Optical Properties of the South Pole Ice at Depths Between 0.8 and 1 Kilometer

Askebjer, P.; Barwick, S. W.; Bergström, Lennart; Bouchta, A.; Carius, Staffan; Coulthard, Alan; Engel, K.; Erlandsson, B.; Goobar, A.; Gray, L.; Hallgren, A.; Halzen, F.; Hulth, P. O.; Jacobsen, J.; Johansson, Sverker; Kandhadai, V.; Liubarsky, I.; Lowder, D. M.; Miller, Tim; Mock, P. C.; Morse, R.; Porrata, R.; Price, P. B.; Richards, A.; Rubinstein, H.R.; Schneider, E.; Sun, Q.; Tilav, S.; Walck, C.; Yodh, G.

doi:10.1126/science.267.5201.1147

Cited by 71 publications

(64 citation statements)

References 11 publications

(1 reference statement)

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“…Blanc et al 1997;Monteleoni 1997;Domogatsky et al 1997), under Antarctic ice (see e.g. Askebjer et al 1995), in space (see e.g. Linsley 1995;DeMarzo 1998;Streitmatter 1998), and using large area ground arrays (see e.g.…”

Section: Discussionmentioning

confidence: 99%

The case for a low extragalactic gamma-ray background

Keshet¹,

Waxman²,

Loeb³

2004

J. Cosmol. Astropart. Phys.

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Measurements of the diffuse extragalactic γ-ray background (EGRB) are complicated by a strong Galactic foreground. Estimates of the EGRB flux and spectrum, obtained by modeling the Galactic emission, have produced a variety of (sometimes conflicting) results. The latest analysis of the EGRET data found an isotropic flux I x = 1.45 ± 0.05 above 100 MeV, in units of 10 −5 ph s −1 cm −2 sr −1 . We analyze the EGRET data in search for robust constraints on the EGRB flux, finding the γ-ray sky strongly dominated by Galactic foreground even at high latitudes, with no conclusive evidence for an additional isotropic component. The γ-ray intensity measured towards the Galactic poles is similar to or lower than previous estimates of I x , even before Galactic foreground subtraction. The high latitude profile of the γ-ray data is disk-like for 40 • |b| 70 • , and even steeper for |b| 70 • ; overall it exhibits strong Galactic features and is well fit by a simple Galactic model. Based on the |b| > 40 • data we find that I x < 0.5 at a 99% confidence level, with evidence for a much lower flux. We show that correlations with Galactic tracers, previously used to identify the Galactic foreground and estimate I x , are not satisfactory; the results depend on the tracers used and on the part of the sky examined, because the Galactic emission is not linear in the Galactic tracers, and exhibits spectral variations across the sky. The low EGRB flux favored by our analysis places stringent limits on extragalactic scenarios involving γ-ray emission, such as radiation from blazars, intergalactic shocks and production of ultra-high energy cosmic rays and neutrinos. We suggest methods by which future γ-ray missions such as GLAST and AGILE could indirectly identify the EGRB.

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Section: Discussionmentioning

confidence: 99%

The case for a low extragalactic gamma-ray background

Keshet¹,

Waxman²,

Loeb³

2004

J. Cosmol. Astropart. Phys.

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“…The weakness of the neutrino interaction means that a large volume of material is required in the detector. The Antarctic ice-cap is the largest homogeneous mass of highpurity material on Earth (Askebjer et al 1995). This makes the South Pole a very attractive location for neutrino detection.…”

Section: Neutrino Telescopes In Antarcticamentioning

confidence: 99%

Neutrino Telescopes in Antarctica

Adams

2000

Publ. – Astron. Soc. Aust

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Abstract:It is hoped that in the near future neutrino astronomy will reach throughout and beyond our galaxy and make measurements relevant to cosmology, astrophysics, cosmic-ray and particle physics. The construction of a high-energy neutrino telescope requires a huge volume of very transparent, deeply buried material such as ocean water or ice, which acts as the medium for detecting the particles. I will describe two experiments using Antarctic ice as this medium: the AMANDA experiment employing photomultiplier tubes and RICE utilising radio receivers.

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“…Depending on depth, the absorption length of blue and UV light in the ice varies between 85 and 225 metres. The effective scattering length, which combines the mean-free path λ with the average scattering angle θ as λ (1− cosθ ) , varies from 15 to 40 metres [13]. Because the absorption length of light in the ice is very long and the scattering length relatively short, many photons are delayed by scattering.…”

Section: B Amanda: Southern Icementioning

confidence: 99%

High Energy Neutrino Astronomy: Towards Kilometer-Scale Detectors

Halzen

2001

Current Topics in Astrofundamental Physics: The Cosmic Microwave Background

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Optical Properties of the South Pole Ice at Depths Between 0.8 and 1 Kilometer

Cited by 71 publications

References 11 publications

The case for a low extragalactic gamma-ray background

The case for a low extragalactic gamma-ray background

Neutrino Telescopes in Antarctica

High Energy Neutrino Astronomy: Towards Kilometer-Scale Detectors

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