Background studies for acoustic neutrino detection at the South Pole

6533b826fe1ef96bd1284841

RESEARCH PRODUCT

Background studies for acoustic neutrino detection at the South Pole

T. Denger H. Taavola E. Blaufuss J. C. Davis P. O. Hulth J. Eisch K. Han G. De Vries-uiterweerd J. J. Beatty B. Semburg A. Piegsa M. Krasberg C. Pérez De Los Heros H. Wissing K. Hoshina L. Koepke Glenn Spiczak J. Posselt Daniel Bindig S. M. Movit J. Auffenberg U. Naumann S. Yoshida J. M. Clem P. Zarzhitsk A. Van Overloop Ch. Weaver Reina H. Maruyama Jon Dumm M. Prikockis T. Waldenmaier Joanna Kiryluk Joanna Kiryluk K. Beattie O. Schulz O. Depaepe P. B. Price Chad Finley T. Griesel M. Ono S. Stoyanov K.-h. Becker J. L. Bazo Alba Peter Mészáros M. Kowalski J. Luenemann K. Rawlins T. Feusels J. E. Jacobsen Marcos Santander L. Gerhardt L. Gerhardt Larissa Paul G. Stephens S. Westerhoff D. Bose T. O. B. Schmidt M. Danninger K. Wiebe T. Fischer-wasels James Madsen A. Schukraft S. Grullon M. J. Carson Segev Benzvi D. Z. Besson Spencer Klein Spencer Klein T. Kowarik A. Marotta Thomas Meures E. Middell Elisa Bernardini R. C. Bay J. M. Joseph M. Ribordy H. S. Matis E. A. Strahler Kurt Woschnagg N. Van Eijndhoven Dirk Ryckbosch Juan Carlos Diaz-velez Paul Evenson Teresa Montaruli P. Roth Kara Hoffman Y. Sestayo M. J. Larson Albrecht Karle D. Tosi J. P. Rodrigues Anatoli Fedynitch Stijn Buitink T. Stezelberger P. Niessen A. Tamburro D. Turcan M. Dierckxsens Jenni Adams Christian Spiering Nathan Whitehorn S. Cohen Fabian Kislat Xinhua Bai S. Boeser Justin Vandenbroucke I. Taboada Francis Halzen C. Ha Dmitry Chirkin Alexander Kappes R. Morse K. Mase J. L. Kelley O. Fadiran M. Merck G. Kroll Markus Ahlers K. Meagher B. D. Fox Wolfgang Rhode M. L. Benabderrahmane J. Dreyer T. Abu-zayyad A. Franckowiak S. Seunarine Y. Abdou Carsten Rott J. Miller J. P. Huelss Ph. Herquet A. Slipak S. Tilav A. Stoessl M. Bissok S. Hickford A. Schoenwald R. G. Stokstad D. Rutledge S. Bechet R. Porrata Pratik Majumdar Gerald Przybylski J. Van Santen R. Wischnewski P. Redl D. Heinen Xianwu Xu Martin Wolf C. Colnard C. Bohm K. Laihem M. Stamatikos M. Olivo T. Straszheim Paraic A. Kenny Juanan Aguilar D. Bertrand Samvel Ter-antonyan L. Demiroers J. K. Becker Takao Kuwabara Kael Hanson Kael Hanson J. Petrovic H. G. Sander B. Christy S. Hussain D. J. Koskinen M. Vehring D. F. Cowen Chun Xu F. Rothmaier Karl-heinz Kampert Kirill Filimonov A. Ishihara Matthias Geisler K. Hultqvist A. Schultes P. Berghaus Timo Karg B. Ruzybayev M. M. Foerster Rasha Abbasi M. Wallraff J. Blumenthal A. Goldschmidt S. Euler M. Voge J. C. Gallagher M. Gurtner Darren Grant S. Panknin Damian Pieloth D. Hubert M. Stüer A. M. Brown Paolo Desiati Allan Hallgren J. A. Goodman Sandro Kopper N. Milke Olga Botner George Japaridze O. Engdegård Aongus O'murchadha Elisa Resconi J. Berdermann Henrik J. Johansson Tim Ruhe M. Walter A. Rizzo T. Gluesenkamp Simona Toscano D. Berley G. C. Hill R. W. Ellsworth K. Schatto G. Kohnen Michael J. Baker J. W. Nam L. Gladstone D. Seckel S. H. Seo Subir Sarkar D. R. Nygren A. R. Fazely Tyce Deyoung P. A. Toale S. Odrowski D. J. Boersma S.j. Lafebre A. Homeier Christopher Wiebusch J. Daughhetee J. H. Koehne F. Clevermann J. P. Yanez G. W. Sullivan James E. Braun Q. Swillens R. J. Lauer C. De Clercq David A. Williams S. W. Barwick Todor Stanev C. Wendt F. Descamps A. Tepe R. Franke C. Walck Thomas K. Gaisser G. B. Yodh A. Gross A. Gross M. Labare A. Silvestri Karen Andeen R. Nahnhauer M. Schunck K. Kuehn W. Huelsnitz K. Helbing R. Ehrlich A. Olivas T. Krings Hermann Kolanoski H. Landsman M. V. D'agostino

subject

Signals TELESCOPE Absolute noise level Astrophysics::High Energy Astrophysical Phenomena Flux FOS: Physical sciences Astrophysics 7. Clean energy 01 natural sciences IceCube Neutrino Observatory law.invention IceCube Telescope Absolute noise level; Acoustic neutrino detection; Neutrino flux limit Neutrino flux limit law SIGNALS 0103 physical sciences WATER Detection theory 010306 general physics Telescope Instrumentation and Methods for Astrophysics (astro-ph.IM)Physics Acoustic neutrino detector 010308 nuclear & particles physics Detector Astrophysics::Instrumentation and Methods for Astrophysics Water Astronomy and Astrophysics Geodesy Acoustic neutrino detection Noise Neutrino detector Physics and Astronomy 13. Climate action ddc:540 Neutrino Astrophysics - Instrumentation and Methods for Astrophysics

description

The detection of acoustic signals from ultra-high energy neutrino interactions is a promising method to measure the tiny flux of cosmogenic neutrinos expected on Earth. The energy threshold for this process depends strongly on the absolute noise level in the target material. The South Pole Acoustic Test Setup (SPATS), deployed in the upper part of four boreholes of the IceCube Neutrino Observatory, has monitored the noise in Antarctic ice at the geographic South Pole for more than two years down to 500 m depth. The noise is very stable and Gaussian distributed. Lacking an in-situ calibration up to now, laboratory measurements have been used to estimate the absolute noise level in the 10 to 50 kHz frequency range to be smaller than 20 mPa. Using a threshold trigger, sensors of the South Pole Acoustic Test Setup registered acoustic pulse-like events in the IceCube detector volume and its vicinity. Acoustic signals from refreezing IceCube holes and from anthropogenic sources have been used to localize acoustic events. Monte Carlo simulations of sound propagating from the established sources to the SPATS sensors have allowed to check corresponding model expectations. An upper limit on the neutrino flux at energies $E_��> 10^{11}$ GeV is derived from acoustic data taken over eight months.

year	journal	country	edition	language
2011-03-07

10.1016/j.astropartphys.2011.09.004 https://bib-pubdb1.desy.de/record/95257