Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole

The Askaryan Radio Array (ARA) experiment at the South Pole is designed to detect high-energy neutrinos which, via in-ice interactions, produce coherent radiation at frequencies up to 1000 MHz. Characterization of ice birefringence, and its effect upon wave polarization, is proposed to enable range...

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Main Authors:	Jordan, Thomas M, Besson, David, Kravchenko, I, Latif, U, Madison, B, Nokikov, A, Schultz, A
Format:	Article in Journal/Newspaper
Language:	English
Published:	2020
Subjects:	South Pole Annals of Glaciology ice core South pole
Online Access:	https://hdl.handle.net/1983/989e9757-015e-40f3-b4bb-ff504efc7dec https://research-information.bris.ac.uk/en/publications/989e9757-015e-40f3-b4bb-ff504efc7dec https://doi.org/10.1017/ aog.2020.18 https://research-information.bris.ac.uk/ws/files/234307371/Full_text_PDF_final_published_version_.pdf

id	ftubristolcris:oai:research-information.bris.ac.uk:publications/989e9757-015e-40f3-b4bb-ff504efc7dec
record_format	openpolar
spelling	ftubristolcris:oai:research-information.bris.ac.uk:publications/989e9757-015e-40f3-b4bb-ff504efc7dec 2024-01-28T09:58:42+01:00 Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole Jordan, Thomas M Besson, David Kravchenko, I Latif, U Madison, B Nokikov, A Schultz, A 2020 application/pdf https://hdl.handle.net/1983/989e9757-015e-40f3-b4bb-ff504efc7dec https://research-information.bris.ac.uk/en/publications/989e9757-015e-40f3-b4bb-ff504efc7dec https://doi.org/10.1017/ aog.2020.18 https://research-information.bris.ac.uk/ws/files/234307371/Full_text_PDF_final_published_version_.pdf eng eng info:eu-repo/semantics/openAccess Jordan , T M , Besson , D , Kravchenko , I , Latif , U , Madison , B , Nokikov , A & Schultz , A 2020 , ' Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole ' , Annals of Glaciology , pp. 1-8 . https://doi.org/10.1017/ aog.2020.18 article 2020 ftubristolcris 2024-01-04T23:59:40Z The Askaryan Radio Array (ARA) experiment at the South Pole is designed to detect high-energy neutrinos which, via in-ice interactions, produce coherent radiation at frequencies up to 1000 MHz. Characterization of ice birefringence, and its effect upon wave polarization, is proposed to enable range estimation to a neutrino interaction and hence aid in neutrino energy reconstruction. Using radio transmitter calibration sources, the ARA collaboration recently measured polarization-dependent time delay variations and reported significant time delays for trajectories perpendicular to ice flow, but not parallel. To explain these observations, and assess the capability for range estimation, we use fabric data from the SPICE ice core to model ice birefringence and construct a bounding radio propagation model that predicts polarization time delays. We compare the model with new data from December 2018 and demonstrate that the measurements are consistent with the prevailing horizontal crystallographic axis aligned near-perpendicular to ice flow. The study supports the notion that range estimation can be performed for near flow-perpendicular trajectories, although tighter constraints on fabric orientation are desirable for improving the accuracy of estimates. Article in Journal/Newspaper Annals of Glaciology ice core South pole University of Bristol: Bristol Research South Pole
institution	Open Polar
collection	University of Bristol: Bristol Research
op_collection_id	ftubristolcris
language	English
description	The Askaryan Radio Array (ARA) experiment at the South Pole is designed to detect high-energy neutrinos which, via in-ice interactions, produce coherent radiation at frequencies up to 1000 MHz. Characterization of ice birefringence, and its effect upon wave polarization, is proposed to enable range estimation to a neutrino interaction and hence aid in neutrino energy reconstruction. Using radio transmitter calibration sources, the ARA collaboration recently measured polarization-dependent time delay variations and reported significant time delays for trajectories perpendicular to ice flow, but not parallel. To explain these observations, and assess the capability for range estimation, we use fabric data from the SPICE ice core to model ice birefringence and construct a bounding radio propagation model that predicts polarization time delays. We compare the model with new data from December 2018 and demonstrate that the measurements are consistent with the prevailing horizontal crystallographic axis aligned near-perpendicular to ice flow. The study supports the notion that range estimation can be performed for near flow-perpendicular trajectories, although tighter constraints on fabric orientation are desirable for improving the accuracy of estimates.
format	Article in Journal/Newspaper
author	Jordan, Thomas M Besson, David Kravchenko, I Latif, U Madison, B Nokikov, A Schultz, A
spellingShingle	Jordan, Thomas M Besson, David Kravchenko, I Latif, U Madison, B Nokikov, A Schultz, A Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole
author_facet	Jordan, Thomas M Besson, David Kravchenko, I Latif, U Madison, B Nokikov, A Schultz, A
author_sort	Jordan, Thomas M
title	Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole
title_short	Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole
title_full	Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole
title_fullStr	Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole
title_full_unstemmed	Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole
title_sort	modeling ice birefringence and oblique radio wave propagation for neutrino detection at the south pole
publishDate	2020
url	https://hdl.handle.net/1983/989e9757-015e-40f3-b4bb-ff504efc7dec https://research-information.bris.ac.uk/en/publications/989e9757-015e-40f3-b4bb-ff504efc7dec https://doi.org/10.1017/ aog.2020.18 https://research-information.bris.ac.uk/ws/files/234307371/Full_text_PDF_final_published_version_.pdf
geographic	South Pole
geographic_facet	South Pole
genre	Annals of Glaciology ice core South pole
genre_facet	Annals of Glaciology ice core South pole
op_source	Jordan , T M , Besson , D , Kravchenko , I , Latif , U , Madison , B , Nokikov , A & Schultz , A 2020 , ' Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole ' , Annals of Glaciology , pp. 1-8 . https://doi.org/10.1017/ aog.2020.18
op_rights	info:eu-repo/semantics/openAccess
_version_	1789329792534839296

Modeling ice birefringence and oblique radio wave propagation for neutrino detection at the South Pole

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