Your search keyword '"Bayes R"' showing total 25 results

1. Event-by-Event Direction Reconstruction of Solar Neutrinos in a High Light-Yield Liquid Scintillator

Author

Allega, A., Anderson, M. R., Andringa, S., Antunes, J., Askins, M., Auty, D. J., Bacon, A., Baker, J., Barros, N., Barão, F., Bayes, R., Beier, E. W., Bezerra, T. S., Bialek, A., Biller, S. D., Blucher, E., Caden, E., Callaghan, E. J., Chen, M., Cheng, S., Cleveland, B., Cookman, D., Corning, J., Cox, M. A., Dehghani, R., Deloye, J., Depatie, M. M., Di Lodovico, F., Dittmer, J., Dixon, K. H., Falk, E., Fatemighomi, N., Ford, R., Gaur, A., Ganzálaz-Reina, O. I., Gooding, D., Grant, C., Grove, J., Hall, S., Hallin, A. L., Heintzelman, W. J., Helmer, R. L., Hewitt, C., Hreljac, B., Howard, V., Hu, J., Hunt-Stokes, R., Hussain, S. M. A., Inácio, A. S., Jillings, C. J., Kaluzienski, S., Kaptanoglu, T., Khaghani, P., Khan, H., Klein, J. R., Kormos, L. L., Krar, B., Kraus, C., Krauss, C. B., Kroupová, T., Lake, C., Lebanowski, L., Lee, J., Lefebvra, C., Lin, Y. H., Lozza, V., Luo, M., Maio, A., Manecki, S., Maneira, J., Martin, R. D., McCauley, N., McDonald, A. B., Mills, C., Milton, G., Morton-Blake, I., Mubasher, M., Colina, A. Molina, Morris, D., Naugle, S., Nolan, L. J., O'Keeffe, H. M., Gann, G. D. Orebi, Page, J., Paleshi, K., Parker, W., Paton, J., Peeters, S. J. M., Pickard, L., Ravi, P., Reichold, A., Riccetto, S., Rigan, M., Rose, J., Rosero, R., Rumleskie, J., Semenec, I., Skensvard, P., Smiley, M., Smith, J., Svoboda, R., Tam, B., Tseng, J., Valder, S., Vázquez-Jáuregui, E., Virtue, C. J., Wang, J., Ward, M., Wilson, J. R., Wilson, J. D., Wright, A., Yanez, J. P., Yang, S., Yeh, M., Ye, Z., Yu, S., Zhang, Y., Zuber, K., and Zummo, A.

Subjects

High Energy Physics - Experiment, Physics - Instrumentation and Detectors

Abstract

The direction of individual $^8$B solar neutrinos has been reconstructed using the SNO+ liquid scintillator detector. Prompt, directional Cherenkov light was separated from the slower, isotropic scintillation light using time information, and a maximum likelihood method was used to reconstruct the direction of individual scattered electrons. A clear directional signal was observed, correlated with the solar angle. The observation was aided by a period of low primary fluor concentration that resulted in a slower scintillator decay time. This is the first time that event-by-event direction reconstruction in high light-yield liquid scintillator has been demonstrated in a large-scale detector., Comment: 6 pages, 6 figures. Accepted manuscript by PRD

Published

2023

2. Multiple Coulomb Scattering of muons in Lithium Hydride

Author

Bogomilov, M., Tsenov, R., Vankova-Kirilova, G., Song, Y. P., Tang, J. Y., Li, Z. H., Bertoni, R., Bonesini, M., Chignoli, F., Mazza, R., Palladino, V., de Bari, A., Orestano, D., Tortora, L., Kuno, Y., Sakamoto, H., Sato, A., Ishimoto, S., Chung, M., Sung, C. K., Filthaut, F., Fedorov, M., Jokovic, D., Maletic, D., Savic, M., Jovancevic, N., Nikolov, J., Vretenar, M., Ramberger, S., Asfandiyarov, R., Blondel, A., Drielsma, F., Karadzhov, Y., Charnley, G., Collomb, N., Dumbell, K., Gallagher, A., Grant, A., Griffiths, S., Hartnett, T., Martlew, B., Moss, A., Muir, A., Mullacrane, I., Oates, A., Owens, P., Stokes, G., Warburton, P., White, C., Adams, D., Bayliss, V., Boehm, J., Bradshaw, T. W., Brown, C., Courthold, M., Govans, J., Hills, M., Lagrange, J. -B., Macwaters, C., Nichols, A., Preece, R., Ricciardi, S., Rogers, C., Stanley, T., Tarrant, J., Tucker, M., Watson, S., Wilson, A., Bayes, R., Nugent, J. C., Soler, F. J. P., Gamet, R., Cooke, P., Blackmore, V. J., Colling, D., Dobbs, A., Dornan, P., Franchini, P., Hunt, C., Jurj, P. B., Kurup, A., Long, K., Martyniak, J., Middleton, S., Pasternak, J., Uchida, M. A., Cobb, J. H., Booth, C. N., Hodgson, P., Langlands, J., Overton, E., Pec, V., Smith, P. J., Wilbur, S., Chatzitheodoridis, G. T., Dick, A. J., Ronald, K., Whyte, C. G., Young, A. R., Boyd, S., Greis, J. R., Lord, T., Pidcott, C., Taylor, I., Ellis, M., Gardener, R. B. S., Kyberd, P., Nebrensky, J. J., Palmer, M., Witte, H., Adey, D., Bross, A. D., Bowring, D., Hanlet, P., Liu, A., Neuffer, D., Popovic, M., Rubinov, P., DeMello, A., Gourlay, S., Lambert, A., Li, D., Luo, T., Prestemon, S., Virostek, S., Freemire, B., Kaplan, D. M., Mohayai, T. A., Rajaram, D., Snopok, P., Torun, Y., Cremaldi, L. M., Sanders, D. A., Summers, D. J., Coney, L. R., Hanson, G. G., and Heidt, C.

Subjects

High Energy Physics - Experiment, Physics - Instrumentation and Detectors

Abstract

Multiple Coulomb Scattering (MCS) is a well known phenomenon occurring when charged particles traverse materials. Measurements of muons traversing low $Z$ materials made in the MuScat experiment showed that theoretical models and simulation codes, such as GEANT4 (v7.0), over-estimated the scattering. The Muon Ionization Cooling Experiment (MICE) measured the cooling of a muon beam traversing a liquid hydrogen or lithium hydride (LiH) energy absorber as part of a programme to develop muon accelerator facilities, such as a Neutrino Factory or a Muon Collider. The energy loss and MCS that occur in the absorber material are competing effects that alter the performance of the cooling channel. Therefore measurements of MCS are required in order to validate the simulations used to predict the cooling performance in future accelerator facilities. We report measurements made in the MICE apparatus of MCS using a LiH absorber and muons within the momentum range 160 to 245 MeV/c. The measured RMS scattering width is about 9% smaller than that predicted by the approximate formula proposed by the Particle Data Group. Data at 172, 200 and 240 MeV/c are compared to the GEANT4 (v9.6) default scattering model. These measurements show agreement with this more recent GEANT4 (v9.6) version over the range of incident muon momenta., Comment: 20 pages, 14 figures, journal

Published

2022

3. Optical calibration of the SNO+ detector in the water phase with deployed sources

Author

Collaboration, SNO, Anderson, M. R., Andringa, S., Askins, M., Auty, D. J., Barão, F., Barros, N., Bayes, R., Beier, E. W., Bialek, A., Biller, S. D., Blucher, E., Boulay, M., Caden, E., Callaghan, E. J., Caravaca, J., Chen, M., Chkvorets, O., Cleveland, B., Cookman, D., Corning, J., Cox, M. A., Deluce, C., Depatie, M. M., Di Lodovico, F., Dittmer, J., Falk, E., Fatemighomi, N., Fischer, V., Ford, R., Frankiewicz, K., Gaur, A., Gilje, K., González-Reina, O. I., Gooding, D., Grant, C., Grove, J., Hallin, A. L., Hallman, D., Hartnell, J., Heintzelman, W. J., Helmer, R. L., Hu, J., Hunt-Stokes, R., Hussain, S. M. A., Inácio, A. S., Jillings, C. J., Kaptanoglu, T., Khaghani, P., Khan, H., Klein, J. R., Kormos, L. L., Krar, B., Kraus, C., Krauss, C. B., Kroupová, T., Lam, I., Land, B. J., LaTorre, A., Lawson, I., Lebanowski, L., Lefebvre, C., Li, A., Lidgard, J., Lin, Y. H., Liu, Y., Lozza, V., Luo, M., Maio, A., Manecki, S., Maneira, J., Martin, R. D., McCauley, N., McDonald, A. B., Meyer, M., Mills, C., Morton-Blake, I., Nae, S., Nirkko, M., Nolan, L. J., O'Keeffe, H. M., Gann, G. D. Orebi, Page, J., Parker, W., Paton, J., Peeters, S. J. M., Pershing, T., Pickard, L., Prior, G., Ravi, P., Reichold, A., Riccetto, S., Richardson, R., Rigan, M., Rose, J., Rumleskie, J., Semenec, I., Shaker, F., Sharma, M. K., Skensved, P., Smiley, M., Stainforth, R., Svoboda, R., Tam, B., Tseng, J., Turner, E., Valder, S., Vázquez-Jáuregui, E., Veinot, J. G. C., Virtue, C. J., Wang, J., Ward, M., Weigand, J. J., Wilson, J. R., Wright, A., Yanez, J. P., Yeh, M., Yu, S., Zhang, T., Zhang, Y., Zuber, K., and Zummo, A.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment, Nuclear Experiment

Abstract

SNO+ is a large-scale liquid scintillator experiment with the primary goal of searching for neutrinoless double beta decay, and is located approximately 2 km underground in SNOLAB, Sudbury, Canada. The detector acquired data for two years as a pure water Cherenkov detector, starting in May 2017. During this period, the optical properties of the detector were measured in situ using a deployed light diffusing sphere, with the goal of improving the detector model and the energy response systematic uncertainties. The measured parameters included the water attenuation coefficients, effective attenuation coefficients for the acrylic vessel, and the angular response of the photomultiplier tubes and their surrounding light concentrators, all across different wavelengths. The calibrated detector model was validated using a deployed tagged gamma source, which showed a 0.6% variation in energy scale across the primary target volume., Comment: Accepted by JINST (30 pages, 19 figures)

