Your search keyword '"Giuliani F."' showing total 1,515 results

1. Implementation of an AI-based predictive structural health monitoring strategy for bonded insulated rail joints using digital twins under varied bolt conditions: Implementation of an AI-based predictive structural health monitoring strategy for bonded...

Author

Bianchi, G., Freddi, F., Giuliani, F., and La Placa, A.

Published

2025

2. Measurement of the Neutron Cross Section on Argon Between 95 and 720 MeV

Author

Martynenko, S., Bhandari, B., Bian, J., Bilton, K., Callahan, C., Chaves, J., Chen, H., Cline, D., Cooper, R. L., Danielson, D. L., Danielson, J., Dokania, N., Elliott, S., Fernandes, S., Gardiner, S., Garvey, G., Gehman, V., Giuliani, F., Glavin, S., Gold, M., Grant, C., Guardincerri, E., Haines, T., Higuera, A., Ji, J. Y., Kadel, R., Kamp, N., Karlin, A., Ketchum, W., Koerner, L. W., Lee, D., Lee, K., Liu, Q., Locke, S., Louis, W. C., Maricic, J., Martin, E., Martinez, M. J., Mauger, C., McGrew, C., Medina, J., Medina, P. J., Mills, A., Mills, G., Mirabal-Martinez, J., Olivier, A., Pantic, E., Philipbar, B., Pitcher, C., Radeka, V., Ramsey, J., Rielage, K., Rosen, M., Sanchez, A. R., Shin, J., Sinnis, G., Smy, M., Sondheim, W., Stancu, I., Sterbenz, C., Sun, Y., Svoboda, R., Taylor, C., Teymourian, A., Thorn, C., Tull, C. E., Tzanov, M., Van de Water, R. G., Walker, D., Walsh, N., Wang, H., Wang, Y., Yanagisawa, C., Yarritu, A., and Yoo, J.

Subjects

Nuclear Experiment, High Energy Physics - Experiment

Abstract

We report an extended measurement of the neutron cross section on argon in the energy range of 95-720 MeV. The measurement was obtained with a 4.3-hour exposure of the Mini-CAPTAIN detector to the WNR/LANSCE beam at LANL. Compared to an earlier analysis of the same data, this extended analysis includes a reassessment of systematic uncertainties, in particular related to unused wires in the upstream part of the detector. Using this information we doubled the fiducial volume in the experiment and increased the statistics by a factor of 2.4. We also shifted the analysis from energy bins to time-of-flight bins. This change reduced the overall considered energy range, but improved the understanding of the energy spectrum of incoming neutrons in each bin. Overall, the new measurements are extracted from a fit to the attenuation of the neutron flux in five time-of-flight regions: 140 ns - 180 ns, 120 ns - 140 ns, 112 ns - 120 ns, 104 ns - 112 ns, 96 ns - 104 ns. The final cross sections are given for the flux-averaged energy in each time-of-flight bin: $\sigma(146~\rm{MeV})=0.60^{+0.14}_{-0.14}\pm0.08$(syst) b, $\sigma(236~\rm{MeV})=0.72^{+0.10}_{-0.10}\pm0.04$(syst) b, $\sigma(319~\rm{MeV})=0.80^{+0.13}_{-0.12}\pm0.040$(syst) b, $\sigma(404~\rm{MeV})=0.74^{+0.14}_{-0.09}\pm0.04$(syst) b, $\sigma(543~\rm{MeV})=0.74^{+0.09}_{-0.09}\pm0.04$(syst) b., Comment: 15 pages, 7 tables, 11 figures. Prepared for submission to PRD

Published

2022

3. Void formation driven by plastic strain partitioning during creep deformation of WC-Co

Author

Weller, L., M'saoubi, R., Giuliani, F., Humphry-Baker, S., and Marquardt, K.

Published

2025

4. Hydrogen desorption kinetics of hafnium hydride powders

Author

Pollard, J.P., Dumain, A., Stratton, B., Irukuvarghula, S., Astbury, J., Middleburgh, S., Giuliani, F., and Humphry-Baker, S.

Published

2025

5. Status and development of the TOP-IMPLART Project

Author

Picardi, L., Ampollini, A., Anello, P., Balduzzi, M., Bazzano, G., Borgognoni, F., Cisbani, E., DAndrea, M., De Angelis, C., De Angelis, G., Della Monaca, S., Esposito, G., Ghio, F., Giuliani, F., Lucentini, M., Marino, C., Montereali, R. M., Nenzi, P., Notaro, C., Patrono, C., Placido, C., Piccinini, M., Ronsivalle, C., Santavenere, F., Spurio, A., Strigari, L., Surrenti, V., Tabocchini, A., Trinca, E., and Vadrucci, M.

Subjects

Physics - Medical Physics, Physics - Applied Physics

Abstract

The TOP-IMPLART project consists of the design and implementation of a linear proton accelerator, its control and monitoring systems for the treatment of superficial and semi-deep tumors. The energy of 150 MeV (corresponding to a penetration in tissue of about 15 cm) is a milestone in design being useful for the proton therapy treatment of almost 50% of tumors based on their position and depth (including ocular melanoma, head-neck tumors, pediatric tumors, and more superficial tumors). The capability to vary the intensity on a pulse-to-pulse basis combined with an electronic feedback system allows to get the required dose uniformity (2.5%) reducing the number of re-paintings. In this paper the state of the art and the objectives of the TOP-IMPLART project are described within the framework of the progress of Protontherapy.

Published

2020

6. The Mini-CAPTAIN Liquid Argon Time Projection Chamber

Author

CAPTAIN Collaboration, Taylor, C. E., Bhandari, B., Bian, J., Bilton, K., Callahan, C., Chaves, J., Chen, H., Cline, D., Cooper, R. L., Danielson, D. L., Danielson, J., Dokania, N., Elliot, S., Fernandes, S., Gardiner, S., Garvey, G., Gehman, V., Giuliani, F., Glavin, S., Gold, M., Grant, C., Guardincerri, E., Haines, T., Higuera, A., Ji, J. Y., Kadel, R., Kamp, N., Karlin, A., Ketchum, W., Koerner, L. W., Lee, D., Lee, K., Liu, Q., Locke, S., Louis, W. C., Madigan, P., Manalaysay, A., Maricic, J., Martin, E., Martinez, M. J., Martynenko, S., Mauger, C., McGrew, C., Medina, J., Medina, P. J., Mills, G., Mirabal-Martinez, J., Olivier, A., Pantic, E., Philipbar, B., Pitcher, C., Radeka, V., Ramsey, J., Rielage, K., Rosen, M., Sanchez, A. R., Shin, J., Sinnis, G., Smy, M., Sondheim, W., Stancu, I., Sterbenz, C., Sun, Y., Svoboda, R., Teymourian, A., Thorn, C., Tull, C. E., Tzanov, M., Van de Water, R., Walsh, N., Wang, H., Wang, Y., Yanagisawa, C., Yarritu, A., and Yoo, J.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

This manuscript describes the commissioning of the Mini-CAPTAIN liquid argon detector in a neutron beam at the Los Alamos Neutron Science Center (LANSCE), which led to a first measurement of high-energy neutron interactions in argon. The Mini-CAPTAIN detector consists of a Time Projection Chamber (TPC) with an accompanying photomultiplier tube (PMT) array sealed inside a liquid-argon-filled cryostat. The liquid argon is constantly purified and recirculated in a closed-loop cycle during operation. The specifications and assembly of the detector subsystems and an overview of their performance in a neutron beam are reported., Comment: 21 pages, 27 figures

