calabi-Yau space

100 150 200 250 300 350 400s

-2

-1.5

-1

-0.5

0.5

V

100 150 200 250 300 350 400s

0.2

0.4

0.6

0.8

1

1.2

V

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It was never easy to discuss anthropicIt was never easy to discuss anthropicprinciple, even with friendsprinciple, even with friends……

But recently the concept of the string theoryBut recently the concept of the string theorylandscape came to the rescuelandscape came to the rescue

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String Theory LandscapeString Theory Landscape

Perhaps 10Perhaps 1010001000 different minima different minima

Bousso, Polchinski; Susskind; Douglas, Denef,…Bousso, Polchinski; Susskind; Douglas, Denef,Bousso, Polchinski; Susskind; Douglas, Denef,……

LercheLerche, Lust, Schellekens 1987, Lust, Schellekens 1987

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Two types of string inflation models:Two types of string inflation models:

Modular Inflation.Modular Inflation. The simplest class of models.They use only the fields that are already presentin the KKLT model.

Brane inflation.Brane inflation. The inflaton field corresponds tothe distance between branes in Calabi-Yauspace. Historically, this was the first class ofstring inflation models.

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Inflation in string theoryInflation in string theory

KKLMMT brane-anti-brane inflation

Racetrack modular inflation

D3/D7 brane inflation

DBI inflation (non-minimal kinetic terms)

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CMB and InflationCMB and InflationBlue and black dots - experimental results (WMAP, ACBAR)

Brown line - predictions of inflationary theory

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Predictions of Inflation:Predictions of Inflation:1) The universe should be homogeneous, isotropic and flat,

Ω = 1 + O(10-4) [Ω=ρ/ρ0]

2) Inflationary perturbations should be gaussian andadiabatic, with flat spectrum, ns = 1+ O(10-1). Spectral indexns slightly differs from 1. (This is an important prediction,similar to asymptotic freedom in QCD.)

Observations: perturbations are gaussian and adiabatic,with flat spectrum:

Observations: it is homogeneous, isotropic and flat:

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Tensor modes:Tensor modes:Kallosh, A.L. 2007

It does make sense to look for tensor modes even ifnone are found at the level r ~ 0.1 (Planck)

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The height of the KKLT barrier is smaller than |VAdS| =m23/2. The

inflationary potential Vinfl cannot be much higher than the height of thebarrier. Inflationary Hubble constant is given by H2 = Vinfl/3 < m2

3/2.

Constraint on H and r in this class of models:

H < m3/2

V

VAdS

Modification ofV at large H

STRING COSMOLOGY AND GRAVITINO MASSSTRING COSMOLOGY AND GRAVITINO MASS

Kallosh, A.L. 2004

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Tensor Modes and GRAVITINO

Superheavygravitino

A discovery or non-discovery of tensor modesA discovery or non-discovery of tensor modeswould be a crucial test for string theorywould be a crucial test for string theory

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Inflationary MultiverseInflationary MultiverseFor a long time, people believed in the cosmological principle,which asserted that the universe is everywhere the same.

This principle is no longer required. Inflationary universe mayconsist of many parts with different properties depending onthe local values of the scalar fields, compactifications, etc.

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Example: SUSY landscapeExample: SUSY landscape

V

SU(5) SU(3)xSU(2)xU(1)SU(4)xU(1)

Weinberg 1982: Supersymmetry forbids tunneling from SU(5) toSU(3)xSU(2)XU(1). This implied that we cannot break SU(5) symmetry.

A.L. 1983: Inflation solves this problem. Inflationary fluctuations bring us toeach of the three minima. Inflation make each of the parts of the universeexponentially big. We can live only in the SU(3)xSU(2)xU(1) minimum.

Supersymmetric SU(5)

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Landscape of eternal inflation Landscape of eternal inflation

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String Theory MultiverseString Theory Multiverse

Λ Λ < 0< 0

Λ Λ = 0= 0Λ Λ > 0> 0 and eternal old inflationand eternal old inflation

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Discrete and continuous parametersDiscrete and continuous parametersProperties of our world (local part of the universe) dependon 101000 discrete parameters (topological numbers,quantized fluxes, etc.), which describe our vacuum state.

Beyond the landscape: Our world may depend ona continuous set of parameters, which took differentvalues during the cosmological evolution far away fromthe vacuum state.

EXAMPLES:a) Axion field could take different values during inflation, which should

affect the local value of the density of dark matter.b) Affleck-Dine fields could take different values in different parts of the

universe, thus affecting the local value of the baryon asymmetry of theuniverse.

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Inflation and Cosmological ConstantInflation and Cosmological Constant

1) Anthropic solutions of the CC problem using inflation andfluxes of antisymmetric tensor fields (A.L. 1984), multiplicity of KK vacua(Sakharov 1984), and slowly evolving scalar field (Banks 1984, A.L.1986). We considered it obvious that we cannot live in the universe with

but the proof was needed for positive .

2) Derivation of the anthropic constraint Weinberg 1987; Martel, Shapiro, Weinberg 1997, …

4 steps in finding the anthropic solution of the CC problem:

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Inflation and Cosmological ConstantInflation and Cosmological Constant3) String theory landscape Multiplicity of (unstable) vacua:Lerche, Lust and Schellekens 1987: 101500 vacuum statesDuff, 1986, 1987; Bousso, Polchinski 2000

Vacuum stabilization and statistics: KKLT 2003, Susskind 2003, Douglas 2003,… perhaps 101000 metastable dS vacuum states - still counting…

4) Counting probabilities in an eternallyinflating universe (more about it later)

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Anthropic constraints on Anthropic constraints on Λ Λ Aguirre, Rees, Tegmark, and Wilczek, astro-ph/0511774

observed valueobserved value

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Dark EnergyDark Energy (Cosmological Constant) (Cosmological Constant)is about 74% of the cosmic pieis about 74% of the cosmic pie

Dark MatterDark Matter constitutes another 22% of constitutes another 22% ofthe pie.the pie. Why there is 5 times more darkWhy there is 5 times more darkmatter than ordinary matter?matter than ordinary matter?

