TeVPA'07 Abstracts

TeV Particle AstrophysicsTeV Particle Astrophysics
27-31 August. Istituto Veneto, Venice (Italy)

Abstracts

Speaker	Albuquerque Ivone
Institution	University of Sao Paulo
Title	Signals for Universal Extra Dimensions in Neutrino
Abstract	Interaction of high energy neutrinos within the Earth will produce KK particles predicted in Universal Extra Dimension models. We will show that these will have a clear signature and detectable rate in km3 neutrino telescopes.
Speaker	Aoi Junichi
Institution	Yukawa Institute for Theoretical Physics
Title	The effect of energy amplification variance on the shock acceleration
Abstract	We compare two methods to calculate the power-law index of the shock acceleration changing the velocity of the shock from the non-relativistic one to the highly-relativistic one. Two methods are developed by Peacock (1981) and Vietri (2003), and Blasi & Vietri (2005) indicated these two methods give different results. We examine this difference in detail and show the reason why two methods give the different results. We consider four cases for the scattering: large-angle scattering both in the upstream and the down stream (model A), deflection by large-scale magnetic fields in the upstream and large-angle scattering in the downstream (model B), small-angle scattering in both the upstream and the downstream (model C) and deflection by large-scale magnetic field in the upstream and small-angle scattering in the downstream (model D). We show the power-law index decreases as the shock velocity becomes fast in model A. The difference between the Peacock's method and Vietri's one becomes biggest in the mildly-relativistic shock regime and disappears in the highly-relativistic shock regime. The power-law index converges as the shock velocity becomes fast in model B. The difference derived from the two methods also converges. We conclude the difference of the two methods is due to the variance of the energy gain factor's distribution.
Speaker	Bass Steven
Institution	Innsbruck
Title	Electroweak baryogenesis and “topological condensates”
Abstract	Electroweak vacuum transition processes (sphalerons) in the early Universe provide a possible explanation of the baryon asymmetry. Combining this physics with the anomalous commutators of Adler and Boulware and renormalization group invariance, we argue that electroweak baryon number violation also induces a ``topological condensate'' in the vacuum, which (probably) survives in the Universe we live in today. The derivation of this effect involves issues of how one should include non-local topological structure in local anomalous Ward identities. Here we discuss the physics of this effect together with its possible phenomenology.
Speaker	Belov Konstantin
Institution	Rutgers University
Title	Proton-air Cross Section at 1018.5 eV
Abstract	We used the High Resolution Fly's Eye cosmic ray detector data to measure the proton-air inelastic cross-section at 1018.5 eV. A deconvolution measurement technique allowed us to reduce the interaction model dependence and increase the stability of the result. We present the result and discuss the systematic uncertainty which includes the uncertainty from unknown mass composition of the cosmic rays at ultra-high energies. A prediction for the LHC cross-section measurement is also discussed.
Speaker	Berge David
Institution	CERN
Title	Very-High-Energy Gamma-Ray Observations of Galactic
Abstract	Shell-type supernova remnants are the prime source candidates for the acceleration of Galactic Cosmic Rays at least up to the knee region. However, experimental proof is difficult due to propagation effects of charged particles in the magnetic fields of the interstellar medium. The most promising way of proving the existence of high-energy particles in supernova shells is the detection of very-high-energy (E > 100 GeV) gamma rays produced in interactions of high-energetic cosmic rays with ambient material close to their acceleration sites.
Speaker	Bertucci Bruna
Institution	Perugia University and INFN Perugia
Title	Dark Matter searches with AMS-02
Abstract	The Alpha Magnetic Spectrometer (AMS), to be installed on the International Space Station, will provide data on cosmic radiations in a large range of rigidity from 0.5 GV up to 2 TV. The main physics goals in the astroparticle domain are the anti- matter and the dark matter searches. Observations and cosmology indicate that the Universe may include a large amount of unknown Dark Matter. It should be composed of non baryonic Weakly Interacting Massive Particles (WIMP). A good WIMP candidate being the lightest SUSY particle in R-parity conserving models. AMS offers a unique opportunity to study simultaneously SUSY dark matter in three decay channels from the neutralino annihilation: e+, antiproton and gamma. The expected flux sensitivities in 3 year exposure for the e+/e- ratio, antiproton, antideuterons and gamma yields as a function of energy are presented and compared to other indirect searches.
Speaker	Blum Kfir
Institution	Weizmann Institute of Science, Israel
Title	Probing CP violation in neutrino oscillations with neutrino telescope
Abstract	Measurements of flavor ratios of astrophysical neutrino fluxes are sensitive to the two yet un- known mixing parameters \theta_{13} and \delta through the combination \sin\theta_{13}\cos\delta. We extend previous studies by considering the possibility that neutrino fluxes from more than a single type of sources will be measured. We point out that, if reactor experiments establish a lower bound on \theta_{13}, then neutrino telescopes might establish an upper bound on \|\cos\delta\| that is smaller than one, and by that prove that CP is violated in neutrino oscillations. Such a measurement requires several favorable ingredients to occur: (i) \theta_{13} is not far below the present upper bound; (ii) The uncertainties in \theta_{12} and \theta_{23} are reduced by a factor of about two; (iii) Neutrino fluxes from muon-damped sources are identified, and their flavor ratios measured with accuracy of order 10% or better. For the last condition to be achieved with the planned km3 detectors, the neutrino flux should be close to the Waxman-Bahcall bound. It motivates neutrino telescopes that are effectively about 10 times larger than IceCube for energies of O(100 TeV), even at the expense of a higher energy threshold.
Speaker	Boyarsky Alexey
Institution	CERN
Title	Searching for sterile neutrino DM
Abstract	The extension of the SM by 3 right-handed ("sterile") neutrinos allows to explain a number of phenomena in particle physics, astrophysics and cosmology, including baryon asymmetry of the Universe and neutrino oscillations. The lightest of these neutrinos is a viable DM candidate, which can be either cold or warm. I will review the properties of this candidate and discuss the existing restrictions on its parameters as well as prospects for future direct and indirect searches. From the point of view of astrophysical searches, it is important that this DM candidate a) is a decaying rather then annihilating particle, which makes it much less sensitive to the details of DM distributions b) should be searched in X-rays, not only in gamma-rays.
Speaker	Bringmann Torsten
Institution	SISSA
Title	Gamma-ray spectra from dark matter annihilations
Abstract	Being able to safely distinguish astrophysical from potential DM annihilation signals is of utmost importance in indirect dark matter searches. To this end, one almost unavoidably needs distinctive -- and unique -- spectral signatures to look for. In this talk, I point out that internal bremsstrahlung, photons radiated off charged annihilation products, provide such a signature. In fact, they often even dominate the expected gamma-ray spectrum from dark matter annihilations and should thus in any case be accounted for. It is, in particular, demonstrated that this is not only true for special situations, such as dark matter candidates with TeV-scale masses or large branching ratios into light leptons, but for a large part of the parameter space of neutralino dark matter in the MSSM. Finally, I comment on the potential of using these signatures to gain further insight into the nature of the dark matter.
Speaker	Brion Elisabeth
Institution	CEA-Saclay
Title	A detailed morphology of the W 28 region at TeV energies as revealed by H.E.S.S.
Abstract	It is believed that supernova remnants (SNR) can be an acceleration site for cosmic rays, which may give rise to observable high-energy gamma-ray emission via neutral pion decay from p-p interactions. This emission mechanism could be further enhanced if the SNR shell interacts with a close by dense molecular cloud, as seems to occur in the W 28 SNR region. Therefore, the four H.E.S.S. telescopes were pointed in the W 28 direction during ~42 hr between 2004 and 2006. The data were analysed using the so-called 2-dimensional model, which revealed a complex morphology consisting of several resolved sources at gamma-ray energies > 0.2 TeV. One such compact source is located at the north-eastern boundary of the W 28 SNR where the presence of several OH masers testify for the interaction of the SNR shell with a dense molecular cloud. This source otherwise seems associated with (90 cm) radio and X-ray features. At ~0.5° south of the SNR shell, a wide gamma-ray excess zone is resolved into three distinct emission spots, one of which is coincident with a new SNR candidate found in a recent 90 cm radio survey. The other sources could be linked to either local molecular clouds or compact HII regions, such as W 28A2. The detailed morphology of the W 28 region as seen with TeV gamma-rays will be presented and possible counterparts for the different emission spots will [...]
Speaker	Budnik Ran
Institution	Weizmann Institute
Title	Cosmic rays from trans-relativistic supernovae
Abstract	We derive constraints which must be satisfied by the sources of 1015 to 1018 eV cosmic rays, under the assumption that the sources are Galactic. We show that while these constraints are not satisfied by ordinary supernovae, which are believed to be the sources of <1015 eV cosmic rays, they may be satisfied by the recently discovered class of trans-relativistic supernovae (TRSNe), supernovae associated with subenergetic gamma-ray bursts. A crucial TRSN characteristic, which distinguishes them from ordinary supernovae and allows them to satisfy the derived constraints, is the deposition of a significant fraction, > 10-2, of the explosion energy in mildly relativistic, \Gamma\beta > 1, ejecta. Galactic TRSNe may therefore be the sources of cosmic rays with energies up to 1018 eV.