Published

2020

7. Optimization of the JUNO liquid scintillator composition using a Daya Bay antineutrino detector

Author

Bay, Daya, collaborations, JUNO, Abusleme, A., Adam, T., Ahmad, S., Aiello, S., Akram, M., Ali, N., An, F. P., An, G. P., An, Q., Andronico, G., Anfimov, N., Antonelli, V., Antoshkina, T., Asavapibhop, B., de André, J. P. A. M., Babic, A., Balantekin, A. B., Baldini, W., Baldoncini, M., Band, H. R., Barresi, A., Baussan, E., Bellato, M., Bernieri, E., Biare, D., Birkenfeld, T., Bishai, M., Blin, S., Blum, D., Blyth, S., Bordereau, C., Brigatti, A., Brugnera, R., Budano, A., Burgbacher, P., Buscemi, M., Bussino, S., Busto, J., Butorov, I., Cabrera, A., Cai, H., Cai, X., Cai, Y. K., Cai, Z. Y., Cammi, A., Campeny, A., Cao, C. Y., Cao, G. F., Cao, J., Caruso, R., Cerna, C., Chakaberia, I., Chang, J. F., Chang, Y., Chen, H. S., Chen, P. A., Chen, P. P., Chen, S. M., Chen, S. J., Chen, X. R., Chen, Y. W., Chen, Y. X., Chen, Y., Chen, Z., Cheng, J., Cheng, Y. P., Cheng, Z. K., Chepurnov, A., Cherwinka, J. J., Chiarello, F., Chiesa, D., Chimenti, P., Chu, M. C., Chukanov, A., Chuvashova, A., Clementi, ., Clerbaux, B., Di Lorenzo, S. Conforti, Corti, D., Costa, S., Corso, F. D., Cummings, J. P., Dalager, O., De La Taille, C., Deng, F. S., Deng, J. W., Deng, Z., Deng, Z. Y., Depnering, W., Diaz, M., Ding, X. F., Ding, Y. Y., Dirgantara, B., Dmitrievsky, S., Diwan, M. V., Dohnal, T., Donchenko, G., Dong, J. M., Dornic, D., Doroshkevich, E., Dove, J., Dracos, M., Druillole, F., Du, S. X., Dusini, S., Dvorak, M., Dwyer, D. A., Enqvist, T., Enzmann, H., Fabbri, A., Fajt, L., Fan, D. H., Fan, L., Fang, C., Fang, J., Fatkina, A., Fedoseev, D., Fekete, V., Feng, L. C., Feng, Q. C., Fiorentini, G., Ford, R., Formozov, A., Fournier, A., Franke, S., Gallo, J. P., Gan, H. N., Gao, F., Garfagnini, A., Göttel, A., Genster, C., Giammarchi, M., Giaz, A., Giudice, N., Giuliani, F., Gonchar, M., Gong, G. H., Gong, H., Gorchakov, O., Gornushkin, Y., Grassi, M., Grewing, C., Gromov, M., Gromov, V., Gu, M. H., Gu, W. Q., Gu, X. F., Gu, Y., Guan, M. Y., Guardone, N., Gul, M., Guo, C., Guo, J. Y., Guo, L., Guo, W. L., Guo, X. H., Guo, Y. H., Guo, Z., Haacke, M., Hackenburg, R. W., Hackspacher, P., Hagner, C., Han, R., Han, Y., Hans, S., He, M., He, W., Heeger, K. M., Heinz, T., Heng, Y. K., Herrera, R., Higuera, A., Hong, D. J., Hor, Y. K., Hou, S. J., Hsiung, Y. B., Hu, B. Z., Hu, H., Hu, J. R., Hu, J., Hu, S. Y., Hu, T., Hu, Z. J., Huang, C. H., Huang, G. H., Huang, H. X., Huang, Q. H., Huang, W. H., Huang, X. T., Huang, Y. B., Huber, P., Hui, J. Q., Huo, L., Huo, W. J., Huss, C., Hussain, S., Insolia, A., Ioannisian, A., Ioannisyan, D., Isocrate, R., Jaffe, D. E., Jen, K. L., Ji, X. L., Ji, X. P., Ji, X. Z., Jia, H. H., Jia, J. J., Jian, S. Y., Jiang, D., Jiang, X. S., Jin, R. Y., Jing, X. P., Johnson, R. A., Jollet, C., Jones, D., Joutsenvaara, J., Jungthawan, S., Kalousis, L., Kampmann, P., Kang, L., Karagounis, M., Kazarian, N., Kettell, S. H., Khan, A., Khan, W., Khosonthongkee, K., Kinz, P., Kohn, S., Korablev, D., Kouzakov, K., Kramer, M., Krasnoperov, A., Krokhaleva, S., Krumshteyn, Z., Kruth, A., Kutovskiy, N., Kuusiniemi, P., Lachacinski, B., Lachenmaier, T., Langford, T. J., Lee, J., Lee, J. H. C., Lefevre, F., Lei, L., Lei, R., Leitner, R., Leung, J., Li, C., Li, D. M., Li, F., Li, H. T., Li, H. L., Li, J., Li, J. J., Li, J. Q., Li, K. J., Li, M. Z., Li, N., Li, Q. J., Li, R. H., Li, S. C., Li, S. F., Li, S. J., Li, T., Li, W. D., Li, W. G., Li, X. M., Li, X. N., Li, X. L., Li, X. Q., Li, Y., Li, Y. F., Li, Z. B., Li, Z. Y., Liang, H., Liang, J. J., Liebau, D., Limphirat, A., Limpijumnong, S., Lin, C. J., Lin, G. L., Lin, S. X., Lin, T., Lin, Y. H., Ling, J. J., Link, J. M., Lippi, I., Littenberg, L., Littlejohn, B. R., Liu, F., Liu, H., Liu, H. B., Liu, H. D., Liu, H. J., Liu, H. T., Liu, J. C., Liu, J. L., Liu, M., Liu, Q., Liu, R. X., Liu, S. Y., Liu, S. B., Liu, S. L., Liu, X. W., Liu, Y., Lokhov, A., Lombardi, P., Loo, K., Lorenz, S., Lu, C., Lu, H. Q., Lu, J. B., Lu, J. G., Lu, S. X., Lu, X. X., Lubsandorzhiev, B., Lubsandorzhiev, S., Ludhova, L., Luk, K. B., Luo, F. J., Luo, G., Luo, P. W., Luo, S., Luo, W. M., Lyashuk, V., Ma, Q. M., Ma, S., Ma, X. B., Ma, X. Y., Ma, Y. Q., Malyshkin, Y., Mantovani, F., Mao, Y. J., Mari, S. M., Marini, F., Marium, S., Marshall, C., Martellini, C., Martin-Chassard, G., Caicedo, D. A. Martinez, Martini, A., Martino, J., Mayilyan, D., McDonald, K. T., McKeown, R. D., Müller, A., Meng, G., Meng, Y., Meregaglia, A., Meroni, E., Meyhöfer, D., Mezzetto, M., Miller, J., Miramonti, L., Monforte, S., Montini, P., Montuschi, M., Morozov, N., Muralidharan, P., Napolitano, J., Nastasi, M., Naumov, D. V., Naumova, E., Nemchenok, I., Nikolaev, A., Ning, F. P., Ning, Z., Nunokawa, H., Oberauer, L., Ochoa-Ricoux, J. P., Olshevskiy, A., Ortica, F., Pan, H. R., Paoloni, A., Park, J., Parkalian, N., Parmeggiano, S., Patton, S., Payupol, T., Pec, V., Pedretti, D., Pei, Y. T., Pelliccia, N., Peng, A. G., Peng, H. P., Peng, J. C., Perrot, F., Petitjean, P. A., Rico, L. F. Pineres, Popov, A., Poussot, P., Pratumwan, W., Previtali, E., Pun, C. S. J., Qi, F. Z., Qi, M., Qian, S., Qian, X., Qian, X. H., Qiao, H., Qin, Z. H., Qiu, S. K., Rajput, M., Ranucci, G., Raper, N., Re, A., Rebber, H., Rebii, A., Ren, B., Ren, J., Reveco, C. M., Rezinko, T., Ricci, B., Robens, M., Roche, M., Rodphai, N., Rohwer, L., Romani, A., Rosero, R., Roskovec, B., Roth, C., Ruan, X. C., Ruan, X. D., Rujirawat, S., Rybnikov, A., Sadovsky, A., Saggese, P., Salamanna, G., Sangka, A., Sanguansak, N., Sawangwit, U., Sawatzki, J., Sawy, F., Schever, M., Schuler, J., Schwab, C., Schweizer, K., Selivanov, D., Selyunin, A., Serafini, A., Settanta, G., Settimo, M., Shahzad, M., Shi, G., Shi, J. Y., Shi, Y. J., Shutov, V., Sidorenkov, A., Simkovic, F., Sirignano, C., Siripak, J., Sisti, M., Slupecki, M., Smirnov, M., Smirnov, O., Sogo-Bezerra, T., Songwadhana, J., Soonthornthum, B., Sotnikov, A., Sramek, O., Sreethawong, W., Stahl, A., Stanco, L., Stankevich, K., Stefanik, D., Steiger, H., Steiner, H., Steinmann, J., Stender, M., Strati, V., Studenikin, A., Sun, G. X., Sun, L. T., Sun, J. L., Sun, S. F., Sun, X. L., Sun, Y. J., Sun, Y. Z., Suwonjandee, N., Szelezniak, M., Tang, J., Tang, Q., Tang, X., Tietzsch, A., Tkachev, I., Tmej, T., Treskov, K., Troni, G., Trzaska, W., Tse, W. -H., Tull, C. E., Tuve, C., van Waasen, S., Boom, J. Vanden, Vassilopoulos, N., Vedin, V., Verde, G., Vialkov, M., Viaud, B., Viren, B., Volpe, C., Vorobel, V., Votano, L., Walker, P., Wang, C., Wang, C. H., Wang, E., Wang, G. L., Wang, J., Wang, K. Y., Wang, L., Wang, M. F., Wang, M., Wang, N. Y., Wang, R. G., Wang, S. G., Wang, W., Wang, W. S., Wang, X., Wang, X. Y., Wang, Y., Wang, Y. F., Wang, Y. G., Wang, Y. M., Wang, Y. Q., Wang, Z., Wang, Z. M., Wang, Z. Y., Watcharangkool, A., Wei, H. Y., Wei, L. H., Wei, W., Wei, Y. D., Wen, L. J., Whisnant, K., White, C. G., Wiebusch, C., Wong, S. C. F., Wong, H. L. H., Wonsak, B., Worcester, E., Wu, C. H., Wu, D. R., Wu, F. L., Wu, Q., Wu, W. J., Wu, Z., Wurm, M., Wurtz, J., Wysotzki, C., Xi, Y. F., Xia, D. M., Xie, Y. G., Xie, Z. Q., Xing, Z. Z., Xu, D. L., Xu, F. R., Xu, H. K., Xu, J. L., Xu, J., Xu, M. H., Xu, T., Xu, Y., Xue, T., Yan, B. J., Yan, X. B., Yan, Y. P., Yang, A. B., Yang, C. G., Yang, H., Yang, J., Yang, L., Yang, X. Y., Yang, Y. F., Yang, Y. Z., Yao, H. F., Yasin, Z., Ye, J. X., Ye, M., Yegin, U., Yeh, M., Yermia, F., Yi, P. H., You, Z. Y., Young, B. L., Yu, B. X., Yu, C. X., Yu, C. Y., Yu, H. Z., Yu, M., Yu, X. H., Yu, Z. Y., Yuan, C. Z., Yuan, Y., Yuan, Z. X., Yuan, Z. Y., Yue, B. B., Zafar, N., Zambanini, A., Zeng, P., Zeng, S., Zeng, T. X., Zeng, Y. D., Zhan, L., Zhang, C., Zhang, F. Y., Zhang, G. Q., Zhang, H. H., Zhang, H. Q., Zhang, J., Zhang, J. B., Zhang, J. W., Zhang, P., Zhang, Q. M., Zhang, T., Zhang, X. M., Zhang, X. T., Zhang, Y., Zhang, Y. H., Zhang, Y. M., Zhang, Y. P., Zhang, Y. X., Zhang, Y. Y., Zhang, Z. J., Zhang, Z. P., Zhang, Z. Y., Zhao, F. Y., Zhao, J., Zhao, R., Zhao, S. J., Zhao, T. C., Zheng, D. Q., Zheng, H., Zheng, M. S., Zheng, Y. H., Zhong, W. R., Zhou, J., Zhou, L., Zhou, N., Zhou, S., Zhou, X., Zhu, J., Zhu, K. J., Zhuang, H. L., Zong, L., and Zou, J. H.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

To maximize the light yield of the liquid scintillator (LS) for the Jiangmen Underground Neutrino Observatory (JUNO), a 20 t LS sample was produced in a pilot plant at Daya Bay. The optical properties of the new LS in various compositions were studied by replacing the gadolinium-loaded LS in one antineutrino detector. The concentrations of the fluor, PPO, and the wavelength shifter, bis-MSB, were increased in 12 steps from 0.5 g/L and <0.01 mg/L to 4 g/L and 13 mg/L, respectively. The numbers of total detected photoelectrons suggest that, with the optically purified solvent, the bis-MSB concentration does not need to be more than 4 mg/L. To bridge the one order of magnitude in the detector size difference between Daya Bay and JUNO, the Daya Bay data were used to tune the parameters of a newly developed optical model. Then, the model and tuned parameters were used in the JUNO simulation. This enabled to determine the optimal composition for the JUNO LS: purified solvent LAB with 2.5 g/L PPO, and 1 to 4 mg/L bis-MSB., Comment: 13 pages, 8 figures