Published

2021

4. The SNO+ Experiment

Author

Collaboration, SNO, Albanese, V., Alves, R., Anderson, M. R., Andringa, S., Anselmo, L., Arushanova, E., Asahi, S., Askins, M., Auty, D. J., Back, A. R., Back, S., Barão, F., Barnard, Z., Barr, A., Barros, N., Bartlett, D., Bayes, R., Beaudoin, C., Beier, E. W., Berardi, G., Bialek, A., Biller, S. D., Blucher, E., Bonventre, R., Boulay, M., Braid, D., Caden, E., Callaghan, E. J., Caravaca, J., Carvalho, J., Cavalli, L., Chauhan, D., Chen, M., Chkvorets, O., Clark, K. J., Cleveland, B., Connors, C., Cookman, D., Coulter, I. T., Cox, M. A., Cressy, D., Dai, X., Darrach, C., Davis-Purcell, B., Deluce, C., Depatie, M. M., Descamps, F., Di Lodovico, F., Dittmer, J., Doxtator, A., Duhaime, N., Duncan, F., Dunger, J., Earle, A. D., Fabris, D., Falk, E., Farrugia, A., Fatemighomi, N., Felber, C., Fischer, V., Fletcher, E., Ford, R., Frankiewicz, K., Gagnon, N., Gaur, A., Gauthier, J., Gibson-Foster, A., Gilje, K., González-Reina, O. I., Gooding, D., Gorel, P., Graham, K., Grant, C., Grove, J., Grullon, S., Guillian, E., Hall, S., Hallin, A. L., Hallman, D., Hans, S., Hartnell, J., Harvey, P., Hedayatipour, M., Heintzelman, W. J., Heise, J., Helmer, R. L., Hodak, B., Hodak, M., Hood, M., Horne, D., Hreljac, B., Hu, J., Hussain, S. M. A., Iida, T., Inácio, A. S., Jackson, C. M., Jelley, N. A., Jillings, C. J., Jones, C., Jones, P. G., Kamdin, K., Kaptanoglu, T., Kaspar, J., Keeter, K., Kefelian, C., Khaghani, P., Kippenbrock, L., Klein, J. R., Knapik, R., Kofron, J., Kormos, L. L., Korte, S., Krar, B., Kraus, C., Krauss, C. B., Kroupová, T., Labe, K., Lafleur, F., Lam, I., Lan, C., Land, B. J., Lane, R., Langrock, S., Larochelle, P., Larose, S., LaTorre, A., Lawson, I., Lebanowski, L., Lefeuvre, G. M., Leming, E. J., Li, A., Li, O., Lidgard, J., Liggins, B., Liimatainen, P., Lin, Y. H., Liu, X., Liu, Y., Lozza, V., Luo, M., Maguire, S., Maio, A., Majumdar, K., Manecki, S., Maneira, J., Martin, R. D., Marzec, E., Mastbaum, A., Mathewson, A., McCauley, N., McDonald, A. B., McFarlane, K., Mekarski, P., Meyer, M., Miller, C., Mills, C., Mlejnek, M., Mony, E., Morissette, B., Morton-Blake, I., Mottram, M. J., Nae, S., Nirkko, M., Nolan, L. J., Novikov, V. M., O'Keeffe, H. M., O'Sullivan, E., Gann, G. D. Orebi, Parnell, M. J., Paton, J., Peeters, S. J. M., Pershing, T., Petriw, Z., Petzoldt, J., Pickard, L., Pracsovics, D., Prior, G., Prouty, J. C., Quirk, S., Read, S., Reichold, A., Riccetto, S., Richardson, R., Rigan, M., Ritchie, I., Robertson, A., Robertson, B. C., Rose, J., Rosero, R., Rost, P. M., Rumleskie, J., Schumaker, M. A., Schwendener, M. H., Scislowski, D., Secrest, J., Seddighin, M., Segui, L., Seibert, S., Semenec, I., Shaker, F., Shantz, T., Sharma, M. K., Shokair, T. M., Sibley, L., Sinclair, J. R., Singh, K., Skensved, P., Smiley, M., Sonley, T., Sörensen, A., St-Amant, M., Stainforth, R., Stankiewicz, S., Strait, M., Stringer, M. I., Stripay, A., Svoboda, R., Tacchino, S., Tam, B., Tanguay, C., Tatar, J., Tian, L., Tolich, N., Tseng, J., Tseung, H. W. C., Turner, E., Van Berg, R., Vázquez-Jáuregui, E., Veinot, J. G. C., Virtue, C. J., von Krosigk, B., Walker, J. M. G., Walker, M., Wallig, J., Walton, S. C., Wang, J., Ward, M., Wasalski, O., Waterfield, J., Weigand, J. J., White, R. F., Wilson, J. R., Winchester, T. J., Woosaree, P., Wright, A., Yanez, J. P., Yeh, M., Zhang, T., Zhang, Y., Zhao, T., Zuber, K., and Zummo, A.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment, Nuclear Experiment

Abstract

The SNO+ experiment is located 2 km underground at SNOLAB in Sudbury, Canada. A low background search for neutrinoless double beta ($0\nu\beta\beta$) decay will be conducted using 780 tonnes of liquid scintillator loaded with 3.9 tonnes of natural tellurium, corresponding to 1.3 tonnes of $^{130}$Te. This paper provides a general overview of the SNO+ experiment, including detector design, construction of process plants, commissioning efforts, electronics upgrades, data acquisition systems, and calibration techniques. The SNO+ collaboration is reusing the acrylic vessel, PMT array, and electronics of the SNO detector, having made a number of experimental upgrades and essential adaptations for use with the liquid scintillator. With low backgrounds and a low energy threshold, the SNO+ collaboration will also pursue a rich physics program beyond the search for $0\nu\beta\beta$ decay, including studies of geo- and reactor antineutrinos, supernova and solar neutrinos, and exotic physics such as the search for invisible nucleon decay. The SNO+ approach to the search for $0\nu\beta\beta$ decay is scalable: a future phase with high $^{130}$Te-loading is envisioned to probe an effective Majorana mass in the inverted mass ordering region., Comment: 61 pages, 23 figures, 4 tables

Published

2021

5. Development, characterisation, and deployment of the SNO+ liquid scintillator

Author

Collaboration, SNO, Anderson, M. R., Andringa, S., Anselmo, L., Arushanova, E., Asahi, S., Askins, M., Auty, D. J., Back, A. R., Barnard, Z., Barros, N., Bartlett, D., Barão, F., Bayes, R., Beier, E. W., Bialek, A., Biller, S. D., Blucher, E., Bonventre, R., Boulay, M., Braid, D., Caden, E., Callaghan, E. J., Caravaca, J., Carvalho, J., Cavalli, L., Chauhan, D., Chen, M., Chkvorets, O., Clark, K. J., Cleveland, B., Cookman, D., Connors, C., Coulter, I. T., Cox, M. A., Cressy, D., Dai, X., Darrach, C., Davis-Purcell, B., Deluce, C., Depatie, M. M., Descamps, F., Dittmer, J., Di Lodovico, F., Duhaime, N., Duncan, F., Dunger, J., Earle, A. D., Fabris, D., Falk, E., Farrugia, A., Fatemighomi, N., Fischer, V., Fletcher, E., Ford, R., Frankiewicz, K., Gagnon, N., Gaur, A., Gilje, K., González-Reina, O. I., Gooding, D., Gorel, P., Graham, K., Grant, C., Grove, J., Grullon, S., Guillian, E., Hall, S., Hallin, A. L., Hallman, D., Hans, S., Hartnell, J., Harvey, P., Hedayatipour, M., Heintzelman, W. J., Heise, J., Helmer, R. L., Horne, D., Hreljac, B., Hu, J., Hussain, A. S. M., Iida, T., Inácio, A. S., Jackson, M., Jelley, N. A., Jillings, C. J., Jones, C., Jones, P. G., Kamdin, K., Kaptanoglu, T., Kaspar, J., Keeter, K., Kefelian, C., Khaghani, P., Kippenbrock, L., Klein, J. R., Knapik, R., Kofron, J., Kormos, L. L., Korte, S., Krar, B., Kraus, C., Krauss, C. B., Kroupova, T., Labe, K., Lafleur, F., Lam, I., Lan, C., Land, B. J., Lane, R., Langrock, S., LaTorre, A., Lawson, I., Lebanowski, L., Lefeuvre, G. M., Leming, E. J., Li, A., Lidgard, J., Liggins, B., Lin, Y. H., Liu, X., Liu, Y., Lozza, V., Luo, M., Maguire, S., Maio, A., Majumdar, K., Manecki, S., Maneira, J., Martin, R. D., Marzec, E., Mastbaum, A., Mauel, J., McCauley, N., McDonald, A. B., Mekarski, P., Meyer, M., Miller, C., Mills, C., Mlejnek, M., Mony, E., Morton-Blake, I., Mottram, M. J., Nae, S., Nirkko, M., Nolan, L. J., Novikov, V. M., O'Keeffe, H. M., O'Sullivan, E., Gann, G. D. Orebi, Parnell, M. J., Paton, J., Peeters, S. J. M., Pershing, T., Petriw, Z., Petzoldt, J., Pickard, L., Pracsovics, D., Prior, G., Prouty, J. C., Quirk, S., Reichold, A., Riccetto, S., Richardson, R., Rigan, M., Robertson, A., Rose, J., Rosero, R., Rost, P. M., Rumleskie, J., Schumaker, M. A., Schwendener, M. H., Scislowski, D., Secrest, J., Seddighin, M., Segui, L., Seibert, S., Semenec, I., Shaker, F., Shantz, T., Sharma, M. K., Shokair, T. M., Sibley, L., Sinclair, J. R., Singh, K., Skensved, P., Smiley, M., Sonley, T., Stainforth, R., Strait, M., Stringer, M. I., Svoboda, R., Sörensen, A., Tam, B., Tatar, J., Tian, L., Tolich, N., Tseng, J., Tseung, H. W. C., Turner, E., Van Berg, R., Veinot, J. G. C., Virtue, C. J., von Krosigk, B., Vázquez-Jáuregui, E., Walker, J. M. G., Walker, M., Walton, S. C., Wang, J., Ward, M., Wasalski, O., Waterfield, J., Weigand, J. J., White, R. F., Wilson, J. R., Winchester, T. J., Woosaree, P., Wright, A., Yanez, J. P., Yeh, M., Zhang, T., Zhang, Y., Zhao, T., Zuber, K., and Zummo, A.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

A liquid scintillator consisting of linear alkylbenzene as the solvent and 2,5-diphenyloxazole as the fluor was developed for the SNO+ experiment. This mixture was chosen as it is compatible with acrylic and has a competitive light yield to pre-existing liquid scintillators while conferring other advantages including longer attenuation lengths, superior safety characteristics, chemical simplicity, ease of handling, and logistical availability. Its properties have been extensively characterized and are presented here. This liquid scintillator is now used in several neutrino physics experiments in addition to SNO+., Comment: 21 pages, 10 figures

