How many stars have been shining in the Universe? Answer can be given by very-high energy gamma-ray observations! [Robertson et al.

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Extra-galactic background light (EBL) Dieter Horns (University of Hamburg) In cooperation with: Martin Raue, Daniel Mazin, Tanja Kneiske, Manuel Meyer, Dominik Elsässer, Peter Hauschildt, Franziska Laatz [Robertson et al. 2010] How many stars have been shining in the Universe? Answer can be given by very-high energy gamma-ray observations!

Outline: EBL Models Observations The EBL has not been unambiguously detected, yet!

Outline: VHE (E>100 GeV & EBL)

Ingredients of an EBL model The simplest type of model (Dwek et al. 1998, Kneiske et al. 2002) [Raue 2012] Models

Star formation rate history Tracers of star formation related to supernova-activity! Neutrinos and grav. Waves from corecollapse events Extinction Star forming region Extinction line emission (Hα [OII] etc.) Radio (synchrotron) UV/X-ray: Heated gas Infra-red (heated dust)

Star formation rate history Tracers of star formation related to supernova-activity! Neutrinos and grav. Waves from corecollapse events Extinction Star forming region Extinction UV/X-ray: Heated gas Infra-red (heated dust) line emission (Hα [OII] etc.) Radio (synchrotron) [Hopkins & Beacom 2006]

Stellar population Spectra Stellar models: Bruzual&Charlot (2003), Starburst99 (Leitherer et al. 1999, 2010) Parameters: Initial mass function Metallicity Dust re-processing More models: Franceschini et al. 2010, Dominguez et al. 2011 CMB Spectral energy distribution (SED) optical far-ir Mid-IR 1 10 100 Wavelength λ / μm

Contact with observations

Contact with observations

Contact with observations [Gilmore et al 2012]

Comment: Additional sources of photons Population III stars [Santos et al. 2002,Fernandez&Komatsu 2006, Raue et al. 2006, Gilmore 2012] [Santos et al. 2002]

Additional sources of photons Dark matter powered stars (Pre-Pop III) [Spolyar et al. 2008] could contribute to the EBL [Maurer et al. 2012]

EBL and very-high energy gammaray propagation [Nikishov 1962, Jelley 1966,Gould&Schréder 1966]

Pair-production absorption+ reprocessing of gamma-rays Photon density of EBL Εn(0.8eV,z=0)~10-2 cm-3 Pair production cross Section peaks at λ=1.2 μm (E/TeV) ~σt~6x10-25 cm²

Pair-production absorption+ reprocessing of gamma-rays

Pair-production absorption+ reprocessing of gamma-rays Pair production Inverse Compton scattering Down-conversion of gamma-rays optically thin regime B-field Scatters electrons out of line of sight

Pair-production absorption+ reprocessing of gamma-rays Pair production Inverse Compton scattering [Neronov &Vovk 2010, Dermer et al. 2011]. Down-conversion of gamma-rays optically thin regime B-field [Meyer et al. 2012] Scatters electrons out of line of sight

Gamma-ray telescopes 100 MeV 500 GeV, all-sky pair-production telescope (AΩ~4 m² srad) 50 GeV-50 TeV, air shower detector (AΩ~103 m² srad)

Extra-galactic sources of HE (E>10 GeV) and VHE (>100 GeV) gammarays Fermi-LAT (>10 GeV): 70 FSRQ 245 BL Lac VHE (>100 GeV): 3 FSRQ 43 BL Lac [Paneque et al. 2012] TeVCat.uchicago.edu

Blazars=BL Lac or Flat spectrum radio quasars More about Blazar sequence [Meyer 2011, Finke 2012]

VHE blazars and the EBL Limits for a fixed EBL-shape: HESS collaboration, Nature (2006)

VHE blazars and the EBL Limits for a free shape of the EBL-SED [Meyer et al. 2012] EBL at z=0 Evolution in z (up to z=0.7) with nebl~(1+z)3-f, f=1.2 Compute optical depth for 1 920 000 shapes of the EBL (splines) Collect measured VHE spectra of all available objects Combine spectra with Fermi-LAT measurements when available Apply correction Fit intrinsic spectrum to a series of model spectra until an acceptable fit is achieved

Assumptions on the intrinsic spectrum of VHE Blazars If any assumption is not fulfilled, the EBL-shape is discarded: Concavity of the intrinsic spectrum Fermi-LAT spectrum+extrapolation (VHE-HEIndex) No super-exponential pile-up at VHE (Pileup) (Double)Broken power-law not convex (VHEConcavity): Reprocessed cascade emission does not exceed FermiLAT measurement (IntVHELumi)

Results: upper limit=envelope of allowed EBL-shapes

Comparison with other limits

So far: Limits on the EBL Now: Measurement of the EBL! Biteau (HESS coll.) 2012, HESS coll. Subm. 2012

Data-set: Observations with H.E.S.S. [Biteau (HESS coll.) 2012]

Spectral fits [Biteau (HESS coll.) 2012]

Stacking of likelihood profiles [Biteau (HESS coll.) 2012]

Measured EBL! First significant detection of an EBLconsistent red-shift dependent common absorption feature in VHE energy spectra at the level of 9 standard deviations!. Good agreement with upper and lower bounds (not per construction!) [Biteau (HESS coll.) 2012]

Constraining the star-formation rate Using the EBL-limits [Meyer et al. 2012] get a (model dependent) handle on the SFR history [Raue et al. 2012]

The SFR-EBL-VHE connection..

The SFR-EBL-VHE connection..

Large Tau

A closer look at the tail of the energy [DH et al. 2012] spectra Slides from Meyer, Under the Assumption of a minimum EBL (=lower limit) Patras-WS 2012

Compare optically thin and optically thick sample

Compare optically thin and optically thick sample

Further analysis of optically thick data with Fermi-LAT [Meyer et al. In prep]

Tension with VHE-measurement of EBL?

Explanations? Systematics: Largely excluded (energy shift, bias on last point) Physics explanation: VHE Cascading (Kusenko et al. 2010a, 2010b, 2011a, 2011b, 2012a, 2012b). Variability? Spectral Fit? [Kusenko 2012]

Exotic explanations Lorentz invariance violation (conflict with limits on UHECR propagation [Galaverni & Sigl 2008], observed effect is tau-dependent and not energy dependent Light (nev) Axion-like (0-)particle with gag~10-11 GeV-1 could explain the observations, and could wash the dirty laundry.

Modified propagation

More complicated scenarios [DH et al. 2012b]

An interesting corner in the ALPS parameter space Transparency [Arias et al. 1202]

An interesting corner in the ALPS parameter space ~ 1.5 M + Helium.. Transparency [Arias et al. 1202]

The evolution of Gamma-ray telescopes MAGIC (2003-) Chudakov Krimean 1950s Whipple 10m/ 1968 MAGIC II (2009CTA (2014-) Whipple 10m/ 1989: The first VHE signal from The Crab nebula H.E.S.S. Phase II (2012- HEGRA CT1 (1991-2003) H.E.S.S. (2003- HEGRA CtSystem (1997-2002) CAT (1996-2001) VERITAS (2008-) Dieter Horns ECRS 2012 - Moscow

Summary EBL models are converging towards the minimum level set by resolved sources Conversely, there is not much room for additional sources for the EBL (e.g. Pop III, dark stars) VHE observations constrain the EBL from above VHE observations can be used to constrain the Star formation history (complementary to traditional tracers of SFR) New result: 8.8 sigma evidence for absorption feature in VHE spectra found Indications for anomalous transparency at optical depth > 2

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