Published

2020

8. The Mini-CAPTAIN liquid argon time projection chamber

Author

Taylor, CE, Bhandari, B, Bian, J, Bilton, K, Callahan, C, Chaves, J, Chen, H, Cline, D, Cooper, RL, Danielson, DL, Danielson, J, Dokania, N, Elliot, S, Fernandes, S, Gardiner, S, Garvey, G, Gehman, V, Giuliani, F, Glavin, S, Gold, M, Grant, C, Guardincerri, E, Haines, T, Higuera, A, Ji, JY, Kadel, R, Kamp, N, Karlin, A, Ketchum, W, Koerner, LW, Lee, D, Lee, K, Liu, Q, Locke, S, Louis, WC, Madigan, P, Manalaysay, A, Maricic, J, Martin, E, Martinez, MJ, Martynenko, S, Mauger, C, McGrew, C, Medina, J, Medina, PJ, Mills, A, Mills, G, Mirabal-Martinez, J, Olivier, A, Pantic, E, Philipbar, B, Pitcher, C, Radeka, V, Ramsey, J, Rielage, K, Rosen, M, Sanchez, AR, Shin, J, Sinnis, G, Smy, M, Sondheim, W, Stancu, I, Sterbenz, C, Sun, Y, Svoboda, R, Teymourian, A, Thorn, C, Tull, CE, Tzanov, M, Van de Water, R, Walsh, N, Wang, H, Wang, Y, Yanagisawa, C, Yarritu, A, and Yoo, J

Subjects

Liquid argon detector, Time projection chamber, Neutron measurement, Photon detection system, physics.ins-det, hep-ex, Nuclear & Particles Physics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences

Abstract

This manuscript describes the commissioning of the Mini-CAPTAIN liquid argon detector in a neutron beam at the Los Alamos Neutron Science Center (LANSCE), which led to a first measurement of high-energy neutron interactions in argon. The Mini-CAPTAIN detector consists of a Time Projection Chamber (TPC) with an accompanying photomultiplier tube (PMT) array sealed inside a liquid-argon-filled cryostat. The liquid argon is constantly purified and recirculated in a closed-loop cycle during operation. The specifications and assembly of the detector subsystems and an overview of their performance in a neutron beam are reported.

Published

2021

9. Limited Angle Tomography reconstruction for non-standard MBI system by means of parallel-hole and pinhole optics

Author

Poma, G. E., Garibaldi, F., Giuliani, F., Insero, T., Lucentini, M., Marcucci, A., Musico, P., Nuyts, J., Santavenere, F., Schramm, G., Sutera, C., and Cisbani, E.

Subjects

Physics - Medical Physics, Physics - Data Analysis, Statistics and Probability

Abstract

The purpose of the present work is the study of reconstruction properties of a new Molecular Breast Imaging (MBI) device for the early diagnosis of breast cancer, in Limited Angle Tomography (LAT), by using two asymmetric detector heads with different collimators. The detectors face each other in anti-parallel viewing direction and, mild-compressing the breast phantom, they are able to reconstruct the inner tumour of the phantoms with only a limited number of projections using a dedicated maximum-likelihood expectation maximization (ML-EM) algorithm. Phantoms, MBI system, as well as Monte Carlo simulator using Geant 4 Application for Tomographic Emission (GATE) software, are briefly described. MBI system's model has been implemented in IDL (Interactive Data Visualization), in order to evaluate the best LAT configuration of the system and its reconstruction ability by varying tumour's size, depth and uptake. LAT setup in real and simulated configurations, as well as the ML-EM method and the preliminary reconstruction results, are discussed., Comment: 10 pages, 10 figures, proceeding conference

Published

2020

10. Development of a high-resolution and high efficiency Single Photon detector for studying cardiovascular diseases in mice

Author

Garibaldi, F., Cisbani, E., Cusanno, F., De Vincentis, G., Giuliani, F., Lucentini, M., Magliozzi, M. L., Majewski, S., Marano, G., Musico, P., Santanvenere, F., Tsui, B. M. W., and Wang, Y.

Subjects

Physics - Medical Physics, Physics - Instrumentation and Detectors

Abstract

SPECT systems using pinhole apertures permit radiolabeled molecular distributions to be imaged in vivo in small animals. Nevertheless studying cardiovascular diseases by means of small animal models is very challenging. Specifically, submillimeter spatial resolution, good energy resolution and high sensitivity are required. We designed what we consider the "optimal" radionuclide detector system for this task. It should allow studying both detection of unstable atherosclerotic plaques and monitoring the effect of therapies. Using mice is particularly challenging in situations that require several intravenous injections of radiotracers, possibly for week or even months, in chronically ill animals. Thus, alternative routes of delivering the radiotracer in tail vein should be investigated. In this study we have performed preliminary measurements of detection of atherosclerotic plaques in genetically modified mice with high-resolution prototype detector. We have also evaluated the feasibility of assessing left ventricular perfusion by intraperitoneal delivering of MIBI-Tc in healthy mice., Comment: 6 pages, 8 figures

Published

2019

11. First Measurement of the Total Neutron Cross Section on Argon Between 100 and 800 MeV

Author

Bhandari, B., Bian, J., Bilton, K., Callahan, C., Chaves, J., Chen, H., Cline, D., Cooper, R. L., Danielson, D., Danielson, J., Dokania, N., Elliott, S., Fernandes, S., Gardiner, S., Garvey, G., Gehman, V., Giuliani, F., Glavin, S., Gold, M., Grant, C., Guardincerri, E., Haines, T., Higuera, A., Ji, J. Y., Kadel, R., Kamp, N., Karlin, A., Ketchum, W., Koerner, L. W., Lee, D., Lee, K., Liu, Q., Locke, S., Louis, W. C., Manalaysay, A., Maricic, J., Martin, E., Martinez, M. J., Martynenko, S., Mauger, C., McGrew, C., Medina, J., Medina, P. J., Mills, A., Mills, G., Mirabal-Martinez, J., Olivier, A., Pantic, E., Philipbar, B., Pitcher, C., Radeka, V., Ramsey, J., Rielage, K., Rosen, M., Sanchez, A. R., Shin, J., Sinnis, G., Smy, M., Sondheim, W., Stancu, I., Sterbenz, C., Sun, Y., Svoboda, R., Taylor, C., Teymourian, A., Thorn, C., Tull, C. E., Tzanov, M., Van de Water, R. G., Walker, D., Walsh, N., Wang, H., Wang, Y., Yanagisawa, C., Yarritu, A., and Yoo, J.

Subjects

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

Abstract

We report the first measurement of the neutron cross section on argon in the energy range of 100-800 MeV. The measurement was obtained with a 4.3-hour exposure of the Mini-CAPTAIN detector to the WNR/LANSCE beam at LANL. The total cross section is measured from the attenuation coefficient of the neutron flux as it traverses the liquid argon volume. A set of 2,631 candidate interactions is divided in bins of the neutron kinetic energy calculated from time-of-flight measurements. These interactions are reconstructed with custom-made algorithms specifically designed for the data in a time projection chamber the size of the Mini-CAPTAIN detector. The energy averaged cross section is $0.91 \pm{} 0.10~\mathrm{(stat.)} \pm{} 0.09~\mathrm{(sys.)}~\mathrm{barns}$. A comparison of the measured cross section is made to the GEANT4 and FLUKA event generator packages., Comment: 5 pages, 1 table, 3 figures, submitted to Physical Review Letters

Published

2019

12. Topological background discrimination in the PandaX-III neutrinoless double beta decay experiment

Author

Galan, J, Chen, X, Du, H, Fu, C, Giboni, K, Giuliani, F, Han, K, Jiang, B, Ji, X, Lin, H, Lin, Y, Liu, J, Ni, K, Ren, X, Wang, S, Wu, S, Xie, C, Yang, Y, Zhang, D, Zhang, T, Zhao, L, Aune, S, Bedfer, Y, Berthoumieux, E, Calvet, D, d'Hose, N, Ferrer-Ribas, E, Kunne, F, Manier, B, Neyret, D, Papaevangelou, T, Chen, L, Hu, S, Jian, S, Li, P, Li, X, Zhang, H, Zhao, M, Zhou, J, Mao, Y, Qiao, H, Yuan, Y, Wang, M, Chen, Y, Khan, A N, Raper, N, Tang, J, Wang, W, Feng, C, Li, C, Liu, S, Wang, X, Zhu, D, Castel, J F, Cebrián, S, Dafni, T, Irastorza, I G, Luzón, G, Mirallas, H, Sun, X, Tan, A, Haxton, W, Mei, Y, Kobdaj, C, and Yan, Y

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The PandaX-III experiment plans to search for neutrinoless double beta decay (0$\nu\beta\beta$) of $^{136}$Xe in the China JinPing underground Laboratory (CJPL). The experiment will use a high pressure gaseous Time Projection Chamber (TPC) to register both the energy and the electron track topology of an event. This article is devoted to the software side of the experiment. As software tool we use REST, a framework developed for the reconstruction and simulation of TPC-based detector systems. We study the potential for background reduction by introducing appropiate parameters based on the properties of 0$\nu\beta\beta$ events. We exploit for the first time not only the energy density of the electron track-ends, but also the electron scattering angles produced by an electron near the end of its trajectory. To implement this, we have added new algorithms for detector signal and track processing inside REST. Their assessment shows that background can be reduced by about 7 orders of magnitude while keeping 0$\nu\beta\beta$ efficiency above 20% for the PandaX-III baseline readout scheme, a 2-dimensional 3mm-pitch stripped readout. More generally, we use the potential of REST to handle 2D/3D data to assess the impact on signal-to-background significance at different detector granularities, and to validate the PandaX-III baseline choice. Finally, we demonstrate the potential to discriminate surface background events generated at the readout plane in the absence of $t_o$, by making use of event parameters related with the diffusion of electrons., Comment: 40 pages, 15 figures. Prepared for submission to Journal of Physics G

Published

2019

13. BIM approach for stone pavements in Archaeological Sites: The case study of Vicolo dei Balconi of Pompeii

Author

Biancardo, S.A., Intignano, M., Veropalumbo, R., Martinelli, R., Calvanese, V., Autelitano, F., Garilli, E., Giuliani, F., and Dell'Acqua, G.

Published

2023

14. High-resolution hypernuclear spectroscopy at Jefferson Lab, Hall A

Author

Jefferson Lab Hall A Collaboration, Garibaldi, F., Acha, A., Ambrozewicz, P., Aniol, K. A., Beturin, P., Benaoum, H., Benesch, J., Bertin, P. Y., Blomqvist, K. I., Boeglin, W. U., Breuer, H., Brindza, P., Bydzovsky, P., Camsonne, A., Chang, C. C., Chen, J. -P., Choi, Seonho, Chudakov, E. A., Cisbani, E., Colilli, S., Coman, L., Cusanno, F., Craver, B. J., De Cataldo, G., de Jager, C. W., De Leo, R., Deur, A. P., Ferdi, C., Feuerbach, R. J., Folts, E., Frullani, S., Gayou, O., Giuliani, F., Gomez, J., Gricia, M., Hansen, J. O., Hayes, D., Higinbotham, D. W., Holmstrom, T. K., Hyde, C. E., Ibrahim, H. F., Iodice, M., Jiang, X., Kaufman, L. J., Kino, K., Kross, B., Lagamba, L., LeRose, J. J., Lindgren, R. A., Lucentini, M., Margaziotis, D. J., Markowitz, P., Marrone, S., Meekins, D. G., Meziani, Z. E., McCormick, K., Michaels, R. W., Millener, D. J., Miyoshi, T., Moffit, B., Monaghan, P. A., Moteabbed, M., Camacho, C. Munoz, Nanda, S., Nappi, E., Nelyubin, V. V., Norum, B. E., Okasyasu, Y., Paschke, K. D., Perdrisat, C. F., Piasetzky, E., Punjabi, V. A., Qiang, Y., Raue, B., Reimer, P. E., Reinhold, J., Reitz, B., Roche, R. E., Rodriguez, V. M., Saha, A., Santavenere, F., Sarty, A. J., Segal, J., Shahinyan, A., Singh, J., Sirca, S., Snyder, R., Solvignon, P. H., Sotona, M., Subedi, R., Sulkosky, V. A., Suzuki, T., Ueno, H., Ulmer, P. E., Urciuoli, G. M., Voutier, E., Wojtsekhowski, B. B., Zheng, X., and Zorn, C.

