Atmospheric muon flux suppression at potential new low-radiation Underground Physics Laboratory in Israel

Nadav Hargittai; Igor Zolkin; Yiftah Silver; Yan Benhammou; Gilad Mizrachi; Hagar Landsman; Erez Etzion; Ran Budnik

doi:10.1140/epjc/s10052-025-14815-5

Atmospheric muon flux suppression at potential new low-radiation Underground Physics Laboratory in Israel

Nadav Hargittai^*
, Igor Zolkin
, Yiftah Silver
, Yan Benhammou
, Gilad Mizrachi
, Hagar Landsman
, Erez Etzion
, Ran Budnik

^*Corresponding author for this work

Department of Particle Physics and Astrophysics

Research output: Contribution to journal › Article › peer-review

Abstract

The residual atmospheric muon flux was measured at a candidate site for a new underground, low-radiation physics laboratory beneath the Kokhav HaYarden national park in Israel. Located inside the tunnels of a hydroelectric pumped-storage facility, the proposed site benefits from a vertical rock overburden of 361 m, large potential floorspace, and easy access by road. A muon hodoscope of vertically stacked wide-area plastic scintillator plates was employed to measure the suppression in the integrated muon flux at the site as compared with above ground at sea level. The suppression factor is reported at 4456±77, expressed as 3.75±0.2×10-6cm-2 s-1 in absolute terms, corresponding to an effective overburden of roughly 873 m.w.e. Furthermore, the asymmetric topography of the mountain above and its muon shadow are clearly visible in the angular data. Finally, auxiliary environmental measurements recorded low background radon activity at 28.3±14.0 Bq m-3. The experimental campaign thus succeeded in demonstrating the viability of the site’s working conditions for future scientific research.

Original language	English
Article number	1083
Journal	European Physical Journal C
Volume	85
Issue number	9
DOIs	https://doi.org/10.1140/epjc/s10052-025-14815-5
Publication status	Published - Sept 2025

Funding

This work was supported by the Weizmann Institute of Science Krenter-Perinot Center for High-Energy Particle Physics, the Deloro center and ISF Grant 1859/22. We thank Gil Doron and Yariv Shalem from Kokhav HaYarden pumped storage facility and Elhanan Hovav and Yuval Sharon for their invaluable assistance and goodwill.

All Science Journal Classification (ASJC) codes

Engineering (miscellaneous)
Physics and Astronomy (miscellaneous)

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10.1140/epjc/s10052-025-14815-5Licence: CC BY

Cite this

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title = "Atmospheric muon flux suppression at potential new low-radiation Underground Physics Laboratory in Israel",

abstract = "The residual atmospheric muon flux was measured at a candidate site for a new underground, low-radiation physics laboratory beneath the Kokhav HaYarden national park in Israel. Located inside the tunnels of a hydroelectric pumped-storage facility, the proposed site benefits from a vertical rock overburden of 361 m, large potential floorspace, and easy access by road. A muon hodoscope of vertically stacked wide-area plastic scintillator plates was employed to measure the suppression in the integrated muon flux at the site as compared with above ground at sea level. The suppression factor is reported at 4456±77, expressed as 3.75±0.2×10-6cm-2 s-1 in absolute terms, corresponding to an effective overburden of roughly 873 m.w.e. Furthermore, the asymmetric topography of the mountain above and its muon shadow are clearly visible in the angular data. Finally, auxiliary environmental measurements recorded low background radon activity at 28.3±14.0 Bq m-3. The experimental campaign thus succeeded in demonstrating the viability of the site{\textquoteright}s working conditions for future scientific research.",

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AU - Hargittai, Nadav

AU - Zolkin, Igor

AU - Silver, Yiftah

AU - Benhammou, Yan

AU - Mizrachi, Gilad

AU - Landsman, Hagar

AU - Etzion, Erez

AU - Budnik, Ran

PY - 2025/9

Y1 - 2025/9

N2 - The residual atmospheric muon flux was measured at a candidate site for a new underground, low-radiation physics laboratory beneath the Kokhav HaYarden national park in Israel. Located inside the tunnels of a hydroelectric pumped-storage facility, the proposed site benefits from a vertical rock overburden of 361 m, large potential floorspace, and easy access by road. A muon hodoscope of vertically stacked wide-area plastic scintillator plates was employed to measure the suppression in the integrated muon flux at the site as compared with above ground at sea level. The suppression factor is reported at 4456±77, expressed as 3.75±0.2×10-6cm-2 s-1 in absolute terms, corresponding to an effective overburden of roughly 873 m.w.e. Furthermore, the asymmetric topography of the mountain above and its muon shadow are clearly visible in the angular data. Finally, auxiliary environmental measurements recorded low background radon activity at 28.3±14.0 Bq m-3. The experimental campaign thus succeeded in demonstrating the viability of the site’s working conditions for future scientific research.

AB - The residual atmospheric muon flux was measured at a candidate site for a new underground, low-radiation physics laboratory beneath the Kokhav HaYarden national park in Israel. Located inside the tunnels of a hydroelectric pumped-storage facility, the proposed site benefits from a vertical rock overburden of 361 m, large potential floorspace, and easy access by road. A muon hodoscope of vertically stacked wide-area plastic scintillator plates was employed to measure the suppression in the integrated muon flux at the site as compared with above ground at sea level. The suppression factor is reported at 4456±77, expressed as 3.75±0.2×10-6cm-2 s-1 in absolute terms, corresponding to an effective overburden of roughly 873 m.w.e. Furthermore, the asymmetric topography of the mountain above and its muon shadow are clearly visible in the angular data. Finally, auxiliary environmental measurements recorded low background radon activity at 28.3±14.0 Bq m-3. The experimental campaign thus succeeded in demonstrating the viability of the site’s working conditions for future scientific research.

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DO - 10.1140/epjc/s10052-025-14815-5

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VL - 85

JO - European Physical Journal C

JF - European Physical Journal C

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ER -

Atmospheric muon flux suppression at potential new low-radiation Underground Physics Laboratory in Israel

Abstract

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