Inflationary Massive Gravity

Similar documents
Misao Sasaki. KIAS-YITP joint workshop 22 September, 2017

Particle Astrophysics, Inflation, and Beyond

The Theory of Inflationary Perturbations

Zhong-Zhi Xianyu (CMSA Harvard) Tsinghua June 30, 2016

COSMIC INFLATION AND THE REHEATING OF THE UNIVERSE

Bispectrum from open inflation

PPP11 Tamkang University 13,14 May, Misao Sasaki. Yukawa Institute for Theoretical Physics Kyoto University

Holographic Model of Cosmic (P)reheating

Inflation, Primordial Black holes and Gravitational Waves

Inflation Daniel Baumann

Nonlinear massive gravity and Cosmology

Inflationary model building, reconstructing parameters and observational limits

Introduction to Inflation

Minimalism in Modified Gravity

Constraints on Inflationary Correlators From Conformal Invariance. Sandip Trivedi Tata Institute of Fundamental Research, Mumbai.

Testing the string theory landscape in cosmology

MASAHIDE YAMAGUCHI. Quantum generation of density perturbations in the early Universe. (Tokyo Institute of Technology)

Analyzing WMAP Observation by Quantum Gravity

Misao Sasaki YITP, Kyoto University. 29 June, 2009 ICG, Portsmouth

Cosmic Inflation Lecture 16 - Monday Mar 10

Could the Higgs Boson be the Inflaton?

Dilaton and IR-Driven Inflation

Inflation and the Primordial Perturbation Spectrum

Inflationary particle production and non-gaussianity

Observational signatures of holographic models of inflation

Stable violation of the null energy condition and non-standard cosmologies

Massive gravity and cosmology

From Inflation to TeV physics: Higgs Reheating in RG Improved Cosmology

Structures in the early Universe. Particle Astrophysics chapter 8 Lecture 4

Beyond N-formalism. Resceu, University of Tokyo. Yuichi Takamizu 29th Aug, 高知

Higgs field as the main character in the early Universe. Dmitry Gorbunov

Inflation, Gravity Waves, and Dark Matter. Qaisar Shafi

Oddities of the Universe

New Model of massive spin-2 particle

Higgs Inflation Mikhail Shaposhnikov SEWM, Montreal, 29 June - 2 July 2010

The multi-field facets of inflation. David Langlois (APC, Paris)

Exact Inflationary Solution. Sergio del Campo

INFLATION. - EARLY EXPONENTIAL PHASE OF GROWTH OF SCALE FACTOR (after T ~ TGUT ~ GeV)

Guido D Amico Center for Cosmology and Particle Physics New York University. Unwinding Inflation

State of the Universe Address

Anisotropic signatures in cosmic structures from primordial tensor perturbations

Scale symmetry a link from quantum gravity to cosmology

PAPER 71 COSMOLOGY. Attempt THREE questions There are seven questions in total The questions carry equal weight

Review of Small Field Models of Inflation

Graviton contributions to the graviton self-energy at one loop order during inflation

Aspects of Spontaneous Lorentz Violation

Will Planck Observe Gravity Waves?

School Observational Cosmology Angra Terceira Açores 3 rd June Juan García-Bellido Física Teórica UAM Madrid, Spain

Parity violation in the Cosmic Microwave Background from a pseudoscalar inflaton

Inflation. By The amazing sleeping man, Dan the Man and the Alices

Inflation and the origin of structure in the Universe

Cosmological perturbations in nonlinear massive gravity

Effects of the field-space metric on Spiral Inflation

Current status of inflationary cosmology. Gunma National college of Technology,Japan

Massive gravity and cosmology

Primordial perturbations from inflation. David Langlois (APC, Paris)

Nonsingular big-bounce cosmology from spin and torsion

CHAPTER 4 INFLATIONARY MODEL BUILDING. 4.1 Canonical scalar field dynamics. Non-minimal coupling and f(r) theories

The Concept of Inflation

Curvature perturbations and non-gaussianity from waterfall phase transition. Hassan Firouzjahi. In collaborations with

Cosmological Signatures of Brane Inflation

Why we need quantum gravity and why we don t have it

Evading non-gaussianity consistency in single field inflation

Patrick Peter. Institut d Astrophysique de Paris Institut Lagrange de Paris. Evidences for inflation constraints on alternatives

HIGGS-GRAVITATIONAL INTERATIONS! IN PARTICLE PHYSICS & COSMOLOGY

Astronomy 182: Origin and Evolution of the Universe

Closed Universes, de Sitter Space and Inflation

Primordial GW from pseudoscalar inflation.

HIGGS INFLATION & VACUUM STABILITY

Classical Dynamics of Inflation

Gravitational waves from the early Universe

Higgs field in cosmology

Symmetries! of the! primordial perturbations!

