The European Spallation Source neutrino Super Beam

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Preprint
Report number	arXiv:2203.08803
Title	The European Spallation Source neutrino Super Beam
Author(s)	Alekou, A. (CERN ; Uppsala U.) ; Baussan, E. (Strasbourg, IPHC) ; Kraljevic, N. Blaskovic (ESS, Lund) ; Blennow, M. (Royal Inst. Tech., Sodertalje ; Stockholm U., OKC) ; Bogomilov, M. (Sofiya U.) ; Bouquerel, E. (Strasbourg, IPHC) ; Burgman, A. (Lund U.) ; Carlile, C.J. (Uppsala U. (main)) ; Cederkall, J. (Lund U.) ; Christiansen, P. (Lund U.) ; Collins, M. (Lund U. ; ESS, Lund) ; Morales, E. Cristaldo (Milan Bicocca U.) ; Cupial, P. (AGH-UST, Cracow) ; Alessi, L.D. (Strasbourg, IPHC) ; Danared, H. (ESS, Lund) ; de Andre, J.P.A.M. (Strasbourg, IPHC) ; Delahaye, J.P. (CERN) ; Dracos, M. (Strasbourg, IPHC) ; Efthymiopoulos, I. (CERN) ; Ekelof, T. (Uppsala U.) ; Eshraqi, M. (ESS, Lund) ; Fanourakis, G. (Democritos Nucl. Res. Ctr.) ; Fernandez-Martinez, E. (Madrid, IFT) ; Folsom, B. (ESS, Lund) ; Gazis, N. (ESS, Lund) ; Geralis, Th. (Democritos Nucl. Res. Ctr.) ; Ghosh, M. (Boskovic Inst., Zagreb) ; Gokbulut, G. (Cukurova U.) ; Halic, L. (Boskovic Inst., Zagreb) ; Topaksu, A. Kayis (Cukurova U.) ; Kildetoft, B. (ESS, Lund) ; Klicek, B. (Boskovic Inst., Zagreb) ; Koziol, M. (AGH-UST, Cracow) ; Krhac, K. (Boskovic Inst., Zagreb) ; Lacny, L. (AGH-UST, Cracow) ; Lindroos, M. (ESS, Lund) ; Mezzetto, M. (INFN, Padua) ; Oglakci, M. (Cukurova U.) ; Ohlsson, T. (Royal Inst. Tech., Stockholm ; Stockholm U., OKC) ; Olvegard, M. (Uppsala U.) ; Ota, T. (Madrid, IFT) ; Park, J. (Lund U. ; INFN, Pavia) ; Patrzalek, D. (ESS, Lund) ; Petkov, G. (Sofiya U.) ; Poussot, P. (Strasbourg, IPHC) ; Johansson, R. (ESS, Lund) ; Rosauro-Alcaraz, S. (Madrid, IFT ; IJCLab, Orsay) ; Szybinski, B. (AGH-UST, Cracow) ; Snamina, J. (AGH-UST, Cracow) ; Stavropoulos, G. (Democritos Nucl. Res. Ctr.) ; Stipcevic, M. (Boskovic Inst., Zagreb) ; Terranova, F. (Milan Bicocca U.) ; Thomas, J. (Strasbourg, IPHC) ; Tolba, T. (U. Hamburg (main)) ; Trachanas, E. (ESS, Lund) ; Tsenov, R. (Sofiya U.) ; Vankova-Kirilova, G. (Sofiya U.) ; Vassilopoulos, N. (DINS, Dongguan) ; Wildner, E. (CERN) ; Wurtz, J. (Strasbourg, IPHC) ; Zormpa, O. (Democritos Nucl. Res. Ctr.) ; Zou, Y. (Uppsala U.)
Imprint	2022-03-15
Number of pages	24
Note	contribution to Snowmass 2021
Presented at	2021 Snowmass Summer Study, Seattle, WA, United States, 11 - 20 July 2021, pp.
Subject category	hep-ex ; Particle Physics - Experiment ; physics.acc-ph ; Accelerators and Storage Rings
Abstract	In this Snowmass 2021 white paper, we summarise the Conceptual Design of the European Spallation Source neutrino Super Beam (ESSvSB) experiment and its synergies with the possible future muon based facilities, e.g. a Low Energy nuSTORM and the Muon Collider. The ESSvSB will benefit from the high power, 5 MW, of the European Spallation Source (ESS) LINAC in Lund-Sweden to produce the world most intense neutrino beam, enabling measurements to be made at the second oscillation maximum. Assuming a ten-year exposure, physics simulations show that the CP-invariance violation can be established with a significance of 5 sigma over more than 70% of all values of delta CP and with an error in the measurement of the delta CP angle of less than 8 degree for all values of delta CP. However, several technological and physics challenges must be further studied before achieving a final Technical Design. Measuring at the 2nd oscillation maximum necessitates a very intense neutrino beam with the appropriate energy. For this, the ESS proton beam LINAC, which is designed to produce the world's most intense neutron beam, will need to be upgraded to 10 MW power, 2.5 GeV energy and 28 Hz beam pulse repetition rate. An accumulator ring will be required for the compression of the ESS LINAC beam pulse from 2.86 ms to 1.3 mus. A high power target station facility will be needed to produce a well-focused intense (super) mu-neutrino beam. The physics performance of that neutrino Super Beam in conjunction with a megaton underground Water Cherenkov neutrino far detector installed at a distance of either 360 km or 540 km from the ESS, the baseline, has been evaluated.
Other source	Inspire
Copyright/License	preprint: (License: CC0 1.0)

$Oscillation probabilities for the \SI{360}{km} (red curves) and \SI{540}{km} (purple curves) baselines as a function of the energy for neutrinos (left panel) and antineutrinos (right panel). The solid (dotted) lines are for $\delta = -90^\circ$ ($\delta =0$). The grey dotted lines show the convolution of the signal component of the neutrino flux with the detection cross section. Thus, they serve as a guide of what energies of the oscillation probability would be well-sampled by the ESS$\nu$SB setup.$ $Oscillation probabilities for the \SI{360}{km} (red curves) and \SI{540}{km} (purple curves) baselines as a function of the energy for neutrinos (left panel) and antineutrinos (right panel). The solid (dotted) lines are for $\delta = -90^\circ$ ($\delta =0$). The grey dotted lines show the convolution of the signal component of the neutrino flux with the detection cross section. Thus, they serve as a guide of what energies of the oscillation probability would be well-sampled by the ESS$\nu$SB setup.$

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Record created 2022-04-09, last modified 2024-01-17

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