Recent developments in Dark Matter Malcolm Fairbairn.

Slides:

Advertisements

Similar presentations

La Biodola (Isola dElba) May 26, 2006The Pamela experiment ready for flight O. Adriani The Pamela experiment ready for flight Oscar Adriani – INFN Firenze,

Advertisements

E. Mocchiutti, INFN Trieste - CALOR th June 2006, Chicago E. Mocchiutti 1, M. Albi 1, M. Boezio 1, V. Bonvicini 1, J. Lund 2, J. Lundquist 1, M.

Fermi LAT Observations of Galactic and Extragalactic Diffuse Emission Jean-Marc Casandjian, on behalf of the Fermi LAT collaboration 7 questions addressed.

The Galactic diffuse emission Sabrina Casanova, MPIK Heidelberg XXth RENCONTRES DE BLOIS 18th - 23rd May 2008, Blois.

Combined Energy Spectra of Flux and Anisotropy Identifying Anisotropic Source Populations of Gamma-rays or Neutrinos Sheldon Campbell The Ohio State University.

Dark Matter Annihilation in the Milky Way Halo Shunsaku Horiuchi (Tokyo) Hasan Yuksel (Ohio State) John Beacom (Ohio State) Shin’ichiro Ando (Caltech)

Limits on the spin-dependent scattering cross section from IceCube Joakim Edsjö Presented by Carlos de los Heros.

AMS Discoveries Affecting Cosmic-Ray SIG Priorities Eun-Suk Seo Inst. for Phys. Sci. & Tech. and Department of Physics University of Maryland AAS HEAD.

MSSM in view of PAMELA and Fermi-LAT Ts. Enkhbat 2 nd workshop on LHC physics, CYCU, Chungli Based on: arXiv: B. BajcB. Bajc, Ts. E, D. K. Ghosh,

Implication of recent cosmic ray data Qiang Yuan Institute of High Energy Physics Collaborated with Xiaojun Bi, Hong Li, Jie Liu, Bing Zhang & Xinmin Zhang.

Dark Matter Explanation For e^\pm Excesses In Cosmic Ray Xiao-Gang He CHEP, PKU and Physics, NTU.

Annihilating Dark Matter Nicole Bell The University of Melbourne with John Beacom (Ohio State) Gianfranco Bertone (Paris, Inst. Astrophys.) and Gregory.

PAMELA Payload for Antimatter Matter Exploration and Light Nuclei Astrophysics.

Testing astrophysical models for the PAMELA positron excess with cosmic ray nuclei Philipp Mertsch Rudolf Peierls Centre for Theoretical Physics, University.

CAN WE UNDERSTAND THE PAMELA POSITRON EXCESS AS WINOS? Gordy Kane January 2009 Ann Arbor arXiv , see also Phill Grajek, Aaron Pierce,

Sergio Palomares-Ruiz November 17, 2008 Dark Matter Annihilation/Decay Scenarios Novel Searches for Dark Matter with Neutrino Telescopes Columbus, OH (USA)

The positron excess and supersymmetric dark matter Joakim Edsjö Stockholm University

CMB constraints on WIMP annihilation: energy absorption during recombination Tracy Slatyer – Harvard University TeV Particle Astrophysics SLAC, 14 July.

DARK MATTER PHENOMENOLOGY CIPANP Jonathan Feng San Diego

Primordial BHs. 2 Main reviews and articles astro-ph/ Primordial Black Holes - Recent Developments astro-ph/ Gamma Rays from Primordial.

Results from PAMELA Mirko Boezio INFN Trieste, Italy On behalf of the PAMELA collaboration Indirect and Direct Detection of Dark Matter February 7 th 2011.

MACRO Atmospheric Neutrinos Barry Barish 5 May 00 1.Neutrino oscillations 2.WIMPs 3.Astrophysical point sources.

Physics 133: Extragalactic Astronomy and Cosmology Lecture 11; February

Antideuteron Searches for Dark Matter LR W/ Yanou Cui John Mason.

Did Dark Matter Annihilations Reionize The Universe? Dan Hooper Fermilab Theoretical Astrophysics Group FNAL Particle Astrophysics Seminar June 1, 2009.

ICHEP 2010, Paris, July 2010 Antiparticle Detection in Space for Dark Matter Search: the PAMELA Experiment Oscar Adriani University of Florence INFN.

PAMELA – a satellite experiment searching for dark matter with cosmic ray antiparticles Mark Pearce KTH, Department of Physics, Stockholm, Sweden For the.

Luminous Dark Matter Brian Feldstein arXiv: B.F., P. Graham and S. Rajendran.

Sayfa 1 EP228 Particle Physics Department of Engineering Physics University of Gaziantep Dec 2014 Topic 5 Cosmic Connection Course web page

HEAD 2010 – Mar.3, 2010 :: IVM/Stanford-KIPAC 1IVM/Stanford-KIPAC 1 PAMELA Workshop, Rome/May 12, 2009 Igor V. Moskalenko (stanford/kipac) Leptons in Cosmic.

The TeV view of the Galactic Centre R. Terrier APC.