Subjects

Nuclear Experiment, Nuclear Theory

Abstract

The experiment E94-107 in Hall A at Jefferson Lab started a systematic study of high resolution hypernuclear spectroscopy in the 0p-shell region of nuclei such as the hypernuclei produced in electroproduction on 9Be, 12C and 16O targets. In order to increase counting rates and provide unambiguous kaon identification two superconducting septum magnets and a ring-imaging Cherenkov detector were added to the Hall A standard equipment. The high-quality beam, the good spectrometers and the new experimental devices allowed us to obtain very good results. For the first time, measurable strength with sub-MeV energy resolution was observed for the core-excited states of Lambda 12B. A high-quality Lambda 16N hypernuclear spectrum was likewise obtained. A first measurement of the Lambda binding energy for Lambda 16N, calibrated against the elementary reaction on hydrogen, was obtained with high precision, 13.76 +/- 0.16 MeV. Similarly, the first Lambda 9Li hypernuclear spectrum shows general agreement with theory (distorted-wave impulse approximation with the SLA and BS3 electroproduction models and shell-model wave functions). Some disagreement exists with respect to the relative strength of the states making up the first multiplet. A Lambda separation energy of 8.36 MeV was obtained, in agreement with previous results. It has been shown that the electroproduction of hypernuclei can provide information complementary to that obtained with hadronic probes and the gamma-ray spectroscopy technique., Comment: 27 pages, 18 figures, submitted to Physical Review C

Published

2018

15. First Measurement of the Total Neutron Cross Section on Argon between 100 and 800 MeV

Author

Bhandari, B, Bian, J, Bilton, K, Callahan, C, Chaves, J, Chen, H, Cline, D, Cooper, RL, Danielson, D, Danielson, J, Dokania, N, Elliott, S, Fernandes, S, Gardiner, S, Garvey, G, Gehman, V, Giuliani, F, Glavin, S, Gold, M, Grant, C, Guardincerri, E, Haines, T, Higuera, A, Ji, JY, Kadel, R, Kamp, N, Karlin, A, Ketchum, W, Koerner, LW, Lee, D, Lee, K, Liu, Q, Locke, S, Louis, WC, Manalaysay, A, Maricic, J, Martin, E, Martinez, MJ, Martynenko, S, Mauger, C, McGrew, C, Medina, J, Medina, PJ, Mills, A, Mills, G, Mirabal-Martinez, J, Olivier, A, Pantic, E, Philipbar, B, Pitcher, C, Radeka, V, Ramsey, J, Rielage, K, Rosen, M, Sanchez, AR, Shin, J, Sinnis, G, Smy, M, Sondheim, W, Stancu, I, Sterbenz, C, Sun, Y, Svoboda, R, Taylor, C, Teymourian, A, Thorn, C, Tull, CE, Tzanov, M, Van de Water, RG, Walker, D, Walsh, N, Wang, H, Wang, Y, Yanagisawa, C, Yarritu, A, and Yoo, J

Subjects

Nuclear and Plasma Physics, Synchrotrons and Accelerators, Physical Sciences, Bioengineering, CAPTAIN Collaboration, hep-ex, nucl-ex, physics.ins-det, Mathematical Sciences, Engineering, General Physics, Mathematical sciences, Physical sciences

Abstract

We report the first measurement of the neutron cross section on argon in the energy range of 100-800 MeV. The measurement was obtained with a 4.3-h exposure of the Mini-CAPTAIN detector to the WNR/LANSCE beam at LANL. The total cross section is measured from the attenuation coefficient of the neutron flux as it traverses the liquid argon volume. A set of 2631 candidate interactions is divided in bins of the neutron kinetic energy calculated from time-of-flight measurements. These interactions are reconstructed with custom-made algorithms specifically designed for the data in a time projection chamber the size of the Mini-CAPTAIN detector. The energy averaged cross section is 0.91±0.10(stat)±0.09(syst)  b. A comparison of the measured cross section is made to the GEANT4 and FLUKA event generator packages, where the energy averaged cross sections in this range are 0.60 and 0.68 b, respectively.

Published

2019

16. PandaX-II constraints on spin-dependent WIMP-nucleon effective interactions

Author

Xia, J, Abdukerim, A, Chen, W, Chen, X, Chen, Y, Cui, X, Fang, D, Fu, C, Giboni, K, Giuliani, F, Gu, L, Guo, X, Guo, Z, Han, K, He, C, He, S, Huang, D, Huang, X, Huang, Z, Ji, P, Ji, X, Ju, Y, Li, S, Lin, H, Liu, H, Liu, J, Ma, Y, Mao, Y, Ni, K, Ning, J, Ren, X, Shi, F, Tan, A, Wang, A, Wang, C, Wang, H, Wang, M, Wang, Q, Wang, S, Wang, X, Wang, Z, Wu, M, Wu, S, Xiao, M, Xie, P, Yan, B, Yang, J, Yang, Y, Yu, C, Yuan, J, Yue, J, Zhang, D, Zhang, H, Zhang, T, Zhao, L, Zheng, Q, Zhou, J, Zhou, N, Zhou, X, and Haxton, WC

Subjects

PandaX-II experiment, WIMP dark matter, Spin-dependent effective interactions, hep-ex, hep-ph, Nuclear & Particles Physics, Mathematical Physics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

We present PandaX-II constraints on candidate WIMP-nucleon effective interactions involving the nucleon or WIMP spin, including, in addition to standard axial spin-dependent (SD) scattering, various couplings among vector and axial currents, magnetic and electric dipole moments, and tensor interactions. The data set corresponding to a total exposure of 54-ton-days is reanalyzed to determine constraints as a function of the WIMP mass and isospin coupling. We obtain WIMP-nucleon cross section bounds of 1.6×10 −41 cm 2 and 9.0×10 −42 cm 2 (90% c.l.) for neutron-only SD and tensor coupling, respectively, for a mass M WIMP ∼40GeV/c 2 . The SD limits are the best currently available for M WIMP >40GeV/c 2 . We show that PandaX-II has reached a sensitivity sufficient to probe a variety of other candidate spin-dependent interactions at the weak scale.

Published

2019

17. Temporary clogging effects induced by a sustainable anti-icing hydrogel on the hydraulic conductivity and inertia coefficient of open-graded asphalt pavements

Author

Autelitano, F., Petrolo, D., Chiapponi, L., Giuliani, F., and Longo, S.

Published

2022

18. A novel TOF-PET MRI detector for diagnosis and follow up of the prostate cancer

Author

Garibaldi, F., Beging, S., Canese, R., Carpinelli, G., Clinthorne, N., Colilli, S., Finocchiaro, L. Cosentino P., Giuliani, F., Gricia, M., Lucentini, M., Majewski, S., Monno, E., Musico, P., Santavenere, F., Tödter, J., Wegener, H., and Ziemons, K.

Subjects

Physics - Medical Physics

Abstract

Prostate cancer is the most common disease in men and the second leading cause of death from cancer. Generic large imaging instruments used in cancer diagnosis have sensitivity, spatial resolution, and contrast inadequate for the task of imaging details of a small organ such as the prostate. In addition, multimodality imaging can play a significant role merging anatomical and functional details coming from simultaneous PET and MRI. Indeed, multi-parametric PET/MRI was demonstrated to improve diagnosis, but it suffers from too many false positives. In order to address the above limits of the current techniques, we have proposed, built and tested, thanks to the TOPEM project funded by Italian National Institute of Nuclear Phisics a prototype of an endorectal PET-TOF/MRI probe. In the applied magnification PET geometry, performance is dominated by a high-resolution detector placed closer to the source. The expected spatial resolution in the selected geometry is about 1.5 mm FWHM and efficiency a factor of 2 with respect to what obtained with the conventional PET scanner. In our experimental studies, we have obtained timing resolution of ~ 320 ps FWHM and at the same time Depth of Interaction (DOI) resolution of under 1 mm. Tests also showed that mutual adverse PET-MR effects are minimal. In addition, the matching endorectal RF coil was designed, built and tested. In the next planned studies, we expect that benefiting from the further progress in scintillator crystal surface treatment, in SiPM technology and associated electronics would allow us to significantly improve TOF resolution

Published

2017

19. First Latin America report on the diagnostic utility of the study of the MYD88 L265P gene mutation in patients with Waldenström Macroglobulinemia

Author

Giuliani, F., Pavlovsky, M. A., Giere, I., Fernandez, I., Sackmann, F., Pavlovsky, A., Remaggi, G., and Castillo, J. J.

Published

2022

20. The construction of a street never opened to traffic. The extraordinary discovery of pavement engineering in vicolo dei Balconi of Pompeii

Author

Autelitano, F., Bruno, N., Martinelli, R., Calvanese, V., Garilli, E., Biancardo, S.A., Dell'Acqua, G., Veropalumbo, R., Zerbi, A., Roncella, R., and Giuliani, F.

Published

2022

21. Disability progression in multiple sclerosis is associated with plasma neuroactive steroid profile

Author

Cheng, C., Gomez, D., McCombe, J. A., Smyth, P., Giuliani, F., Blevins, G., Baker, G. B., and Power, C.

Published

2021

22. Advancement in measuring the hydraulic conductivity of porous asphalt pavements

Author

Giuliani, F., Petrolo, D., Chiapponi, L., Zanini, A., and Longo, S.

