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NEUTRINO PHYSICS AND COSMOLOGY STEEN HANNESTAD, Aarhus University BLOIS, 31 MAY 2012 e    

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Presentation on theme: "NEUTRINO PHYSICS AND COSMOLOGY STEEN HANNESTAD, Aarhus University BLOIS, 31 MAY 2012 e    "— Presentation transcript:

1 NEUTRINO PHYSICS AND COSMOLOGY STEEN HANNESTAD, Aarhus University BLOIS, 31 MAY 2012 e    

2 FLAVOUR STATESPROPAGATION STATES MIXING MATRIX (UNITARY) LATE-TIME COSMOLOGY IS (ALMOST) INSENSITIVE TO THE MIXING STRUCTURE

3 Normal hierarchyInverted hierarchy If neutrino masses are hierarchical then oscillation experiments do not give information on the absolute value of neutrino masses However, if neutrino masses are degenerate no information can be gained from such experiments. Experiments which rely on either the kinematics of neutrino mass or the spin-flip in neutrinoless double beta decay are the most efficient for measuring m 0 SOLAR KAMLAND ATMO. K2K MINOS

4 LIGHTEST INVERTED NORMAL HIERARCHICALDEGENERATE

5 experimental observable is m 2 model independent neutrino mass from ß-decay kinematics only assumption: relativistic energy-momentum relation E 0 = 18.6 keV T 1/2 = 12.3 y ß-decay and neutrino mass T2:T2:

6 Tritium decay endpoint measurements have provided limits on the electron neutrino mass This translates into a limit on the sum of the three mass eigenstates Mainz experiment, final analysis (Kraus et al.)

7 TLK KATRIN experiment Karlsruhe Tritium Neutrino Experiment at Forschungszentrum Karlsruhe Data taking starting 2013 25 m

8 NEUTRINO MASS AND ENERGY DENSITY FROM COSMOLOGY NEUTRINOS AFFECT STRUCTURE FORMATION BECAUSE THEY ARE A SOURCE OF DARK MATTER (n ~ 100 cm -3 ) HOWEVER, eV NEUTRINOS ARE DIFFERENT FROM CDM BECAUSE THEY FREE STREAM SCALES SMALLER THAN d FS DAMPED AWAY, LEADS TO SUPPRESSION OF POWER ON SMALL SCALES FROM

9 N-BODY SIMULATIONS OF  CDM WITH AND WITHOUT NEUTRINO MASS (768 Mpc 3 ) – GADGET 2 T Haugboelle, University of Aarhus 256 Mpc

10 AVAILABLE COSMOLOGICAL DATA

11 WMAP TEMPERATURE MAP THE COSMIC MICROWAVE BACKGROUND

12 WMAP-7 TEMPERATURE POWER SPECTRUM LARSON ET AL, ARXIV 1001.4635 ADDITIONAL DATA ON SMALLER SCALES FROM ATACAMA COSMOLOGY TELESCOPE (Dunkley et al. 2011) SOUTH POLE TELESCOPE (Keisler et al. 2011)

13 LARGE SCALE STRUCTURE SURVEYS - 2dF AND SDSS

14 SDSS DR-7 LRG SPECTRUM (Reid et al ’09)

15 S m = 0.3 eV FINITE NEUTRINO MASSES SUPPRESS THE MATTER POWER SPECTRUM ON SCALES SMALLER THAN THE FREE-STREAMING LENGTH S m = 1 eV S m = 0 eV P(k)/P(k,m 

16 NOW, WHAT ABOUT NEUTRINO PHYSICS?

17 WHAT IS THE PRESENT BOUND ON THE NEUTRINO MASS? STH, MIRIZZI, RAFFELT, WONG (arxiv:1004:0695) HAMANN, STH, LESGOURGUES, RAMPF & WONG (arxiv:1003.3999) DEPENDS ON DATA SETS USED AND ALLOWED PARAMETERS USING THE MINIMAL COSMOLOGICAL MODEL THERE ARE MANY ANALYSES IN THE LITERATURE JUST ONE EXAMPLE

18 THE NEUTRINO MASS FROM COSMOLOGY PLOT Larger model space More data CMB only + SDSS + SNI-a +WL +Ly-alpha Minimal  CDM +N +w+…… 1.1 eV 0.6 eV ~ 0.5 eV ~ 0.2 eV ~ 2 eV2.? eV??? eV ~ 1 eV1-2 eV 0.5-0.6 eV 0.2-0.3 eV

19 Gonzalez-Garcia et al., arxiv:1006.3795

20 WHAT IS N  A MEASURE OF THE ENERGY DENSITY IN NON-INTERACTING RADIATION IN THE EARLY UNIVERSE THE STANDARD MODEL PREDICTION IS BUT ADDITIONAL LIGHT PARTICLES (STERILE NEUTRINOS, AXIONS, MAJORONS,…..) COULD MAKE IT HIGHER Mangano et al., hep-ph/0506164