Speaker	Carrigan Svenja
Institution	MPIK, Heidelberg, Germany
Title	Establishing a connection between high-power pulsars and very-high-energy gamma-ray sources
Abstract	Recently, advances in VHE instrumentation have made the discovery of many new, predominantly Galactic, sources possible. Of these, a significant number can be identified as pulsar wind nebulae. It has long been known that pulsars can drive powerful winds of highly relativistic particles. These winds end in a termination shock from which high-energy particles with a wide spectrum of energies emerge. High-energy electrons and positrons among these particles give rise to two components of electromagnetic radiation: a low-energy component from synchrotron radiation and a high-energy component from inverse Compton upscattering of ambient photons. Details of the energy conversion mechanisms in the vicinity of pulsars are not well understood, nor is it known if all pulsars drive pulsar wind nebulae and emit high-energy radiation. Here we show that for a sample of pulsars in the central Milky Way, pulsars with large spin-down energy flux are with high probability associated with VHE gamma-ray sources. This implies that these pulsars emit on the order of 1% of their spin-down energy in tera electron volt gamma-ray energies.
Speaker	Cerdeno David G.
Institution	Universidad Autonoma de Madrid
Title	Identifying WIMPs through the simultaneous measurements of their axial and scalar couplings
Abstract	The potential identification of WIMP dark matter candidates in direct detection experiments which are simultaneously sensitive to both spin-dependent and spin-independent couplings is investigated. The particular cases of the neutralino in supersymmetric theories and Kaluza-Klein dark matter in models with universal extra dimensions are studied through the determination of the theoretical predictions for their axial and scalar couplings. A case study is done for the COUPP experiment (Chicagoland Observatory for Underground Particle Physics), whose projected sensitivity could allow the exploration of a part of the parameter space of both WIMP candidates. Furthermore, the possibility of employing different detection liquids provides a significantly more precise determination of the WIMP axial and scalar couplings. This possibly allows the discrimination between neutralino and Kaluza-Klein dark matter.
Speaker	Colafrancesco Sergio
Institution	ASI-ASDC and INAF
Title	Direct probes of DM through radio and microwave
Abstract	We discuss the multifrequency DM annihilation signals and we focus in particular on the ability of radio and microwave experiments to provide stringent and direct probes of the nature of DM matter.
Speaker	Cirelli Marco
Institution	SphT – CEA/Saclay
Title	Minimal Dark Matter
Abstract	I present a simple model of Dark Matter in terms of a WIMP that has gauge interactions only (a property that assures automatically the stability of the particle, for suitable choices of quantum numbers) and discuss its phenomenology and astrophysical signatures.
Speaker	Cuoco Alessandro
Institution	Institute for Physics and Astronomy, University of Aarhus
Title	The Signature of Large Scale Structure on the Very High Energy Gamma-Ray Sky
Abstract	If the diffuse extragalactic gamma ray emission traces the large scale structures of the universe, peculiar anisotropy patterns are expected in the gamma ray sky. In particular, because of the cutoff distance introduced by the absorption of 0.1-10 TeV photons on the infrared/optical background, prominent correlations with the local structures within a range of few hundreds Mpc should be present. We provide detailed predictions of the signal based on the PSCz map of the local universe. We also use mock N-body catalogues complemented with the halo model of structures to study some statistical features of the expected signatures. The results are largely independent from cosmological details, and depend mostly on the index of correlation (or bias) of the sources with respect to the large scale distribution of galaxies. For instance, the predicted signal in the case of a quadratic correlation (as it may happen for a dark matter annihilation contribution to the diffuse gamma flux) differs substantially from a linear correlation case, providing a complementary tool to unveil the nature of the sources of the diffuse gamma ray emission. The chances of the present and future space and ground based observatories to measure these features are discussed.
Speaker	De Mitri Ivan
Institution	Università del salento and INFN, Lecce
Title	First results from the ARGO-YBJ experiment
Abstract	Very high energy gamma ray astronomy and cosmic ray physics are among the main scientific goals of the ARGO-YBJ experiment. The detector, which is located in Tibet (China) at 4300 m a.s.l., is a full coverage Extensive Air Shower array consisting of a carpet of Resistive Plate Chambers (RPC) of about 7000 m2. The high altitude and the full coverage ensure a very low energy threshold (few hundreds of GeV for primary photons), while the detector time resolution (sigma_t ≈1ns) gives a good pointing accuracy, thus allowing a high sensitivity to gamma-ray sources, with a field of view of more than 2 sr and a duty cycle close to hundred percent. The detector layout, performance and location, offer a unique possibility to make a detailed study of several properties of the hadronic component of the cosmic ray flux in the 1-1000 TeV primary energy range. In particular, the topological structure of the shower, the lateral distribution, the energy spectrum and the space and time flux modulations can be measured with high sensitivity. Moreover, the use of a full coverage detector with a high space granularity gives detailed images of the shower front, that can be used to test different hypotheses on the cosmic ray interaction model, the shower development in the atmosphere, and particle physics at very high energies.
Speaker	Donato Fiorenza
Institution	University of Torino
Title	Dark Matter in Cosmic Ray
Abstract	I discuss the antimatter cosmic fluxes produced by supersymmetric dark matter annihilation in the Galactic halo. Propagation properties for charged particles originating in the halo will be treated. I will also how the present/next generation of instruments will be able to disentangle an exotic contribution against the astrophysical background of antiprotons, antideuterons and positrons, thus unraveling the presence of a particle dark halo in the Milky Way.
Speaker	Das Santabrata
Institution	ARCSEC, Sejong University, South Korea
Title	Propagation of UHE protons through a magnetized large scale structure
Abstract	The propagation of UHECRs is affected by the intergalactic magnetic fields that were produced during the course of the large scale structure formation of the universe. We adopt a novel model where the large scale extragalactic magnetic fields (EGMF) are estimated from local dynamic properties of the gas flows in hydrodynamic simulations of a concordance $\Lambda$CDM universe. With the model magnetic fields, we calculate the deflection angle, time delay and energy spectrum of protons with $E > 10^{19}$ eV that are injected at cosmological sources and then travel through the large scale structure of the universe, losing the energy due to interactions with the cosmic background radiation. Implications of this study on the origin of UHECRs are discussed.
Speaker	Descamps Freija
Institution	University of Ghent
Title	Feasibility study for acoustic neutrino detection in ice: the South Pole Acoustic Test Setup.
Abstract	The target volume needed for detection of the predicted small cosmogenic neutrino flux is a few orders of magnitude larger than the instrumented volumes of the Cherenkov neutrino telescopes currently under construction. Combining this optical technique with new instrumentation that is sensitive to the radio and acoustic signatures of an UHE neutrino interaction would allow for a larger sensitive volume at reasonable cost. The South Pole Acoustic Test Setup (SPATS) has been built to evaluate the acoustic characteristics of the Antarctic ice in the 10 to 100 kHz frequency range so that the feasibility and specific design of an acoustic neutrino detection array at South Pole can be evaluated. SPATS consists of three vertical strings that have been deployed in the upper 400 meter of the Antarctic ice cap in January 2007, using the upper part of IceCube holes. Each of them has 7 stages, consisting of one transmitter and one sensor module. An overview of the SPATS detector and first results will be presented.
Speaker	Diemand Juerg
Institution	UCSC
Title	Evolution of Dark Matter Structures
Abstract	Supercomputer simulations now allow to follow the formation and evolution of CDM halos and some of their subhalos. I will discuss recent results from the "Via Lactea" run: It samples a Milky Way scale halo with over 200 million particles and resolves over 10'000 subhalos and sub-subhalos. The mass in substructure has still not converged, i.e. it is growing with better numerical resolution. This wealth of structure has implications for direct and indirect dark matter detection, stellar streams, disk heating, gravitational lensing and for comparisons to the Local Group dwarf galaxy population.
Speaker	Dobler Gregory
Institution	Harvard University
Title	The WMAP Haze Excess and WIMP Annihilations
Abstract	The WMAP "haze" is an extended region of excess microwaves towards the Galactic Center relative to known ISM emissions. I will first present the results of our analysis of the morphological and spectral features of the haze. From there, I will show that they are consistent with synchrotron emission from an injection of high energy electrons/positrons sourced by ~500 GeV neutralino DM annihilations with thermal relic cross section in the galactic DM halo with a rho~r-1.2 density profile and no boost factor. Halo annihilations of this type have significant consequences for present and future indirect observations such as PAMELA and GLAST.
Speaker	Ergin Tulun
Institution	University of Massachusetts, USA
Title	TeV Gamma-ray Astronomy with the VERITAS Array
Abstract	The Very Energetic Radiation Imaging Telescope Array System (VERITAS) is an array of four imaging atmospheric Cherenkov telescopes designed for gamma-ray astronomy above 100 GeV. VERITAS is located at the Whipple Observatory at Mt. Hopkins in southern Arizona, USA, and the first telescope has been operating since the beginning of 2005. Observations in full array mode started in April 2007. The recent status on initial observations and results from data recorded from several different potential gamma-ray sources will be presented.
Speaker	Fargion Daniele
Institution	Physics Department, Rome Univ. 1, La Sapienza
Title	Neutrino and SUSY signals by airshowering beyond the edge
Abstract	The UHECR must contain both GZK neutrino component as well as PeV energy Antineutrino electron signals. They might interact in air and produce air-showers at atmosphere edges. Also UHE neutralino and Gluinos might induce such inclined airshowers. Finally UHE neutrino tau may skim the Earth and lead to up-ward Tau Air-showers beyond the Earth edge. These events might be present in TeV telescope records by different signatures: Splitting Cherenkov lights, Correlation between UHECR and gamma active sources, delayed air-showering clustered along Gamma TeV-GeV sources. We enlist the novel way to see the sky at horizons and the surprising imprint of rising UHE Neutrino and UHE SUSY Astronomy.