Published

2021

23. Optimization of the JUNO liquid scintillator composition using a Daya Bay antineutrino detector

Author

Abusleme, A., Adam, T., Ahmad, S., Aiello, S., Akram, M., Ali, N., An, F.P., An, G.P., An, Q., Andronico, G., Anfimov, N., Antonelli, V., Antoshkina, T., Asavapibhop, B., de André, J.P.A.M., Babic, A., Balantekin, A.B., Baldini, W., Baldoncini, M., Band, H.R., Barresi, A., Baussan, E., Bellato, M., Bernieri, E., Biare, D., Birkenfeld, T., Bishai, M., Blin, S., Blum, D., Blyth, S., Bordereau, C., Brigatti, A., Brugnera, R., Budano, A., Burgbacher, P., Buscemi, M., Bussino, S., Busto, J., Butorov, I., Cabrera, A., Cai, H., Cai, X., Cai, Y.K., Cai, Z.Y., Cammi, A., Campeny, A., Cao, C.Y., Cao, G.F., Cao, J., Caruso, R., Cerna, C., Chang, J.F., Chang, Y., Chen, H.S., Chen, P.A., Chen, P.P., Chen, S.M., Chen, S.J., Chen, X.R., Chen, Y.W., Chen, Y.X., Chen, Y., Chen, Z., Cheng, J., Cheng, Y.P., Cheng, Z.K., Chepurnov, A., Cherwinka, J.J., Chiarello, F., Chiesa, D., Chimenti, P., Chu, M.C., Chukanov, A., Chuvashova, A., Clementi, C., Clerbaux, B., Di Lorenzo, S. Conforti, Corti, D., Costa, S., Dal Corso, F., Cummings, J.P., Dalager, O., De La Taille, C., Deng, F.S., Deng, J.W., Deng, Z., Deng, Z.Y., Depnering, W., Diaz, M., Ding, X.F., Ding, Y.Y., Dirgantara, B., Dmitrievsky, S., Diwan, M.V., Dohnal, T., Donchenko, G., Dong, J.M., Dornic, D., Doroshkevich, E., Dove, J., Dracos, M., Druillole, F., Du, S.X., Dusini, S., Dvorak, M., Dwyer, D.A., Enqvist, T., Enzmann, H., Fabbri, A., Fajt, L., Fan, D.H., Fan, L., Fang, C., Fang, J., Fatkina, A., Fedoseev, D., Fekete, V., Feng, L.C., Feng, Q.C., Fiorentini, G., Ford, R., Formozov, A., Fournier, A., Franke, S., Gallo, J.P., Gan, H.N., Gao, F., Garfagnini, A., Göttel, A., Genster, C., Giammarchi, M., Giaz, A., Giudice, N., Giuliani, F., Gonchar, M., Gong, G.H., Gong, H., Gorchakov, O., Gornushkin, Y., Grassi, M., Grewing, C., Gromov, M., Gromov, V., Gu, M.H., Gu, W.Q., Gu, X.F., Gu, Y., Guan, M.Y., Guardone, N., Gul, M., Guo, C., Guo, J.Y., Guo, L., Guo, W.L., Guo, X.H., Guo, Y.H., Guo, Z., Haacke, M., Hackenburg, R.W., Hackspacher, P., Hagner, C., Han, R., Han, Y., Hans, S., He, M., He, W., Heeger, K.M., Heinz, T., Heng, Y.K., Herrera, R., Higuera, A., Hong, D.J., Hor, Y.K., Hou, S.J., Hsiung, Y.B., Hu, B.Z., Hu, H., Hu, J.R., Hu, J., Hu, S.Y., Hu, T., Hu, Z.J., Huang, C.H., Huang, G.H., Huang, H.X., Huang, Q.H., Huang, W.H., Huang, X.T., Huang, Y.B., Huber, P., Hui, J.Q., Huo, L., Huo, W.J., Huss, C., Hussain, S., Insolia, A., Ioannisian, A., Ioannisyan, D., Isocrate, R., Jaffe, D.E., Jen, K.L., Ji, X.L., Ji, X.P., Ji, X.Z., Jia, H.H., Jia, J.J., Jian, S.Y., Jiang, D., Jiang, X.S., Jin, R.Y., Jing, X.P., Johnson, R.A., Jollet, C., Jones, D., Joutsenvaara, J., Jungthawan, S., Kalousis, L., Kampmann, P., Kang, L., Karagounis, M., Kazarian, N., Kettell, S.H., Khan, A., Khan, W., Khosonthongkee, K., Kinz, P., Kohn, S., Korablev, D., Kouzakov, K., Kramer, M., Krasnoperov, A., Krokhaleva, S., Krumshteyn, Z., Kruth, A., Kutovskiy, N., Kuusiniemi, P., Lachacinski, B., Lachenmaier, T., Landini, C., Langford, T.J., Lee, J., Lee, J.H.C., Lefevre, F., Lei, L., Lei, R., Leitner, R., Leung, J., Li, D.M., Li, F., Li, H.T., Li, H.L., Li, J., Li, J.J., Li, J.Q., Li, K.J., Li, M.Z., Li, N., Li, Q.J., Li, R.H., Li, S.C., Li, S.F., Li, S.J., Li, T., Li, W.D., Li, W.G., Li, X.M., Li, X.N., Li, X.L., Li, X.Q., Li, Y., Li, Y.F., Li, Z.B., Li, Z.Y., Liang, H., Liang, J.J., Liebau, D., Limphirat, A., Limpijumnong, S., Lin, C.J., Lin, G.L., Lin, S.X., Lin, T., Lin, Y.H., Ling, J.J., Link, J.M., Lippi, I., Littenberg, L., Littlejohn, B.R., Liu, F., Liu, H., Liu, H.B., Liu, H.D., Liu, H.J., Liu, H.T., Liu, J.C., Liu, J.L., Liu, M., Liu, Q., Liu, R.X., Liu, S.Y., Liu, S.B., Liu, S.L., Liu, X.W., Liu, Y., Lokhov, A., Lombardi, P., Loo, K., Lorenz, S., Lu, C., Lu, H.Q., Lu, J.B., Lu, J.G., Lu, S.X., Lu, X.X., Lubsandorzhiev, B., Lubsandorzhiev, S., Ludhova, L., Luk, K.B., Luo, F.J., Luo, G., Luo, P.W., Luo, S., Luo, W.M., Lyashuk, V., Ma, Q.M., Ma, S., Ma, X.B., Ma, X.Y., Ma, Y.Q., Malyshkin, Y., Mantovani, F., Mao, Y.J., Mari, S.M., Marini, F., Marium, S., Marshall, C., Martellini, C., Martin-Chassard, G., Caicedo, D.A. Martinez, Martini, A., Martino, J., Mayilyan, D., McDonald, K.T., McKeown, R.D., Müller, A., Meng, G., Mednieks, I., Meng, Y., Meregaglia, A., Meroni, E., Meyhöfer, D., Mezzetto, M., Miller, J., Miramonti, L., Monforte, S., Montini, P., Montuschi, M., Morozov, N., Muralidharan, P., Napolitano, J., Nastasi, M., Naumov, D.V., Naumova, E., Nemchenok, I., Nikolaev, A., Ning, F.P., Ning, Z., Nunokawa, H., Oberauer, L., Ochoa-Ricoux, J.P., Olshevskiy, A., Ortica, F., Pan, H.R., Paoloni, A., Park, J., Parkalian, N., Parmeggiano, S., Patton, S., Payupol, T., Pec, V., Pedretti, D., Pei, Y.T., Pelliccia, N., Peng, A.G., Peng, H.P., Peng, J.C., Perrot, F., Petitjean, P.A., Rico, L.F. Pineres, Popov, A., Poussot, P., Pratumwan, W., Previtali, E., Pun, C.S.J., Qi, F.Z., Qi, M., Qian, S., Qian, X., Qian, X.H., Qiao, H., Qin, Z.H., Qiu, S.K., Rajput, M., Ranucci, G., Raper, N., Re, A., Rebber, H., Rebii, A., Ren, B., Ren, J., Reveco, C.M., Rezinko, T., Ricci, B., Robens, M., Roche, M., Rodphai, N., Rohwer, L., Romani, A., Rosero, R., Roskovec, B., Roth, C., Ruan, X.C., Ruan, X.D., Rujirawat, S., Rybnikov, A., Sadovsky, A., Saggese, P., Salamanna, G., Sangka, A., Sanguansak, N., Sawangwit, U., Sawatzki, J., Sawy, F., Schever, M., Schuler, J., Schwab, C., Schweizer, K., Selivanov, D., Selyunin, A., Serafini, A., Settanta, G., Settimo, M., Shahzad, M., Shi, G., Shi, J.Y., Shi, Y.J., Shutov, V., Sidorenkov, A., Šimkovic, F., Sirignano, C., Siripak, J., Sisti, M., Slupecki, M., Smirnov, M., Smirnov, O., Sogo-Bezerra, T., Songwadhana, J., Soonthornthum, B., Sotnikov, A., Sramek, O., Sreethawong, W., Stahl, A., Stanco, L., Stankevich, K., Štefánik, D., Steiger, H., Steiner, H., Steinmann, J., Stender, M., Strati, V., Studenikin, A., Sun, G.X., Sun, L.T., Sun, J.L., Sun, S.F., Sun, X.L., Sun, Y.J., Sun, Y.Z., Suwonjandee, N., Szelezniak, M., Tang, J., Tang, Q., Tang, X., Tietzsch, A., Tkachev, I., Tmej, T., Treskov, K., Troni, G., Trzaska, W., Tse, W.-H., Tull, C.E., Tuve, C., van Waasen, S., Boom, J. van den, Vassilopoulos, N., Vedin, V., Verde, G., Vialkov, M., Viaud, B., Viren, B., Volpe, C., Vorobel, V., Votano, L., Walker, P., Wang, C., Wang, C.H., Wang, E., Wang, G.L., Wang, J., Wang, K.Y., Wang, L., Wang, M.F., Wang, M., Wang, N.Y., Wang, R.G., Wang, S.G., Wang, W., Wang, W.S., Wang, X., Wang, X.Y., Wang, Y., Wang, Y.F., Wang, Y.G., Wang, Y.M., Wang, Y.Q., Wang, Z., Wang, Z.M., Wang, Z.Y., Watcharangkool, A., Wei, H.Y., Wei, L.H., Wei, W., Wei, Y.D., Wen, L.J., Whisnant, K., White, C.G., Wiebusch, C., Wong, S.C.F., Wong, H.L.H., Wonsak, B., Worcester, E., Wu, C.H., Wu, D.R., Wu, F.L., Wu, Q., Wu, W.J., Wu, Z., Wurm, M., Wurtz, J., Wysotzki, C., Xi, Y.F., Xia, D.M., Xie, Y.G., Xie, Z.Q., Xing, Z.Z., Xu, D.L., Xu, F.R., Xu, H.K., Xu, J.L., Xu, J., Xu, M.H., Xu, T., Xu, Y., Xue, T., Yan, B.J., Yan, X.B., Yan, Y.P., Yang, A.B., Yang, C.G., Yang, H., Yang, J., Yang, L., Yang, X.Y., Yang, Y.F., Yang, Y.Z., Yao, H.F., Yasin, Z., Ye, J.X., Ye, M., Yegin, U., Yeh, M., Yermia, F., Yi, P.H., You, Z.Y., Young, B.L., Yu, B.X., Yu, C.X., Yu, C.Y., Yu, H.Z., Yu, M., Yu, X.H., Yu, Z.Y., Yuan, C.Z., Yuan, Y., Yuan, Z.X., Yuan, Z.Y., Yue, B.B., Zafar, N., Zambanini, A., Zeng, P., Zeng, S., Zeng, T.X., Zeng, Y.D., Zhan, L., Zhang, C., Zhang, F.Y., Zhang, G.Q., Zhang, H.H., Zhang, H.Q., Zhang, J., Zhang, J.B., Zhang, J.W., Zhang, P., Zhang, Q.M., Zhang, T., Zhang, X.M., Zhang, X.T., Zhang, Y., Zhang, Y.H., Zhang, Y.M., Zhang, Y.P., Zhang, Y.X., Zhang, Y.Y., Zhang, Z.J., Zhang, Z.P., Zhang, Z.Y., Zhao, F.Y., Zhao, J., Zhao, R., Zhao, S.J., Zhao, T.C., Zheng, D.Q., Zheng, H., Zheng, M.S., Zheng, Y.H., Zhong, W.R., Zhou, J., Zhou, L., Zhou, N., Zhou, S., Zhou, X., Zhu, J., Zhu, K.J., Zhuang, H.L., Zong, L., and Zou, J.H.