Published

2020

6. Measurement of neutron-proton capture in the SNO+ water phase

Author

Collaboration, The SNO, Anderson, M. R., Andringa, S., Askins, M., Auty, D. J., Barros, N., Barão, F., Bayes, R., Beier, E. W., Bialek, A., Biller, S. D., Blucher, E., Bonventre, R., Boulay, M., Caden, E., Callaghan, E. J., Caravaca, J., Chauhan, D., Chen, M., Chkvorets, O., Cleveland, B., Cox, M. A., Depatie, M. M., Dittmer, J., Di Lodovico, F., Earle, A. D., Falk, E., Fatemighomi, N., Fischer, V., Fletcher, E., Ford, R., Frankiewicz, K., Gilje, K., Gooding, D., Grant, C., Grove, J., Hallin, A. L., Hallman, D., Hans, S., Hartnell, J., Harvey, P., Heintzelman, W. J., Helmer, R. L., Horne, D., Hreljac, B., Hu, J., Hussain, A. S. M., Inácio, A. S., Jillings, C. J., Kaptanoglu, T., Khaghani, P., Klein, J. R., Knapik, R., Kormos, L. L., Krar, B., Kraus, C., Krauss, C. B., Kroupova, T., Lam, I., Land, B. J., LaTorre, A., Lawson, I., Lebanowski, L., Leming, E. J., Li, A., Lidgard, J., Liggins, B., Lin, Y. H., Liu, Y., Lozza, V., Luo, M., Maguire, S., Maio, A., Manecki, S., Maneira, J., Martin, R. D., Marzec, E., Mastbaum, A., McCauley, N., McDonald, A. B., Mekarski, P., Meyer, M., Mills, C., Morton-Blake, I., Nae, S., Nirkko, M., Nolan, L. J., O'Keeffe, H. M., Gann, G. D. Orebi, Parnell, M. J., Paton, J., Peeters, S. J. M., Pershing, T., Pickard, L., Prior, G., Reichold, A., Riccetto, S., Richardson, R., Rigan, M., Rose, J., Rosero, R., Rost, P. M., Rumleskie, J., Semenec, I., Shaker, F., Sharma, M. K., Singh, K., Skensved, P., Smiley, M., Stringer, M. I., Svoboda, R., Tam, B., Tian, L., Tseng, J., Turner, E., Van Berg, R., Veinot, J. G. C., Virtue, C. J., Vázquez-Jáuregui, E., Walton, S. C., Wang, J., Ward, M., Weigand, J. J., Wilson, J. R., Woosaree, P., Wright, A., Yanez, J. P., Yeh, M., Zhang, T., Zhang, Y., Zuber, K., and Zummo, A.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment, Nuclear Experiment

Abstract

The SNO+ experiment collected data as a low-threshold water Cherenkov detector from September 2017 to July 2019. Measurements of the 2.2-MeV $\gamma$ produced by neutron capture on hydrogen have been made using an Am-Be calibration source, for which a large fraction of emitted neutrons are produced simultaneously with a 4.4-MeV $\gamma$. Analysis of the delayed coincidence between the 4.4-MeV $\gamma$ and the 2.2-MeV capture $\gamma$ revealed a neutron detection efficiency that is centered around 50% and varies at the level of 1% across the inner region of the detector, which to our knowledge is the highest efficiency achieved among pure water Cherenkov detectors. In addition, the neutron capture time constant was measured and converted to a thermal neutron-proton capture cross section of $336.3^{+1.2}_{-1.5}$ mb.

Published

2020

7. Search for invisible modes of nucleon decay in water with the SNO+ detector

Author

Collaboration, SNO, Anderson, M., Andringa, S., Arushanova, E., Asahi, S., Askins, M., Auty, D. J., Back, A. R., Barnard, Z., Barros, N., Bartlett, D., Barão, F., Bayes, R., Beier, E. W., Bialek, A., Biller, S. D., Blucher, E., Bonventre, R., Boulay, M., Braid, D., Caden, E., Callaghan, E. J., Caravaca, J., Carvalho, J., Cavalli, L., Chauhan, D., Chen, M., Chkvorets, O., Clark, K. J., Cleveland, B., Connors, C., Coulter, I. T., Cressy, D., Dai, X., Darrach, C., Davis-Purcell, B., Depatie, M. M., Descamps, F., Di Lodovico, F., Duhaime, N., Duncan, F., Dunger, J., Falk, E., Fatemighomi, N., Fischer, V., Fletcher, E., Ford, R., Gagnon, N., Gilje, K., Gorel, P., Graham, K., Grant, C., Grove, J., Grullon, S., Guillian, E., Hallin, A. L., Hallman, D., Hans, S., Hartnell, J., Harvey, P., Hedayatipour, M., Heintzelman, W. J., Heise, J., Helmer, R. L., Hernández-Hernández, J. L., Hreljac, B., Hu, J., Iida, T., Inácio, A. S., Jackson, C. M., Jelley, N. A., Jillings, C. J., Jones, C., Jones, P. G., Kamdin, K., Kaptanoglu, T., Kaspar, J., Keeter, K., Kefelian, C., Khaghani, P., Kippenbrock, L., Klein, J. R., Knapik, R., Kofron, J., Kormos, L. L., Krar, B., Kraus, C., Krauss, C. B., Kroupova, T., Labe, K., Lam, I., Lan, C., Land, B. J., Lane, R., Langrock, S., LaTorre, A., Lawson, I., Lebanowski, L., Lefeuvre, G. M., Leming, E. J., Li, A., Lidgard, J., Liggins, B., Liu, X., Liu, Y., Lozza, V., Luo, M., Maguire, S., Maio, A., Majumdar, K., Manecki, S., Maneira, J., Martin, R. D., Marzec, E., Mastbaum, A., McCauley, N., McDonald, A. B., McMillan, J. E., Mekarski, P., Meyer, M., Miller, C., Mlejnek, M., Mony, E., Morton-Blake, I., Mottram, M. J., Nae, S., Nirkko, M., Novikov, V., O'Keeffe, H. M., O'Sullivan, E., Gann, G. D. Orebi, Parnell, M. J., Paton, J., Peeters, S. J. M., Pershing, T., Petriw, Z., Pickard, L., Pracsovics, D., Prior, G., Prouty, J. C., Quirk, S., Reichold, A., Richardson, R., Rigan, M., Robertson, A., Rose, J., Rosero, R., Rost, P. M., Rumleskie, J., Schumaker, M. A., Schwendener, M. H., Scislowski, D., Secrest, J., Seddighin, M., Segui, L., Seibert, S., Semenec, I., Shantz, T., Shokair, T. M., Sibley, L., Sinclair, J. R., Singh, K., Skensved, P., Sonley, T., Stainforth, R., Strait, M., Stringer, M. I., Svoboda, R., Sörensen, A., Tam, B., Tatar, J., Tian, L., Tolich, N., Tseng, J., Tseung, H. W. C., Turner, E., Van Berg, R., Veinot, J. G. C., Virtue, C. J., von Krosigk, B., Vázquez-Jáuregui, E., Walker, J. M. G., Walker, M., Wang, J., Wasalski, O., Waterfield, J., Weigand, J. J., White, R. F., Wilson, J. R., Winchester, T. J., Woosaree, P., Wright, A., Yanez, J. P., Yeh, M., Zhao, T., Zuber, K., and Zummo, A.

Subjects

High Energy Physics - Experiment, Physics - Instrumentation and Detectors

Abstract

This paper reports results from a search for nucleon decay through 'invisible' modes, where no visible energy is directly deposited during the decay itself, during the initial water phase of SNO+. However, such decays within the oxygen nucleus would produce an excited daughter that would subsequently de-excite, often emitting detectable gamma rays. A search for such gamma rays yields limits of $2.5 \times 10^{29}$ y at 90% Bayesian credibility level (with a prior uniform in rate) for the partial lifetime of the neutron, and $3.6 \times 10^{29}$ y for the partial lifetime of the proton, the latter a 70% improvement on the previous limit from SNO. We also present partial lifetime limits for invisible dinucleon modes of $1.3\times 10^{28}$ y for $nn$, $2.6\times 10^{28}$ y for $pn$ and $4.7\times 10^{28}$ y for $pp$, an improvement over existing limits by close to three orders of magnitude for the latter two., Comment: 13 pages, 6 figures

Published

2018

8. First particle-by-particle measurement of emittance in the Muon Ionization Cooling Experiment

Author

The MICE Collaboration, Adams, D., Adey, D., Asfandiyarov, R., Barber, G., de Bari, A., Bayes, R., Bayliss, V., Bertoni, R., Blackmore, V., Blondel, A., Boehm, J., Bogomilov, M., Bonesini, M., Booth, C. N., Bowring, D., Boyd, S., Bradshaw, T. W., Bross, A. D., Brown, C., Coney, L., Charnley, G., Chatzitheodoridis, G. T., Chignoli, F., Chung, M., Cline, D., Cobb, J. H., Colling, D., Collomb, N., Cooke, P., Courthold, M., Cremaldi, L. M., DeMello, A., Dick, A. J., Dobbs, A., Dornan, P., Drielsma, F., Dumbell, K., Ellis, M., Filthaut, F., Franchini, P., Freemire, B., Gallagher, A., Gamet, R., Gardener, R. B. S., Gourlay, S., Grant, A., Greis, J. R., Griffiths, S., Hanlet, P., Hanson, G. G., Hartnett, T., Heidt, C., Hodgson, P., Hunt, C., Ishimoto, S., Jokovic, D., Jurj, P. B., Kaplan, D. M., Karadzhov, Y., Klier, A., Kuno, Y., Kurup, A., Kyberd, P., Lagrange, J-B., Langlands, J., Lau, W., Li, D., Li, Z., Liu, A., Long, K., Lord, T., Macwaters, C., Maletic, D., Martlew, B., Martyniak, J., Mazza, R., Middleton, S., Mohayai, T. A., Moss, A., Muir, A., Mullacrane, I., Nebrensky, J. J., Neuffer, D., Nichols, A., Nugent, J. C., Oates, A., Orestano, D., Overton, E., Owens, P., Palladino, V., Palmer, M., Pasternak, J., Pec, V., Pidcott, C., Popovic, M., Preece, R., Prestemon, S., Rajaram, D., Ricciardi, S., Robinson, M., Rogers, C., Ronald, K., Rubinov, P., Sakamoto, H., Sanders, D. A., Sato, A., Savic, M., Snopok, P., Smith, P. J., Soler, F. J. P., Song, Y., Stanley, T., Stokes, G., Suezaki, V., Summers, D. J., Sung, C. K., Tang, J., Tarrant, J., Taylor, I., Tortora, L., Torun, Y., Tsenov, R., Tucker, M., Uchida, M. A., Virostek, S., Vankova-Kirilova, G., Warburton, P., Wilbur, S., Wilson, A., Witte, H., White, C., Whyte, C. G., Yang, X., Young, A. R., and Zisman, M.

Subjects

Physics - Accelerator Physics, Physics - Instrumentation and Detectors

Abstract

The Muon Ionization Cooling Experiment (MICE) collaboration seeks to demonstrate the feasibility of ionization cooling, the technique by which it is proposed to cool the muon beam at a future neutrino factory or muon collider. The emittance is measured from an ensemble of muons assembled from those that pass through the experiment. A pure muon ensemble is selected using a particle-identification system that can reject efficiently both pions and electrons. The position and momentum of each muon are measured using a high-precision scintillating-fibre tracker in a 4\,T solenoidal magnetic field. This paper presents the techniques used to reconstruct the phase-space distributions and reports the first particle-by-particle measurement of the emittance of the MICE Muon Beam as a function of muon-beam momentum.

