Accelerator Neutrinos

Measuring the electric dipole moment of the neutron: The cryoEDM experiment

Proceedings of Science EPS-HEP 2009 376

Authors:

CA Baker, SN Balashov, V Francis, K Green, MGD van der Grinten, PS Iaydjiev, SN Ivanov, A Khazov, MAH Tucker, DL Wark, A Davidson, JR Grozier, M Hardiman, PG Harris, JR Karamath, K Katsika, JM Pendlebury, SJM Peeters, DB Shiers, PN Smith, CM Townsley, I Wardell, C Clarke, S Henry, H Kraus, M McCann, P Geltenbort, H Yoshiki

Abstract:

The cryoEDM experiment at the Institut Laue-Langevin in Grenoble will measure the electric dipole moment (EDM) of the neutron with unparalleled precision. A neutron EDM arises due to CP violation. The cryoEDM experiment is sensitive to levels of CP violation predicted by many “beyond the standard model” theories and the result will therefore constrain or support these theories. The current limit to the neutron EDM stands at d_n<2.9x 10^-26 e cm as measured with a room temperature experiment. By operating in superfluid helium below 0.9 K and collecting high densities of ultra cold neutrons, the cryoEDM experiment will improve on the existing limit or measure an EDM. High precision magnetometry is essential to reduce the systematic errors in the cryoEDM experiment originating from changes in the magnetic environment. We present the cryoEDM apparatus and technologies.

Monte Carlo simulations of B(d)0 —\ensuremath> pi+ pi- from p p interactions at s**1/2 = 40-TeV

Authors:

OR Long, NS Lockyer, PT Keener, F Azfar, KT McDonald, JG Heinrich, LA Roberts

Optimisation of the scintillation light collection and uniformity for the SoLid experiment

Journal of Instrumentation IOP Publishing

Authors:

Y Abreu, Y Amhis, W Beaumont, M Bongrand, D Boursette, BC Castle, K Clark, B Coupé, D Cussans, A De Roeck, D Durand, M Fallot, L Ghys, L Giot, K Graves, B Guillon, D Henaff, B Hosseini, S Ihantola, S Jenzer, S Kalcheva, LN Kalousis, M Labare, G Lehaut, S Manley, L Manzanillas, J Mermans, I Michiels, C Moortgat, D Newbold, J Park, V Pestel, K Petridis, I Piñera, L Popescu, D Ryckbosch, N Ryder, D Saunders, M-H Schune, M Settimo, L Simard, A Vacheret, G Vandierendonck, S Van Dyck, P Van Mulders, N van Remortel, S Vercaemer, M Verstraeten, B Viaud, A Weber, F Yermia

Abstract:

This paper presents a comprehensive optimisation study to maximise the light collection efficiency of scintillating cube elements used in the SoLid detector. Very short baseline reactor experiments, like SoLid, look for active to sterile neutrino oscillation signatures in the anti-neutrino energy spectrum as a function of the distance to the core and energy. Performing a precise search requires high light yield of the scintillating elements and uniformity of the response in the detector volume. The SoLid experiment uses an innovative hybrid technology with two different scintillators: polyvinyltoluene scintillator cubes and $^6$LiF:ZnS(Ag) screens. A precision test bench based on a $^{207}$Bi calibration source has been developed to study improvements on the energy resolution and uniformity of the prompt scintillation signal of antineutrino interactions. A trigger system selecting the 1~MeV conversion electrons provides a Gaussian energy peak and allows for precise comparisons of the different detector configurations that were considered to improve the SoLid detector light collection. The light collection efficiency is influenced by the choice of wrapping material, the position of the $^6$LiF:ZnS(Ag) screen, the type of fibre, the number of optical fibres and the type of mirror at the end of the fibre. This study shows that large gains in light collection efficiency are possible compared to the SoLid SM1 prototype. The light yield for the SoLid detector is expected to be at least 52$\pm$2 photo-avalanches per MeV per cube, with a relative non-uniformity of 6 %, demonstrating that the required energy resolution of at least 14 % at 1 MeV can be achieved.