Open Inflation in the String Landscape

Cosmology meets Quantum Gravity?

Alternatives To Inflation. Jean-Luc Lehners MPI for Gravitational Physics Albert-Einstein-Institute

Stringy Origins of Cosmic Structure

POST-INFLATIONARY HIGGS RELAXATION AND THE ORIGIN OF MATTER- ANTIMATTER ASYMMETRY

Supergravity and inflationary cosmology Ana Achúcarro

Dissipative and Stochastic Effects During Inflation 1

Stephen Blaha, Ph.D. M PubHsMtw

(Gaussian) Random Fields

primordial avec les perturbations cosmologiques *

Observational signatures in LQC?

Naturally inflating on steep potentials through electromagnetic dissipation

Inflation and String Theory

Priming the BICEP. Wayne Hu Chicago, March BB

The primordial CMB 4-point function

PROBLEM SET 10 (The Last!)

Massive gravity and cosmology

Phenomenology of Axion Inflation

German physicist stops Universe

Effective Field Theories for Inflation

GRAVITATIONAL WAVES AND THE END OF INFLATION. Richard Easther (Yale)

Holographic Cosmology Beyond Inflation? Mark Trodden! University of Pennsylvania

4 Evolution of density perturbations

Higgs inflation: dark matter, detectability and unitarity

Cosmic Inflation Tutorial

Towards a new scenario of inflationary magnetogenesis. Shinji Mukohyama (YITP, Kyoto U) Based on PRD94, 12302(R) (2016)

Large Primordial Non- Gaussianity from early Universe. Kazuya Koyama University of Portsmouth

Transcription:

New perspectives on cosmology APCTP, 15 Feb., 017 Inflationary Massive Gravity Misao Sasaki Yukawa Institute for Theoretical Physics, Kyoto University C. Lin & MS, PLB 75, 84 (016) [arxiv:1504.01373 ] G. Domenech, T. Hiramatsu, C. Lin, MS, M. Shiraishi, Y. Wang, arxiv:1701.05554

Introduction

Inflation: the origin of Big Bang Brout, Englert & Gunzig 77, Starobinsky 79, Guth 81, Sato 81, Inflation is a quasi-exponential expansion of the Universe at its very early stage; perhaps at t~10-36 sec. It was meant to solve the initial condition (singularity, horizon & flatness, etc.) problems in Big-Bang Cosmology: if any of them can be said to be solved depends on precise definitions of the problems. Quantum vacuum fluctuations during inflation turn out to play the most important role. They give the initial condition for all the structures in the Universe. Cosmic gravitational wave background is also generated. 3

4 温故知新 (learning from the past) ds dt a ( t) dh ; ( 3) 1 a( t) H sinh Ht Creation of Open Universe! Now in the context of String Landscape

length scales of the inflationary universe log L L=H 0-1 Size of the Observable Universe 10 8 cm ~ 46 e-folds 10 8 cm LIGO band L=H -1 Inflationary Universe Bigbang Universe log a(t) 5

Planck constraints on inflation Planck 015 XX V scalar spectral index: n s ~ 0.96 tensor-to-scalar ratio: r < 0.1 simplest V model is almost excluded n s 1 d 3 log[ k PS ( k)] dlog k PT ( k) r P ( k) S 6

Current status scalar spectral index: n s <1 at ~ 5 s tensor/scalar ratio: r < 0.1 implies E inflation < 10 16 GeV simple, canonical models are on verge of extinction (m model excluded at > s) R (Starobinsky) model seems to fit best. But why? (large R correction but negligible higher order terms) f NL local <O(1) suggests (effectively) single-field slow-roll (but non-slow-roll models with f NL local =O(1) not excluded) some element of non-canonicality is needed 7

Massive Gravity? 8

Gauge theory: The idea of massive gravity Higgs VEV spontaneously breaks gauge symmetry Gravity: massive gauge field Spontaneous broken general covariance massive gravitons This assumes however Poincare symmetry on flat background. If no background, covariance should NOT be violated. E Spontaneous broken local Lorentz invariance = existence of a preferred frame drgt gravity Boulware-Deser (BD) ghost must be removed spin = ++1 (+1) dof (tensor+vector+scalar) massive tensor modes! (helicity ) 9

4 scalar (Stuckelberg) fields: Dubovsky s model a 0 i (, ) Dubovsky 004 ( a) ( b) ( a) ( a) a ( b) a ds abe e dx dx e e b x e b SO : ( ), ( 31, ) VEV spontaneously breaks local SO(3,1) symmetry a ( a) a a ( a) a e : x e x required symmetry (Poincare symmetry is not imposed) i i j i i i 0 i, ( ); global ( 3) action: j j SO MP 4 ij S d x R mg f ( X, Z ) X g g N 0 0 00 Lapse fcn. g g Z g h X 0 i 0 j ij i j ij only 0 +1 dof (tensor+scalar) 3-metric becomes dynamical 10