Published

2018

9. Neutron detection in the SNO+ water phase

Author

Liu, Y., Andringa, S., Auty, D., Barão, F., Bayes, R., Caden, E., Grant, C., Grove, J., Krar, B., LaTorre, A., Lebanowski, L., Lidgard, J., Maneira, J., Mekarski, P., Nae, S., Pershing, T., Semenec, I., Singh, K., Skensved, P., Tam, B., and Wright, A.

Subjects

Physics - Instrumentation and Detectors

Abstract

SNO+ is a multipurpose neutrino experiment located approximately 2 km underground in SNOLAB, Sudbury, Canada. The detector started taking physics data in May 2017 and is currently completing its first phase, as a pure water Cherenkov detector. The low trigger threshold of the SNO+ detector allows for a substantial neutron detection efficiency, as observed with a deployed ^{241}Am^{9}Be source. Using a statistical analysis of one hour AmBe calibration data, we report a neutron capture constant of 208.2 + 2.1(stat.) us and a lower bound of the neutron detection efficiency of 46% at the center of the detector., Comment: proceeding for Neutrino 2018

Published

2018

10. Baby MIND: A magnetized segmented neutrino detector for the WAGASCI experiment

Author

Antonova, M., Asfandiyarov, R., Bayes, R., Benoit, P., Blondel, A., Bogomilov, M., Bross, A., Cadoux, F., Cervera, A., Chikuma, N., Dudarev, A., Ekelöf, T., Favre, Y., Fedotov, S., Hallsjö, S-P., Izmaylov, A., Karadzhov, Y., Khabibullin, M., Khotyantsev, A., Kleymenova, A., Koga, T., Kostin, A., Kudenko, Y., Likhacheva, V., Martinez, B., Matev, R., Medvedeva, M., Mefodiev, A., Minamino, A., Mineev, O., Nessi, M., Nicola, L., Noah, E., Ovsiannikova, T., Da Silva, H. Pais, Parsa, S., Rayner, M., Rolando, G., Shaykhiev, A., Simion, P., Soler, F. J. P., Suvorov, S., Tsenov, R., Kate, H. Ten, Vankova-Kirilova, G., and Yershov, N.

Subjects

Physics - Instrumentation and Detectors

Abstract

T2K (Tokai-to-Kamioka) is a long-baseline neutrino experiment in Japan designed to study various parameters of neutrino oscillations. A near detector complex (ND280) is located 280~m downstream of the production target and measures neutrino beam parameters before any oscillations occur. ND280's measurements are used to predict the number and spectra of neutrinos in the Super-Kamiokande detector at the distance of 295~km. The difference in the target material between the far (water) and near (scintillator, hydrocarbon) detectors leads to the main non-cancelling systematic uncertainty for the oscillation analysis. In order to reduce this uncertainty a new WAter-Grid-And-SCintillator detector (WAGASCI) has been developed. A magnetized iron neutrino detector (Baby MIND) will be used to measure momentum and charge identification of the outgoing muons from charged current interactions. The Baby MIND modules are composed of magnetized iron plates and long plastic scintillator bars read out at the both ends with wavelength shifting fibers and silicon photomultipliers. The front-end electronics board has been developed to perform the readout and digitization of the signals from the scintillator bars. Detector elements were tested with cosmic rays and in the PS beam at CERN. The obtained results are presented in this paper., Comment: In new version: modified both plots of Fig.1 and added one sentence in the introduction part explaining Baby MIND role in WAGASCI experiment, added information for the affiliations

Published

2017

11. Baby MIND Experiment Construction Status

Author

Antonova, M., Asfandiyarov, R., Bayes, R, Benoit, P., Blondel, A., Bogomilov, M., Bross, A., Cadoux, F., Cervera, A., Chikuma, N., Dudarev, A., Ekelöf, T., Favre, Y., Fedotov, S., Hallsjö, S-P., Izmaylov, A., Karadzhov, Y., Khabibullin, M., Khotyantsev, A., Kleymenova, A., Koga, T., Kostin, A., Kudenko, Y., Likhacheva, V., Martinez, B., Matev, R., Medvedeva, M., Mefodiev, A., Minamino, A., Mineev, O., Nessi, M., Nicola, L., Noah, E., Ovsiannikova, T., Da Silva, H. Pais, Parsa, S., Rayner, M., Rolando, G., Shaykhiev, A, Simion, P., Soler, F. J. P., Suvorov, S., Tsenov, R., Kate, H. Ten, Vankova-Kirilova, G., and Yershov, N.

Subjects

Physics - Instrumentation and Detectors

Abstract

Baby MIND is a magnetized iron neutrino detector, with novel design features, and is planned to serve as a downstream magnetized muon spectrometer for the WAGASCI experiment on the T2K neutrino beam line in Japan. One of the main goals of this experiment is to reduce systematic uncertainties relevant to CP-violation searches, by measuring the neutrino contamination in the anti-neutrino beam mode of T2K. Baby MIND is currently being constructed at CERN, and is planned to be operational in Japan in October 2017., Comment: Poster presented at NuPhys2016 (London, 12-14 December 2016). 4 pages, LaTeX, 7 figures

Published

2017

12. Baby MIND: A magnetised spectrometer for the WAGASCI experiment

Author

Antonova, M., Asfandiyarov, R., Bayes, R, Benoit, P., Blondel, A., Bogomilov, M., Cross, A., Cadoux, F., Cervera, A., Chikuma, N., Dudarev, A., Ekelöf, T., Favre, Y., Fedotov, S., Hallsjö, S-P., Izmaylov, A., Karadzhov, Y., Khabibullin, M., Khotyantsev, A., Kleymenova, A., Koga, T., Kostin, A., Kudenko, Y., Likhacheva, V., Martinez, B., Matev, R., Medvedeva, M., Mefodiev, A., Minamino, A., Mineev, O., Nessi, M., Nicola, L., Noah, E., Ovsiannikova, T., Da Silva, H. Pais, Parsa, S., Rayner, M., Rolando, G., Shaykhiev, A, Simion, P., Soler, F. J. P., Suvorov, S., Tsenov, R., Kate, H. Ten, Vankova-Kirilova, G., and Yershov, N.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The WAGASCI experiment being built at the J-PARC neutrino beam line will measure the difference in cross sections from neutrinos interacting with a water and scintillator targets, in order to constrain neutrino cross sections, essential for the T2K neutrino oscillation measurements. A prototype Magnetised Iron Neutrino Detector (MIND), called Baby MIND, is being constructed at CERN to act as a magnetic spectrometer behind the main WAGASCI target to be able to measure the charge and momentum of the outgoing muon from neutrino charged current interactions., Comment: Poster presented at NuPhys2016 (London, 12-14 December 2016). Title + 4 pages, LaTeX, 6 figures

Published

2017

13. Pion contamination in the MICE muon beam

Author

Adams, D., Alekou, A., Apollonio, M., Asfandiyarov, R., Barber, G., Barclay, P., de Bari, A., Bayes, R., Bayliss, V., Bertoni, R., Blackmore, V. J., Blondel, A., Blot, S., Bogomilov, M., Bonesini, M., Booth, C. N., Bowring, D., Boyd, S., Bradshaw, T. W., Bravar, U., Bross, A. D., Capponi, M., Carlisle, T., Cecchet, G., Charnley, C., Chignoli, F., Cline, D., Cobb, J. H., Colling, G., Collomb, N., Coney, L., Cooke, P., Courthold, M., Cremaldi, L. M., DeMello, A., Dick, A., Dobbs, A., Dornan, P., Drews, M., Drielsma, F., Filthaut, F., Fitzpatrick, T., Franchini, P., Francis, V., Fry, L., Gallagher, A., Gamet, R., Gardener, R., Gourlay, S., Grant, A., Greis, J. R., Griffiths, S., Hanlet, P., Hansen, O. M., Hanson, G. G., Hart, T. L., Hartnett, T., Hayler, T., Heidt, C., Hills, M., Hodgson, P., Hunt, C., Iaciofano, A., Ishimoto, S., Kafka, G., Kaplan, D. M., Karadzhov, Y., Kim, Y. K., Kuno, Y., Kyberd, P., Lagrange, J-B, Langlands, J., Lau, W., Leonova, M., Li, D., Lintern, A., Littlefield, M., Long, K., Luo, T., Macwaters, C., Martlew, B., Martyniak, J., Mazza, R., Middleton, S., Moretti, A., Moss, A., Muir, A., Mullacrane, I., Nebrensky, J. J., Neuffer, D., Nichols, A., Nicholson, R., Nugent, J. C., Oates, A., Onel, Y., Orestano, D., Overton, E., Owens, P., Palladino, V., Pasternak, J., Pastore, F., Pidcott, C., Popovic, M., Preece, R., Prestemon, S., Rajaram, D., Ramberger, S., Rayner, M. A., Ricciardi, S., Roberts, T. J., Robinson, M., Rogers, C., Ronald, K., Rubinov, P., Rucinski, P., Sakamato, H., Sanders, D. A., Santos, E., Savidge, T., Smith, P. J., Snopok, P., Soler, F. J. P., Speirs, D., Stanley, T., Stokes, G., Summers, D. J., Tarrant, J., Taylor, I., Tortora, L., Torun, Y., Tsenov, R., Tunnell, C. D., Uchida, M. A., Vankova-Kirilova, G., Virostek, S., Vretenar, M., Warburton, P., Watson, S., White, C., Whyte, C. G., Wilson, A., Winter, M., Yang, X., Young, A., and Zisman, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The international Muon Ionization Cooling Experiment (MICE) will perform a systematic investigation of ionization cooling with muon beams of momentum between 140 and 240\,MeV/c at the Rutherford Appleton Laboratory ISIS facility. The measurement of ionization cooling in MICE relies on the selection of a pure sample of muons that traverse the experiment. To make this selection, the MICE Muon Beam is designed to deliver a beam of muons with less than $\sim$1\% contamination. To make the final muon selection, MICE employs a particle-identification (PID) system upstream and downstream of the cooling cell. The PID system includes time-of-flight hodoscopes, threshold-Cherenkov counters and calorimetry. The upper limit for the pion contamination measured in this paper is $f_\pi < 1.4\%$ at 90\% C.L., including systematic uncertainties. Therefore, the MICE Muon Beam is able to meet the stringent pion-contamination requirements of the study of ionization cooling., Comment: 16 pages, 7 figures