Published

2021

24. JUNO Conceptual Design Report

Author

Adam, T., An, F., An, G., An, Q., Anfimov, N., Antonelli, V., Baccolo, G., Baldoncini, M., Baussan, E., Bellato, M., Bezrukov, L., Bick, D., Blyth, S., Boarin, S., Brigatti, A., Brugière, T., Brugnera, R., Avanzini, M. Buizza, Busto, J., Cabrera, A., Cai, H., Cai, X., Cammi, A., Cao, D., Cao, G., Cao, J., Chang, J., Chang, Y., Chen, M., Chen, P., Chen, Q., Chen, S., Chen, X., Chen, Y., Cheng, Y., Chiesa, D., Chukanov, A., Clemenza, M., Clerbaux, B., D'Angelo, D., de Kerret, H., Deng, Z., Ding, X., Ding, Y., Djurcic, Z., Dmitrievsky, S., Dolgareva, M., Dornic, D., Doroshkevich, E., Dracos, M., Drapier, O., Dusini, S., Díaz, M. A., Enqvist, T., Fan, D., Fang, C., Fang, J., Fang, X., Favart, L., Fedoseev, D., Fiorentini, G., Ford, R., Formozov, A., Gaigher, R., Gan, H., Garfagnini, A., Gaudiot, G., Genster, C., Giammarchi, M., Giuliani, F., Gonchar, M., Gong, G., Gong, H., Gonin, M., Gornushkin, Y., Grassi, M., Grewing, C., Gromov, V., Gu, M., Guan, M., Guarino, V., Guo, W., Guo, X., Guo, Y., Göger-Neff, M., Hackspacher, P., Hagner, C., Han, R., Han, Z., Hao, J., He, M., Hellgartner, D., Heng, Y., Hong, D., Hou, S., Hsiung, Y., Hu, B., Hu, J., Hu, S., Hu, T., Hu, W., Huang, H., Huang, X., Huo, L., Huo, W., Ioannisian, A., Ioannisyan, D., Jeitler, M., Jen, K., Jetter, S., Ji, X., Jian, S., Jiang, D., Jiang, X., Jollet, C., Kaiser, M., Kan, B., Kang, L., Karagounis, M., Kazarian, N., Kettell, S., Korablev, D., Krasnoperov, A., Krokhaleva, S., Krumshteyn, Z., Kruth, A., Kuusiniemi, P., Lachenmaier, T., Lei, L., Lei, R., Lei, X., Leitner, R., Lenz, F., Li, C., Li, F., Li, J., Li, N., Li, S., Li, T., Li, W., Li, X., Li, Y., Li, Z., Liang, H., Liang, J., Licciardi, M., Lin, G., Lin, S., Lin, T., Lin, Y., Lippi, I., Liu, G., Liu, H., Liu, J., Liu, Q., Liu, S., Liu, Y., Lombardi, P., Long, Y., Lorenz, S., Lu, C., Lu, F., Lu, H., Lu, J., Lubsandorzhiev, B., Lubsandorzhiev, S., Ludhova, L., Luo, F., Luo, S., Lv, Z., Lyashuk, V., Ma, Q., Ma, S., Ma, X., Malyshkin, Y., Mantovani, F., Mao, Y., Mari, S., Mayilyan, D., McDonough, W., Meng, G., Meregaglia, A., Meroni, E., Mezzetto, M., Min, J., Miramonti, L., Montuschi, M., Morozov, N., Mueller, T., Muralidharan, P., Nastasi, M., Naumov, D., Naumova, E., Nemchenok, I., Ning, Z., Nunokawa, H., Oberauer, L., Ochoa-Ricoux, J. P., Olshevskiy, A., Ortica, F., Pan, H., Paoloni, A., Parkalian, N., Parmeggiano, S., Pec, V., Pelliccia, N., Peng, H., Poussot, P., Pozzi, S., Previtali, E., Prummer, S., Qi, F., Qi, M., Qian, S., Qian, X., Qiao, H., Qin, Z., Ranucci, G., Re, A., Ren, B., Ren, J., Rezinko, T., Ricci, B., Robens, M., Romani, A., Roskovec, B., Ruan, X., Rybnikov, A., Sadovsky, A., Saggese, P., Salamanna, G., Sawatzki, J., Schuler, J., Selyunin, A., Shi, G., Shi, J., Shi, Y., Sinev, V., Sirignano, C., Sisti, M., Smirnov, O., Soiron, M., Stahl, A., Stanco, L., Steinmann, J., Strati, V., Sun, G., Sun, X., Sun, Y., Taichenachev, D., Tang, J., Tietzsch, A., Tkachev, I., Trzaska, W. H., Tung, Y., van Waasen, S., Volpe, C., Vorobel, V., Votano, L., Wang, C., Wang, G., Wang, H., Wang, M., Wang, R., Wang, S., Wang, W., Wang, Y., Wang, Z., Wei, W., Wei, Y., Weifels, M., Wen, L., Wen, Y., Wiebusch, C., Wipperfurth, S., Wong, S. C., Wonsak, B., Wu, C., Wu, Q., Wu, Z., Wurm, M., Wurtz, J., Xi, Y., Xia, D., Xia, J., Xiao, M., Xie, Y., Xu, J., Xu, L., Xu, Y., Yan, B., Yan, X., Yang, C., Yang, H., Yang, L., Yang, M., Yang, Y., Yanovich, E., Yao, Y., Ye, M., Ye, X., Yegin, U., Yermia, F., You, Z., Yu, B., Yu, C., Yu, G., Yu, Z., Yuan, Y., Yuan, Z., Zanetti, M., Zeng, P., Zeng, S., Zeng, T., Zhan, L., Zhang, C., Zhang, F., Zhang, G., Zhang, H., Zhang, J., Zhang, K., Zhang, P., Zhang, Q., Zhang, T., Zhang, X., Zhang, Y., Zhang, Z., Zhao, J., Zhao, M., Zhao, T., Zhao, Y., Zheng, H., Zheng, M., Zheng, X., Zheng, Y., Zhong, W., Zhou, G., Zhou, J., Zhou, L., Zhou, N., Zhou, R., Zhou, S., Zhou, W., Zhou, X., Zhou, Y., Zhu, H., Zhu, K., Zhuang, H., Zong, L., and Zou, J.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The Jiangmen Underground Neutrino Observatory (JUNO) is proposed to determine the neutrino mass hierarchy using an underground liquid scintillator detector. It is located 53 km away from both Yangjiang and Taishan Nuclear Power Plants in Guangdong, China. The experimental hall, spanning more than 50 meters, is under a granite mountain of over 700 m overburden. Within six years of running, the detection of reactor antineutrinos can resolve the neutrino mass hierarchy at a confidence level of 3-4$\sigma$, and determine neutrino oscillation parameters $\sin^2\theta_{12}$, $\Delta m^2_{21}$, and $|\Delta m^2_{ee}|$ to an accuracy of better than 1%. The JUNO detector can be also used to study terrestrial and extra-terrestrial neutrinos and new physics beyond the Standard Model. The central detector contains 20,000 tons liquid scintillator with an acrylic sphere of 35 m in diameter. $\sim$17,000 508-mm diameter PMTs with high quantum efficiency provide $\sim$75% optical coverage. The current choice of the liquid scintillator is: linear alkyl benzene (LAB) as the solvent, plus PPO as the scintillation fluor and a wavelength-shifter (Bis-MSB). The number of detected photoelectrons per MeV is larger than 1,100 and the energy resolution is expected to be 3% at 1 MeV. The calibration system is designed to deploy multiple sources to cover the entire energy range of reactor antineutrinos, and to achieve a full-volume position coverage inside the detector. The veto system is used for muon detection, muon induced background study and reduction. It consists of a Water Cherenkov detector and a Top Tracker system. The readout system, the detector control system and the offline system insure efficient and stable data acquisition and processing., Comment: 328 pages, 211 figures

Published

2015

25. Crack Element in the Non-linear f.e.m. Program PA.R.M.A. for the Design of Reinforced Concrete Pavements

Author

Montepara, A., primary and Giuliani, F., additional

Published

2021

26. Achieving accurate estimates of fetal gestational age and personalised predictions of fetal growth based on data from an international prospective cohort study: a population-based machine learning study