Speaker	Finkbeiner Douglas
Institution	Harvard-Smithsonian Center for Astrophysics
Title	Observable consequences of eXciting Dark Matter (XDM)
Abstract	I will discuss the astrophysical implications of the "Exciting Dark Matter" theory (XDM; Finkbeiner & Weiner 2007). XDM refers to a class of theories in which a WIMP has an internal degree of freedom that can be excited by collisions, and de-excites by emitting an e+e- pair (via an intermediate virtual boson). The net result is that WIMP kinetic energy is converted into pairs. There are multiple possible realizations of this scenario, but all have similar astrophysical consequences: (i) a substantial e+e- signal in the center of the Galaxy (as observed by CGRO/OSSE and Integral/SPI) and in other galaxies and clusters, (ii) heating the inner tens of kpc of galaxy clusters -- possibly enough to balance X-ray cooling, and (iii) enhanced BH accretion in the most massive clusters at early times.Because XDM WIMPs do not couple directly to e+e-, but rather couple via a (~1-1000 MeV) intermediate boson, XDM annihilation is then also expected to result in a hard e+e-/neutrino spectrum, and the (unusually hard) indirect synchrotron and gamma-rays from those e+e- interacting with the interstellar medium.
Speaker	Filippini Jeffrey
Institution	University of California - Berkeley
Title	Status and prospects of the Cryogenic Dark Matter Search
Abstract	The Cryogenic Dark Matter Search (CDMS) seeks to detect the interactions of dark matter WIMPs using simultaneous measurements of ionization and athermal phonons in semiconductor detectors. Based on a run of 74.5 live days with 12 detectors at the Soudan Underground Laboratory, CDMS has excluded spin-independent WIMP-nucleon cross sections greater than 1.6e-43 cm2 for a 60 GeV/c2 WIMP within the standard halo model. The collaboration had been running its full complement of 30 detectors at Soudan since October 2006 and is in the process of analyzing its first run in this configuration. The collaboration is also engaged in the development of SuperCDMS, an extension of our technology to larger detector masses which will be very complementary to searches for new physics at the LHC. I will outline the current status and future directions of the CDMS experiment.
Speaker	Fairbairn Malcolm
Institution	CERN
Title	The HR diagram of WIMP burning stars
Abstract	I will present work detailing the effects upon stellar evolution of WIMP accretion onto stars. In particular I will focus on the change in the HR diagram of stars in regions of high WIMP density and how it can constrain the density and properties of dark matter.
Speaker	Fairbairn Malcolm
Institution	CERN
Title	Stable massive particles at colliders
Abstract	I will review the zoo of stable massive particles which might be produced at the LHC and their possible implications for cosmology and astrophysics.
Speaker	Feinstein Fabrice
Institution	LPTA / Université Montpellier II/IN2P3/CNRS
Title	H.E.S.S. phase II
Abstract	H.E.S.S. in its phase I is the most sensitive gamma ray Cherenkov telescope currently operating with a 100 GeV threshold. The construction of the H.E.S.S. phase II telescope has started in 2006. First light is foreseen in 2009. Its 28 m diameter mirror will allow observations down to 20 GeV, giving a useful overlap with the GLAST satellite sensitive range. In the steroscopic mode with the four 13 m diameter mirrors of phase I, the sensitivity will be increased by a factor 2 and the angular resolution improved, while the threshold will be 50 GeV. I will review the design, the status of construction and the expected performances of HESS II.
Speaker	Green Anne
Institution	University of Nottingham
Title	Dark matter substructure
Abstract	WIMP direct and indirect detection signals both depend on the dark matter distribution on sub-galactic scales. I will discuss the microphysics of WIMPs in the early Universe and the properties of the first, smallest WIMP microhalos to form. I will then overview the dynamical processes which these microhalos are subject to, the current state of our understanding of these processes and the implications for experiments.
Speaker	Gabici Stefano
Institution	MPIK - Heidelberg
Title	Searching for galactic cosmic ray pevatrons with multi-TeV gamma rays and neutrinos
Abstract	We discuss the possibility of observing ultra high energy cosmic ray sources in high energy gamma rays. Protons propagating away from their accelerators produce secondary electrons during interactions with cosmic microwave background photons. These electrons start an electromagnetic cascade that results in a broad band gamma ray emission. We show that in a magnetized Universe (B > 10-12 G) such emission is likely to be too extended to be detected above the diffuse background. A more promising possibility comes from the detection of synchrotron photons from the extremely energetic secondary electrons. Although this emission is produced in a rather extended region of size ~ 10Mpc, it is expected to be point-like and detectable at GeV energies if the intergalactic magnetic field is at the nanogauss level.
Speaker	Gilmore Rudy
Institution	University of California, santa Cruz
Title	The Extragalactic Background Light and Absorption in Gamma Ray Spectra
Abstract	Recent state-of-the-art semi-analytic models (SAMs) can now accurately model the history of galaxy formation and evolution. These SAMs utilize a 'forward evolution' approach and include all of the important processes for determining photon emission from galaxies, such as cooling and shock heating of gas, galaxy mergers, star formation and aging, supernova and AGN feedback, and the reprocessing of light by dust. I will be presenting our group's latest prediction of the extra-galactic background light based on this work and will discuss the implications for the attenuation of VHE gamma rays from distant sources due to pair-production. These results will be compared to recent limits placed on the EBL by observations of TeV blazar spectra by experiments such as H.E.S.S. The implications for reconstructing the intrinsic spectra of distant TeV blazars will be addressed. Additionally, by including in this model estimates of far-UV emission from quasars and star-forming galaxies, as determined by the latest constraints on ionizing flux, I will discuss the prospects for detecting attenuation in the spectrum of high-redshift gamma-ray sources by the upcoming GLAST experiment.
Speaker	Giocoli Carlo
Institution	University of Padova
Title	Hierarchical formation of the Milky Way with micro-solar mass resolution
Abstract	In the hierarchical picture the dark matter halos grow as consequence of repeated merging events. The satellites that merge with the main branch of the merging-history-tree of a present-day halo, can survive as substructures. According to the extended-Press & Schechter theory, I will discuss how to built up a merger-tree of a Milky Way-size dark matter halo with micro solar mass resolution. Will be also discussed the gamma-ray emission from this population.
Speaker	Goodman Jordan
Institution	University of Maryland, College Park
Title	HAWC – A Wide Field TeV Observatory
Abstract	The HAWC (High Altitude Water Cherenkov) observatory is a next generation EAS detector based upon technology that was developed and proven with the Milagro detector. HAWC will have ~15 times the sensitivity of Milagro while retaining a ~2sr field of view and ~95% duty cycle. When completed, HAWC will be sensitive to gamma-ray induced air showers from 100 GeV to 100 TeV with a median energy around 1 TeV. After two years of operation HAWC will have surveyed the entire of the northern sky with a sensitivity below 35mCrab and will be able to see transient signals of 1 Crab at 5σ in a single day. HAWC will have unprecedented sensitivity to diffuse sources and the capability to map out diffuse emission in the galaxy. In this talk, the design, performance and capabilities of the HAWC observatory will be discussed.
Speaker	Guetta Dafne
Institution	OAR – Osservatorio di Roma
Title	High energy emission from internal shocks in Gamma Ray Bursts
Abstract	In this talk I will give some prediction of the high energy emission that can be produced in the internal shock scenario and the possibility that this will be detected by present and future detectors like AGILE and GLAST. Internal shocks may be responsible both of the prompt emission and of the flares superimposed on the afterglow X-ray lightcurves. The detection of this high energy (GeV) emission will allow to disentangle between different models.
Speaker	Hambye Thomas
Institution	Service de Physique Theorique
Title	TeV effects of neutrino seasaw model
Abstract	In the context of the 3 basic seesaw neutrino mass models, we present a systematic study of possible processes induced at low scale (renormalization of the Standard Model parameter effects, rare leptonic decays, W and Z decays,etc). We determine under which conditions such processes could be large enough to be observable in a near future.
Speaker	Hill Gary
Institution	University of Wisconsin, Madison
Title	Diffuse high-energy neutrino searches in AMANDA-II and IceCube: results and future prospects
Abstract	With the analysis of AMANDA-II data and the partial completion of the IceCube neutrino detector at the south pole, the field of high-energy neutrino astronomy continues its exciting progress. The AMANDA-II data collected during the period 2000-03 have been analysed in a search for a diffuse flux of high-energy extra- terrestrial neutrinos from the sum of all sources in the universe. With no excess of events seen, a 90% confidence level upper limit on an E-2 flux of E2 Phi < 7.4 x 10-8 GeV cm-2 s-1 sr-1 was obtained. The astrophysical implications of this bound and of others obtained for specific models (including atmospheric charm) will be discussed. First results from the IceCube 9 string array, and detection prospects for the currently operating 22 string array will be discussed.
Speaker	Hooper Dan
Institution	Fermilab
Title	High energy neutrinos from extragalactic sources
Abstract	Neutrino astronomy is rapidly reaching the level of sensitivity thought to be required to observe the first high energy and ultra-high energy neutrinos from extragalactic sources, including gamma ray bursts, active galactic nuclei and starburst galaxies. I will summarize the experimental and theoretical status of this rapidly developing field and discuss what we can learn from the first detections of high energy cosmic neutrinos.
