Gravitons and Dark Matter in Universal Extra Dimensions

Slides:

Advertisements

Similar presentations

Ze-Peng Liu, Yue-Liang Wu and Yu-Feng Zhou Kavli Institute for Theoretical Physics China, Institute of Theoretical Physics, Chinese Academy of Sciences.

Advertisements

Extra Dimensions of Space-Time String theory suffers conformal anomaly that makes theory inconsistent --> get rid of it Conformal anomaly ~ (D-26) for.

Comprehensive Analysis on the Light Higgs Scenario in the Framework of Non-Universal Higgs Mass Model M. Asano (Tohoku Univ.) M. Senami (Kyoto Univ.) H.

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

Constraints on the very early universe from thermal WIMP Dark Matter Mitsuru Kakizaki (Bonn Univ.) Mitsuru Kakizaki (Bonn Univ.) July 27, Karlsruhe.

Cosmological Constraint on the Minimal Universal Extra Dimension Model Mitsuru Kakizaki (Bonn Univ. & ICRR, Univ. of Tokyo) Mitsuru Kakizaki (Bonn Univ.

Cosmological Constraint on the Minimal Universal Extra Dimension Model Mitsuru Kakizaki (Bonn University) Mitsuru Kakizaki (Bonn University) October 4,

WIMPs and superWIMPs Jonathan Feng UC Irvine SUGRA20 18 March 2003.

Particle Physics and Cosmology Dark Matter. What is our universe made of ? quintessence ! fire, air, water, soil !

Significant effects of second KK particles on LKP dark matter physics Mitsuru Kakizaki (Bonn Univ. & ICRR, Univ. of Tokyo) Mitsuru Kakizaki (Bonn Univ.

Cosmological Constraint on the Minimal Universal Extra Dimension Model Mitsuru Kakizaki (Bonn Univ. & ICRR, Univ. of Tokyo) Mitsuru Kakizaki (Bonn Univ.

20 June 07Feng 1 MICROPHYSICS AND THE DARK UNIVERSE Jonathan Feng University of California, Irvine CAP Congress 20 June 2007.

Significant effects of second KK particles on LKP dark matter physics Mitsuru Kakizaki (Bonn Univ. & ICRR, Univ. of Tokyo) 13 March, Bad Honnef.

Soft Leptogenesis in Warped Extra Dimensions Anibal D. Medina Department of Astronomy and Astrophysics The University of Chicago and Argonne National Laboratory.

Quintessino model and neutralino annihilation to diffuse gamma rays X.J. Bi (IHEP)

SUSY Dark Matter Collider – direct – indirect search bridge. Sabine Kraml Laboratoire de Physique Subatomique et de Cosmologie Grenoble, France ● 43. Rencontres.

Kaluza-Klein gluon production at the LHC

Relating dark matter and radiative Seesaw neutrino mass scales without beyond SM gauge symmetry Xiao-Gang He 1. Introduction 2. Radiative seesaw and dark.

The Dark Side of the Universe What is dark matter? Who cares?

H125 & Natural Alignment in the Z3 NMSSM Nausheen R. Shah University of Michigan Aug 7, 2015 In Collaboration with: M. Carena, H. Haber, I. Low & C. Wagner.

Masato Yamanaka (Saitama University) collaborators Shigeki Matsumoto Joe Sato Masato Senami arXiv: [hep-ph]Phys.Lett.B647: and Relic abundance.

Masato Yamanaka (Tokyo university, ICRR) Collaborators Shigeki Matsumoto Joe Sato Masato Senami PHYSICAL REVIEW D 80, (2009)

Neutralino Dark Matter in Light Higgs Boson Scenario (LHS) The scenario is consistent with  particle physics experiments Particle mass b → sγ Bs →μ +

DARK MATTER CANDIDATES Cody Carr, Minh Nguyen December 9 th, 2014.

Twin Higgs Theories Z. Chacko, University of Arizona H.S Goh & R. Harnik; Y. Nomura, M. Papucci & G. Perez.

1 Determination of Dark Matter Properties in the Littlest Higgs Model with T-parity Masaki Asano (SOKENDAI) Collaborator: E. Asakawa (Meiji-gakuin), S.

1 Gauge-singlet dark matter in the left-right symmetric model with spontaneous CP violation 郭万磊中国科学院理论物理研究所 CPS 2008, JiNan ， W.L. Guo, L.M.