Published

2015

14. Electron-Muon Ranger: performance in the MICE Muon Beam

Author

Adams, D., Alekou, A., Apollonio, M., Asfandiyarov, R., Barber, G., Barclay, P., de Bari, A., Bayes, R., Bayliss, V., Bene, P., Bertoni, R., Blackmore, V. J., Blondel, A., Blot, S., Bogomilov, M., Bonesini, M., Booth, C. N., Bowring, D., Boyd, S., Bradshaw, T. W., Bravar, U., Bross, A. D., Cadoux, F., Capponi, M., Carlisle, T., Cecchet, G., Charnley, C., Chignoli, F., Cline, D., Cobb, J. H., Colling, G., Collomb, N., Coney, L., Cooke, P., Courthold, M., Cremaldi, L. M., Debieux, S., DeMello, A., Dick, A., Dobbs, A., Dornan, P., Drielsma, F., Filthaut, F., Fitzpatrick, T., Franchini, P., Francis, V., Fry, L., Gallagher, A., Gamet, R., Gardener, R., Gourlay, S., Grant, A., Graulich, J. S., Greis, J., Griffiths, S., Hanlet, P., Hansen, O. M., Hanson, G. G., Hart, T. L., Hartnett, T., Hayler, T., Heidt, C., Hills, M., Hodgson, P., Hunt, C., Husi, C., Iaciofano, A., Ishimoto, S., Kafka, G., Kaplan, D. M., Karadzhov, Y., Kim, Y. K., Kuno, Y., Kyberd, P., Lagrange, J-B, Langlands, J., Lau, W., Leonova, M., Li, D., Lintern, A., Littlefield, M., Long, K., Luo, T., Macwaters, C., Martlew, B., Martyniak, J., Masciocchi, F., Mazza, R., Middleton, S., Moretti, A., Moss, A., Muir, A., Mullacrane, I., Nebrensky, J. J., Neuffer, D., Nichols, A., Nicholson, R., Nicola, L., Messomo, E. Noah, Nugent, J. C., Oates, A., Onel, Y., Orestano, D., Overton, E., Owens, P., Palladino, V., Pasternak, J., Pastore, F., Pidcott, C., Popovic, M., Preece, R., Prestemon, S., Rajaram, D., Ramberger, S., Rayner, M. A., Ricciardi, S., Roberts, T. J., Robinson, M., Rogers, C., Ronald, K., Rothenfusser, K., Rubinov, P., Rucinski, P., Sakamato, H., Sanders, D. A., Sandstrom, R., Santos, E., Savidge, T., Smith, P. J., Snopok, P., Soler, F. J. P., Speirs, D., Stanley, T., Stokes, G., Summers, D. J., Tarrant, J., Taylor, I., Tortora, L., Torun, Y., Tsenov, R., Tunnell, C. D., Uchida, M. A., Vankova-Kirilova, G., Virostek, S., Vretenar, M., Warburton, P., Watson, S., White, C., Whyte, C. G., Wilson, A., Wisting, H., Yang, X., Young, A., and Zisman, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The Muon Ionization Cooling Experiment (MICE) will perform a detailed study of ionization cooling to evaluate the feasibility of the technique. To carry out this program, MICE requires an efficient particle-identification (PID) system to identify muons. The Electron-Muon Ranger (EMR) is a fully-active tracking-calorimeter that forms part of the PID system and tags muons that traverse the cooling channel without decaying. The detector is capable of identifying electrons with an efficiency of 98.6%, providing a purity for the MICE beam that exceeds 99.8%. The EMR also proved to be a powerful tool for the reconstruction of muon momenta in the range 100-280 MeV/$c$., Comment: 22 pages, 19 figures

Published

2015

15. LBNO-DEMO: Large-scale neutrino detector demonstrators for phased performance assessment in view of a long-baseline oscillation experiment

Author

Agostino, L., Andrieu, B., Asfandiyarov, R., Autiero, D., Bésida, O., Bay, F., Bayes, R., Blebea-Apostu, A. M., Blondel, A., Bogomilov, M., Bolognesi, S., Bordoni, S., Bravar, A., Buizza-Avanzini, M., Cadoux, F., Caiulo, D., Calin, M., Campanelli, M., Cantini, C., Chaussard, L., Chesneanu, D., Colino, N., Crivelli, P., De Bonis, I., Déclais, Y., Dawson, J., De La Taille, C., Sanchez, P. Del Amo, Delbart, A., Di Luise, S., Duchesneau, D., Dulucq, F., Dumarchez, J., Efthymiopoulos, I., Emery, S., Enqvist, T., Epprecht, L., Esanu, T., Franco, D., Friend, M., Galymov, V., Gendotti, A., Giganti, C., Gil-Botella, I., Gomoiu, M. C, Gorodetzky, P., Haesler, A., Hasegawa, T., Horikawa, S., Ieva, M., Jipa, A., Karadzhov, Y., Karpikov, I., Khotjantsev, A., Korzenev, A., Kryn, D., Kudenko, Y., Kuusiniemi, P., Lazanu, I., Levy, J. -M., Loo, K., Lux, T., Maalampi, J., Margineanu, R. M., Marteau, J., Martin, C., Martin-Chassard, G., Mazzucato, E., Mefodiev, A., Mineev, O., Mitrica, B., Murphy, S., Nakadaira, T., Nessi, M., Nikolics, K., Nita, L., Noah, E., Novella, P., Nuijten, G. A., Ovsiannikova, T., Palomares, C., Patzak, T., Pennacchio, E., Periale, L., Pessard, H., Popov, B., Ravonel, M., Rayner, M., Regenfus, C., Ristea, C., Ristea, O., Robert, A., Rubbia, A., Sakashita, K., Sanchez, F., Santorelli, R., Scantamburlo, E., Sergiampietri, F., Sgalaberna, D., Slupecki, M., Soler, F. J. P., Stanca, D. L., Tonazzo, A., Trzaska, W. H., Tsenov, R., Vankova-Kirilova, G., Vannucci, F., Vasseur, G., Verdugo, A., Viant, T., Wu, S., Yershov, N., Zambelli, L., and Zito, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

In June 2012, an Expression of Interest for a long-baseline experiment (LBNO) has been submitted to the CERN SPSC. LBNO considers three types of neutrino detector technologies: a double-phase liquid argon (LAr) TPC and a magnetised iron detector as far detectors. For the near detector, a high-pressure gas TPC embedded in a calorimeter and a magnet is the baseline design. A mandatory milestone is a concrete prototyping effort towards the envisioned large-scale detectors, and an accompanying campaign of measurements aimed at assessing the detector associated systematic errors. The proposed $6\times 6\times 6$m$^3$ DLAr is an industrial prototype of the design discussed in the EoI and scalable to 20 kton or 50~kton. It is to be constructed and operated in a controlled laboratory and surface environment with test beam access, such as the CERN North Area (NA). Its successful operation and full characterisation will be a fundamental milestone, likely opening the path to an underground deployment of larger detectors. The response of the DLAr demonstrator will be measured and understood with an unprecedented precision in a charged particle test beam (0.5-20 GeV/c). The exposure will certify the assumptions and calibrate the response of the detector, and allow to develop and to benchmark sophisticated reconstruction algorithms, such as those of 3-dimensional tracking, particle ID and energy flow in liquid argon. All these steps are fundamental for validating the correctness of the physics performance described in the LBNO EoI., Comment: 217 pages, 164 figures, LBNO-DEMO (CERN WA105) Collaboration

Published

2014

16. Proposal for SPS beam time for the baby MIND and TASD neutrino detector prototypes

Author

Asfandiyarov, R., Bayes, R., Blondel, A., Bogomilov, M., Bross, A., Cadoux, F., Cervera, A., Izmaylov, A., Karadzhov, Y., Karpikov, I., Khabibulin, M., Khotyantsev, A., Kopylov, A., Kudenko, Y., Matev, R., Mineev, O., Musienko, Y., Nessi, M., Noah, E., Rubbia, A., Shaykiev, A., Soler, P., Tsenov, R., Vankova-Kirilova, G., and Yershov, N.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The design, construction and testing of neutrino detector prototypes at CERN are ongoing activities. This document reports on the design of solid state baby MIND and TASD detector prototypes and outlines requirements for a test beam at CERN to test these, tentatively planned on the H8 beamline in the North Area, which is equipped with a large aperture magnet. The current proposal is submitted to be considered in light of the recently approved projects related to neutrino activities with the SPS in the North Area in the medium term 2015-2020.

Published

2014

17. nuSTORM - Neutrinos from STORed Muons: Proposal to the Fermilab PAC

Author

Adey, D., Agarwalla, S. K., Ankenbrandt, C. M., Asfandiyarov, R., Back, J. J., Barker, G., Baussan, E., Bayes, R., Bhadra, S., Blackmore, V., Blondel, A., Bogacz, S. A., Booth, C., Boyd, S. B., Bravar, A., Brice, S. J., Bross, A. D., Cadoux, F., Cease, H., Cervera, A., Cobb, J., Colling, D., Coloma, P., Coney, L., Dobbs, A., Dobson, J., Donini, A., Dornan, P., Dracos, M., Dufour, F., Edgecock, R., Evans, J., Geelhoed, M., George, M. A., Ghosh, T., Gomez-Cadenas, J. J., de Gouvea, A., Haesler, A., Hanson, G., Harrison, P. F., Hartz, M., Hernandez, P., Morata, J. A. Hernando, Hodgson, P., Huber, P., Izmaylov, A., Karadzhov, Y., Kobilarcik, T., Kopp, J., Kormos, L., Korzenev, A., Kuno, Y., Kurup, A., Kyberd, P., Lagrange, J. B., Laing, A., Liu, A., Link, J. M., Long, K., Mahn, K., Mariani, C., Martin, C., Martin, J., McCauley, N., McDonald, K. T., Mena, O., Mishra, S. R., Mokhov, N., Morfin, J., Mori, Y., Murray, W., Neuffer, D., Nichol, R., Noah, E., Palmer, M. A., Parke, S., Pascoli, S., Pasternak, J., Popovic, M., Ratoff, P., Ravonel, M., Rayner, M., Ricciardi, S., Rogers, C., Rubinov, P., Santos, E., Sato, A., Sen, T., Scantamburlo, E., Sedgbeer, J. K., Smith, D. R., Smith, P. J., Sobczyk, J. T., Soby, L., Soler, F. J. P., Soldner-Rembold, S., Sorel, M., Snopok, P., Stamoulis, P., Stanco, L., Striganov, S., Tanaka, H. A., Taylor, I. J., Touramanis, C., Tunnell, C. D., Uchida, Y., Vassilopoulos, N., Wascko, M. O., Weber, A., Wilking, M. J., Wildner, E., Winter, W., and Yang, U. K.

Subjects

Physics - Accelerator Physics, High Energy Physics - Experiment, Physics - Instrumentation and Detectors

Abstract

The nuSTORM facility has been designed to deliver beams of electron neutrinos and muon neutrinos (and their anti-particles) from the decay of a stored muon beam with a central momentum of 3.8 GeV/c and a momentum acceptance of 10%. The facility is unique in that it will: 1. Allow searches for sterile neutrinos of exquisite sensitivity to be carried out; 2. Serve future long- and short-baseline neutrino-oscillation programs by providing definitive measurements of electron neutrino and muon neutrino scattering cross sections off nuclei with percent-level precision; and 3. Constitutes the crucial first step in the development of muon accelerators as a powerful new technique for particle physics. The document describes the facility in detail and demonstrates its physics capabilities. This document was submitted to the Fermilab Physics Advisory Committee in consideration for Stage I approval.