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Example:Example: Dark matter in the axion field Dark matter in the axion fieldOld lore: If the axion mass is smaller than 10-5 eV,the amount of dark matter in the axion field contradictsobservations, for a typical initial value of the axion field.

Anthropic argument: Inflationary fluctuations make theamount of the axion dark matter a CONTINUOUS RANDOMPARAMETER. We can live only in those parts of theuniverse where the initial value of the axion field wassufficiently small (A.L. 1988).

Recently this possibility was analyzed by Aguirre, Rees, Tegmark, andWilczek.

Can we give a scientific definition of Can we give a scientific definition of ““typicaltypical”” ? ?

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Anthropic Constraints on Axion Dark MatterAnthropic Constraints on Axion Dark Matter Aguirre, Rees, Tegmark, and Wilczek, astro-ph/0511774

The situation with Dark Matter is even better than with the CC ! The situation with Dark Matter is even better than with the CC !

observed valueobserved value

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Problem:Problem: Eternal inflation creates infinitely many differentEternal inflation creates infinitely many differentparts of the universe, so we must compare infinitiesparts of the universe, so we must compare infinities

What is so special about our world?What is so special about our world?

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1.1. Study events at a given point, ignoring growth of volumeStudy events at a given point, ignoring growth of volume

Starobinsky 1986, Garriga, Vilenkin 1998, Bousso 2006, A.L. 2006Starobinsky 1986, Garriga, Vilenkin 1998, Bousso 2006, A.L. 2006

Two different approaches:Two different approaches:

2.2. Take into account growth of volumeTake into account growth of volume

A.L. 1986; A.L., D.Linde, Mezhlumian, Garcia-Bellido 1994;A.L. 1986; A.L., D.Linde, Mezhlumian, Garcia-Bellido 1994;

Garriga, Schwarz-Perlov, Vilenkin, Winitzki 2005;Garriga, Schwarz-Perlov, Vilenkin, Winitzki 2005; A.L. 2007 A.L. 2007

No problems with infinities, but the results depend on initial conditions.No problems with infinities, but the results depend on initial conditions.It is not clear whether these methods are appropriate for description ofIt is not clear whether these methods are appropriate for description ofeternal inflation, where the exponential growth of volume is crucial.eternal inflation, where the exponential growth of volume is crucial.

No dependence on initial conditions, but we are still learning how to doNo dependence on initial conditions, but we are still learning how to doit properly. I will review some recent progress.it properly. I will review some recent progress.

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V

BB1BB3

Boltzmann Brains are coming!!!Boltzmann Brains are coming!!!

Fortunately, Fortunately, normal brainsnormal brainsare created even fasterare created even faster, due, due

to eternal inflationto eternal inflation

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V

3

4 2 15

Problems with probabilitiesProblems with probabilities

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Time can be measured in thenumber of oscillations ( )or in the number of e-foldings ofinflation ( ). The universeexpands as

Unfortunately, the result depends on the time parametrization.

is thegrowth of volumeduring inflation

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t21t45

t = 0

We should compare the “trees of bubbles” not at the time when the treeswere seeded, but at the time when the bubbles appear

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If we want to compare apples to apples, instead of the trunksof the trees, we need to reset the time to the moment whenthe stationary regime of exponential growth begins. In thiscase we obtain the gauge-invariant result

As expected, the probability is proportional to the rate oftunneling and to the growth of volume during inflation.

A.L., arXiv:0705.1160

A possible solution of this problem:A possible solution of this problem:

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This result agrees with the expectation that theprobability to be born in a part of the universewhich experienced inflation can be very large,because of the exponential growth of volume

during inflation.

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Applications: Probabilities and the solution of theApplications: Probabilities and the solution of theCC problem in the BP landscapeCC problem in the BP landscape

The main source of volume of new bubbles is the tunneling from thefastest growing dS vacua with large vacuum energy towards theanthropic sphere with .

If the tunneling occurs sequentially, between the nearby vacua, theprocess typically moves us to a minor fraction of the anthropic spherewith one of the fluxes being much greater than all others. This allowssharp predictions. One of the predictions - vacuum decay few billionyears from now.

However, if the tunneling with large jumps is possible due to nucleationof large stacks of branes (which seems plausible during the tunnelingfrom the high energy dS vacua), then the probability distribution on theanthropic sphere becomes rather uniform, no doomsday.

Clifton, Shenker, Sivanandam, arXiv:0706:3201

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The cosmological constant problem is solved in this scenarioin either case (small or large jumps): the probabilitydistribution for the CC is flat and smooth near the anthropicsphere. It seems that the solution of the CC problem can beachieved with many different probability measures.

Predictions of other features of our world, includingstability/instability of our vacuum, depend on the propertiesof the landscape, on the possibility of the nucleation oflarge stacks of branes, on the proper choice of theprobability measure, and on the duration of the slow-rollstage of inflation.

Hopefully we will learn many new interestingthings before the next Biermann lectures…