X ± -Gauge Boson Production in Simplest Higgs Matthew Bishara University of Rochester Meeting of Division of Particles and Fields August 11, 2011  Simplest.

Neutrino mass and DM direct detection Daijiro Suematsu (Kanazawa Univ.) Erice Sept., 2013 Based on the collaboration with S.Kashiwase PRD86 (2012)

Yukawa and scalar interactions induced by scalar relevant for neutrino masss generation are: Since is assumed to be an exact symmetry of the model has.

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.

Significant effects of second KK particles on LKP dark matter physics Collaborated with Mitsuru Kakizaki (ICRR) Mitsuru Kakizaki (ICRR) Shigeki Matsumoto.

Detecting metastable staus and gravitinos at the ILC Hans-Ulrich Martyn RWTH Aachen & DESY.

Masato Yamanaka (Saitama University) collaborators Shigeki Matsumoto Joe Sato Masato Senami Phys.Rev.D76:043528,2007Phys.Lett.B647: and Universal.

Search for dark-sector Higgs and gauge bosons at B A B AR Adrian Bevan 1July 2012 h'h' A'A' χ A0A0.

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

Z’ Signals from KK Dark Matter Sabine Riemann (DESY) LCWS, Stanford, March 18-22, 2005 Outline  Universal extra dimensions (UED)  KK dark matter?  Sensitivity.

Collider Signals of Extra Dimension Scenarios

Kaluza-Klein Electroweak Dark matter Dong Woo Kang (SKKU) T. Flacke, DWK, K. C. Kong, G. M. Mohlabeng, S. C. Park arXiv:1503.xxxxx Exploring the Dark Sector.

Kaluza-Klein Electroweak Dark matter Dong Woo Kang (SKKU) T. Flacke, DWK, K. C. Kong, G. M. Mohlabeng, S. C. Park arXiv:1504.xxxxx Wonju Spring School.

Phys. Lett. B646 (2007) 34, (hep-ph/ ) Non-perturbative effect on thermal relic abundance of dark matter Masato Senami (University of Tokyo, ICRR)

We have the Higgs!!! Now What?? Nausheen R. Shah Wayne State University Oct 14, 2015 In Collaboration with: M. Carena, H. Haber, I. Low & C. Wagner arXiv:1510.xxxxx.

A New Framework for Dark-Matter Physics Brooks Thomas (University of Hawaii) Based on work done in collaboration with Keith Dienes [arXiv:1105.xxxx, arXiv:1105.yyyy,

Universal Extra Dimension models with right-handed neutrinos

An interesting candidate?

A Solution to the Li Problem by the Long Lived Stau

Nick Evans University of Southampton

Direct Detection of Vector Dark Matter

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

Generating Neutrino Mass & Electroweak Scale Radiatively

Lecture II: Dark Matter Candidates and WIMPs

John Kelley IceCube Journal Club 27 February 2008

Section VI - Weak Interactions

Implications of new physics from cosmic e+- excesses

MSSM4G: MOTIVATIONS AND ALLOWED REGIONS

朱守华, 北京大学物理学院.

Some Implications Of The Recent LHC Higgs Search Results Xiao-Gang He (SJTU&NTU) Xiao-Gang He and German Valencia, arXiv: Xiao-Gang He and.

Shufang Su • U. of Arizona

Relating Radiative Seesaw Neutrino And Dark Matter Mass Scales

Shufang Su • U. of Arizona

Shufang Su • U. of Arizona

Masato Yamanaka (Saitama University)

Introduction to universal extra dimensions (UEDs)

Daisuke Harada (Sokendai, KEK)

Leptophilic Dark Matter from ATIC and Pamela

Dark Matter Explanation in Singlet Extension of MSSM

Collider Signals of Large Extra Dimension

Can new Higgs boson be Dark Matter Candidate in the Economical Model

(Tokyo university, ICRR)

Dark Matter Detection,Models and Constraints

Presentation transcript:

Gravitons and Dark Matter in Universal Extra Dimensions Nausheen R. Shah Carlos E. M. Wagner PRD 74:104008, 2006 [arXiv: hep-ph/0608140] Enrico Fermi Institute and Kavli Institute for Cosmological Physics, University of Chicago. HEP Division, Argonne National Labs.

