The NuMoon Experiment: Preliminary results and upper limits on UHE particles

G. K. Krampah; S. Buitink; J. Bhavani; M. Desmet; A. Corstanje; H. Falcke; B. M. Hare; J. R. Hörandel; T. Huege; N. Karasthatis; K. Mulrey; P. Mitra; A. Nelles; K. Nivedita; H. Pandya; J. P. Rachen; O. Scholten; S. ter Veen; S. Thoudam; T. N.G. Trinh; T. Winchen

The NuMoon Experiment: Preliminary results and upper limits on UHE particles

G. K. Krampah
, S. Buitink
, J. Bhavani
, M. Desmet
, A. Corstanje
, H. Falcke
, B. M. Hare
, J. R. Hörandel
, T. Huege
, N. Karasthatis
, K. Mulrey
, P. Mitra
, A. Nelles
, K. Nivedita
, H. Pandya
, J. P. Rachen
, O. Scholten
, S. ter Veen
, S. Thoudam
, T. N.G. Trinh

T. Winchen

Research output: Contribution to journal › Conference article › peer-review

1 Scopus citations

Abstract

The main goal of the NuMoon experiment is study ultra-high energy cosmic rays and neutrinos interacting with the Moon using ground-based radio telescopes. Ultra-high energy (UHE) particles interacting with the Moon produce particle showers in the regolith. Due to charge asymmetry in the shower front, a short broadband coherent burst of radio emission is produced - via a phenomenon referred to as the Askaryan effect. With ground based radio telescopes, such pulses can be searched for. The LOw Frequency ARray (LOFAR) - a radio observatory located in the Netherlands - is currently the largest radio array operating at frequencies between 110 − 190 MHz; an optimal frequency range for Lunar signal search. A pulse search on the near-surface of the Moon is carried out. This requires a proper understanding of the background noise and other factors (like the ionosphere) that could have an adverse effect on the signal. In this contribution, we discuss results from first Lunar observations with LOFAR and the development of a trigger algorithm for future observations. Results from a detailed Monte-Carlo (MC) simulation of the effective lunar aperture for UHE particles and the expected sensitivity to the UHE particle flux are shown.

Original language	British English
Article number	011
Journal	Proceedings of Science
Volume	424
State	Published - 25 Oct 2023
Event	9th International Workshop on Acoustic and Radio EeV Neutrino Detection Activities, ARENA 2022 - Santiago de Compostela, Spain Duration: 7 Jun 2022 → 10 Jun 2022

Cite this

Krampah, G. K., Buitink, S., Bhavani, J., Desmet, M., Corstanje, A., Falcke, H., Hare, B. M., Hörandel, J. R., Huege, T., Karasthatis, N., Mulrey, K., Mitra, P., Nelles, A., Nivedita, K., Pandya, H., Rachen, J. P., Scholten, O., ter Veen, S., Thoudam, S., ... Winchen, T. (2023). The NuMoon Experiment: Preliminary results and upper limits on UHE particles. Proceedings of Science, 424, Article 011.

@article{f9e8a633f07a4baf86dfeba255780d34,

title = "The NuMoon Experiment: Preliminary results and upper limits on UHE particles",

abstract = "The main goal of the NuMoon experiment is study ultra-high energy cosmic rays and neutrinos interacting with the Moon using ground-based radio telescopes. Ultra-high energy (UHE) particles interacting with the Moon produce particle showers in the regolith. Due to charge asymmetry in the shower front, a short broadband coherent burst of radio emission is produced - via a phenomenon referred to as the Askaryan effect. With ground based radio telescopes, such pulses can be searched for. The LOw Frequency ARray (LOFAR) - a radio observatory located in the Netherlands - is currently the largest radio array operating at frequencies between 110 − 190 MHz; an optimal frequency range for Lunar signal search. A pulse search on the near-surface of the Moon is carried out. This requires a proper understanding of the background noise and other factors (like the ionosphere) that could have an adverse effect on the signal. In this contribution, we discuss results from first Lunar observations with LOFAR and the development of a trigger algorithm for future observations. Results from a detailed Monte-Carlo (MC) simulation of the effective lunar aperture for UHE particles and the expected sensitivity to the UHE particle flux are shown.",

author = "Krampah, \{G. K.\} and S. Buitink and J. Bhavani and M. Desmet and A. Corstanje and H. Falcke and Hare, \{B. M.\} and H{\"o}randel, \{J. R.\} and T. Huege and N. Karasthatis and K. Mulrey and P. Mitra and A. Nelles and K. Nivedita and H. Pandya and Rachen, \{J. P.\} and O. Scholten and \{ter Veen\}, S. and S. Thoudam and Trinh, \{T. N.G.\} and T. Winchen",