Optimised sensitivity to leptonic CP violation from spectral information: the LBNO case at 2300 km baseline

arXiv

Authors:

LAGUNA-LBNO Collaboration, SK Agarwalla, L Agostino, M Aittola, A Alekou, B Andrieu, F Antoniou, R Asfandiyarov, D Autiero, O Bésida, A Balik, P Ballett, I Bandac, D Banerjee, W Bartmann, F Bay, B Biskup, AM Blebea-Apostu, A Blondel, M Bogomilov, S Bolognesi, E Borriello, I Brancus, A Bravar, M Buizza-Avanzini, D Caiulo, M Calin, M Calviani, M Campanelli, C Cantini, G Cata-Danil, S Chakraborty, N Charitonidis, L Chaussard, D Chesneanu, F Chipesiu, P Crivelli, J Dawson, I De Bonis, Y Declais, P Del Amo Sanchez, A Delbart, S Di Luise, D Duchesneau, J Dumarchez, I Efthymiopoulos, A Eliseev, S Emery, T Enqvist, K Enqvist, L Epprecht, AN Erykalov, T Esanu, D Franco, M Friend, V Galymov, G Gavrilov, A Gendotti, C Giganti, S Gilardoni, B Goddard, CM Gomoiu, YA Gornushkin, P Gorodetzky, A Haesler, T Hasegawa, S Horikawa, K Huitu, A Izmaylov, A Jipa, K Kainulainen, Y Karadzhov, M Khabibullin, A Khotjantsev, AN Kopylov, A Korzenev, S Kosyanenko, D Kryn, Y Kudenko, P Kuusiniemi, I Lazanu, C Lazaridis, J-M Levy, K Loo, J Maalampi, RM Margineanu, J Marteau, C Martin-Mari, V Matveev, E Mazzucato, A Mefodiev, O Mineev, A Mirizzi, B Mitrica, S Murphy, T Nakadaira, S Narita, DA Nesterenko, K Nguyen, K Nikolics, E Noah, Yu Novikov, A Oprima, J Osborne, T Ovsyannikova, Y Papaphilippou, S Pascoli, T Patzak, M Pectu, E Pennacchio, L Periale, H Pessard, B Popov, M Ravonel, M Rayner, F Resnati, O Ristea, A Robert, A Rubbia, K Rummukainen, A Saftoiu, K Sakashita, F Sanchez-Galan, J Sarkamo, N Saviano, E Scantamburlo, F Sergiampietri, D Sgalaberna, E Shaposhnikova, M Slupecki, D Smargianaki, D Stanca, R Steerenberg, AR Sterian, P Sterian, S Stoica, C Strabel, J Suhonen, V Suvorov, G Toma, A Tonazzo, WH Trzaska, R Tsenov, K Tuominen, M Valram, G Vankova-Kirilova, F Vannucci, G Vasseur, F Velotti, P Velten, V Venturi, T Viant, S Vihonen, H Vincke, A Vorobyev, A Weber, S Wu, N Yershov, L Zambelli, M Zito

Abstract:

One of the main goals of the Long Baseline Neutrino Observatory (LBNO) is to study the $L/E$ behaviour (spectral information) of the electron neutrino and antineutrino appearance probabilities, in order to determine the unknown CP-violation phase $\delta_{CP}$ and discover CP-violation in the leptonic sector. The result is based on the measurement of the appearance probabilities in a broad range of energies, covering t he 1st and 2nd oscillation maxima, at a very long baseline of 2300 km. The sensitivity of the experiment can be maximised by optimising the energy spectra of the neutrino and anti-neutrino fluxes. Such an optimisation requires exploring an extended range of parameters describing in details the geometries and properties of the primary protons, hadron target and focusing elements in the neutrino beam line. In this paper we present a numerical solution that leads to an optimised energy spectra and study its impact on the sensitivity of LBNO to discover leptonic CP violation. In the optimised flux both 1st and 2nd oscillation maxima play an important role in the CP sensitivity. The studies also show that this configuration is less sensitive to systematic errors (e.g. on the total event rates) than an experiment which mainly relies on the neutrino-antineutrino asymmetry at the 1st maximum to determine the existence of CP-violation.

Placeholder for new paper