Nonthermal production of WIMPs, cosmic e± excesses, and γ rays from the Galactic Center

Bi, Xiao-Jun; Yuan, Qiang; Brandenberger, Robert; Gondolo, Paolo; Zhang, Xin-min; Li, Tian-jun

doi:10.1103/PhysRevD.80.103502

Article
Report number	arXiv:0905.1253 ; CERN-PH-TH-2009-082
Title	Nonthermal production of WIMPs, cosmic e± excesses, and γ rays from the Galactic Center
Preprint title	Non-Thermal Production of WIMPs, Cosmic $e^\pm$ Excesses and $\gamma$-rays from the Galactic Center
Author(s)	Bi, Xiao-Jun (Beijing, Inst. High Energy Phys. ; Peking U.) ; Brandenberger, Robert (McGill U. ; Beijing, Inst. High Energy Phys. ; TPCSF, Beijing ; Beijing, KITPC ; CERN) ; Gondolo, Paolo (Utah U. ; Beijing, KITPC) ; Li, Tian-jun (Beijing, Inst. Theor. Phys. ; Texas A-M ; Beijing, KITPC) ; Yuan, Qiang (Beijing, Inst. High Energy Phys.) ; Zhang, Xin-min (Beijing, Inst. High Energy Phys. ; TPCSF, Beijing ; Beijing, KITPC)
Publication	2009
Imprint	11 May 2009
Number of pages	23
Note	Comments: 23 pages, 2 figures
In:	Phys. Rev. D 80 (2009) 103502
DOI	10.1103/PhysRevD.80.103502
Subject category	Particle Physics - Phenomenology
Abstract	In this paper we propose a dark matter model and study aspects of its phenomenology. Our model is based on a new dark matter sector with a U(1)′ gauge symmetry plus a discrete symmetry added to the standard model of particle physics. The new fields of the dark matter sector have no hadronic charges and couple only to leptons. Our model cannot only give rise to the observed neutrino mass hierarchy, but can also generate the baryon number asymmetry via nonthermal leptogenesis. The breaking of the new U(1)′ symmetry produces cosmic strings. The dark matter particles are produced nonthermally from cosmic string loop decay which allows one to obtain sufficiently large annihilation cross sections to explain the observed cosmic ray positron and electron fluxes recently measured by the PAMELA, ATIC, PPB-BETS, Fermi-LAT, and HESS experiments while maintaining the required overall dark matter energy density. The high velocity of the dark matter particles from cosmic string loop decay leads to a low phase space density and thus to a dark matter profile with a constant density core in contrast to what happens in a scenario with thermally produced cold dark matter where the density keeps rising towards the center. As a result, the flux of γ rays radiated from the final leptonic states of dark matter annihilation from the Galactic center is suppressed and satisfies the constraints from the HESS γ-ray observations.

$Left: The $e^++e^-$ spectrum including the contribution from DM annihilation compared with the observational data from ATIC \cite{Chang:2008zz}, PPB-BETS \cite{Torii:2008}, HESS \cite{HESS:2008aa,Aharonian:2009ah} and Fermi-LAT \cite{Fermi:2009zk}. Right: The $e^+/(e^-+e^+)$ ratio including the contribution from DM annihilation as a function of energy compared with the data from AMS \cite{Aguilar:2007yf}, HEAT \cite{Barwick:1997ig, Coutu:2001jy} and PAMELA \cite{Adriani:2008zr}. Two sets of fitting parameters are considered: in one model (Model I) the DM mass is $620$ GeV with $e^+e^-$ being the main annihilation channel to fit the ATIC data, while in the other model (Model II) the DM mass is $1500$ GeV and we assume that $\mu^+\mu^-$ is the main annihilation channel to fit the Fermi-LATdata.$ $Left: The $e^++e^-$ spectrum including the contribution from DM annihilation compared with the observational data from ATIC \cite{Chang:2008zz}, PPB-BETS \cite{Torii:2008}, HESS \cite{HESS:2008aa,Aharonian:2009ah} and Fermi-LAT \cite{Fermi:2009zk}. Right: The $e^+/(e^-+e^+)$ ratio including the contribution from DM annihilation as a function of energy compared with the data from AMS \cite{Aguilar:2007yf}, HEAT \cite{Barwick:1997ig, Coutu:2001jy} and PAMELA \cite{Adriani:2008zr}. Two sets of fitting parameters are considered: in one model (Model I) the DM mass is $620$ GeV with $e^+e^-$ being the main annihilation channel to fit the ATIC data, while in the other model (Model II) the DM mass is $1500$ GeV and we assume that $\mu^+\mu^-$ is the main annihilation channel to fit the Fermi-LATdata.$ $Upper: the FSR $\gamma$-ray fluxes from a region with $|l|<0.8^\circ$ and $|b|<0.3^\circ$ close to GC compared with the observational data from HESS \cite{hess}. The left panel compares the two models given in Table \ref{table:cross} directly with the data, while the right panel shows the combined fitting results using a power law astrophysical background together with the FSR contribution from DM annihilation at $95\%$ ($2\sigma$) confidence level. Lower: constraints on the DM profile parameters $\gamma$ and $c_{vir}$ due to the HESS observation of $\gamma$-ray radiation from the GC by assuming different final leptonic states. The left panel corresponds to the constraint Case I, while the right panel corresponds to Case II. The two curves in the right panel represent the $1\sigma$ and $2\sigma$ upper bounds respectively.$ Show more plots

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ჩანაწერი შექმნილია 2010-01-14, ბოლოს შესწორებულია 2023-03-12

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