The Cosmic Microwave Background

Slides:

Advertisements

Similar presentations

Observational constraints on primordial perturbations Antony Lewis CITA, Toronto

Advertisements

Primordial perturbations and precision cosmology from the Cosmic Microwave Background Antony Lewis CITA, University of Toronto

Anisotropies of Cosmic Microwave Background and Its Polarization A New & Ultimate Tool for Cosmology and Particle Physics Naoshi Sugiyama Nagoya University.

Planck 2013 results, implications for cosmology

Observational Cosmology - a laboratory for fundamental physics MPI-K, Heidelberg Marek Kowalski.

CMB?. 1. Espectro de la RCF 2. Anisotropías de la RCF.

Cosmological Structure Formation A Short Course

The Physics of the cosmic microwave background Bonn, August 31, 2005 Ruth Durrer Départment de physique théorique, Université de Genève.

COSMOLOGY AS A TOOL FOR PARTICLE PHYSICS Roberto Trotta University of Oxford Astrophysics & Royal Astronomical Society.

Observational Cosmology - a unique laboratory for fundamental physics Marek Kowalski Physikalisches Institut Universität Bonn.

Is the Universe homogeneous and isotropic? Marc Kamionkowski (Caltech) Tsvi-fest, 17 December 2009 Statistically.

Å rhus, 4 September 2007 Julien Lesgourgues (LAPTH, Annecy, France)

Curvature Perturbations from a Non-minimally Coupled Vector Boson Field Mindaugas Karčiauskas work done with Konstantinos Dimopoulos Mindaugas Karčiauskas.

Lecture 2: Observational constraints on dark energy Shinji Tsujikawa (Tokyo University of Science)

Dark Energy Cosmology INPE Winter School September 12-16, 2005 Robert Caldwell Dartmouth College.

José Beltrán and A. L. Maroto Dpto. Física teórica I, Universidad Complutense de Madrid XXXI Reunión Bienal de Física Granada, 11 de Septiembre de 2007.

The Curvature Perturbation from Vector Fields: the Vector Curvaton Case Mindaugas Karčiauskas Dimopoulos, Karčiauskas, Lyth, Rodriguez, JCAP 13 (2009)

The Statistically Anisotropic Curvature Perturbation from Vector Fields Mindaugas Karčiauskas Dimopoulos, MK, JHEP 07 (2008) Dimopoulos, MK, Lyth, Rodriguez,

CMB as a physics laboratory

Constraints on the Primordial Magnetic Field and Neutrino Mass from the CMB Polarization and Power Spectra G. J. Mathews - University of Notre Dame D..

The Statistically Anisotropic Curvature Perturbation from Vector Fields Mindaugas Karčiauskas Dimopoulos, Karčiauskas, JHEP 07, 119 (2008) Dimopoulos,

1 What is the Dark Energy? David Spergel Princeton University.

Probing Dark Matter with the CMB and Large-Scale Structure 1 Cora Dvorkin IAS (Princeton) Harvard (Hubble fellow) COSMO 2014 August 2014, Chicago.

Program 1.The standard cosmological model 2.The observed universe 3.Inflation. Neutrinos in cosmology.

Physics 133: Extragalactic Astronomy and Cosmology Lecture 14; March

NEUTRINO MASS FROM LARGE SCALE STRUCTURE STEEN HANNESTAD CERN, 8 December 2008 e    

Based on Phys.Rev.D84:043515,2011,arXiv: &JCAP01(2012)016 Phys.Rev.D84:043515,2011,arXiv: &JCAP01(2012)016.

Dynamical Dark Energy. What is dynamical dark energy ?

Different physical properties contribute to the density and temperature perturbation growth. In addition to the mutual gravity of the dark matter and baryons,

Early times CMB.

Cosmology from CMB Dmitry Pogosyan University of Alberta Lake Louise, February, 2003 Lecture 1: What can Cosmic Microwave Background tell us about the.

Academic Training Lectures Rocky Kolb Fermilab, University of Chicago, & CERN Cosmology and the origin of structure Rocky I : The universe observed Rocky.

Dark energy I : Observational constraints Shinji Tsujikawa (Tokyo University of Science)

Cosmic Microwave Background  Cosmological Overview/Definitions  Temperature  Polarization  Ramifications  Cosmological Overview/Definitions  Temperature.

Relic Neutrinos, thermal axions and cosmology in early 2014 Elena Giusarma arXiv: Based on work in collaboration with: E. Di Valentino, M. Lattanzi,

The Cosmic Microwave Background Lecture 2 Elena Pierpaoli.

CMB observations and results Dmitry Pogosyan University of Alberta Lake Louise, February, 2003 Lecture 1: What can Cosmic Microwave Background tell us.

27 th May 2009, School of Astrophysics, Bertinoro Daniela Paoletti University and INFN of Ferrara INAF/IASF-Bologna Work in collaboration with Fabio Finelli.

Probing fundamental physics with CMB B-modes Cora Dvorkin IAS Harvard (Hubble fellow) Status and Future of Inflationary Theory workshop August 2014, KICP.

Constraints on Dark Energy from CMB Eiichiro Komatsu University of Texas at Austin Dark Energy February 27, 2006.

NEUTRINO COSMOLOGY STEEN HANNESTAD UNIVERSITY OF AARHUS LAUNCH WORKSHOP, 21 MARCH 2007 e    

Lecture 5: Matter Dominated Universe: CMB Anisotropies and Large Scale Structure Today, matter is assembled into structures: filaments, clusters, galaxies,

The Theory/Observation connection lecture 2 perturbations Will Percival The University of Portsmouth.

University of Durham Institute for Computational Cosmology Carlos S. Frenk Institute for Computational Cosmology, Durham Galaxy clusters.