Author

Norris, S, Abbott, SE, Abubakar, A, Acedo, J, Ahmed, I, Al-Aamri, F, Al-Abduwani, J, Al-Abri, J, Alam, D, Albernaz, E, Algren, H, Al-Habsi, F, Alija, M, Al-Jabri, H, Al-Lawatiya, H, Al-Rashidiya, B, Altman, DG, Al-Zadjali, WK, Andersen, HF, Aranzeta, L, Ash, S, Baricco, M, Barros, FC, Barsosio, H, Batiuk, C, Batra, M, Berkley, J, Bertino, E, Bhan, MK, Bhat, BA, Bhutta, ZA, Blakey, I, Bornemeier, S, Bradman, A, Buckle, M, Burnham, O, Burton, F, Capp, A, Cararra, VI, Carew, R, Carrara, VI, Carter, AA, Carvalho, M, Chamberlain, P, Cheikh, Ismail L, Cheikh Ismail, L, Choudhary, A, Choudhary, S, Chumlea, WC, Condon, C, Corra, LA, Cosgrove, C, Craik, R, da Silveira, MF, Danelon, D, de Wet, T, de Leon, E, Deshmukh, S, Deutsch, G, Dhami, J, Di, Nicola P, Dighe, M, Dolk, H, Domingues, M, Dongaonkar, D, Enquobahrie, D, Eskenazi, B, Farhi, F, Fernandes, M, Finkton, D, Fonseca, S, Frederick, IO, Frigerio, M, Gaglioti, P, Garza, C, Gilli, G, Gilli, P, Giolito, M, Giuliani, F, Golding, J, Gravett, MG, Gu, SH, Guman, Y, He, YP, Hoch, L, Hussein, S, Ibanez, D, Ioannou, C, Jacinta, N, Jackson, N, Jaffer, YA, Jaiswal, S, Jimenez-Bustos, JM, Juangco, FR, Juodvirsiene, L, Katz, M, Kemp, B, Kennedy, S, Ketkar, M, Khedikar, V, Kihara, M, Kilonzo, J, Kisiang'ani, C, Kizidio, J, Knight, CL, Knight, HE, Kunnawar, N, Laister, A, Lambert, A, Langer, A, Lephoto, T, Leston, A, Lewis, T, Liu, H, Lloyd, S, Lumbiganon, P, Macauley, S, Maggiora, E, Mahorkar, C, Mainwaring, M, Malgas, L, Matijasevich, A, McCormick, K, McGready, R, Miller, R, Min, A, Mitidieri, A, Mkrtychyan, V, Monyepote, B, Mota, D, Mulik, I, Munim, S, Muninzwa, D, Musee, N, Mwakio, S, Mwangudzah, H, Napolitano, R, Newton, CR, Ngami, V, Noble, JA, Norris, T, Nosten, F, Oas, K, Oberto, M, Occhi, L, Ochieng, R, Ohuma, EO, Olearo, E, Olivera, I, Owende, MG, Pace, C, Pan, Y, Pang, RY, Papageorghiou, AT, Patel, B, Paul, V, Paulsene, W, Puglia, F, Purwar, M, Rajan, V, Raza, A, Reade, D, Rivera, J, Rocco, DA, Roseman, F, Roseman, S, Rossi, C, Rothwell, PM, Rovelli, I, Saboo, K, Salam, R, Salim, M, Salomon, L, Sanchez, Luna M, Sande, J, Sarris, I, Savini, S, Sclowitz, IK, Seale, A, Shah, J, Sharps, M, Shembekar, C, Shen, YJ, Shorten, M, Signorile, F, Singh, A, Sohoni, S, Somani, A, Sorensen, TK, Soria- Frisch, A, Staines Urias, E, Stein, A, Stones, W, Taori, V, Tayade, K, Todros, T, Uauy, R, Varalda, A, Venkataraman, M, Victora, C, Villar, J, Vinayak, S, Waller, S, Walusuna, L, Wang, JH, Wang, L, Wanyonyi, S, Weatherall, D, Wiladphaingern, S, Wilkinson, A, Wilson, D, Wu, MH, Wu, QQ, Wulff, K, Yellappan, D, Yuan, Y, Zaidi, S, Zainab, G, Zhang, JJ, Zhang, Y, Fung, Russell, Villar, Jose, Dashti, Ali, Ismail, Leila Cheikh, Staines-Urias, Eleonora, Ohuma, Eric O, Salomon, Laurent J, Victora, Cesar G, Barros, Fernando C, Lambert, Ann, Carvalho, Maria, Jaffer, Yasmin A, Noble, J Alison, Gravett, Michael G, Purwar, Manorama, Pang, Ruyan, Bertino, Enrico, Munim, Shama, Min, Aung Myat, McGready, Rose, Norris, Shane A, Bhutta, Zulfiqar A, Kennedy, Stephen H, Papageorghiou, Aris T, and Ourmazd, Abbas

Published

2020

27. Improving Photoelectron Counting and Particle Identification in Scintillation Detectors with Bayesian Techniques

Author

Akashi-Ronquest, M., Amaudruz, P. -A., Batygov, M., Beltran, B., Bodmer, M., Boulay, M. G., Broerman, B., Buck, B., Butcher, A., Cai, B., Caldwell, T., Chen, M., Chen, Y., Cleveland, B., Coakley, K., Dering, K., Duncan, F. A., Formaggio, J. A., Gagnon, R., Gastler, D., Giuliani, F., Gold, M., Golovko, V. V., Gorel, P., Graham, K., Grace, E., Guerrero, N., Guiseppe, V., Hallin, A. L., Harvey, P., Hearns, C., Henning, R., Hime, A., Hofgartner, J., Jaditz, S., Jillings, C. J., Kachulis, C., Kearns, E., Kelsey, J., Klein, J. R., Kuzniak, M., LaTorre, A., Lawson, I., Li, O., Lidgard, J. J., Liimatainen, P., Linden, S., McFarlane, K., McKinsey, D. N., MacMullin, S., Mastbaum, A., Mathew, R., McDonald, A. B., Mei, D. -M., Monroe, J., Muir, A., Nantais, C., Nicolics, K., Nikkel, J. A., Noble, T., O'Dwyer, E., Olsen, K., Gann, G. D. Orebi, Ouellet, C., Palladino, K., Pasuthip, P., Perumpilly, G., Pollmann, T., Rau, P., Retiere, F., Rielage, K., Schnee, R., Seibert, S., Skensved, P., Sonley, T., Vazquez-Jauregui, E., Veloce, L., Walding, J., Wang, B., Wang, J., Ward, M., and Zhang, C.

Subjects

Physics - Instrumentation and Detectors, Astrophysics - Instrumentation and Methods for Astrophysics, High Energy Physics - Experiment, Nuclear Experiment

Abstract

Many current and future dark matter and neutrino detectors are designed to measure scintillation light with a large array of photomultiplier tubes (PMTs). The energy resolution and particle identification capabilities of these detectors depend in part on the ability to accurately identify individual photoelectrons in PMT waveforms despite large variability in pulse amplitudes and pulse pileup. We describe a Bayesian technique that can identify the times of individual photoelectrons in a sampled PMT waveform without deconvolution, even when pileup is present. To demonstrate the technique, we apply it to the general problem of particle identification in single-phase liquid argon dark matter detectors. Using the output of the Bayesian photoelectron counting algorithm described in this paper, we construct several test statistics for rejection of backgrounds for dark matter searches in argon. Compared to simpler methods based on either observed charge or peak finding, the photoelectron counting technique improves both energy resolution and particle identification of low energy events in calibration data from the DEAP-1 detector and simulation of the larger MiniCLEAN dark matter detector., Comment: 16 pages, 16 figures

Published

2014

28. Spectroscopy of Lambda-9Li by electroproduction

Author

Urciuoli, G. M., Cusanno, F., Marrone, S., Acha, A., Ambrozewicz, P., Aniol, K. A., Baturin, P., Bertin, P. Y., Benaoum, H., Blomqvist, K. I., Boeglin, W. U., Breuer, H., Brindza, P., Bydzovsky, P., Camsonne, A., Chang, C. C., Chen, J. -P., Choi, Seonho, Chudakov, E. A., Cisbani, E., Colilli, S., Coman, L., Craver, B. J., De Cataldo, G., de Jager, C. W., De Leo, R., Deur, A. P., Ferdi, C., Feuerbach, R. J., Folts, E., Fratoni, R., Frullani, S., Garibaldi, F., Gayou, O., Giuliani, F., Gomez, J., Gricia, M., Hansen, J. O., Hayes, D., Higinbotham, D. W., Holmstrom, T. K., Hyde, C. E., Ibrahim, H. F., Iodice, M., Jiang, X., Kaufman, L. J., Kino, K., Kross, B., Lagamba, L., LeRose, J. J., Lindgren, R. A., Lucentini, M., Margaziotis, D. J., Markowitz, P., Meziani, Z. E., McCormick, K., Michaels, R. W., Millener, D. J., Miyoshi, T., Moffit, B., Monaghan, P. A., Moteabbed, M., Camacho, C. Munoz, Nanda, S., Nappi, E., Nelyubin, V. V., Norum, B. E., Okasyasu, Y., Paschke, K. D., Perdrisat, C. F., Piasetzky, E., Punjabi, V. A., Qiang, Y., Reimer, P. E., Reinhold, J., Reitz, B., Roche, R. E., Rodriguez, V. M., Saha, A., Santavenere, F., Sarty, A. J., Segal, J., Shahinyan, A., Singh, J., Sirca, S., Snyder, R., Solvignon, P. H., Sotona, M., Subedi, R., Sulkosky, V. A., Suzuki, T., Ueno, H., Ulmer, P. E., Veneroni, P., Voutier, E., Wojtsekhowski, B. B., Zheng, X., and Zorn, C.

Subjects

Nuclear Experiment

Abstract

In the absence of accurate data on the free two-body hyperon-nucleon interaction, the spectra of hypernuclei can provide information on the details of the effective hyperon-nucleon interaction. Electroproduction of the hypernucleus Lambda-9Li has been studied for the first time with sub-MeV energy resolution in Hall A at Jefferson Lab on a 9Be target. In order to increase the counting rate and to provide unambiguous kaon identification, two superconducting septum magnets and a Ring Imaging CHerenkov detector (RICH) were added to the Hall A standard equipment. The cross section to low-lying states of Lambda-9Li is concentrated within 3 MeV of the ground state and can be fitted with four peaks. The positions of the doublets agree with theory while a disagreement could exist with respect to the relative strengths of the peaks in the doublets. A Lambda separation energy of 8.36 +- 0.08 (stat.) +- 0.08 (syst.) MeV was measured, in agreement with an earlier experiment., Comment: 14 pages, 8 figures

Published

2014

29. Update on the MiniCLEAN Dark Matter Experiment

Author

Rielage, K., Akashi-Ronquest, M., Bodmer, M., Bourque, R., Buck, B., Butcher, A., Caldwell, T., Chen, Y., Coakley, K., Flores, E., Formaggio, J. A., Gastler, D., Giuliani, F., Gold, M., Grace, E., Griego, J., Guerrero, N., Guiseppe, V., Henning, R., Hime, A., Jaditz, S., Kachulis, C., Kearns, E., Kelsey, J., Klein, J. R., Latorre, A., Lawson, I., Linden, S., Lopez, F., McKinsey, D. N., MacMullin, S., Mastbaum, A., Mei, D. -M., Monroe, J., Nikkel, J. A., Oertel, J., Gann, G. D. Orebi, Palladino, K., Perumpilly, G., Rodriguez, L., Schnee, R., Seibert, S., Walding, J., Wang, B., Wang, J., and Zhang, C.

