Cosmic-Ray Tomography for Border Security
Sarah Barnes,A.Sh. Georgadze,Andrea Giammanco,Madis Kiisk,V. A. Kudryavtsev,Maxime Lagrange,Olin Lyod Pinto +6 more
TL;DR: Cosmic ray tomography (CRT) is a promising technology for cargo screening as discussed by the authors , which has average energies of around 10,000 times larger than a typical X-ray and therefore can penetrate relatively large and dense materials.
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Abstract: A key task for customs workers is the interception of hazardous, illegal and counterfeit items in order to protect the health and safety of citizens. However, it is estimated that only a small fraction of cargo is inspected and an even smaller fraction of trafficked goods are detected. Today, the most widely used technology for scanning vehicles, ranging from vans and trucks to railcars, is γ ray and X-ray radiography. New technologies are required to overcome current technological shortcomings, such as the inability to detect the target material composition, the usage of harmful ionising radiation sources and the resultant low throughput. Cosmic ray tomography (CRT) is a promising technology for cargo screening. Cosmic ray muons have average energies of around 10,000 times larger than a typical X-ray and therefore can penetrate relatively large and dense materials. By analysing muon scattering, it is possible to identify materials hidden inside shielding that is too thick or deep for other imaging methods. CRT is also completely passive, exploiting naturally occurring secondary cosmic radiation, and is therefore safe for humans and animals. Contrary to conventional X-ray- or γ-ray-based imaging techniques, CRT also allows material differentiation and anomaly localisation within the cargo or vehicle through the provision of 3D images. This article reviews the current state-of-the-art technology in CRT, critically assessing the strengths and weaknesses of the method, and suggesting further directions for development.
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Citations
Muography
Hiroyuki K. M. Tanaka,Cristiano Bozza,A. Bross,Elena Cantoni,O. Catalano,G. Cerretto,A. Giammanco,Jon Gluyas,I. Gnesi,Marko Holma,Tadahiro Kin,I. Roche,Giovanni Leone,Zhiyi Liu,D. L. Presti,J. Marteau,Jun Matsushima,László Oláh,N. Polukhina,Surireddi S. V. S. Ramakrishna,Marco Sellone,A. H. Shinohara,Sara Steigerwald,Kenji Sumiya,Lee Thompson,Valeri Tioukov,Yusuke Yokota,D. Varga +27 more
TL;DR: Muography leverages cosmic-ray muons' high penetrating power and relativistic nature for various applications, including imagery, positioning, navigation, timing, and secured communication, with global applicability and reproducible results across diverse fields.
7
Towards a muon scattering tomography system for both low-Z and high-Z materials
Jiahui Chen,Huiling Li,Yiyue Li,Pingcheng Liu +3 more
TL;DR: A novel muon scattering tomography system is proposed to discriminate both low-Z and high-Z materials by measuring the momentum of low-energy muons. The system utilizes a Cherenkov detector and a momentum-dependent track reconstruction algorithm. The results show that the system can significantly improve the separation power of low-Z materials.
Muons for cultural heritage
M. Moussawi,Andrea Giammanco,Vishal Kumar,Maxime Lagrange +3 more
- 15 Sep 2023
TL;DR: Muography has the potential to non-destructively image small cultural heritage objects, but its applicability is limited by the size and density of the object.
Image reconstruction algorithm for momentum dependent muon scattering tomography
Junghyun Bae,Rose Montgomery,Stylianos Chatzidakis +2 more
TL;DR: A new image reconstruction algorithm for muon scattering tomography maximizes cosmic ray muon utility by incorporating muon momentum and scattering angle information, improving image resolution and density quantification without increasing computation costs.
2
Simulation and validation studies of a large drift tube muon tracker.
Guangliang Yang,Josh Schoetker,D. Poulson,E. Guardincerri,John Matthew Durham,Sven Vogel,Shaun Hoerner,Derek Aberle,K. Sun,C. Morris,Ralf Kaiser,Andrew G. Osborne +11 more
TL;DR: Researchers validated a Monte Carlo simulation of a Giant Muon Tracker using experimental data, demonstrating excellent agreement between simulated and actual imaging results of high-Z element samples, enabling nondestructive imaging capabilities.
2
References
Geant4—a simulation toolkit
S. Agostinelli,John Allison,K. Amako,J. Apostolakis,Henrique Araujo,P. Arce,Makoto Asai,D. Axen,S. Banerjee,G. Barrand,F. Behner,Lorenzo Bellagamba,J. Boudreau,L. Broglia,A. Brunengo,H. Burkhardt,Stephane Chauvie,J. Chuma,R. Chytracek,Gene Cooperman,G. Cosmo,P. V. Degtyarenko,Andrea Dell'Acqua,G. Depaola,D. Dietrich,R. Enami,A. Feliciello,C. Ferguson,H. Fesefeldt,Gunter Folger,Franca Foppiano,Alessandra Forti,S. Garelli,S. Gianì,R. Giannitrapani,D. Gibin,J. J. Gomez Y Cadenas,I. González,G. Gracia Abril,G. Greeniaus,Walter Greiner,Vladimir Grichine,A. Grossheim,Susanna Guatelli,P. Gumplinger,R. Hamatsu,K. Hashimoto,H. Hasui,A. Heikkinen,A. S. Howard,Vladimir Ivanchenko,A. Johnson,F.W. Jones,J. Kallenbach,Naoko Kanaya,M. Kawabata,Y. Kawabata,M. Kawaguti,S.R. Kelner,Paul R. C. Kent,A. Kimura,T. Kodama,R. P. Kokoulin,M. Kossov,Hisaya Kurashige,E. Lamanna,Tapio Lampén,V. Lara,Veronique Lefebure,F. Lei,M. Liendl,W. S. Lockman,Francesco Longo,S. Magni,M. Maire,E. Medernach,K. Minamimoto,P. Mora de Freitas,Yoshiyuki Morita,K. Murakami,M. Nagamatu,R. Nartallo,Petteri Nieminen,T. Nishimura,K. Ohtsubo,M. Okamura,S. W. O'Neale,Y. Oohata,K. Paech,J Perl,Andreas Pfeiffer,Maria Grazia Pia,F. Ranjard,A.M. Rybin,S.S Sadilov,E. Di Salvo,Giovanni Santin,Takashi Sasaki,N. Savvas,Y. Sawada,Stefan Scherer,S. Sei,V. Sirotenko,David J. Smith,N. Starkov,H. Stoecker,J. Sulkimo,M. Takahata,Satoshi Tanaka,E. Tcherniaev,E. Safai Tehrani,M. Tropeano,P. Truscott,H. Uno,L. Urbán,P. Urban,M. Verderi,A. Walkden,W. Wander,H. Weber,J.P. Wellisch,Torre Wenaus,D.C. Williams,Douglas Wright,T. Yamada,H. Yoshida,D. Zschiesche +126 more
TL;DR: The Gelfant 4 toolkit as discussed by the authors is a toolkit for simulating the passage of particles through matter, including a complete range of functionality including tracking, geometry, physics models and hits.