Speaker	Horiuchi Shunsaku
Institution	University of Tokyo
Title	Dark matter annihilation from cosmological IMBH
Abstract	We explore contributions to the extragalactic gamma-ray background from neutralino dark matter pair-annihilations, from dark matter density enhancements surrounding intermediate-mass black holes (IMBHs). These enhancements, termed minispikes, are thought to be formed during the formation of IMBHs. Focusing on two IMBH formation scenarios, we take into account later minispike depletion processes and sum contributions from a cosmological distribution of IMBHs with maintained minispikes. We show that as a result contributions are increased by 1 to 3 orders. We also determine the dark matter annihilation spectra into monochromatic gamma-rays, which may provide a potential `smoking-gun' signature of neutralino dark matter in the gamma-ray background.
Speaker	Ichikawa Kazuhide
Institution	Institute for Cosmic Ray Research
Title	Energy budget of cosmic rays, magnetic fields and radio background
Abstract	We consider energy budget of cosmic rays and magnetic fields assuming the magnetic field would leak into intergalactic space with the cosmic rays. Then, we compute the radio background produced by cosmic ray electrons in that magnetic fields and compare with the observed radio background.
Speaker	Jouvenot Fabrice
Institution	University of Liverpool
Title	Sensitivity of a cubic-kilometre deep-sea neutrino telescope - KM3NeT - to galactic sources
Abstract	A future km3-scale neutrino telescope in the Mediterranean Sea, offers the possibility to significantly constrain models of cosmic ray propagation in the galaxy as well as the acceleration mechanisms involved in their production within astrophysical sources.
Speaker	Kashti Tamar
Institution	Weizmann Institute of Science
Title	Flavoring Astrophysical Neutrinos: Flavor Ratios Depend on Energy
Abstract	Electromagnetic (and adiabatic) energy losses of pions and muons modify the flavor ratio (measured at Earth) of neutrinos produced by pion decay in astrophysical sources. We saw that the flux ratio, $\Phi_{\nu_e}:\Phi_ {\nu_\mu}:\Phi_{\nu_\tau}$, is modified from 1:1:1 at low energy to 1:1.8:1.8 at high energy. The transition occurs over 1-2 decades of nuetrino energy, and is correlated with a modification of the neutrino spectrum. For gamma-ray bursts, e.g., the transition is expected at ~100 TeV, and may be detected by km-scale neutrino telescopes. Measurements of the transition energy and energy-width will provide unique probes of the physics of the sources. Pion and muon energy losses also affect the ratio of $\bar\nu_e$ flux to total neutrino flux, which may be measured at the W- resonance (6.3 PeV): It is modified from 1/6 (1/15) at low energy to 1/9 (practically 0) at high energy for neutrinos produced in pp ($p\gamma$) interactions.
Speaker	Kocharovsky Vladimir
Institution	Institute of Applied Physics RAS
Title	The converter acceleration mechanism for potential sources of ultra-high energy cosmic rays
Abstract	We consider particle acceleration in relativistic shocks or shear flows, which are most likely sources of ultra-high energy cosmic rays. We compare acceleration mechanisms and show that the converter mechanism, suggested recently (Phys. Rev. D 68 (2003) 043003, ASS 297 (2005) 21-30), is the least sensitive to the geometry of the magnetic field in accelerators and can routinely operate up to cosmic-ray energies close to the fundamental limit. The converter mechanism utilizes multiple conversions of charged particles into neutral ones (protons to neutrons) and back by means of photon-induced reactions or inelastic nucleon-nucleon collisions. It outperforms the standard diffusive shock acceleration in Active Galactic Nuclei, Gamma-Ray Bursts, and microquasars. The main advantages of the converter mechanism in such environments are that it greatly diminishes particle losses downstream and avoids the reduction in the energy gain factor. We also analyze the properties of gamma-ray and neutrino radiation, which accompanies acceleration of particles via the converter mechanism and can provide an evidence for the latter. In particular, we point out the fact that the opening angle of the radiation beam-pattern is energy dependent, which is relevant to the observability of the cosmic-ray sources as well as to their timing properties.
Speaker	Kotera Kumiko
Institution	Institut d'Astrophysique de Paris
Title	Inhomogeneous magnetic fields and the Second Knee in the cosmic ray spectrum
Abstract	There seems to be a consensus among various experiments on the existence of the Second Knee around E=3x1017 eV in the cosmic ray spectrum. This feature could be the signature of the end of the galactic component and the emergence of the extra-galactic one, provided that the latter cuts off at low energies. Recent analytical calculations have shown that this cut-off could be naturally explained by a "magnetic horizon" effect (Lemoine 2005,Berezinsky & Gazizov, 2006): low energy protons diffuse on extra-galactic magnetic fields and cannot reach the observer within a given time. We study the influence of inhomogeneous magnetic fields on the magnetic horizon, using a newly written original semi-analytical propagation code. Our results indicate that, at a fixed value of the volume averaged <B>, the amplitude of the low energy cut-off is mainly controled by the strength of magnetic fields in the voids of the large scale structure distribution. Our simulations also enable us to constrain some crucial parameters: <B> should be greater than 0.3 nG and not exceed 10 nG for a source density n_s=10^(-5) Mpc^(-3).
Speaker	Kowalski Marek
Institution	Humboldt University
Title	Searching for high-energy neutrino transient sources
Abstract	Transient high-energy neutrino sources, such as Gamma-Ray Bursts (GRBs) and core-collapse Supernovae (SNe) are predicted to be, constitute both chance and challenge. I will briefly discuss the astrophysical motivation for high-energy neutrinos from SNe and GRBs and some of the consequences (chances) their detection would have for astrophysics and particle-physics. We then turn to the observational challenge. A novel search strategy will be discussed, which consists of complementing large neutrino telescopes (such as IceCube) with optical follow-up observations. By searching for GRB afterglows or rising SN lightcurves through optical follow-up observations, one can significantly improve the perspectives for the detection of such sources. We describe first steps towards the creation of a global network of optical telescopes for follow-up observations of neutrino events and discuss its prospects.
Speaker	Kryvdyk Volodymyr
Institution	National Taras Shevchenko University of Kiev
Title	Cosmic ray and GRB from collapsing star
Abstract	Cosmic ray acceleration and the non-thermal radiation from the magnetized collapsing stars with the initial dipole magnetic fields are considered. The analysis of particles dynamics and its acceleration in the stellar magnetosphere under collapse show that the collapsing stars can by powerful sources of cosmic rays. The fluxes of cosmic rays from collapsing stars depend on its magnetic field and the initial particle spectrum in the magnetospheres. The collapsing stars can by also powerful sources of non- thermal radiation produced by the interaction of charged particles with the magnetic field. This radiation can be observed as GRB.
Speaker	Laffranchi Marco
Institution	ETH Zurich
Title	The ArDM, a ton-scale liquid argon experiment for direct detection of Dark Matter
Abstract	The ArDM project aims at developing and operating large noble liquid detectors to search for direct evidence of Weakly Interacting Massive Particles (WIMP) as Dark Matter in the universe. The initial goal is to design, assemble and operate an approximately 1 ton liquid argon prototype to demonstrate the feasibility of a ton-scale experiment with the required performance to efficiently detect and sufficiently discriminate backgrounds for a successful WIMP detection. Our design addresses the possibility to independently detect ionization and scintillation signals. In this talk, the concept of the detector and the status of the construction are described.
Speaker	Leisos Antonis
Institution	Hellenic Open University
Title	A sea top infrastructure for calibrating an underwater neutrino telescope
Abstract	The HEllenic LYceum Cosmic Observatories Network- HELYCON collaboration is constructing a network of detector stations distributed over three extended geographical areas. The goal of HELYCON is to observe Extensive Air Showers and to collect data corresponding to the flux, the direction and possible correlations between very energetic cosmic rays. In this report the design, the construction and the performance of a prototype detector array is presented. The results of a feasibility study on the use of HELYCON detectors for the calibration of the Mediterranean neutrino telescope, KM3NeT, are also presented.
Speaker	Levine Ilan
Institution	Indiana University South Bend
Title	COUPP, A Dark Matter Search Experiment Using Superheated Liquids
Abstract	COUPP - The Chicagoland Observatory for Underground Particle Physics (E961 at Fermilab) is a search experiment using moderately superheated heavy liquids in a bubble chamber as a WIMP dark matter target. I will discuss the experimental technique, the data taken with a 2.2 kg test chamber, and the progress toward ~67 kg modules currently under construction.
Speaker	Liolios Anastasios
Institution	Aristotele University of Thessaloniki
Title	The search for the direct detection of solar axions by CAST experiment
Abstract	We describe the present status of the CERN Axion Solar Telescope (CAST), an experiment dedicated to the direct detection of solar axions. The results from the CAST phase I, with vacuum inside the magnet bores, gave an upper limit on the axion-photon coupling of ga < 8.8×10-11 GeV-1 for ma < 0.02 eV, the best experimental limit so far by nearly an order of magnitude. In order to extend CAST sensitivity to higher axion rest masses, the experimental setup was upgraded (CAST phase II) in order to operate with the magnet bores filled with a buffer gas (4He at first and later on 3He). In order to fully exploit the discovery potential of the experiment, CAST plans to expand its solar axion rest mass sensitivity towards higher masses and lower its energy threshold.
Speaker	Lionetto Andrea
Institution	INFN Roma Tor Vergata
Title	Dark Matter in Models with Anomalous U(1)
Abstract	The appearence of extra anomalous U(1) gauge groups is a generic prediction of many string inspired scenario. We study in this framework the possible dark matter candidate and we give an overview of the direct and indirect detection prospects.