Inflationary massive gravity: minimal model 0 Identify with inflaton: 0 ij ij 4 M 1 9 ( ) ( ) Z Z P S d x R g V MPmg 8 Z ik kj Z Z Z Z 3 ; Z Z Z mg H during inflation assumption: 1 mg during reheating Symmetry: ij ij ii i i j i i i j, ; j global SO( 3), const. These symmetries guarantees i to be non-dynamical. x : w ( t) x v( t) x O( 1 ), w w i i i i ij j i ij ji at leading order in gradient expansion 11

notes on non-dynamical modes helicity 1 and traceless helicity 0 modes (=3 NG bosons) at leading order on spatially flat slicing (~ decoupling limit) 9 4 j 1 i 4 i S m ( ) gm P d x i i O M P k 4 3 i i i 4 x mm : cutoff scale become dynamical at higher orders S d x g g Z Z ~ k ( ) 4 ij ij i rescaling: i i k 4 i i S d x ( ) ( ) g P H massive enough: can be integrated out 1

massive tensor perturbation tensor nd order action S M ( ) P 3 3 T d x dt a ( ij ) m ( ) g ij 8 quantization eom k a 3 dk ij 3 ij k s ( ) k k () t k ikx a(, s) e (, s) ( t) e h. c. / a( k, s) : e ij ( k, s) : : positive frequency fcn. annihilation operator polarization tensor e ( k, s) e ij ( k, s) k a * * k 3H k mg 0 : k k k k k 3 ij ss i a KG normalization 13

during inflation P T ( k) tensor spectrum H M P spectral index: Lyth bound r if r if m g 3H 0 mg H k k f n T g / H m 3 at the end of inflation k a( t ) H( t ) f f f mg ; 3H, blue-tilted! H H 1 / 15 MPr : distance traveled by during inflation P P T S ( k) ( k) 0. 001, 16 for standard slow-roll inflation travels more than Planck distance beyond validity of QFT? 14

Observational Signatures? 13

resonant GW amplification Lin & MS 15 3/ 1 a f Mt mg ; f sin( Mt ) e after inflation a M : inflaton mass M : decay (reheating) rate Mathiew-like eq. for k/a << H < m g k a 3 ( ) k H k mg 0 k 0 dx x dx x x d d e sin ( x) k x Mt, broad parametric resonance for f 3 M Mx e 1 x 0 16

broad parametric resonance amplified by a factor ~ 10 6! f 3 M 6 10, 0. 05 17

parameter dependence 18

evading Lyth bound tensor perturbation can be exponentially amplified by broad parametric resonance: P ( k) AP ( k); T T,0 A 1 scalar (curvature) perturbation remains the same: P ( k) P ( k) S r S,0 P P T S ( k) 16 A ( k) Lyth bound is modified as 15M P r A tensor perturbation can be large enough to be detected without invalidating low-energy EFT 19

non-gaussianity? Domenech, Hiramatsu, Lin, MS, Shiraishi & Wang 17 3 rd order Hamiltonian in =0 spatially isotropic gauge: H L M d x a 3-pt fcn: 3 int int SST P ij i c SST m g 4 H coupling term that could appear in lowenergy EFT from (unknown) UV physics i c ij i j Z 4 s s 3 ( 3) S ST H ij i 3j i j i j k1k k3 ( ) k1 k k 3 ki k 4 3 t 4 M P k i kt kt e k k dominates CMB 3-pt fcn if SST >> 1 kk k k k k t 1 3 0

scale-dependent non-gaussianity TTT ij a ij i c j c 1 after horizon re-entry small scale modes re-enters horizon earlier large l multipoles are suppressed max dependence of f local NL SST 100, 0. 01 1

WMAP 010/Planck 015 f f local NL local NL 3 1 for 500 WMAP 010 max 0. 8 5. 0 for 500 Planck 015 max non-g from SST (arbitrary scale)

more from Planck 015/other shapes a hint of non-g due to SST but not yet conclusive non-g from SST 3

Summary Inflation is a natural platform for modified gravity Inflation = scalar-tensor theory GW (tensor mode) can become massive during inflation without encountering BD ghost problem symmetry: i i j, i i ; i j j SO( 3), const. GW can be parametrically amplified during reheating evading Lyth bound even if r > 0.001 GW spectrum may be blue-tilted primordial GW may be detectable by LIGO/Virgo/KAGRA 3 rd order interaction can give rise to sizable scale-dependent non-gaussianity E already a hint in WMAP/Planck data needs further tests! 4

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback