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66 lines
3.6 KiB
BibTeX
66 lines
3.6 KiB
BibTeX
@misc{1606.06907,
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Author = {Prashant Shukla and Sundaresh Sankrith},
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Title = {Energy and angular distributions of atmospheric muons at the Earth},
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Year = {2016},
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Eprint = {arXiv:1606.06907},
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}
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@article{GROOM2001183,
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title = "MUON STOPPING POWER AND RANGE TABLES 10 MeV–100 TeV",
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journal = "Atomic Data and Nuclear Data Tables",
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volume = "78",
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number = "2",
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pages = "183 - 356",
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year = "2001",
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issn = "0092-640X",
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doi = "https://doi.org/10.1006/adnd.2001.0861",
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url = "http://www.sciencedirect.com/science/article/pii/S0092640X01908617",
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author = "DONALD E. GROOM and NIKOLAI V. MOKHOV and SERGEI I. STRIGANOV",
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abstract = "The mean stopping power for high-energy muons in matter can be described by 〈−dE/dx〉=a(E)+b(E)E, where a(E) is the electronic stopping power and b(E) is the energy-scaled contribution from radiative processes—bremsstrahlung, pair production, and photonuclear interactions. a(E) and b(E) are both slowly varying functions of the muon energy E where radiative effects are important. Tables of these stopping power contributions and continuous-slowing-down-approximation ranges (which neglect multiple scattering and range straggling) are given for a selection of elements, compounds, mixtures, and biological materials for incident kinetic energies in the range of 10 MeV to 100 TeV. Tables of the contributions to b(E) are given for the same materials."
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}
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@article{Landau:216256,
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author = "Landau, Lev Davidovich",
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title = "{On the energy loss of fast particles by ionization}",
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journal = "J. Phys.",
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number = "4",
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volume = "8",
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pages = "201-205",
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year = "1944",
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url = "https://cds.cern.ch/record/216256",
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}
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@online{codata,
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author = {CODATA},
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title = {CODATA Internationally recommended 2018 values of the fundamental physical constants},
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year = {2018},
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url = {https://physics.nist.gov/cuu/Constants/index.html}
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}
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@article{pdg,
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title = {LEPTONS sumary table},
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author = {J. Beringer et al. (Particle Data Group)},
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url = {http://pdg.lbl.gov},
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year = {2012}}
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@BOOK{Barlow,
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AUTHOR = {R. J. Barlow},
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YEAR = {2013},
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TITLE = {Statistics - A Guide to the Use of Statistical Methods in the Physical Sciences},
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ISBN = {111-8-723-236-},
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PUBLISHER = {John Wiley \& Sons},
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ADDRESS = {New York},
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}
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@phdthesis{fast,
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author={Casella,Maria C.},
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year={2007},
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month={07/31},
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title={High precision muon lifetime measurement with the FAST experiment},
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note={ID: unige:81},
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abstract={The goal of the FAST experiment is the precise measurement of the muon lifetime, to the accuracy of 2 ppm. After including the theoretical and experimental errors, this results in a precise measurement of the Fermi coupling constant, to a precision that is one order of magnitude better than the present world average. FAST consists in a high granularity scintillator target, where a positive pion beam (from PSI accelerator facility) is stopped. The pions decay at rest inside the target; the consequent decays of muons into positrons are registered by the readout chain. The times of the particles are measured, and the muon lifetime is extracted. The high precision requirement imposes a high statistics collection of muon decay events (order of a few 10¹¹ events). This work presents the first measurement of the muon lifetime with FAST, with the analysis of a data sample of ~10¹⁰ muon decay events, collected in December 2006. The precision of the measurement (16 ppm) is competitive with the world average.},
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keywords={Muon lifetime; Fermi coupling constant},
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language={eng},
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url={https://nbn-resolving.org/urn:nbn:ch:unige-810},
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}
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