Speaker	Lisanti Mariangela
Institution	SLAC, Stanford University
Title	Unification and Dark Matter in a Minimal Scalar Extension of the Standard Model
Abstract	The six Higgs doublet model is a minimal extension of the Standard Model (SM) that addresses dark matter and gauge coupling unification. Another Higgs doublet in the 5 representation of a discrete symmetry group, such as S_6, is added to the SM. The lightest components of the 5-Higgs are neutral, stable and serve as dark matter so long as the discrete symmetry is not broken. Direct and indirect detection signals, as well as collider signatures are discussed. The five-fold multiplicity of the dark matter decreases its mass and typically helps make the dark matter more visible in upcoming experiments.
Speaker	Longo Francesco
Institution	University of Trieste and INFN Trieste
Title	Gamma-ray astrophysics with GLAST
Abstract	The Gamma ray Large Area Space Telescope (GLAST) is the next-generation high energy gamma-ray astronomy mission, scheduled for launch in late 2007. The observatory is composed by two instruments. The Large Area Telescope (LAT) will survey the sky in the energy range from 20 MeV to >300 GeV, while the GLAST Burst Monitor (GBM) will monitor gamma-ray bursts and other transients in the 10 keV to 25 MeV range. The LAT's high angular resolution, large effective area and broad field of view provide nearly two orders of magnitude increase in sensitivity over previous missions. With such unprecedented capability, GLAST will increase our understanding of the high energy emission of black holes and active galaxies, pulsars and supernova remnants, gamma-ray bursts, solar flares and diffuse sources. Many of its science investigations will benefit from coordinated, multiwavelength observations. In particular, GLAST LAT will be the only instrument sensitive in a common energy range with ground based TeV telescopes. The GLAST team welcomes cooperative efforts from observers in all wavebands to maximize its scientific return. In particular I will review the current status of the observatory and the LAT instrument performance, with special emphasis on GLAST's broad science objectives and the connection with TeV instruments.
Speaker	Maccione Luca
Institution	SISSA - Trieste
Title	Diffuse gamma-ray and neutrino emissions of the Galaxy
Abstract	We construct simulated maps of the expected neutrino and gamma-ray emissions above 1 TeV due to the hadronic scattering of cosmic rays (CR) with the interstellar medium (ISM). We estimate the spatial distribution of primary nuclei by solving numerically the diffusion equation. We consider several models of the galactic magnetic field (GMF) finding no significant dependence of our results on the uncertainties involved. Assuming that CR sources are supernova remnants, we use a distribution of those objects as estimated from observations of pulsars and progenitor stars. For the ISM distribution, we adopt most recent data both for the atomic and molecular hydrogen. Due to the major uncertainties in the determination of hydrogen maps, we compare predictions obtained with different models. With respect to previous results, we find the neutrino and gamma-ray emissions to be more peaked along the galactic plane (GP) and in the galactic centre, improving significantly the perspectives of a detection. We compare our predictions with present experimental limits for both gamma-rays and neutrinos and show that air shower array experiments may soon be able to detect the gamma-ray emission from the GP. Finally, we discuss the perspectives that a km3-size neutrino telescope based in the North hemisphere has to measure the diffuse emission from the inner Galaxy.
Speaker	Marcowith Alexandre
Institution	LPTA Montpellier, France
Title	The Fermi acceleration process in astrophysical shocks
Abstract	Insert the Abstract of your talk in 1200 char or less - NO HTML TAGS in this area OR THE SUBMISSION WILL BE REJECTED The Fermi acceleration of energetic particles in astrophysical shock fronts appears as a key process to explain the extreme cosmic ray energies that may be produced in different astrophysical sources. The efficiency of the Fermi process mostly relies on the properties of the turbulence that develops in the up- and down-stream flows. This work concerns about the consequences of a strong magnetic field amplification in the shock precursor through the excitation of the MHD turbulence by the streaming of accelerated cosmic rays. Estimates on the turbulence spectrum, anisotropy and coherence length up-stream, the effect of relaxation and scale compression down-stream, necessary to properly account for the particle transport, are investigated using analytical and numerical calculations. The recent X and gamma-ray observations of supernova remnants and also gamma-ray burst are used to discuss and constrain the previous theoretical investigation.
Speaker	Margiotta Anna
Institution	INFN and Università di Bologna
Title	The ANTARES neutrino telescope
Abstract	The ANTARES collaboration is building an underwater telescope for high energy neutrinos in the Mediterranean Sea, 40 km off the French coasts. The final detector will consist of 900 photomultipliers (PMTs) arranged in a 3- dimensional array of 12 lines, at a depth of about 2500 m and will be completed by January 2008. In March 2006, the first line was successfully connected to the deep undersea junction box. Presently, 5 lines are connected and continuously sending data to the shore station. With its 375 PMTs, ANTARES is already the largest underwater neutrino telescope in the world. In this talk, the status of the experiment and preliminary results will be reported.
Speaker	Marsella Giovanni
Institution	Dip.Ingegneria dell'Innovazione – Università del Salento - Lecce
Title	Time structure in shower longitudinal development with ARGO-YBJ detector
Abstract	ARGO-YBJ is a full coverage layer of Resistive Plate Counters (RPCs) covering an area of about 5.800 m2 installed at the Yanbaijing Laboratory (Tibet, P.R. China) at 4.300 m a.s.l. The detector reads out and digitizes the space and time information with a high granularity (56x62 cm2 pads and 1 ns accuracy in time measurements) making it a unique device for a detailed study of atmospheric shower characteristics. This peculiarity allows a wide range of cosmic ray physics in the energy range between 300 GeV and 100 TeV. A study on shower phenomenology and time structure in shower longitudinal development with ARGO-YBJ detector is presented.
Speaker	Matsumoto Shigeki
Institution	Tohoku University
Title	Cosmology of Gravitino LSP Scenario with Right-Handed Sneutrino NLSP
Abstract	We consider supersymmetric model with right-handed (s) neutrinos where the neutrino masses are purely Dirac type. We discuss cosmology based on such a scenario, paying particular attention to the case that the gravitino is the LSP while the right-handed sneutrino is the next-LSP. It will be shown that the cosmological constraints on the gravitino-LSP scenario (in particular, those from the big- bang nucleosynthesis) are drastically relaxed in such a case. We will also show that the dark matter abundance reproduced by the LHC experiment will provide us important information for the small scale structure problem in our galaxy.
Speaker	McKay Douglas
Institution	University of Kansas
Title	Neutrino telescopes, cross sections and fluxes
Abstract	When UHE neutrino events are observed, the physics of sources (flux) must be separated from the physics of detection (cross sections). We propose several simple diagnostics that suggest the cross section and flux can be cleanly disentangled. We show the simple picture holds up for a wide range of energy behaviors and normalizations of flux and cross section. We illustrate the application of the ideas to several present and future telescope configurations.
Speaker	McKinsey Dan
Institution	Yale University
Title	First results from the XENON10 direct dark matter search
Abstract	The XENON10 experiment at Gran Sasso National Laboratory uses a 15 kg dual phase xenon time projection chamber to search for dark matter in the form of weakly interacting massive particles (WIMPs). The detector measures simultaneously the scintillation and the ionization produced by radiation in pure liquid xenon, to discriminate signal from background down to 4.5 keV nuclear recoil energy. Ionization electrons are extracted into the xenon vapor where they produce a large proportional scintillation signal in a grid assembly. Both prompt and proportional scintillation light are detected by PMT arrays on the top and bottom of the active liquid xenon volume. The distribution of proportional scintillation light in the top PMT array can be used to achieve xy position resolution, while the ionization drift time gives position resolution in the z direction. This allows the definition of a low- background fiducial volume. A blind analysis of 58.6 live days of data, acquired between October 6, 2006 and February 14, 2007, and using a fiducial mass of 5.4 kg, excludes previously unexplored parameter space, setting a new 90% C.L. upper limit for the WIMP-nucleon spin- independent cross-section of 8.8E-44 cm2 for a WIMP mass of 100 GeV, and 4.5E-44 cm2 for a WIMP mass of 30 GeV.
Speaker	Mena Olga
Institution	INFN Sez. di Roma - “La Sapienza”
Title	Ultrahigh-energy neutrino flux as a probe of large extra dimension
Abstract	A suppression in the spectrum of ultrahigh-energy (UHE, $\gtrsim 10^{18}$~eV) neutrinos will be present in extra-dimensional scenarios, due to enhanced neutrino-antineutrino annihilation processes with the supernova relic neutrinos. In this scenario, neutrinos can not be responsible for the highest energy events observed in the UHE cosmic ray spectrum. A direct implication of these extra-dimensional interactions would be the absence of UHE neutrinos in ongoing and future neutrino observatories, such as in ANITA and ARIANNA neutrino telescopes.
Speaker	Mezzetto Mauro
Institution	INFN – Sezione di Padova
Title	HARP results on pion production on carbon, nitrogen and oxygen
Abstract	Motivated by the importance of the measurement of proton and pions interactions on carbon, nitrogen and oxygen for tuning hadronic interaction models used in neutrino flux and extensive air shower simulations, we analyze pion production in proton and pion reactions on C, N2 and O2 up to 12GeV/c measured by the fixed target experiment HARP at CERN-PS. We present momentum spectra of positive and negative pions and compare them with predictions of frequently used hadronic interaction models.