Weighing neutrinos with Cosmology Fogli, Lisi, Marrone, Melchiorri, Palazzo, Serra, Silk hep-ph , PRD 71, , (2005) Paolo Serra Physics Department.

Michael Doran Institute for Theoretical Physics Universität Heidelberg Time Evolution of Dark Energy (if any …)

Results from Three- Year WMAP Observations Eiichiro Komatsu (UT Austin) TeV II Particle Astrophysics August 29, 2006.

Cosmic Microwave Background Carlo Baccigalupi, SISSA CMB lectures at TRR33, see the complete program at darkuniverse.uni-hd.de/view/Main/WinterSchoolLecture5.

Primordial fluctuations 20  Isotropic 3K background. The most perfect blackbody we know Dipole (3.4 mK). Our motion relative to CMB.

JPL, 12 April 2007 Discovering Relic Gravitational Waves in Cosmic Microwave Background Radiation L. P. Grishchuk Cardiff University and Moscow State University.

Cosmological aspects of neutrinos (III) Sergio Pastor (IFIC Valencia) JIGSAW 2007 TIFR Mumbai, February 2007 ν.

Basics of the Cosmic Microwave Background Eiichiro Komatsu (UT Austin) Lecture at Max Planck Institute August 14, 2007.

The Planck Satellite Matthew Trimble 10/1/12. Useful Physics Observing at a redshift = looking at light from a very distant object that was emitted a.

Neutrino Cosmology and Astrophysics Jenni Adams University of Canterbury, New Zealand TexPoint fonts used in EMF. Read the TexPoint manual before you delete.

Cosmology : a short introduction Mathieu Langer Institut d’Astrophysique Spatiale Université Paris-Sud XI Orsay, France Egyptian School on High Energy.

Understanding the CMB Neutrino Isocurvature modes S. MUYA KASANDA School of Mathematical Sciences University of KwaZulu-Natal Supervisor: Dr K. Moodley.

Cosmological aspects of neutrinos (II) Sergio Pastor (IFIC Valencia) JIGSAW 2007 TIFR Mumbai, February 2007 ν.

Wilkinson Microwave Anisotropy Probe (WMAP) By Susan Creager April 20, 2006.

Cosmological constraints on neutrino mass Francesco De Bernardis University of Rome “Sapienza” Incontro Nazionale Iniziative di Fisica Astroparticellare.

Smoke This! The CMB, the Big Bang, Inflation, and WMAP's latest results Spergel et al, 2006, Wilkinson Microwave Anisotropy Probe (WMAP) Three Year results:

Cosmological constraints from μE cross correlations

Recent status of dark energy and beyond

The Cosmic Microwave Background and the WMAP satellite results

dark matter Properties stable non-relativistic non-baryonic

Standard ΛCDM Model Parameters

Cosmic Microwave Background

Shintaro Nakamura (Tokyo University of Science)

The impact of non-linear evolution of the cosmological matter power spectrum on the measurement of neutrino masses ROE-JSPS workshop Edinburgh.

The dark matter sector and new forces mediated by dark energy

CMB Anisotropy 이준호 류주영 박시헌.

Presentation transcript:

The Cosmic Microwave Background Lecture 1 Elena Pierpaoli

(Cosmic Microwave Background) Brief History of time

Properties: isotropy and anisotropies The CMB radiation is isotropic We are moving with respect to the CMB rest frame There are tiny anisotropies, imprints of matter-radiation fluctuations.

Space Missions PLANCK: Smaller beam Lower noise Polarization Better frequency coverage

Measuring the Fundamental Properties of the Universe Observables Radiation Matter SDSS slice CMB - Cosmic Microwave Background (Temperature and Polarization) DT(q,f) = S al,m Yl,m (q,f) cl = Sm |al,m|2 d (x) = dr/r (x) d (k) = FT[d (x)] P(k) = < |d (k)|2> Pgal(k) = b2 P(k) bias

The power spectrum Nolta et al 08

The decomposition of the CMB spectrum Challinor 04

Evolution equations Photons Cold dark amtter Baryons metric Massive neutrinos Massless neutrinos

Evolution of fluctuations Ma & Bertschinger 95

Line of sight approach Seljak & Zaldarriaga 06

Polarization Due to parity symmetry of the density field, scalar perturbations Have U=0, and hence only produce E modes.

Scattering and polarization If there is no U mode to start with, scattering does not generate it. No B mode is generated. Scattering sources polarization through the quadrupole.

Tensor modes Parity and rotation symmetry are no longer satisfied. B modes could be generated, along with T and E.

The tensor modes expansion Scattering only produces E modes, B Are produced through coupling with E And free streaming.

Power spectra for scalar and tensor perturbations Tensor to scalar ratio r=1

Effect of parameters Effect of various parameters on the T and P spectrum

1)Neutrino mass: Physical effects on fluctuations Fluctuation on scale  enters the horizon Neutrinos free-stream Neutrinos do not free-stream (I.e. behave like Cold Dark Matter) Derelativization Expan. factor a Recombination Radiation dominated Matter dominated heavy light (T=0.25 eV) on expansion change the expansion rate Change matter-radiation equivalence (but not recombination)

2) The relativistic energy density Nn Nn = (rrad - rg) / r1n Expan. factor a Recombination Radiation dominated Matter dominated 3 >3 Effects: change the expansion rate Change matter-radiation equivalence (but not the radiation temperature, I.e. not recombination) Model for: neutrino asymmetry other relativistic particles Gravitational wave contribution (Smith, Pierpaoli, Kamionkowski 2006) CONSTRAINTS: Before WMAP: N <17 After WMAP:N< 6.6 (Pierpaoli MNRAS 2003)

Neutrino species Bell, Pierpaoli, Sigurdson 06

Neutrino interactions