Oxford University Press : Review of Particle Physics, 2020-2021
P A Zyla,Paul William Richardson,Oleg Zenin,A Bettini,L. Garren,Vorobyev,D. E. Groom,M Kenzie,G Zanderighi,M Karliner,Debadi Chakraborty,D. M. Asner,V A Khoze,Torbjörn Sjöstrand,J. Beringer,A A Godizov,Siegfried Bethke,V A Petrov,L Verde,G. Gerbier,B C Allanach,R. Kowalewski,Paolo Nason,Sophia L. Stone,Y. Sakai,Jamie Holder,O. Schneider,E Pianori,M. Silari,Keith A. Olive,Alessandro Cerri,H J Gerber,A. de Gouvea,Ron L. Workman,R A Ryutin,K Rabbertz,V. S. Lugovsky,T Mannel,Filip Moortgat,M S Sozzi,Andreas Vogt,Fabio Sauli,M Mikhasenko,C. Hanhart,T. Sumiyoshi,B. N. Ratcliff,J Anderson,Howard Baer,John Matthews,H. R. Gallagher,M C Gonzalez-Garcia,Thomas DeGrand,A Soffer,A Höcker,W-M. Yao,R Yoshida,Mario Antonelli,Arnulf Quadt,J Tanaka,G. Venanzoni,Yoshinari Hayato,J Schwiening,Giancarlo D'Ambrosio,U Thoma,K. S. Lugovsky,M Ryskin,G Rybka,Howard E. Haber,Matthias Neubert,M Ramsey-Musolf,William J. Marciano,Ken Ichi Hikasa,Burkert,Peter Skands,S. Sánchez Navas,Michael Syphers,J.J. Hernández-Rey,D Wands,A J Schwartz,A Freitas,G Aielli,Zoltan Ligeti,Andreas Ringwald,P. Nevski,T Shutt,D J Robinson,Jonathan L. Rosner,T Hyodo,V I Belousov,Alberto Masoni,O Buchmuller,Douglas Scott,Christian Spiering,David H. Weinberg,Brian D. Fields,G P Zeller,M A Bychkov,Charles G Wohl,E C Aschenauer,K M Black,D A Dwyer,Manuel Drees,Christoph Grab,Sw. Banerjee,L.J. Rosenberg,M. C. Goodman,George F. Smoot,David Milstead,B. K. Heltsley,L. Tiator,Th. Gutsche,N. P. Tkachenko,Daniel de Florian,Georg G. Raffelt,Frank Zimmermann,Jonas Rademacker,S. Rolli,Sharma,C. Grojean,Ezhela,Masaharu Tanabashi,L Baudis,Claude Amsler,J Lesgourgues,T. Basaglia,J. Erler,C. L. Woody,Joey Huston,Klaus Mönig,A Pomarol,Y Gershtein,John Terning,P Urquijo,L. R. Wiencke,Daniel Tovey,A Lusiani,J Ellis,Kurtis F Johnson,A. Piepke,R. M. Barnett,Eberhard Klempt,S. T. Petcov,S Profumo,A. Stahl,R S Thorne,P Eerola,Younghoon Kwon,Manuella Vincter,Subir Sarkar,C. Patrignani,Martin White,Ren-Yuan Zhu,Fabio Maltoni,G. Dissertori,Y Sumino,C Lourengo,M D'Onofrio,B. Krusche,Herbert K. Dreiner,Frank Krauss,Meenakshi Narain,N Varelas,Wolfgang Walkowiak,Gavin P. Salam,Christian W. Bauer,W Vogelsang,Augusto Ceccucci,Stefan Roesler,D J Miller,J Hisano,A Pich,K Terashi,Maksym Titov,Ofer Lahav,W Zheng,U Egede,Bogdan A. Dobrescu,Marcela Carena,Marumi Kado,Orin I. Dahl,M Moskovic,Martin Grunewald,A. Gurtu,M Yokoyama,S Heinemeyer,Stephen R. Sharpe,Tony Liss,S. P. Wakely,S.I. Eidelman,Timothy Gershon,U G Meißner,R. N. Cahn,Petr Vogel,E. J. Weinberg,M O Wascko,R E Mitchell,G. Cowan,Tony Gherghetta,Andrei Gritsan,S Willocq,Shoji Hashimoto,A Holtkamp,L. S. Littenberg,Michal Kreps,Paolo Molaro,W. Fetscher,R Sekhar Chivukula,E. Blucher,Anatoli Romaniouk,P. de Jong,B. Foster,S. B. Lugovsky,S L Zhu,Kate Scholberg,R. G. Van de Water,T Skwarnicki,S. M. Spanier,P. Schaffner,H Ramani,Andrew R. Liddle,M Taševský,German Valencia,Y. Nir,C. W. Walter,C Lippmann,Jack Laiho,Otmar Biebel,Thibault Damour,Uli Katz,Aneesh V. Manohar,J. J. Beatty,Kaustubh Agashe,Y Makida,K Trabelsi,S. R. Klein,John A. Peacock,Michael Doser,F Takahashi,Chi Lin,A Hebecker,Koji Nakamura,L P Lellouch +241 more