Universal Extra Dimensions Models beyond Standard Model (SM) frequently imply the existence of extra dimensions (ED). Simplest incorporation of ED: Universal Extra Dimensions (UED). All fields propagate in ED. Only one free parameter: mKK~1/R. Nausheen R. Shah Cosmo 08

Universal Extra Dimensions S1/Z2 (-1)KK KK Parity LKP Stable LKP DM Candidate w/ mKK ~ O(1) TeV Nausheen R. Shah Cosmo 08

Gravitons? G1 as the LKP very tightly constrained by Big Bang Nucleosynthesis (BBN) and diffuse gamma spectrum. Usually effect of the G1 considered not important, when it is not the LKP, since all interactions are Planck suppressed. We will show that in fact the gravitons can have significant effects on the DM density. Nausheen R. Shah Cosmo 08

Present Day WDM = WLKP + WGn Reheating Temperature Thermal Production of LKP Non-thermal Graviton Production Via Collisions LKP Freeze Out BBN BBN and Diffuse Gamma Ray Constraints on Graviton Decay. Gravitons decay to the LKP WGn ~ C [TR / mKK]7/2 C~O(1) Present Day WDM = WLKP + WGn Nausheen R. Shah Cosmo 08

Reheating Temperature Demanding that WDM = WLKP + WGn be consistent with observation constrains the reheating temperature, TR, as a function of the LKP mass: Nausheen R. Shah Cosmo 08

Values of TR obtained by demanding a proper DM density, for different values of the graviton production parameter, C, for D=5. Also shown are lines of constant ratios of TR to the LKP mass. Nausheen R. Shah Cosmo 08

Additional Contributions to the Annihilation Cross-Section A precise calculation of LKP density must include co-annihilation and second KK resonances effects. This changes the numerical results obtained, but the qualitative picture presented remains unchanged. These corrections can be quantified by noting that due to the weak logarithmic dependence of xF, we can approximately parameterize Y as being proportional to mKK: The change in mWG necessary to reproduce the correct DM density for a given TR: Nausheen R. Shah Cosmo 08

Ratio of the LKP mass consistent with DM density to the one obtained in the absence of gravitons, mWG, for TR = 20 mKK and D=5 Nausheen R. Shah Cosmo 08

TR = 40 mKK, D = 5. Nausheen R. Shah Cosmo 08

TR = 100 mKK, D=5. Nausheen R. Shah Cosmo 08

Decay Lifetimes Gn , for n>1, primarily decays to a pair of gauge bosons with equal KK numbers, with lifetime given by: Only long lived graviton is G1: Nausheen R. Shah Cosmo 08

Constraints on the G1-B1 mass difference. If we assume that TR is such that W = 0.23, we find that to preserve BBN predicted light element abundances : Requiring that late decays don’t destroy the diffuse photon flux: Nausheen R. Shah Cosmo 08

Combined constraints due to both BBN and observed diffuse flux on the mass difference. Nausheen R. Shah Cosmo 08

One Loop Corrections to the KK Masses. The gauge boson mass matrix due to the Higgs vev in the B n, W 3n basis: Since the mixing is very small, the first KK mode of the photon is very well approximated by the B1: Nausheen R. Shah Cosmo 08

Absolute value of the one loop corrections to the B1 mass in the MUED as a function of mKK. The graviton would be the LKP below masses ~ 800 GeV. Nausheen R. Shah Cosmo 08

Determining TR Due to small couplings to matter, provided the G1 is not the LKP, it will not be produced in laboratory experiments. If conclusive evidence for UED is found in collider experiments, and relevant properties of the first and second modes were measured, then assuming that no other exotic particle exists, we could estimate the contribution of the Gn to WDM , and therefore be able to infer TR. Nausheen R. Shah Cosmo 08

If LKP observed at LHC, the reheating temperature required to make up the deficit DM density by KK gravitons. Nausheen R. Shah Cosmo 08

Conclusion We have studied the cosmological effects of the inclusion of the KK graviton tower in detail. Conventionally, due to Planck suppression, the graviton has been ignored. We have shown that it can in fact have significant effects. Requiring that the graviton decays don’t destroy BBN predicted light element abundances and the diffuse gamma ray flux, we have obtained a bound on the mass difference between the G1 and the LKP, which is consistent with the one obtained from one loop corrections in the MUED for a large range of values of mKK. If UED is observed experimentally, we show that an upper limit on the reheating temperature can be deduced. Nausheen R. Shah Cosmo 08