Speaker	Michelson Peter
Institution	Stanford University
Title	The Gamma-ray Large Area Space telescope
Abstract	The Gamma ray Large Area Space Telescope (GLAST) is the next-generation high energy gamma-ray astronomy mission, scheduled for launch in Fall 2007. The observatory comprises two instruments. The Large Area Telescope (LAT) will survey the sky with unprecedented sensitivity in the energy range from 20 MeV to >300 GeV, while the GLAST Burst Monitor (GBM) will monitor gamma-ray bursts and other transients in the 5 keV to 25 MeV range. The LAT s high angular resolution, large effective area, and broad field of view provide nearly two orders of magnitude increase in sensitivity over previous missions. GLAST promises major advances in our knowledge and understanding of the high energy emission of black holes and active galaxies, pulsars and supernova remnants, gamma-ray bursts, and diffuse sources. All GLAST data will be public after the first year of observation. With many of its science investigations benefiting greatly from coordinated, multiwavelength observations, the GLAST team welcomes cooperative efforts from observers in all wavebands to maximize scientific return. In this talk I will summarize the current status of the observatory testing and instrument performance, as well as review the mission's broad science reach.
Speaker	Moskalenko Igor
Institution	Stanford University
Title	Matter and antimatter in Cosmi Ray
Abstract	The fraction of antimatter in cosmic rays (CR), positrons, antiprotons, and yet-to-be-discovered antinuclei, is small, however it can provide us with unique information on our Galactic environment. Most of the antimatter in CRs, positrons and antiprotons, is produced in energetic interactions of CR nuclei, primarily protons, with interstellar gas. The spectra of these "secondary" particles depends on the Galactic CR proton distribution as well as the conditions in the interstellar medium, such as the spectrum of interstellar turbulence, distribution of the interstellar radiation and magnetic fields, gas density, the Galactic wind, etc. Their propagation in the heliosphere depends on the solar modulation. Contrary to other CR species, the production spectra of secondary positrons and antiprotons depend mostly on the ambient proton spectrum; this enables us to study the effects of their propagation in the interstellar medium and in the heliosphere. The production of secondary CRs is also intimately related to that of the Galactic diffuse emission, which dominates the gamma-ray sky; the gamma rays deliver information directly from distant locations, thus enabling us to study the Galactic CR distribution independent of propagation effects. Additionally, the spectra of CR positrons and antiprotons, and diffuse gamma rays, could contain signatures of exotic ph.
Speaker	Holger Motz
Institution	Antares Collaboration
Title	Dark Matter Sensitivity of ANTARES
Abstract	The ANTARES neutrino telescope is under construction in the Mediterranean Sea near Toulon. The telescope is built to search for astrophysical neutrino point sources and for neutrinos created in self-annihilation of Dark-Matter particles. A likely source of such neutrino emission would be the Sun, where Dark-Matter particles are expected to accumulate. Predictions of the neutrino flux originating from the Sun have been made based on the minimal Supergravity (mSugra) model including the effect of neutrino oscillations. Within mSugra the lightest supersymmetric particle, if a neutralino, is a possible candidate for cold Dark Matter. The neutrino flux from the Sun is given for a large range in the mSugra parameter space. Using the general features of ANTARES in the energy range from 10 GeV to 400 GeV the anticipated exclusion limits for indirect neutralino detection have been calculated.
Speaker	Carlos Munoz
Institution	Universidad Autonoma de Madrid & IFT
Title	A comparison between direct and indirect dark matter
Abstract
Speaker	Murase Kotha
Institution	Yukawa Institute for Theoretical Physics
Title	High Energy Neutrino Emission from Gamma-Ray Bursts
Abstract	Gamma-ray bursts (GRBs) are the most violent phenomena in the universe. In the internal-external shock scenarios, protons may be accelerated as well as electrons. Through the photomeson or pp reactions, such high energy protons can produce high energy neutrinos, which may be detected by large Cherenkov detectors such as IceCube in the future. Since proton acceleration in GRBs has not been confirmed, these possibilities are interesting, and important in order to reveal the connection between GRBs and ultra-high-energy cosmic-rays. We have numerically evaluated high energy neutrino background from GRBs for various scenarios. We discuss neutrino bursts associated with prompt emission and neutrino flashes associated with flares. In addition, neutrino emission during the late phase is also discussed. We also discuss possible high energy neutrino background from POP3 GRBs.
Speaker	Nakamori Takeshi
Institution	Kyoto University
Title	Status of the CANGAROO-III
Abstract	The CANGAROO-III telescope system for very-high-energy gamma-ray astrophysics consists of four 10-m atmospheric Cherenkov telescopes located near Woomera, South Australia. We have been observing southern-sky objects since March 2004. Here we report the status of the system and recent results of CANGAROO-III observations.
Speaker	Nishimura Hironobu
Institution	Kyoto University
Title	NEWAGE – A direction-sensitive direct darkmater search
Abstract	We developed a three-dimensional gaseous tracking device for a direct direction-sensitive dark matter search. Our device, we call “micro-TPC” consists of a pixel-type two- dimensional imaging device which has 768768 anodes with a pitch of 0.4 mm and an 100MHz readout system. It is able to detect the deposit energy and 3D-tracks of charged particles with a position resolution of sub mm so that it has a potential to detect the tracks of recoil nuclei scattered by WIMPs with enough energy and angular resolution. Furthermore this device can be reject more than 99.99% gamma-ray event by using the information of dE/dx. We had already operated this device at a surface laboratory by using 0.2 atm carbon-tetrafluoride(CF4) gas with a fidutial volume of 2124*31 cm3 and set the first limit on the spin-dependent WIMP-proton cross section by a direction-sensitive method. As a next step we installed it in the Kamioka Observatory and started operating it. I will introduce our device and its performance and report the first underground result of WIMP.
Speaker	Ohnishi Munehiro
Institution	Institute for Cosmic Ray Research, The University of Tokyo
Title	Gamma-ray Observation with the Tibet ASgamma Experiment: Present and Future
Abstract	The Tibet air shower array, which has an effective area of 37,000 m2, has been in operation since 1999 at Yangbajing in Tibet, China at an altitude of 4,300 m above sea level. We are planning to add a large muon detector array to it and to improve its sensitivity to cosmic gamma rays with energies around 100 TeV by discriminating them from background cosmic-ray hadrons. In this workshop, we will report on the observation of multi-TeV gamma rays from the Cygnus region and the Crab Nebula with the present Tibet air shower array. In addition the possibility of detection of gamma rays in the 100 TeV energy region in our field of view will be discussed, based on the improved sensitivity of our future air shower array.
Speaker	Paneque David
Institution	SLAC/Kipac
Title	Prospects of GLAST to study blazars
Abstract	.........................................
Speaker	Pastushenko Vladimir
Institution	..............................
Title	Elementary particles, Quantum Theory of the Relativity
Abstract	After creation of the Special Theory of the Relativity, the theory of gravitation in the General Theory of the Relativity has been created. After creation of the Quantum Theory of the Relativity, the theory of Quantum Gravitation has been created. The special case of Quantum Gravitation is the General Theory of the Relativity and the theory of Electro- strong Interaction. The special case of the theory of Electro- strong Interaction is equations of Maxwell.
Speaker	Pavlidou Vasiliki
Institution	University of Chicago
Title	Cosmology and Low-energy Astrophysics with Gamma-ray Observations
Abstract	The spectral shape of gamma-ray emission from extragalactic sources and the extragalactic gamma-ray background in the GeV and TeV bands encode information about the cosmic star formation rate, the cosmological distribution and evolution of active and normal galaxies, as well as about the properties of the dark matter particle. I will discuss how we can improve our theoretical understanding of the spectral shape of guaranteed contributions (those of normal galaxies and blazars) to the gamma-ray background and how we can use this understanding in combination with gamma-ray observations in the GLAST era as an independent constraint on cosmologically relevant quantities such as the cosmic star formation rate.
Speaker	Pieri Lidia
Institution	INAF & INFN - Padova
Title	Indirect Detection of clumps inside the Milky Way
Abstract	Within the Cold Dark Matter scenario of structure formation, assuming the dark matter is composed by common candidates such as supersymmetric particles, the smallest bound structures have masses as low as 10-6. High-resolution N-body experiments have shown that a large fraction of these small structures survive hierarchical clustering and can be found within the halo of our own Galaxy. These clumps are expected to boost up significantly the expected annihilation signal. In this work we perform a thorough analysis of the prospects for indirect detection of these objects with GLAST-like experiments, exploring different prescriptions for the formation and evolution of dark matter clumps, and allowing the sub-halos shape parameters to vary within the range currently allowed by numerical simulations. Our results show that an experiment like GLAST can detect the annihilation signal if the subhalo mass distribution within our Galaxy is as clumpy as in the more optimistic, yet not unrealistic, cases we have explored. We also show that the annihilation signal comes preferably from the top-massive rather than the many lightest sub-Galactic clumps.
Speaker	Rodejohann Werner
Institution	Max-Planck-Institute for Nuclear Physics
Title	Neutrino Mixing and Neutrino Telescopes
Abstract	Measuring flux ratios of ultra-high energy neutrinos is an alternative method to determine the neutrino mixing angles and the CP phase delta. We study general properties of the relevant neutrino mixing probabilities and obtain explicit formulae of various flux ratios for neutrinos from pion, neutron and muon-damped sources. We expand the probabilities and flux ratios in terms of two small parameters: those are U_{e3} and the deviation from maximal atmopsheric neutrino mixing. The first order correction of this expansion is found to be universal. We investigate which flux ratio from which source is best suited for measuring certain neutrino parameters. We also analyze how precise the initial flavor composition should be known to obtain useful results.