Published

2013

18. A Toroidal Magnetised Iron Neutrino Detector (MIND) for a Neutrino Factory

Author

Bross, A., Wands, R., Bayes, R., Laing, A., Soler, F. J. P., Villanueva, A. Cervera, Ghosh, T., Cadenas, J. J. Gómez, Hernández, P., Martín-Albo, J., and Burguet-Castell, J.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

A neutrino factory has unparalleled physics reach for the discovery and measurement of CP violation in the neutrino sector. A far detector for a neutrino factory must have good charge identification with excellent background rejection and a large mass. An elegant solution is to construct a magnetized iron neutrino detector (MIND) along the lines of MINOS, where iron plates provide a toroidal magnetic field and scintillator planes provide 3D space points. In this report, the current status of a simulation of a toroidal MIND for a neutrino factory is discussed in light of the recent measurements of large $\theta_{13}$. The response and performance using the 10 GeV neutrino factory configuration are presented. It is shown that this setup has equivalent $\delta_{CP}$ reach to a MIND with a dipole field and is sensitive to the discovery of CP violation over 85% of the values of $\delta_{CP}$., Comment: Results from the studies of a far detector at a neutrino factory as part of the European Framework Programme 7 project, EUROnu. 35 pages, 13 figures

Published

2013

19. Neutrinos from Stored Muons nuSTORM: Expression of Interest

Author

Adey, D., Agarwalla, S. K., Ankenbrandt, C. M., Asfandiyarov, R., Back, J. J., Barker, G., Baussan, E., Bayes, R., Bhadra, S., Blackmore, V., Blondel, A., Bogacz, S. A., Booth, C., Boyd, S. B., Bravar, A., Brice, S. J., Bross, A. D., Cadoux, F., Cease, H., Cervera, A., Cobb, J., Colling, D., Coney, L., Dobbs, A., Dobson, J., Donini, A., Dornan, P. J., Dracos, M., Dufour, F., Edgecock, R., Evans, J., George, M. A., Ghosh, T., deGouvea, A., Gomez-Cadenas, J. J., Haesler, A., Hanson, G., Geelhoed, M., Harrison, P. F., Hartz, M., Hernandez, P., Hernando-Morata, J. A., Hodgson, P. J., Huber, P., Izmaylov, A., Karadhzov, Y., Kobilarcik, T., Kopp, J., Kormos, L., Korzenev, A., Kurup, A., Kuno, Y., Kyberd, P., Lagrange, J. P., Laing, A. M., Link, J., Liu, A., Long, K. R., McCauley, N., McDonald, K. T., Mahn, K., Martin, C., Martin, J., Mena, O., Mishra, S. R., Mokhov, N., Morfin, J., Mori, Y., Murray, W., Neuffer, D., Nichol, R., Noah, E., Palmer, M. A., Parke, S., Pascoli, S., Pasternak, J., Popovic, M., Ratoff, P., Ravonel, M., Rayner, M., Ricciardi, S., Rogers, C., Rubinov, P., Santos, E., Sato, A., Scantamburlo, E., Sedgbeer, J. K., Smith, D. R., Smith, P. J., Sobczyk, J. T., Soldner-Rembold, S., Soler, F. J. P., Sorel, M., Stahl, A., Stanco, L., Stamoulis, P., Striganov, S., Tanaka, H., Taylor, I. J., Touramanis, C., Tunnel, C. D., Uchida, Y., Vassilopoulos, N., Wascko, M. O., Weber, A., Wildner, E., Wilking, M. J., Winter, W., and Yang, U. K.

Subjects

Physics - Accelerator Physics, High Energy Physics - Phenomenology, Physics - Instrumentation and Detectors

Abstract

The nuSTORM facility has been designed to deliver beams of electron and muon neutrinos from the decay of a stored muon beam with a central momentum of 3.8 GeV/c and a momentum spread of 10%. The facility is unique in that it will: serve the future long- and short-baseline neutrino-oscillation programmes by providing definitive measurements of electron-neutrino- and muon-neutrino-nucleus cross sections with percent-level precision; allow searches for sterile neutrinos of exquisite sensitivity to be carried out; and constitute the essential first step in the incremental development of muon accelerators as a powerful new technique for particle physics. Of the world's proton-accelerator laboratories, only CERN and FNAL have the infrastructure required to mount nuSTORM. Since no siting decision has yet been taken, the purpose of this Expression of Interest (EoI) is to request the resources required to: investigate in detail how nuSTORM could be implemented at CERN; and develop options for decisive European contributions to the nuSTORM facility and experimental programme wherever the facility is sited. The EoI defines a two-year programme culminating in the delivery of a Technical Design Report., Comment: 59 pages; 24 figures; 5 tables

Published

2013

20. nuSTORM: Neutrinos from STORed Muons

Author

Kyberd, P., Smith, D. R., Coney, L., Pascoli, S., Ankenbrandt, C., Brice, S. J., Bross, A. D., Cease, H., Kopp, J., Mokhov, N., Morfin, J., Neuffer, D., Popovic, M., Rubinov, P., Striganov, S., Blondel, A., Bravar, A., Noah, E., Bayes, R., Soler, F. J. P., Dobbs, A., Long, K., Pasternak, J., Santos, E., Wascko, M. O., Agarwalla, S. K., Bogacz, S. A., Mori, Y., Lagrange, J. B., de Gouvêa, A., Kuno, Y., Sato, A., Blackmore, V., Cobb, J., Tunnell, C. D., Link, J. M., Huber, P., and Winter, W.

Subjects

High Energy Physics - Experiment, Physics - Instrumentation and Detectors

Abstract

The results of LSND and MiniBooNE, along with the recent papers on a possible reactor neutrino flux anomaly give tantalizing hints of new physics. Models beyond the neutrino-SM have been developed to explain these results and involve one or more additional neutrinos that are non-interacting or "sterile." Neutrino beams produced from the decay of muons in a racetrack-like decay ring provide a powerful way to study this potential new physics. In this Letter of Intent, we describe a facility, nuSTORM, "Neutrinos from STORed Muons," and an appropriate far detector for neutrino oscillation searches at short baseline. We present sensitivity plots that indicated that this experimental approach can provide over 10 sigma confirmation or rejection of the LSND/MinBooNE results. In addition we indicate how the facility can be used to make precision neutrino interaction cross section measurements important to the next generation of long-baseline neutrino oscillation experiments.

Published

2012

21. First particle-by-particle measurement of emittance in the Muon Ionization Cooling Experiment

Author

The MICE Collaboration, Adams, D., Adey, D., Asfandiyarov, R., Barber, G., de Bari, A., Bayes, R., Bayliss, V., Bertoni, R., Blackmore, V., Blondel, A., Boehm, J., Bogomilov, M., Bonesini, M., Booth, C. N., Bowring, D., Boyd, S., Bradshaw, T. W., Bross, A. D., Brown, C., Coney, L., Charnley, G., Chatzitheodoridis, G. T., Chignoli, F., Chung, M., Cline, D., Cobb, J. H., Colling, D., Collomb, N., Cooke, P., Courthold, M., Cremaldi, L. M., DeMello, A., Dick, A. J., Dobbs, A., Dornan, P., Drielsma, F., Dumbell, K., Ellis, M., Filthaut, F., Franchini, P., Freemire, B., Gallagher, A., Gamet, R., Gardener, R. B. S., Gourlay, S., Grant, A., Greis, J. R., Griffiths, S., Hanlet, P., Hanson, G. G., Hartnett, T., Heidt, C., Hodgson, P., Hunt, C., Ishimoto, S., Jokovic, D., Jurj, P. B., Kaplan, D. M., Karadzhov, Y., Klier, A., Kuno, Y., Kurup, A., Kyberd, P., Lagrange, J-B., Langlands, J., Lau, W., Li, D., Li, Z., Liu, A., Long, K., Lord, T., Macwaters, C., Maletic, D., Martlew, B., Martyniak, J., Mazza, R., Middleton, S., Mohayai, T. A., Moss, A., Muir, A., Mullacrane, I., Nebrensky, J. J., Neuffer, D., Nichols, A., Nugent, J. C., Oates, A., Orestano, D., Overton, E., Owens, P., Palladino, V., Palmer, M., Pasternak, J., Pec, V., Pidcott, C., Popovic, M., Preece, R., Prestemon, S., Rajaram, D., Ricciardi, S., Robinson, M., Rogers, C., Ronald, K., Rubinov, P., Sakamoto, H., Sanders, D. A., Sato, A., Savic, M., Snopok, P., Smith, P. J., Soler, F. J. P., Song, Y., Stanley, T., Stokes, G., Suezaki, V., Summers, D. J., Sung, C. K., Tang, J., Tarrant, J., Taylor, I., Tortora, L., Torun, Y., Tsenov, R., Tucker, M., Uchida, M. A., Virostek, S., Vankova-Kirilova, G., Warburton, P., Wilbur, S., Wilson, A., Witte, H., White, C., Whyte, C. G., Yang, X., Young, A. R., Zisman, M., Adams, D., Adey, D., Asfandiyarov, R., Barber, G., de Bari, A., Bayes, R., Bayliss, V., Bertoni, R., Blackmore, V., Blondel, A., Boehm, J., Bogomilov, M., Bonesini, M., Booth, C. N., Bowring, D., Boyd, S., Bradshaw, T. W., Bross, A. D., Brown, C., Charnley, G., Chatzitheodoridis, G. T., Chignoli, F., Chung, M., Cline, D., Cobb, J. H., Colling, D., Collomb, N., Cooke, P., Courthold, M., Cremaldi, L. M., Demello, A., Dick, A. J., Dobbs, A., Dornan, P., Drielsma, F., Dumbell, K., Ellis, M., Filthaut, F., Franchini, P., Freemire, B., Gallagher, A., Gamet, R., Gardener, R. B. S., Gourlay, S., Grant, A., Greis, J. R., Griffiths, S., Hanlet, P., Hanson, G. G., Hartnett, T., Heidt, C., Hodgson, P., Hunt, C., Ishimoto, S., Jokovic, D., Jurj, P. B., Kaplan, D. M., Karadzhov, Y., Klier, A., Kuno, Y., Kurup, A., Kyberd, P., Lagrange, J. -B., Langlands, J., Lau, W., Li, D., Li, Z., Liu, A., Long, K., Lord, T., Macwaters, C., Maletic, D., Martlew, B., Martyniak, J., Mazza, R., Middleton, S., Mohayai, T. A., Moss, A., Muir, A., Mullacrane, I., Nebrensky, J. J., Neuffer, D., Nichols, A., Nugent, J. C., Oates, A., Orestano, D., Overton, E., Owens, P., Palladino, V., Palmer, M., Pasternak, J., Pec, V., Pidcott, C., Popovic, M., Preece, R., Prestemon, S., Rajaram, D., Ricciardi, S., Robinson, M., Rogers, C., Ronald, K., Rubinov, P., Sakamoto, H., Sanders, D. A., Sato, A., Savic, M., Snopok, P., Smith, P. J., Soler, F. J. P., Song, Y., Stanley, T., Stokes, G., Suezaki, V., Summers, D. J., Sung, C. K., Tang, J., Tarrant, J., Taylor, I., Tortora, L., Torun, Y., Tsenov, R., Tucker, M., Uchida, M. A., Virostek, S., Vankova-Kirilova, G., Warburton, P., Wilbur, S., Wilson, A., Witte, H., White, C., Whyte, C. G., Yang, X., Young, A. R., Zisman, M., Science and Technology Facilities Council (STFC), Imperial College Trust, Council for the Central Laboratory of the Research Councils' (CCLRC), Asfandiyarov, Ruslan, Blondel, Alain, Drielsma, François, and Karadzhov, Yordan Ivanov