- 01 Aug 2020
5.5K
Recent developments in GEANT4
John Allison,K. Amako,John Apostolakis,Pedro Arce,Makoto Asai,Tsukasa Aso,Enrico Bagli,Alexander Bagulya,Sw. Banerjee,G. Barrand,B. R. Beck,Alexey Bogdanov,D. Brandt,Jeremy M. C. Brown,Helmut Burkhardt,Ph Canal,D. Cano-Ott,Stephane Chauvie,Kyung-Suk Cho,G.A.P. Cirrone,Gene Cooperman,M. A. Cortés-Giraldo,G. Cosmo,Giacomo Cuttone,G.O. Depaola,Laurent Desorgher,X. Dong,Andrea Dotti,Victor Daniel Elvira,Gunter Folger,Ziad Francis,A. Galoyan,L. Garnier,M. Gayer,K. Genser,Vladimir Grichine,Vladimir Grichine,Susanna Guatelli,Susanna Guatelli,Paul Gueye,P. Gumplinger,Alexander Howard,Ivana Hřivnáčová,S. Hwang,Sebastien Incerti,Sebastien Incerti,A. Ivanchenko,Vladimir Ivanchenko,F.W. Jones,S. Y. Jun,Pekka Kaitaniemi,Nicolas A. Karakatsanis,Nicolas A. Karakatsanis,M. Karamitrosi,M.H. Kelsey,Akinori Kimura,Tatsumi Koi,Hisaya Kurashige,A. Lechner,S. B. Lee,Francesco Longo,M. Maire,Davide Mancusi,A. Mantero,E. Mendoza,B. Morgan,K. Murakami,T. Nikitina,Luciano Pandola,P. Paprocki,J Perl,Ivan Petrović,Maria Grazia Pia,W. Pokorski,J. M. Quesada,M. Raine,Maria A.M. Reis,Alberto Ribon,A. Ristic Fira,Francesco Romano,Giorgio Ivan Russo,Giovanni Santin,Takashi Sasaki,D. Sawkey,J. I. Shin,Igor Strakovsky,A. Taborda,Satoshi Tanaka,B. Tome,Toshiyuki Toshito,H.N. Tran,Pete Truscott,L. Urbán,V. V. Uzhinsky,Jerome Verbeke,M. Verderi,B. Wendt,H. Wenzel,D. H. Wright,Douglas Wright,T. Yamashita,J. Yarba,H. Yoshida +102 more
TL;DR: Geant4 as discussed by the authors is a software toolkit for the simulation of the passage of particles through matter, which is used by a large number of experiments and projects in a variety of application domains, including high energy physics, astrophysics and space science, medical physics and radiation protection.
FLUKA: A Multi-Particle Transport Code
A. Ferrari,Paola Sala,Milan Infn,Alberto Fasso,Johannes Ranft,U Siegen +5 more
- 14 Dec 2005
TL;DR: The 2005 version of the Fluka particle transport code is described in this article, where the basic notions, modular structure of the system, and an installation and beginner's guide are described.
Algebraic Reconstruction Techniques (ART) for three-dimensional electron microscopy and X-ray photography
TL;DR: The method works for totally asymmetric objects, and requires little computer time or storage, and is also applicable to X-ray photography, and may greatly reduce the exposure compared to current methods of body-section radiography.
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