Speaker	Rott Carsten
Institution	Pennsylvania State University
Title	Search for extremely high energy neutrinos with IceCube
Abstract	Extremely high energy (EHE) cosmic neutrinos (E>10^19eV) are expected to carry important information about particle acceleration mechanisms in the universe and the origin of EHE cosmic-rays. IceCube, currently under construction at the South Pole, will instrument a volume of one cubic kilometer by 2011 using 70-80 strings each having 60 digital optical modules attached to them. The IceCube experiment is uniquely designed to detect these highly energetic astrophysical neutrino events. As the neutrino cross-section increases with energy, the mean free path of neutrinos in the EHE region becomes shorter than the Earth radius, which implies that these neutrino events would reach the detector from the horizon or above. Using detailed Monte Carlo simulations we show that these EHE signatures can be distinguished from background atmospheric muon bundles. We present a search for these events in the data sample recorded during 2006 using the nine string detector and discuss improvements in the ongoing analysis of the 2007 dataset collected with 22 strings. We focus in particular on track and energy reconstruction for these events.
Speaker	Rott Carsten
Institution	Pennsylvania State University
Title	Study of the potential of the IceCube array for reconstruction of low energy events
Abstract	The IceCube Neutrino Telescope is currently under construction at the geographic South Pole and will instrument a volume of one cubic kilometer by 2011. It currently consists of 22 strings with 60 Digital Optical Modules each. The AMANDA detector is now fully integrated into IceCube and provides a more densely spaced sub-array surrounded by the IceCube strings. IceCube is a multipurpose detector and its sensitivity extends within a wide energy range. In this work we will present the study of low energy fully and partially contained events. As most of the energy of these events is deposited inside the array, energy can be more reliably reconstructed. These events are especially interesting for atmospheric neutrino studies, where IceCube's sensitivity lies above the range accessible by other atmospheric neutrino detectors. Furthermore the analysis of starting tracks is not limited to muon neutrinos from the northern hemisphere. In this talk we explore IceCube's physics potential and present reconstruction methods for this class of events.
Speaker	Salati Pierre
Institution	LAPTH – Université de Savoie
Title	The antiproton cosmic ray signal at TeV energies
Abstract	A new generation of upcoming space-based experiments will soon start to probe the spectrum of cosmic ray antiparticles with an unprecedented accuracy and, in particular, will open up a window to energies much higher than those accessible so far. It is thus timely to carefully investigate the expected antiparticle fluxes at high energies. Here, we perform such an analysis for the case of antiprotons. We consider both standard sources as the collision of other cosmic rays with interstellar matter, as well as exotic contributions from dark matter annihilations in the galactic halo. Up to energies well above 100 GeV, we find that the background flux in antiprotons is almost uniquely determined by the existing low-energy data on various cosmic ray species; for even higher energies, however, the uncertainties in the parameters of the underlying propagation model eventually become significant. We also show that if the dark matter is composed of particles with masses at the TeV scale, which is naturally expected in extra-dimensional models as well as in certain parameter regions of supersymmetric models, the annihilation flux can become comparable to - or even dominate - the antiproton background at the high energies considered here.
Speaker	Sakurai Nobyuki
Institution	ICRR, University of Tokyo
Title	Telescope Array Experiment
Abstract	Telescope Array (TA) is a EAS detector which is now building in the western desert in Utah, USA. In order to estimate the performance of TA, a detailed detector simulation is being developed in Java. The number of particles produced during the development of the EAS shower with various inclinations is calculated by COSMOS code. The detection efciency of each detector is evaluated by using the various calibration data and the results of GEANT4 simulation. And it is taken into account in estimating the signal. The analysis methods of the EAS data are also being developed using TA simulation. This report describes the structure of our simulation code, the analysis methods and the TA performance estimation based on our simulation.
Speaker	Savchenko Volodymyr
Institution	BITP, Kiev Ukraine
Title	Sterile Neutrino Warm Dark Matter constraints fron XMM-Newton M31 observations
Abstract	We derive constraints on parameters of a radiatively decaying warm dark matter particle, e.g., the mass and mixing angle for a "sterile" neutrino, using XMM-Newton MOS spectra of the Andromeda galaxy (M31). We show that the observation of its outer parts can provide nearly the bigger amount of DM flux, although the X-ray signal from the outer parts is much less than that from the central part. This makes better constraints on sterile neutrino complementary to earlier results that used M31 on-center observations. Our limits are comparable and even better to the best existing constraints.
Speaker	Senami Masato
Institution	ICRR, University of Tokyo
Title	Dark matter abundance in universal extra dimension models
Abstract	Relic abundance of dark matter is investigated in the minimal universal extra dimension model and the extension with right-handed neutrinos. The relic abundance in the minimal universal extra dimension model will be improved by the recent WMAP data and precise tree cross sections, compared to my recent result, hep-ph/0605280. Contribution from KK right-handed neutrino will also be mentioned.
Speaker	Siegal-Gaskins Jennifer
Institution	University of Chicago
Title	Do tidal stremas constrain dark matter substructure?
Abstract	In recent years a number of tidal streams have been observed in the Milky Way, and it has been suggested that the existence of coherent tidal streams is incompatible with the abundance of dark matter substructure predicted by lambda-CDM models. We investigate whether current and upcoming observations may constrain dark matter models by examining the conditions under which coherent tidal streams can arise. We select a wide range of orbital paths in host galaxy models similar to the Milky Way, and simulate the disruption of a self-gravitating satellite on these orbits in both a smooth dark matter halo and one with substructure. In general, we find that the presence of substructure has a less significant effect on the resulting tidal debris than the orbital path of the satellite in a given host model, and conclude that the predicted level of substructure is consistent with current observations. We discuss the ability of upcoming experiments to probe the distribution of dark matter on these scales.
Speaker	Smith Nigel
Institution	STFC Rutherford Appleton Laboratory
Title	Direct Dark Matter Searches
Abstract	Relic abundance of dark matter is investigated in the minimal universal extra dimension model and the extension with right-handed neutrinos. The relic abundance in the minimal universal extra dimension model will be improved by the recent WMAP data and precise tree cross sections, compared to my recent result, hep-ph/0605280. Contribution from KK right-handed neutrino will also be mentioned.
Speaker	Sparvoli Roberta
Institution	University of Rome Tor Vergata and INFN Roma
Title	Cosmic Ray measurements with space telescope PAMELA: a status report
Abstract	The PAMELA apparatus is designed to study charged particles in the cosmic radiation over a wide energy range with unprecedent statistics. The instrument was launched into space on the 15th of June 2006 and, after a short period of satellite operation, has been continuously acquiring data. The scientific objectives addresses by the mission are the measurement of the antiprotons and positrons spectra in cosmic rays, the hunt for anti-nuclei as well as the determination of electron and light nuclei fluxes from hydrogen to oxygen up to several hundreds of GeV. This talk will present the potentiality of PAMELA instrument in cosmic ray measurements. The status of the experiment approximately 1 year after launch will also be discussed.
Speaker	Spiering Christian
Institution	DESY
Title	Matter
Abstract	Tunka-133, a large EAS Cherenkov array with about 1 km2 sensitive area, is being installed in the Siberian Tunka Valley, 50 km from Lake Baikal. This is a successor of the Tunka-25 array operated over several years at he same location. Tunka-133 will permit a detailed study of the cosmic ray energy spectrum and mass composition in the energy range PeV-EeV. The array will consist of 19 clusters, each composed of 7 optical stations. The first cluster started operation in October 2006. We describe the data acquisition system, status of the array after summer 2007 and present preliminary results from data taken with the first cluster.
Speaker	Taylor Andrew
Institution	Max-Planck-Institut fuer Kernphysik
Title	High-Energy Neutrinos from Astrophysical Accelerators of Cosmic Ray Nuclei
Abstract	Ongoing experimental efforts to detect cosmic sources of high energy neutrinos are guided by the expectation that astrophysical accelerators of cosmic ray protons would also generate neutrinos through interactions with ambient matter and/or photons. However there will be a reduction in the predicted neutrino flux if cosmic ray sources accelerate not only protons but also significant number of heavier nuclei, as is indicated by recent air shower data. We consider plausible extragalactic sources such as active galactic nuclei, gamma-ray bursts and starburst galaxies and demand consistency with the observed cosmic ray composition and energy spectrum at Earth after allowing for propagation through intergalactic radiation fields. This allows us to calculate the expected neutrino fluxes from the sources, normalised to the observed cosmic ray spectrum. We find that the likely signals are still within reach of next generation neutrino telescopes such as IceCube.
Speaker	Totani Tomonori
Institution	Kyoto University
Title	The Past High Activity of the Galactic Center and the 511 keV Annihilation Line Emission
Abstract	There are several lines of evidence that the SMBH at the Galacticcenter had higher activities in the past than at present. Here I showthat these lines of evidence can quantitatively and consistently be explained if the mean accretion rate during the past ~107 yrs has been ~10^{3-4} times higher than the current rate, by the picture of radiatively inefficient accretion flow (RIAF) and associated outflow that has been successfully applied to Sgr A*. I argue that this increased rate and its duration are theoretically reasonable in the Galactic center environment, while the accretion rate suddenly dropped about 300 years ago most likely because of the shell passage of the supernova remnant Sgr A East. Then I show that a significant amount of positrons should have been created around the event horizon during the higher activity phase, and injected into ISM by the outflow. The predicted positron production rate and propagation distance are close to those required to explain the observed 511 keV annihilation line emission from the Galactic bulge, giving a natural explanation for this enigmatic radiation.