U NDERSTANDING C OSMIC R AYS AND S EARCHING FOR D ARK M ATTER WITH PAMELA Roberta Sparvoli for the PAMELA Collaboration University of Rome Tor Vergata.

High-energy electrons, pulsars, and dark matter Martin Pohl.

Singlet Dark Matter, Type II Seesaw and Cosmic Ray Signals Nobuchika Okada Miami Fort Fauderdale, Dec , 2009 University of Alabama, Tuscaloosa.

The Origin and Acceleration of Cosmic Rays in Clusters of Galaxies HWANG, Chorng-Yuan 黃崇源 Graduate Institute of Astronomy NCU Taiwan.

Very high energy  -ray observations of the Galactic Center with H.E.S.S. Matthieu Vivier IRFU/SPP CEA-Saclay On behalf the H.E.S.S. collaboration.

1 PEBS Prototype PERDaix was launched in October 2010 from Kiruna, Sweden.

Dark Matter: halo-shape and relic density constraints on dark matter theories with Sommerfeld enhancement Recent observations by PAMELA, etc. have been.

The PAMELA Experiment: Preliminary Results after Two Years of Data Taking Emiliano Mocchiutti - INFN Trieste on behalf of the PAMELA Collaboration.

Launch in orbit of the space experiment PAMELA and ground data results Roberta Sparvoli on behalf of the PAMELA Collaboration.

Astronomy 1143 – Spring 2014 Lecture 30: Dark Matter Revisted…..

KIAA-WAP, Peking U 2015/9/28 Implications on CRs and DM from the AMS-02 results Xiao-Jun Bi ( 毕效军 ) Center for Particle and Astrophysics IHEP, Beijing.

Collider searchIndirect Detection Direct Detection.

MARCH 11YPM 2015  ray from Galactic Center Tanmoy Mondal SRF PRL Dark Matter ?

Indirect Detection Of Dark Matter

Dark matter and hidden U(1) X (Work in progress, In collaboration with E.J. Chun & S. Scopel) Park, Jong-Chul (KIAS) August 10, 2010 Konkuk University.

Propagation of CR electrons and the interpretation of diffuse  rays Andy Strong MPE, Garching GLAST Workshop, Rome, 17 Sept 2003 with Igor Moskalenko.

Yu-Feng Zhou KITPC/ITP-CAS

Cosmic Ray Excesses From Multi-Component Dark Matter Da Huang Physics Department, Fo Guang Shan Fo Guang Shan PRD89, (2014) [arXiv:

Multi-wavelength signals of dark matter annihilations in the Galactic diffuse emission (based on MR and P. Ullio, arXiv: )‏ Marco Regis University.

Direct measurements of cosmic rays in space ROBERTA SPARVOLI ROME “TOR VERGATA” UNIVERSITY AND INFN, ITALY Vulcano Workshop 2014 Vulcano Island (Italy),

Type II Seesaw Portal and PAMELA/Fermi LAT Signals Toshifumi Yamada Sokendai, KEK In collaboration with Ilia Gogoladze, Qaisar Shafi (Univ. of Delaware)

Dark matter search at HERD X.-J. Bi Institute of High Energy Physics 3 nd Workshop of Herd. Xi’an,

Keegan Stoner Columbia High School. dark matter Obeying Inverse Square Law Outer stars orbit too fast what we should seewhat we actually see.

Cosmic-Ray Electron Excess from Pulsars is Spiky or Smooth?: Continuous and Multiple Electron/Positron Injections Cosmic-Ray Electron Excess from Pulsars.

DARK MATTER Fisica delle Astroparticelle Piergiorgio Picozza a.a

“VERITAS Science Highlights” VERITAS: TeV Astroparticle Physics Array of four 12-m Cherenkov telescopes Unprecedented sensitivity: ~100 GeV to ~30 TeV.

The 2nd workshop of air shower detection at high LHAASO detection of dark matter and astrophysical gamma ray sources Xiao-Jun Bi IHEP, CAS.

Topics on Dark Matter Annihilation

An interesting candidate?

Dark Matter in Galactic Gamma Rays

Dark Matter Subhalos in the Fermi First Source Catalog

Electron Observations from ATIC and HESS

Can dark matter annihilation account for the cosmic e+- excesses?

Implications of new physics from cosmic e+- excesses

DARK MATTER AND INDIRECT DETECTION IN COSMIC RAYS

Leptophilic Dark Matter from ATIC and Pamela

Dark Matter Explanation in Singlet Extension of MSSM

Two-zone diffusion of e-/e+ from Geminga explains the e+ anomaly

Kunihito Ioka & Mihoko M. Nojiri (KEK, Japan)

Presentation transcript:

Recent developments in Dark Matter Malcolm Fairbairn

PART 1 :- DAMA/LIBRA signal and interpretation PART 2 :- PAMELA, ATIC signal and interpretation

Part 1 DAMA/LIBRA signal and interpretation

Direct detection of dark matter

Earth goes round Sun, Sun goes round Galaxy

DAMA/Libra experiment 250 kg of NaI(Ti)

Quenching in NaI

Channeled events create more electrons and bigger signal Channelling in NaI

DAMA/LIBRA results

DAMA/LIBRA interpretation

MF, Schwetz-Mangold, DAMA/LIBRA interpretation

However, large tension exists with XENON-10 and CDMS data... DAMA signal therefore cannot be dark matter?

