Muons are constantly produced in cosmic-rays and reach the Earth surface with a flux of about 160 particles per second per square meter. The abundance of muons with respect to other cosmic particles and their capability to cross dense materials with low absorption rate allow them to be exploited for large scale geological or human-made object imaging. Muon radiography is based on similar principles as X-ray radiography, measuring the surviving rate of muons escaping the target and relating it to the mass distribution inside the object. In the course of decades, after the first application in 1955, the methodology has been applied in several different fields. Muography allows us to measure the internal density distribution of the investigated object, or to simply highlight the presence of void regions by observing any excess of muons. Most of these applications require the detector to be installed below the rock being probed. In case that possible installation sites are not easily accessible by people, common instrumentation cannot be installed. A novel borehole cylindrical detector for muon radiography has been recently developed to deal with these conditions. It has been realized with a cylindrical geometry to fit typical borehole dimensions. Its design maximizes the geometrical acceptance, minimizing the dead spaces by the use of arc-shaped scintillators. The details of the construction and preliminary results of the first usage are described in this paper. © 2022 by the authors.

Muon Radiography Investigations in Boreholes with a Newly Designed Cylindrical Detector / D'Errico, M.; Ambrosino, F.; Cimmino, L.; Masone, V.; Mirra, M.; Saracino, G.; Roscilli, L.. - In: INSTRUMENTS. - ISSN 2410-390X. - 7:1(2023), p. 2. [10.3390/instruments7010002]

Muon Radiography Investigations in Boreholes with a Newly Designed Cylindrical Detector

D'Errico M.;Ambrosino F.;Cimmino L.;Saracino G.;
2023

Abstract

Muons are constantly produced in cosmic-rays and reach the Earth surface with a flux of about 160 particles per second per square meter. The abundance of muons with respect to other cosmic particles and their capability to cross dense materials with low absorption rate allow them to be exploited for large scale geological or human-made object imaging. Muon radiography is based on similar principles as X-ray radiography, measuring the surviving rate of muons escaping the target and relating it to the mass distribution inside the object. In the course of decades, after the first application in 1955, the methodology has been applied in several different fields. Muography allows us to measure the internal density distribution of the investigated object, or to simply highlight the presence of void regions by observing any excess of muons. Most of these applications require the detector to be installed below the rock being probed. In case that possible installation sites are not easily accessible by people, common instrumentation cannot be installed. A novel borehole cylindrical detector for muon radiography has been recently developed to deal with these conditions. It has been realized with a cylindrical geometry to fit typical borehole dimensions. Its design maximizes the geometrical acceptance, minimizing the dead spaces by the use of arc-shaped scintillators. The details of the construction and preliminary results of the first usage are described in this paper. © 2022 by the authors.
2023
Muon Radiography Investigations in Boreholes with a Newly Designed Cylindrical Detector / D'Errico, M.; Ambrosino, F.; Cimmino, L.; Masone, V.; Mirra, M.; Saracino, G.; Roscilli, L.. - In: INSTRUMENTS. - ISSN 2410-390X. - 7:1(2023), p. 2. [10.3390/instruments7010002]
File in questo prodotto:
File Dimensione Formato  
instruments-07-00002.pdf

accesso aperto

Licenza: Creative commons
Dimensione 8.31 MB
Formato Adobe PDF
8.31 MB Adobe PDF Visualizza/Apri

I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.

Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11588/921474
Citazioni
  • ???jsp.display-item.citation.pmc??? ND
  • Scopus 0
  • ???jsp.display-item.citation.isi??? ND
social impact