Speaker	Trotta Roberto
Institution	Oxford University Astrophysics
Title	Prospects for direct dark matter detection in the CMSSM
Abstract	I will preent an up-to-date analysis of the Constrained MSSM, performed using Bayesian inference techniques that allow for the first time to derive constraints that take into account all sources of uncertainties and all relevant data, from accelerator bounds to cosmological and astrophysical observations. I will discuss prospects of direct dark matter detections and forecasts for the most probable regions for the neutralino scattering cross sections, showing that a direct detection is feasible with the next generation of dark matter searches. The complementarity of direct searches with collider searches will be highlighted.
Speaker	Trotta Roberto
Institution	Oxford University Astrophysics
Title	New statistical inference tools for SUSY searches
Abstract	The complexity of SUSY models parameter spaces and the growing amount of data of different nature (from collider constraints to astrophysical and cosmological observations) demands the use of more sophisticated statistical tools to produce model constraints and model predictions. In this talk I will present a Bayesian framework for statistical inference and highlight its computational efficiency and flexibility of use. The case of the Constrained MSSM will be explored, discussing present constraints on the model parameters and predictions for the LHC and the Tevatron.
Speaker	Tluczykont Martin
Institution	DESY
Title	Performance studies of the combined AMANDA and IceCube Neutrino Telescopes of opportunity Program
Abstract	The current IceCube telescope consists of 22 operational detector strings of which 13 were recently deployed during the polar summer season 2006/2007. The full integration of the AMANDA detector into IceCube operation was finalized in this season. This includes hardware synchronisation, combined triggering, common event building and a combined data analysis strategy. In this contribution the expected performance of the detector based on Monte Carlo simulations of the combined detector will be presented.
Speaker	Tluczykont Martin
Institution	DESY
Title	The Multi Messenger Approach and The MAGIC/IceCube Target of Opportunity Program
Abstract	Current neutrino detectors are approaching a sensitivity that allows one to detect Active Galactic Nuclei (AGN) in their high state. However, the expected signals might be too weak to result in a significant detection. One possibility to increase the detection chance is to combine neutrino observations with the rich information available from observations in the electromagnetic regime (Multi Messenger Approach). A directional and time-like coincidence between one or more neutrino events with a signal, e.g. in the gamma-ray regime, would increase the significance of the otherwise possibly too weak neutrino signal. For a comprehensive analysis of simultaneous neutrino and gamma-ray data several ingredients are necessary. This contribution will address some of these ingredients as well as the ongoing target of opportunity program, a cooperation between the MAGIC gamma-ray and the AMANDA/IceCube neutrino telescopes.
Speaker	Taboada Ignacio
Institution	University of California
Title	Neutrinos from GRBs and other high energy transients with IceCube.
Abstract	The search for high energy neutrinos from Gamma Ray Bursts (GRBs) and other short transient sources of gamma rays or X-rays is one of the main objectives of IceCube. Several methods have been proposed to search for short neutrino transients: Coincident searches with satellites, neutrino triggered optical follow-up monitoring and time-rolling searches. We will present the sensitivity and the advantages of each technique. Some of these techniques have been used with AMANDA and we will present a summary of the results. We will show that in few years of operation IceCube has the capability to discover neutrinos from GRBs/transients or rule out current theoretical predictions.
Speaker	Taoso Marco
Institution	Università degli Studi di Padova
Title	Gamma-Rays from Dark Matter Mini-Spikes in M31
Abstract	The existence of a population of wandering Intermediate Mass Black Holes (IMBHs) is a generic prediction of scenarios that seek to explain the formation of Supermassive Black Holes in terms of growth from massive seeds. The growth of IMBHs may lead to the formation of DM overdensities called "mini-spikes", recently proposed as ideal targets for indirect DM searches. Current ground- based gamma-ray experiments, however, cannot search for these objects due to their limited field of view, and it might be challenging to discriminate mini-spikes in the Milky Way from the many astrophysical sources that GLAST is expected to observe. We show here that gamma-ray experiments can effectively search for IMBHs in the nearby Andromeda galaxy (also known as M31), where mini-spikes would appear as a distribution of point-sources, isotropically distributed in a \thickapprox 3^{\circ} circle around the galactic center. For a neutralino-like DM candidate with a mass m_{\chi}=150 GeV, up to 20 sources would be detected with GLAST (at 5\sigma, in 2 months). With Air Cherenkov Telescopes such as MAGIC and VERITAS, up to 10 sources might be detected, provided that the mass of neutralino is in the TeV range or above.
Speaker	Turini Nicola
Institution	University of Siena and INFN Pisa
Title	The MAGIC experiment
Abstract	The Magic Experiment. The MAGIC experiment is taking data since fall 2003. It�s large single dish cherenkov telescope allows to explore VHE sources at lower energies than the competitors. Situated in the north hemisphere, in the canary island La Palma, it has produced measurements on galactic and especially extragalactic sources. The smaller sensitivity will be soon increased adding a new clone telescope, named MAGICII. The search for better light sensors and faster readout electronics will allow the new system to lower again it�s energy threshold and enlarge the overlap with the new space based gamma ray observatories such as GLAST and AGILE.
Speaker	Taylor James
Institution	University of Waterloo
Title	Dark Matter on the Smallest Scales
Abstract	WIMP dark matter should cluster to form dense, gravitationally bound structures over a huge range of scales, from the scale of galaxy clusters to the scale of our solar system. I will discuss novel techniques to model structure formation over this whole range, and what they have to say about dark matter in the solar neighbourhood.
Speaker	Venters Tonia
Institution	University of Chicago
Title	The Spectral Index Distribution of Blazars and the Spectral Shape of the Blazar Contribution to the EGRB: Prospects for GLAST
Abstract	The intrinsic distribution of spectral indices in GeV energies of gamma-ray�loud blazars is a critical input in determining the spectral shape of the unresolved blazar contribution to the diffuse extragalactic gamma-ray background, as well as an important test of blazar emission theories. We present a maximum-likelihood method of determining the intrinsic spectral index distribution (ISID) of a population of gamma-ray emitters which accounts for error in measurement of individual spectral indices, and we apply it to the case of Energetic Gamma-Ray Experiment Telescope (EGRET) blazars. We find that the most likely Gaussian ISID for EGRET blazars has a mean of 2.27 and a standard deviation of 0.20, much narrower than one would conclude if measurement error had not been accounted for. We additionally find some indication that FSRQs and BL Lacs may have different ISIDs (with BL Lacs being harder). We also test for spectral index hardening associated with blazar variability for which we find no evidence. We produce simulated Gamma-ray Large Area Space Telescope (GLAST) spectral index datasets and perform the same analyses finding that with improved number statistics, GLAST data will help us determine the ISIDs with much improved accuracy. Should any difference exist between the ISIDs of BL Lacs and FSRQs or between the ISIDs of blazars in the quiescent.
Speaker	Wagner Stefan
Institution	LSW
Title	Constraints on quantum gravity from fast TeV gamma-ray
Abstract	A number of models of quantum gravity violate Lorentz invariance and predict an energy dependence of the speed of light, leading to a dispersion of signals at high energies that travel over cosmological distances. The bright and fast flares observed by the Cherenkov experiment H.E.S.S. in blazar PKS 2155-304 in summer 2006 provides very tight constraints, especially for high-order terms and dispersion relations with an energy dependence that is steeper than linear. We present spectral timing analysis from this event, derive the limits on dispersion and discuss the limits on violation of Lorentz invariance.
Speaker	Williams Dawn
Institution	Pennsylvania State University
Title	Development and prospects for a future extension of the IceCube array with radio and acoustic detectors
Abstract	Neutrinos in the energy range from 1 PeV to above 1 EeV may provide a clue to the origin of the highest-energy cosmic rays. However, the predicted neutrino fluxes at these energies are essentially beyond the reach of kilometer-scale detectors such as IceCube, so non-optical technology is required for the next generation of neutrino telescope. Some promising avenues are radio and acoustic detection. The IceCube optical array at the South Pole, currently under construction, offers a unique opportunity for radio and acoustic instruments to co-deploy with optical modules without additional drilling. The Askaryan Underice Radio Array (AURA) began deployment in 2006/7 in new IceCube holes, with 3 prototype digital radio modules in the ice. I will discuss the status of the AURA modules and prospects for future radio deployment in the South Pole ice. I will briefly discuss the status of acoustic detection at the South Pole.
Speaker	Williams Dawn
Institution	Pennsylvania State University
Title	Prospects for tau neutrino detection in IceCube
Abstract	Tau neutrinos produce unique signatures in charged current interactions because of the relatively short decay time of the tau. These signatures do not have the atmospheric neutrino background of muon neutrinos. The classic "double bang" signature of the charged current interaction and subsequent tau decay can be resolved by the IceCube neutrino detector for tau energies above 1 PeV. Partially contained double bangs and the muonic decay channel of the tau will also produce readily identifiable signatures with larger effective volume and energy range than the fully contained double bang. I will discuss the current prospects for tau neutrino detection in IceCube.
Speaker	Zhao HongSheng
Institution	Univ. Of St. Andrews
Title	Annihilation signatures of the Bullet Cluster and other moving substructures
Abstract	We model the electrons/positrons produced by dark matter annihilations in the colliding galaxy cluster system 1E0561 (Bullet). These, confined by the magnetic field, mark a clear track of the bullet, which passes through the main cluster with a speed of 3000-5000 km/s. Similar trails exist for moving subhalos (minihalos) in any x-ray cluster. These trails are often far away from the galactic astronomical sources, hence offers an unambiguous proof of the DM annihilation signal through, e.g., inverse-Compton scattering of cosmic microwave photons.