Subjects

Accelerator Physics (physics.acc-ph), Physics - Instrumentation and Detectors, Physics and Astronomy (miscellaneous), Physics::Instrumentation and Detectors, FOS: Physical sciences, lcsh:Astrophysics, ddc:500.2, Electron, 01 natural sciences, Physics, Particles & Fields, Nuclear physics, Momentum, Pion, DESIGN, 0103 physical sciences, lcsh:QB460-466, Ionization cooling, Thermal emittance, lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, High Energy Physics, 010306 general physics, physics.ins-det, 0206 Quantum Physics, Engineering (miscellaneous), QC, physics.acc-ph, Physics, Science & Technology, Muon, 010308 nuclear & particles physics, Instrumentation and Detectors (physics.ins-det), Nuclear & Particles Physics, Muon collider, Physical Sciences, 0202 Atomic, Molecular, Nuclear, Particle and Plasma Physics, Experimental High Energy Physics, lcsh:QC770-798, Physics::Accelerator Physics, Physics - Accelerator Physics, Neutrino Factory, High Energy Physics::Experiment

Abstract

The Muon Ionization Cooling Experiment (MICE) collaboration seeks to demonstrate the feasibility of ionization cooling, the technique by which it is proposed to cool the muon beam at a future neutrino factory or muon collider. The emittance is measured from an ensemble of muons assembled from those that pass through the experiment. A pure muon ensemble is selected using a particle identification system that can reject efficiently both pions and electrons. The position and momentum of each muon are measured using a high-precision scintillating-fibre tracker in a 4 T solenoidal magnetic field. This paper presents the techniques used to reconstruct the phase-space distributions in the upstream tracking detector and reports the first particle by-article measurement of the emittance of the MICE Muon Beam as a function of muon-beam momentum. Science and Technology Facilities Council (UK)

Published

2019

22. Search for invisible modes of nucleon decay in water with the SNO+ detector

Author

Collaboration, SNO+, Anderson, M., Andringa, S., Arushanova, E., Asahi, S., Askins, M., Auty, D. J., Back, A. R., Barnard, Z., Barros, N., Bartlett, D., Bar��o, F., Bayes, R., Beier, E. W., Bialek, A., Biller, S. D., Blucher, E., Bonventre, R., Boulay, M., Braid, D., Caden, E., Callaghan, E. J., Caravaca, J., Carvalho, J., Cavalli, L., Chauhan, D., Chen, M., Chkvorets, O., Clark, K. J., Cleveland, B., Connors, C., Coulter, I. T., Cressy, D., Dai, X., Darrach, C., Davis-Purcell, B., Depatie, M. M., Descamps, F., Di Lodovico, F., Duhaime, N., Duncan, F., Dunger, J., Falk, E., Fatemighomi, N., Fischer, V., Fletcher, E., Ford, R., Gagnon, N., Gilje, K., Gorel, P., Graham, K., Grant, C., Grove, J., Grullon, S., Guillian, E., Hallin, A. L., Hallman, D., Hans, S., Hartnell, J., Harvey, P., Hedayatipour, M., Heintzelman, W. J., Heise, J., Helmer, R. L., Hern��ndez-Hern��ndez, J. L., Hreljac, B., Hu, J., Iida, T., In��cio, A. S., Jackson, C. M., Jelley, N. A., Jillings, C. J., Jones, C., Jones, P. G., Kamdin, K., Kaptanoglu, T., Kaspar, J., Keeter, K., Kefelian, C., Khaghani, P., Kippenbrock, L., Klein, J. R., Knapik, R., Kofron, J., Kormos, L. L., Krar, B., Kraus, C., Krauss, C. B., Kroupova, T., Labe, K., Lam, I., Lan, C., Land, B. J., Lane, R., Langrock, S., LaTorre, A., Lawson, I., Lebanowski, L., Lefeuvre, G. M., Leming, E. J., Li, A., Lidgard, J., Liggins, B., Liu, X., Liu, Y., Lozza, V., Luo, M., Maguire, S., Maio, A., Majumdar, K., Manecki, S., Maneira, J., Martin, R. D., Marzec, E., Mastbaum, A., McCauley, N., McDonald, A. B., McMillan, J. E., Mekarski, P., Meyer, M., Miller, C., Mlejnek, M., Mony, E., Morton-Blake, I., Mottram, M. J., Nae, S., Nirkko, M., Novikov, V., O'Keeffe, H. M., O'Sullivan, E., Gann, G. D. Orebi, Parnell, M. J., Paton, J., Peeters, S. J. M., Pershing, T., Petriw, Z., Pickard, L., Pracsovics, D., Prior, G., Prouty, J. C., Quirk, S., Reichold, A., Richardson, R., Rigan, M., Robertson, A., Rose, J., Rosero, R., Rost, P. M., Rumleskie, J., Schumaker, M. A., Schwendener, M. H., Scislowski, D., Secrest, J., Seddighin, M., Segui, L., Seibert, S., Semenec, I., Shantz, T., Shokair, T. M., Sibley, L., Sinclair, J. R., Singh, K., Skensved, P., Sonley, T., Stainforth, R., Strait, M., Stringer, M. I., Svoboda, R., S��rensen, A., Tam, B., Tatar, J., Tian, L., Tolich, N., Tseng, J., Tseung, H. W. C., Turner, E., Van Berg, R., Veinot, J. G. C., Virtue, C. J., von Krosigk, B., V��zquez-J��uregui, E., Walker, J. M. G., Walker, M., Wang, J., Wasalski, O., Waterfield, J., Weigand, J. J., White, R. F., Wilson, J. R., Winchester, T. J., Woosaree, P., Wright, A., Yanez, J. P., Yeh, M., Zhao, T., Zuber, K., and Zummo, A.

Subjects

Physics, Physics - Instrumentation and Detectors, Proton, 010308 nuclear & particles physics, Gamma ray, Phase (waves), FOS: Physical sciences, Instrumentation and Detectors (physics.ins-det), 01 natural sciences, 7. Clean energy, High Energy Physics - Experiment, High Energy Physics - Experiment (hep-ex), Orders of magnitude (time), Excited state, 0103 physical sciences, Bound state, Neutron, Atomic physics, 010306 general physics, Nucleon, QC

Abstract

This paper reports results from a search for nucleon decay through 'invisible' modes, where no visible energy is directly deposited during the decay itself, during the initial water phase of SNO+. However, such decays within the oxygen nucleus would produce an excited daughter that would subsequently de-excite, often emitting detectable gamma rays. A search for such gamma rays yields limits of $2.5 \times 10^{29}$ y at 90% Bayesian credibility level (with a prior uniform in rate) for the partial lifetime of the neutron, and $3.6 \times 10^{29}$ y for the partial lifetime of the proton, the latter a 70% improvement on the previous limit from SNO. We also present partial lifetime limits for invisible dinucleon modes of $1.3\times 10^{28}$ y for $nn$, $2.6\times 10^{28}$ y for $pn$ and $4.7\times 10^{28}$ y for $pp$, an improvement over existing limits by close to three orders of magnitude for the latter two., Comment: 13 pages, 6 figures

Published

2019

23. LBNO-DEMO: Large-scale neutrino detector demonstrators for phased performance assessment in view of a long-baseline oscillation experiment

Author

Agostino, L., Andrieu, B., Asfandiyarov, R., Autiero, D., Bésida, O., Bay, F., Bayes, R., Blebea-Apostu, A. M., Blondel, A., Bogomilov, M., Bolognesi, S., Bordoni, S., Bravar, A., Buizza-Avanzini, M., Cadoux, F., Caiulo, D., Calin, M., Campanelli, M., Cantini, C., Chaussard, L., Chesneanu, D., Colino, N., Crivelli, P., De Bonis, I., Déclais, Y., Dawson, J., De La Taille, C., Sanchez, P. Del Amo, Delbart, A., Di Luise, S., Duchesneau, D., Dulucq, F., Dumarchez, J., Efthymiopoulos, I., Emery, S., Enqvist, T., Epprecht, L., Esanu, T., Franco, D., Friend, M., Galymov, V., Gendotti, A., Giganti, C., Gil-Botella, I., Gomoiu, M. C, Gorodetzky, P., Haesler, A., Hasegawa, T., Horikawa, S., Ieva, M., Jipa, A., Karadzhov, Y., Karpikov, I., Khotjantsev, A., Korzenev, A., Kryn, D., Kudenko, Y., Kuusiniemi, P., Lazanu, I., Levy, J. -M., Loo, K., Lux, T., Maalampi, J., Margineanu, R. M., Marteau, J., Martin, C., Martin-Chassard, G., Mazzucato, E., Mefodiev, A., Mineev, O., Mitrica, B., Murphy, S., Nakadaira, T., Nessi, M., Nikolics, K., Nita, L., Noah, E., Novella, P., Nuijten, G. A., Ovsiannikova, T., Palomares, C., Patzak, T., Pennacchio, E., Periale, L., Pessard, H., Popov, B., Ravonel, M., Rayner, M., Regenfus, C., Ristea, C., Ristea, O., Robert, A., Rubbia, A., Sakashita, K., Sanchez, F., Santorelli, R., Scantamburlo, E., Sergiampietri, F., Sgalaberna, D., Slupecki, M., Soler, F. J. P., Stanca, D. L., Tonazzo, A., Trzaska, W. H., Tsenov, R., Vankova-Kirilova, G., Vannucci, F., Vasseur, G., Verdugo, A., Viant, T., Wu, S., Yershov, N., Zambelli, L., Zito, M., AstroParticule et Cosmologie (APC (UMR_7164)), Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Observatoire de Paris, PSL Research University (PSL)-PSL Research University (PSL)-Université Paris Diderot - Paris 7 (UPD7), Laboratoire de Physique Nucléaire et de Hautes Énergies (LPNHE), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Institut de Physique Nucléaire de Lyon (IPNL), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Institut de Recherches sur les lois Fondamentales de l'Univers (IRFU), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, Laboratoire d'Annecy de Physique des Particules (LAPP/Laboratoire d'Annecy-le-Vieux de Physique des Particules), Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS), and WA105

Subjects

High Energy Physics - Experiment (hep-ex), Physics - Instrumentation and Detectors, Physics::Instrumentation and Detectors, [PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex], FOS: Physical sciences, High Energy Physics::Experiment, Instrumentation and Detectors (physics.ins-det), [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], High Energy Physics - Experiment