21 TIME EVOLUTION OF THE 95% BOUND ON N ESTIMATED PLANCK SENSITIVITY Pre-WMAP WMAP-1 WMAP-3 WMAP-5 WMAP-7

22 ASSUMING A NUMBER OF ADDITIONAL STERILE STATES OF APPROXIMATELY EQUAL MASS, TWO QUALITATIVELY DIFFERENT HIERARCHIES EMERGE 3+N N+3 s s A A A STERILE NEUTRINO IS PERHAPS THE MOST OBVIOUS CANDIDATE FOR AN EXPLANATION OF THE EXTRA ENERGY DENSITY

23 HOW DO THESE TWO HINTS FIT TOGETHER? CAN THEY BE EXPLAINED BY THE SAME PHYSICS? SHORT ANSWER: IT IS DIFFICULT WITHOUT MODIFYING COSMOLOGY MODIFYING FOR EXAMPLE THE DARK ENERGY EQUATION OF STATE CAN HELP, BUT THE 3+2 MODEL IS STRONGLY DISFAVOURED THE 3+1 MODEL PROVIDES AS GOOD A FIT AS STANDARD  CDM (Hamann, STH, Raffelt, Wong 2011)

24 WHAT IS IN STORE FOR THE FUTURE? BETTER CMB TEMPERATURE AND POLARIZATION MEASUREMENTS (PLANCK) LARGE SCALE STRUCTURE SURVEYS AT HIGHER REDSHIFT AND IN LARGER VOLUMES MEASUREMENTS OF WEAK GRAVITATIONAL LENSING ON LARGE SCALES

25 Distortion of background images by foreground matter UnlensedLensed WEAK LENSING – A POWERFUL PROBE FOR THE FUTURE

26 FROM A WEAK LENSING SURVEY THE ANGULAR POWER SPECTRUM CAN BE CONSTRUCTED, JUST LIKE IN THE CASE OF CMB MATTER POWER SPECTRUM (NON-LINEAR) WEIGHT FUNCTION DESCRIBING LENSING PROBABILITY (SEE FOR INSTANCE JAIN & SELJAK ’96, ABAZAJIAN & DODELSON ’03, SIMPSON & BRIDLE ’04)

27 STH, TU, WONG 2006

28 EUCLID ESA M-CLASS MISSION 2019 SELECTED OCTOBER 2011

29 THE EUCLID MISSION

30 EUCLID WILL FEATURE: A WEAK LENSING MEASUREMENT OUT TO z ~ 2, COVERING APPROXIMATELY 20,000 deg 2 (THIS WILL BE MAINLY PHOTOMETRIC) A GALAXY SURVEY OF ABOUT few x 10 7 GALAXIES (75 x SDSS) A WEAK LENSING BASED CLUSTER SURVEY

31 z~0.35 z~1100 z~2

32 STH, TU & WONG 2006 EUCLID WL HAMANN, STH, WONG 12: COMBINING THE EUCLID WL AND GALAXY SURVEYS WILL ALLOW FOR A 3-4  DETECTION OF THE NORMAL HIERARCHY

33 THIS SOUNDS GREAT, BUT UNFORTUNATELY THE THEORETICIANS CANNOT JUST LEAN BACK AND WAIT FOR FANTASTIC NEW DATA TO ARRIVE…..

34 FUTURE SURVEYS LIKE EUCLID WILL PROBE THE POWER SPECTRUM TO ~ 1-2 PERCENT PRECISION WE SHOULD BE ABLE TO CALCULATE THE POWER SPECTRUM TO AT LEAST THE SAME PRECISION! ”LSST” ERROR BARS

35 IN ORDER TO CALCULATE THE POWER SPECTRUM TO 1% ON THESE SCALES, A LARGE NUMBER OF EFFECTS MUST BE TAKEN INTO ACCOUNT BARYONIC PHYSICS – STAR FORMATION, SN FEEDBACK,….. NEUTRINOS, EVEN WITH NORMAL HIERARCHY NON-LINEAR GRAVITY ……………………..

36 FULL NON-LINEAR LINEAR THEORY Brandbyge, STH, Haugbølle, Thomsen ’08 Brandbyge & STH ’09, ’10, Viel, Haehnelt, Springel ’10 STH, Haugbølle & Schultz ’12, Wagner, Verde & Jimenez ’12 NON-LINEAR EVOLUTION PROVIDES AN ADDITIONAL SUPPRESSION OF FLUCTUATION POWER IN MODELS WITH MASSIVE NEUTRINOS

37 CDM 1 < p/T < 20 < p/T < 12 < p/T < 3 3 < p/T < 44 < p/T < 55 < p/T < 6 512 h -1 Mpc INDIVIDUAL HALO PROPERTIES

38 CONCLUSIONS NEUTRINO PHYSICS IS PERHAPS THE PRIME EXAMPLE OF HOW TO USE COSMOLOGY TO DO PARTICLE PHYSICS THE BOUND ON NEUTRINO MASSES IS SIGNIFICANTLY STRONGER THAN WHAT CAN BE OBTAINED FROM DIRECT EXPERIMENTS, ALBEIT MUCH MORE MODEL DEPENDENT COSMOLOGICAL DATA MIGHT ACTUALLY BE POINTING TO PHYSICS BEYOND THE STANDARD MODEL IN THE FORM OF STERILE NEUTRINOS NEW DATA FROM PLANCK AND EUCLID WILL PROVIDE A POSITIVE DETECTION OF A NON-ZERO NEUTRINO MASS

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