note = "Publisher Copyright: {\textcopyright} Copyright owned by the author(s) under the terms of the Creative Commons.; 9th International Workshop on Acoustic and Radio EeV Neutrino Detection Activities, ARENA 2022 ; Conference date: 07-06-2022 Through 10-06-2022",

year = "2023",

month = oct,

day = "25",

language = "British English",

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journal = "Proceedings of Science",

issn = "1824-8039",

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Krampah, GK, Buitink, S, Bhavani, J, Desmet, M, Corstanje, A, Falcke, H, Hare, BM, Hörandel, JR, Huege, T, Karasthatis, N, Mulrey, K, Mitra, P, Nelles, A, Nivedita, K, Pandya, H, Rachen, JP, Scholten, O, ter Veen, S, Thoudam, S, Trinh, TNG & Winchen, T 2023, 'The NuMoon Experiment: Preliminary results and upper limits on UHE particles', Proceedings of Science, vol. 424, 011.

TY - JOUR

T1 - The NuMoon Experiment

T2 - 9th International Workshop on Acoustic and Radio EeV Neutrino Detection Activities, ARENA 2022

AU - Krampah, G. K.

AU - Buitink, S.

AU - Bhavani, J.

AU - Desmet, M.

AU - Corstanje, A.

AU - Falcke, H.

AU - Hare, B. M.

AU - Hörandel, J. R.

AU - Huege, T.

AU - Karasthatis, N.

AU - Mulrey, K.

AU - Mitra, P.

AU - Nelles, A.

AU - Nivedita, K.

AU - Pandya, H.

AU - Rachen, J. P.

AU - Scholten, O.

AU - ter Veen, S.

AU - Thoudam, S.

AU - Trinh, T. N.G.

AU - Winchen, T.

PY - 2023/10/25

Y1 - 2023/10/25

N2 - The main goal of the NuMoon experiment is study ultra-high energy cosmic rays and neutrinos interacting with the Moon using ground-based radio telescopes. Ultra-high energy (UHE) particles interacting with the Moon produce particle showers in the regolith. Due to charge asymmetry in the shower front, a short broadband coherent burst of radio emission is produced - via a phenomenon referred to as the Askaryan effect. With ground based radio telescopes, such pulses can be searched for. The LOw Frequency ARray (LOFAR) - a radio observatory located in the Netherlands - is currently the largest radio array operating at frequencies between 110 − 190 MHz; an optimal frequency range for Lunar signal search. A pulse search on the near-surface of the Moon is carried out. This requires a proper understanding of the background noise and other factors (like the ionosphere) that could have an adverse effect on the signal. In this contribution, we discuss results from first Lunar observations with LOFAR and the development of a trigger algorithm for future observations. Results from a detailed Monte-Carlo (MC) simulation of the effective lunar aperture for UHE particles and the expected sensitivity to the UHE particle flux are shown.

AB - The main goal of the NuMoon experiment is study ultra-high energy cosmic rays and neutrinos interacting with the Moon using ground-based radio telescopes. Ultra-high energy (UHE) particles interacting with the Moon produce particle showers in the regolith. Due to charge asymmetry in the shower front, a short broadband coherent burst of radio emission is produced - via a phenomenon referred to as the Askaryan effect. With ground based radio telescopes, such pulses can be searched for. The LOw Frequency ARray (LOFAR) - a radio observatory located in the Netherlands - is currently the largest radio array operating at frequencies between 110 − 190 MHz; an optimal frequency range for Lunar signal search. A pulse search on the near-surface of the Moon is carried out. This requires a proper understanding of the background noise and other factors (like the ionosphere) that could have an adverse effect on the signal. In this contribution, we discuss results from first Lunar observations with LOFAR and the development of a trigger algorithm for future observations. Results from a detailed Monte-Carlo (MC) simulation of the effective lunar aperture for UHE particles and the expected sensitivity to the UHE particle flux are shown.

UR - https://www.scopus.com/pages/publications/85179121887

M3 - Conference article

AN - SCOPUS:85179121887

SN - 1824-8039

VL - 424

JO - Proceedings of Science

JF - Proceedings of Science

M1 - 011

Y2 - 7 June 2022 through 10 June 2022

ER -

The NuMoon Experiment: Preliminary results and upper limits on UHE particles

Abstract

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