Abstract

In June 2012, an Expression of Interest for a long-baseline experiment (LBNO) has been submitted to the CERN SPSC. LBNO considers three types of neutrino detector technologies: a double-phase liquid argon (LAr) TPC and a magnetised iron detector as far detectors. For the near detector, a high-pressure gas TPC embedded in a calorimeter and a magnet is the baseline design. A mandatory milestone is a concrete prototyping effort towards the envisioned large-scale detectors, and an accompanying campaign of measurements aimed at assessing the detector associated systematic errors. The proposed $6\times 6\times 6$m$^3$ DLAr is an industrial prototype of the design discussed in the EoI and scalable to 20 kton or 50~kton. It is to be constructed and operated in a controlled laboratory and surface environment with test beam access, such as the CERN North Area (NA). Its successful operation and full characterisation will be a fundamental milestone, likely opening the path to an underground deployment of larger detectors. The response of the DLAr demonstrator will be measured and understood with an unprecedented precision in a charged particle test beam (0.5-20 GeV/c). The exposure will certify the assumptions and calibrate the response of the detector, and allow to develop and to benchmark sophisticated reconstruction algorithms, such as those of 3-dimensional tracking, particle ID and energy flow in liquid argon. All these steps are fundamental for validating the correctness of the physics performance described in the LBNO EoI., Comment: 217 pages, 164 figures, LBNO-DEMO (CERN WA105) Collaboration

Published

2015

24. Baby MIND: A Magnetised Spectrometer for the WAGASCI Experiment

Author

Antonova, M., Asfandiyarov, R., Bayes, R., Benoit, P., Blondel, A., Bogomilov, M., Bross, A., Cadoux, F., Cervera, A., Chikuma, N., Dudarev, A., Ekelöf, T., Favre, Y., Fedotov, S., Hallsjö, S-P, Izmaylov, A., Karadzhov, Y., Khabibullin, M., Khotyantsev, A., Kleymenova, A., Koga, T., Kostin, A., Kudenko, Y., Likhacheva, V., Martinez, B., Matev, R., Medvedeva, M., Mefodiev, A., Minamino, A., Mineev, O., Nessi, M., Nicola, L., Noah, E., Ovsiannikova, T., Pais Da Silva, H., Parsa, S., Rayner, M., Rolando, G., Shaykhiev, A., Simion, P., Soler, F. J. P., Suvorov, S., Roumen Tsenov, Ten Kate, H., Vankova-Kirilova, G., and Yershov, N.

Subjects

Physics - Instrumentation and Detectors, Physics::Instrumentation and Detectors, hep-ex, Astrophysics::High Energy Astrophysical Phenomena, High Energy Physics::Phenomenology, FOS: Physical sciences, Instrumentation and Detectors (physics.ins-det), High Energy Physics - Experiment, High Energy Physics - Experiment (hep-ex), High Energy Physics::Experiment, Detectors and Experimental Techniques, Large scale cryogenic liquid detectors [8], physics.ins-det, Particle Physics - Experiment

Abstract

The WAGASCI experiment being built at the J-PARC neutrino beam line will measure the difference in cross sections from neutrinos interacting with a water and scintillator targets, in order to constrain neutrino cross sections, essential for the T2K neutrino oscillation measurements. A prototype Magnetised Iron Neutrino Detector (MIND), called Baby MIND, is being constructed at CERN to act as a magnetic spectrometer behind the main WAGASCI target to be able to measure the charge and momentum of the outgoing muon from neutrino charged current interactions., Comment: Poster presented at NuPhys2016 (London, 12-14 December 2016). Title + 4 pages, LaTeX, 6 figures

25. Electron-muon ranger: performance in the MICE muon beam

Author

D. Adams, A. Alekou, M. Apollonio, R. Asfandiyarov, G. Barber, P. Barclay, A. de Bari, R. Bayes, V. Bayliss, P. Bene, R. Bertoni, V.J. Blackmore, A. Blondel, S. Blot, M. Bogomilov, M. Bonesini, C.N. Booth, D. Bowring, S. Boyd, T.W. Bradshaw, U. Bravar, A.D. Bross, F. Cadoux, M. Capponi, T. Carlisle, G. Cecchet, C. Charnley, F. Chignoli, D. Cline, J.H. Cobb, G. Colling, N. Collomb, L. Coney, P. Cooke, M. Courthold, L.M. Cremaldi, S. Debieux, A. DeMello, A. Dick, A. Dobbs, P. Dornan, F. Drielsma, F. Filthaut, T. Fitzpatrick, P. Franchini, V. Francis, L. Fry, A. Gallagher, R. Gamet, R. Gardener, S. Gourlay, A. Grant, J.S. Graulich, J. Greis, S. Griffiths, P. Hanlet, O.M. Hansen, G.G. Hanson, T.L. Hart, T. Hartnett, T. Hayler, C. Heidt, M. Hills, P. Hodgson, C. Hunt, C. Husi, A. Iaciofano, S. Ishimoto, G. Kafka, D.M. Kaplan, Y. Karadzhov, Y.K. Kim, Y. Kuno, P. Kyberd, J.-B. Lagrange, J. Langlands, W. Lau, M. Leonova, D. Li, A. Lintern, M. Littlefield, K. Long, T. Luo, C. Macwaters, B. Martlew, J. Martyniak, F. Masciocchi, R. Mazza, S. Middleton, A. Moretti, A. Moss, A. Muir, I. Mullacrane, J.J. Nebrensky, D. Neuffer, A. Nichols, R. Nicholson, L. Nicola, E. Noah Messomo, J.C. Nugent, A. Oates, Y. Onel, D. Orestano, E. Overton, P. Owens, V. Palladino, J. Pasternak, F. Pastore, C. Pidcott, M. Popovic, R. Preece, S. Prestemon, D. Rajaram, S. Ramberger, M.A. Rayner, S. Ricciardi, T.J. Roberts, M. Robinson, C. Rogers, K. Ronald, K. Rothenfusser, P. Rubinov, P. Rucinski, H. Sakamato, D.A. Sanders, R. Sandström, E. Santos, T. Savidge, P.J. Smith, P. Snopok, F.J.P. Soler, D. Speirs, T. Stanley, G. Stokes, D.J. Summers, J. Tarrant, I. Taylor, L. Tortora, Y. Torun, R. Tsenov, C.D. Tunnell, M.A. Uchida, G. Vankova-Kirilova, S. Virostek, M. Vretenar, P. Warburton, S. Watson, C. White, C.G. Whyte, A. Wilson, H. Wisting, X. Yang, A. Young, M. Zisman, Science and Technology Facilities Council (STFC), Adams, D., Alekou, A., Apollonio, M., Asfandiyarov, R., Barber, G., Barclay, P., De Bari, A., Bayes, R., Bayliss, V., Bene, P., Bertoni, R., Blackmore, V. J., Blondel, A., Blot, S., Bogomilov, M., Bonesini, M., Booth, C. N., Bowring, D., Boyd, S., Bradshaw, T. W., Bravar, U., Bross, A. D., Cadoux, F., Capponi, M., Carlisle, T., Cecchet, G., Charnley, C., Chignoli, F., Cline, D., Cobb, J. H., Colling, G., Collomb, N., Coney, L., Cooke, P., Courthold, M., Cremaldi, L. M., Debieux, S., Demello, A., Dick, A., Dobbs, A., Dornan, P., Drielsma, F., Filthaut, F., Fitzpatrick, T., Franchini, P., Francis, V., Fry, L., Gallagher, A., Gamet, R., Gardener, R., Gourlay, S., Grant, A., Graulich, J. S., Greis, J., Griffiths, S., Hanlet, P., Hansen, O. M., Hanson, G. G., Hart, T. L., Hartnett, T., Hayler, T., Heidt, C., Hills, M., Hodgson, P., Hunt, C., Husi, C., Iaciofano, A., Ishimoto, S., Kafka, G., Kaplan, D. M., Karadzhov, Y., Kim, Y. K., Kuno, Y., Kyberd, P., Lagrange, J. -B., Langlands, J., Lau, W., Leonova, M., Li, D., Lintern, A., Littlefield, M., Long, K., Luo, T., Macwaters, C., Martlew, B., Martyniak, J., Masciocchi, F., Mazza, R., Middleton, S., Moretti, A., Moss, A., Muir, A., Mullacrane, I., Nebrensky, J. J., Neuffer, D., Nichols, A., Nicholson, R., Nicola, L., Messomo, E. N., Nugent, J. C., Oates, A., Onel, Y., Orestano, D., Overton, E., Owens, P., Palladino, V., Pasternak, J., Pastore, F., Pidcott, C., Popovic, M., Preece, R., Prestemon, S., Rajaram, D., Ramberger, S., Rayner, M. A., Ricciardi, S., Roberts, T. J., Robinson, M., Rogers, C., Ronald, K., Rothenfusser, K., Rubinov, P., Rucinski, P., Sakamato, H., Sanders, D. A., Sandstrom, R., Santos, E., Savidge, T., Smith, P. J., Snopok, P., Soler, F. J. P., Speirs, D., Stanley, T., Stokes, G., Summers, D. J., Tarrant, J., Taylor, I., Tortora, L., Torun, Y., Tsenov, R., Tunnell, C. D., Uchida, M. A., Vankova-Kirilova, G., Virostek, S., Vretenar, M., Warburton, P., Watson, S., White, C., Whyte, C. G., Wilson, A., Wisting, H., Yang, X., Young, A., Zisman, M., and Palladino, Vittorio

Subjects

Technology, Physics - Instrumentation and Detectors, Traverse, Physics::Instrumentation and Detectors, FOS: Physical sciences, Electron, Cooling channel, 01 natural sciences, High Energy Physics - Experiment, Nuclear physics, High Energy Physics - Experiment (hep-ex), Particle identification method, Particle identification methods, Calorimeters, DESIGN, Particle tracking detectors, 0103 physical sciences, Ionization cooling, Detectors and Experimental Techniques, Nuclear Experiment, 010306 general physics, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries), Instrumentation, Instruments & Instrumentation, QC, Mathematical Physics, Physics, Calorimeter, Range (particle radiation), Muon, Science & Technology, 010308 nuclear & particles physics, Detector, Instrumentation and Detectors (physics.ins-det), Nuclear & Particles Physics, Particle tracking detector, Experimental High Energy Physics, Physics::Accelerator Physics, High Energy Physics::Experiment, Performance of High Energy Physics Detectors, Beam (structure)

Abstract

The Muon Ionization Cooling Experiment (MICE) will perform a detailed study of ionization cooling to evaluate the feasibility of the technique. To carry out this program, MICE requires an efficient particle-identification (PID) system to identify muons. The Electron-Muon Ranger (EMR) is a fully-active tracking-calorimeter that forms part of the PID system and tags muons that traverse the cooling channel without decaying. The detector is capable of identifying electrons with an efficiency of 98.6%, providing a purity for the MICE beam that exceeds 99.8%. The EMR also proved to be a powerful tool for the reconstruction of muon momenta in the range 100-280 MeV/$c$., 22 pages, 19 figures

Published

2015