Non Extensive Statistics At any given time, probability of a particular delay time, t, given by Over course of a year,  varies quite a lot due to seasonal factors. Therefore, over the long term, one needs to include fluctuations in 

Non Extensive Statistics if  is sum over Gaussian random variables... leads to a   distribution... which yields

Applied to train times

Non Extensive Statistics of Dark Matter Distributions

Is such a halo conceivable? To see, we need to solve Jeans equation

Part 2 PAMELA, ATIC signal and interpretation

Resurs-DK1 satellite Mass: 6.7 tonnes Height: 7.4 m Solar array area: 36 m 2 Main task: multi-spectral remote sensing of earth’s surface Built by TsSKB Progress in Samara, Russia Lifetime >3 years (assisted) Data transmitted to ground via high-speed radio downlink PAMELA mounted inside a pressurized container

Positrons Secondary production ‘Leaky box model’ R. Protheroe, ApJ 254 (1982) 391. Secondary production ‘Moskalenko + Strong model’ without reacceleration. ApJ 493 (1998) 694. Primary production from  annihilation (m(  ) = 336 GeV) Secondary production ‘M+S model’ + primary  distortion PAMELA Baltz + Edsjö, Phys Rev D59 (1999) STOLEN FROM 2007 PRESENTATION BY MARK PEARCE, KTH STOCKHOLM

Adriani et al Discrepancy may be explained by variable solar activity. This one not!

Is it actually positrons? ( ) Intensity of cosmic ray protons at 10 GeV exceeds that of positrons by 5 x 10 5

ATIC AMS PPB Chang et al. Nature 456, 362, 20 th November 2008

Cholis et al Compatibility of the two experiments

Can be interpreted as Dark matter Cut-off corresponding to 620 GeV KK particle However, need large boost factors, B = ( 10, 10 2, 10 3 ) for m DM = ( 100 GeV, 1 TeV, 10 TeV) respectively

Branching ratio into e + e - Thermally averaged self annihilation cross section at freeze-out Thermally averaged self annihilation cross section today Expected local density (0.3 GeV cm -3 ) Actual local density Possible origins of the Boost Factor

Problems with diffusion equations? Diffusion term = f(r)?, f  f(E)? Energy loss term = f(r)?, f  f(E)? Energy injection term = f(r)?, f  f(E)?

Probes of GUT scale physics Decay of WIMP via dimension six operator. Decay of WIMP via dimension five operator. Avanitaki et al. arXiv:

Probes of GUT scale physics Lower Limit on dark matter lifetime

Probes of GUT scale physics Avanitaki et al. arXiv:

Probes of GUT scale physics What a fit!until Monday...

New H.E.S.S. data

New Fermi Data

Astrophysical origin of electrons/positrons 10 GeV – 10 TeV SNR - Secondary Pulsars - Primary Where are we now?

high energy electron/positron flux > 10 GeV still anomalously large Can fit FERMI by assuming local increase in SNR, but not PAMELA Grasso et al

FERMI and PAMELA can be simultaneously fitted with local pulsars Grasso et al

Where are we now with dark matter interpretations? Spectral shape well fitted by dark matter annihilating into muons required self annihilation cross section ~ 1000 times larger than expected need to avoid annihilations into hadrons (no anomalous antiproton signal) No feature at GeV a la ATIC

If you accept these prerequisites, Fermi, HESS and PAMELA data can be fit by dark matter also...

Branching ratio into e + e - Thermally averaged self annihilation cross section at freeze-out Thermally averaged self annihilation cross section today Expected local density (0.3 GeV cm -3 ) Actual local density Possible origins of the Boost Factor

Sommerfeld Enhancement S-channel annihilations P-channel annihilations Need something else to enhance the cross section. If Then dark matter particles are pulled together by exchange of W,Z bosons, enhancing annihilation by

Sommerfeld Enhancement ATIC data suggested DM particle of GeV, W, Z no good. Instead, consider much lighter GeV boson, weakly coupled (Arkani-Hamed & Weiner ) Also DM annihilates through boson – muon final states! However, since cross section goes like 1/v, forms problems for first structures formed (Kamionkowski and Profumo)

CDF Halloween Particle ? DATA MONTE CARLO

Two component dark matter MF and Zupan First component is the dark matter today. Second component decays into first. AAAAAAAAA

Two component dark matter

Conclusions DAMA/LIBRA data shows annual modulation Interpretation of that as dark matter contradicts with XENON/CDMS Can reconcile the two with non-standard density profiles Both PAMELA and FERMI show new population of electrons Dark matter is possible explanation Requires large boost factor and leptophilic decays Can also be explained by astrophysics Difficult confused future for this discovery channel for ordinary WIMPs PART 1 PART 2