Subjects

Physics - Instrumentation and Detectors, Astrophysics - Instrumentation and Methods for Astrophysics, High Energy Physics - Experiment

Abstract

The direct search for dark matter is entering a period of increased sensitivity to the hypothetical Weakly Interacting Massive Particle (WIMP). One such technology that is being examined is a scintillation only noble liquid experiment, MiniCLEAN. MiniCLEAN utilizes over 500 kg of liquid cryogen to detect nuclear recoils from WIMP dark matter and serves as a demonstration for a future detector of order 50 to 100 tonnes. The liquid cryogen is interchangeable between argon and neon to study the A$^{2}$ dependence of the potential signal and examine backgrounds. MiniCLEAN utilizes a unique modular design with spherical geometry to maximize the light yield using cold photomultiplier tubes in a single-phase detector. Pulse shape discrimination techniques are used to separate nuclear recoil signals from electron recoil backgrounds. MiniCLEAN will be spiked with additional $^{39}$Ar to demonstrate the effective reach of the pulse shape discrimination capability. Assembly of the experiment is underway at SNOLAB and an update on the project is given., Comment: To appear in the Proceedings of the TAUP 2013 Conference (F. Avignone & W. Haxton, editors, Physics Procedia, Elsevier)

Published

2014

30. Attorno alla complessità feconda delle residenze creative

Author

Biondi, F, Donat, L, Ferrante, D, Guerra, G, Argano, L, Ferraresi, R, Guccini, G, Toppi, A, D'Ippolito, F, Ferrari, S, Giuliani, F, Gemini, L, Amico, M, Angelini, I, Bianchi, P, Banci Del Bene, T, Borghesi, N, Cantù, P, D'Agostino, A, Gravano, V, Meucci, E, Olivier, R, Ninarello, D, Pennini, F, Palermo, G, Tonsini, S, Villa, D, Zardi, A, Donati, L, Argano, Lucio, Argano L, Biondi, F, Donat, L, Ferrante, D, Guerra, G, Argano, L, Ferraresi, R, Guccini, G, Toppi, A, D'Ippolito, F, Ferrari, S, Giuliani, F, Gemini, L, Amico, M, Angelini, I, Bianchi, P, Banci Del Bene, T, Borghesi, N, Cantù, P, D'Agostino, A, Gravano, V, Meucci, E, Olivier, R, Ninarello, D, Pennini, F, Palermo, G, Tonsini, S, Villa, D, Zardi, A, Donati, L, Argano, Lucio, and Argano L

Abstract

Il contributo si concentra sul fenomeno delle residenze creative, con riguardo a quelle correlate allo spettacolo dal vivo, sotto la lente della complessità, dell'ottica sistemica e delle manifestazioni emergenti

Published

2024

31. JUNO Conceptual Design Report

Author

Adam, T, An, F, An, G, An, Q, Anfimov, N, Antonelli, V, Baccolo, G, Baldoncini, M, Baussan, E, Bellato, M, Bezrukov, L, Bick, D, Blyth, S, Boarin, S, Brigatti, A, Brugière, T, Brugnera, R, Avanzini, M Buizza, Busto, J, Cabrera, A, Cai, H, Cai, X, Cammi, A, Cao, D, Cao, G, Cao, J, Chang, J, Chang, Y, Chen, M, Chen, P, Chen, Q, Chen, S, Chen, X, Chen, Y, Cheng, Y, Chiesa, D, Chukanov, A, Clemenza, M, Clerbaux, B, D'Angelo, D, Kerret, H de, Deng, Z, Ding, X, Ding, Y, Djurcic, Z, Dmitrievsky, S, Dolgareva, M, Dornic, D, Doroshkevich, E, Dracos, M, Drapier, O, Dusini, S, Díaz, MA, Enqvist, T, Fan, D, Fang, C, Fang, J, Fang, X, Favart, L, Fedoseev, D, Fiorentini, G, Ford, R, Formozov, A, Gaigher, R, Gan, H, Garfagnini, A, Gaudiot, G, Genster, C, Giammarchi, M, Giuliani, F, Gonchar, M, Gong, G, Gong, H, Gonin, M, Gornushkin, Y, Grassi, M, Grewing, C, Gromov, V, Gu, M, Guan, M, Guarino, V, Guo, W, Guo, X, Guo, Y, Göger-Neff, M, Hackspacher, P, Hagner, C, Han, R, Han, Z, Hao, J, He, M, Hellgartner, D, Heng, Y, Hong, D, Hou, S, Hsiung, Y, and Hu, B

Subjects

physics.ins-det, hep-ex

Abstract

The Jiangmen Underground Neutrino Observatory (JUNO) is proposed to determinethe neutrino mass hierarchy using an underground liquid scintillator detector.It is located 53 km away from both Yangjiang and Taishan Nuclear Power Plantsin Guangdong, China. The experimental hall, spanning more than 50 meters, isunder a granite mountain of over 700 m overburden. Within six years of running,the detection of reactor antineutrinos can resolve the neutrino mass hierarchyat a confidence level of 3-4$\sigma$, and determine neutrino oscillationparameters $\sin^2\theta_{12}$, $\Delta m^2_{21}$, and $|\Delta m^2_{ee}|$ toan accuracy of better than 1%. The JUNO detector can be also used to studyterrestrial and extra-terrestrial neutrinos and new physics beyond the StandardModel. The central detector contains 20,000 tons liquid scintillator with anacrylic sphere of 35 m in diameter. $\sim$17,000 508-mm diameter PMTs with highquantum efficiency provide $\sim$75% optical coverage. The current choice ofthe liquid scintillator is: linear alkyl benzene (LAB) as the solvent, plus PPOas the scintillation fluor and a wavelength-shifter (Bis-MSB). The number ofdetected photoelectrons per MeV is larger than 1,100 and the energy resolutionis expected to be 3% at 1 MeV. The calibration system is designed to deploymultiple sources to cover the entire energy range of reactor antineutrinos, andto achieve a full-volume position coverage inside the detector. The veto systemis used for muon detection, muon induced background study and reduction. Itconsists of a Water Cherenkov detector and a Top Tracker system. The readoutsystem, the detector control system and the offline system insure efficient andstable data acquisition and processing.

Published

2015

32. Differential disease phenotypes and progression in relapsing–remitting multiple sclerosis: comparative analyses of single Canadian and Saudi Arabian clinics

Author

Alluqmani, M., Roda, W., Qqrmli, M., Blevins, G., Giuliani, F., and Power, C.

Published

2021

33. New analytical correlations between SPT, overburden pressure and relative density

Author

Giuliani, F., primary and Giuliani Nicoll, F.L., additional

Published

2021

34. Reducibility of first order linear operators on tori via Moser's theorem

Author

Feola, R., Giuliani, F., Montalto, R., and Procesi, M.

Published

2019

35. Isospin conserving Dark Matter with isospin dependent interaction, and reconciliation of contrasting results from direct Dark Matter experiments

Author

Giuliani, F.

Subjects

Astrophysics - Cosmology and Extragalactic Astrophysics, High Energy Physics - Experiment

Abstract

A simple model of Dark Matter (DM) which couples with the two nucleons with different coupling strengths without violating isospin conservation is explored as an example of the importance of keeping the experimental data analysis as model independent as possible. The apparent contrast between the recent CRESST event excess and current XENON100 spin-independent (SI) exclusions is shown to be removed by simply not assuming that the couplings of the DM with the two nucleons are equal.

Published

2011

36. The effect of the recoil energy window on the results of direct dark matter experiments

Author

Giuliani, F.

Subjects

Astrophysics - Cosmology and Extragalactic Astrophysics, High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

The effect of the chosen analysis energy window on the results of a dark matter experiment is exemplified by the curious intersection of the exclusion plots of the XENON10 and the CDMS experiments. After proving that the narrow energy window XENON10 chose to analyze is indeed the cause of such intersection, a method to determine the high-energy extreme of the recoil energy window an experiment should use is obtained., Comment: 4 pages, 5 figures

Published

2009

37. Measurement of the scintillation time spectra and pulse-shape discrimination of low-energy beta and nuclear recoils in liquid argon with DEAP-1

Author

Amaudruz, P. -A., Batygov, M., Beltran, B., Bonatt, J., Boudjemline, K., Boulay, M. G., Broerman, B., Bueno, J. F., Butcher, A., Cai, B., Caldwell, T., Chen, M., Chouinard, R., Cleveland, B. T., Cranshaw, D., Dering, K., Duncan, F., Fatemighomi, N., Ford, R., Gagnon, R., Giampa, P., Giuliani, F., Gold, M., Golovko, V. V., Gorel, P., Grace, E., Graham, K., Grant, D. R., Hakobyan, R., Hallin, A. L., Hamstra, M., Harvey, P., Hearns, C., Hofgartner, J., Jillings, C. J., Kuźniak, M., Lawson, I., La Zia, F., Li, O., Lidgard, J. J., Liimatainen, P., Lippincott, W. H., Mathew, R., McDonald, A. B., McElroy, T., McFarlane, K., Mehdiyev, R., McKinsey, D. N., Monroe, J., Muir, A., Nantais, C., Nicolics, K., Nikkel, J., Noble, A. J., O'Dwyer, E., Olsen, K., Ouellet, C., Pasuthip, P., Peeters, S. J. M., Pollmann, T., Rau, W., Retière, F., Ronquest, M., Seeburn, N., Skensved, P., Smith, B., Sonley, T., Tang, J., Vázquez-Jáuregui, E., Veloce, L., Walding, J., and Ward, M.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The DEAP-1 low-background liquid argon detector was used to measure scintillation pulse shapes of electron and nuclear recoil events and to demonstrate the feasibility of pulse-shape discrimination (PSD) down to an electron-equivalent energy of 20 keV. In the surface dataset using a triple-coincidence tag we found the fraction of beta events that are misidentified as nuclear recoils to be $<1.4\times 10^{-7}$ (90% C.L.) for energies between 43-86 keVee and for a nuclear recoil acceptance of at least 90%, with 4% systematic uncertainty on the absolute energy scale. The discrimination measurement on surface was limited by nuclear recoils induced by cosmic-ray generated neutrons. This was improved by moving the detector to the SNOLAB underground laboratory, where the reduced background rate allowed the same measurement with only a double-coincidence tag. The combined data set contains $1.23\times10^8$ events. One of those, in the underground data set, is in the nuclear-recoil region of interest. Taking into account the expected background of 0.48 events coming from random pileup, the resulting upper limit on the electronic recoil contamination is $<2.7\times10^{-8}$ (90% C.L.) between 44-89 keVee and for a nuclear recoil acceptance of at least 90%, with 6% systematic uncertainty on the absolute energy scale. We developed a general mathematical framework to describe PSD parameter distributions and used it to build an analytical model of the distributions observed in DEAP-1. Using this model, we project a misidentification fraction of approx. $10^{-10}$ for an electron-equivalent energy threshold of 15 keV for a detector with 8 PE/keVee light yield. This reduction enables a search for spin-independent scattering of WIMPs from 1000 kg of liquid argon with a WIMP-nucleon cross-section sensitivity of $10^{-46}$ cm$^2$, assuming negligible contribution from nuclear recoil backgrounds., Comment: Accepted for publication in Astroparticle Physics

Published

2009

38. High Resolution Spectroscopy of 16N_Lambda by Electroproduction

Author

Cusanno, F., Urciuoli, G. M., Acha, A., Ambrozewicz, P., Aniol, K. A., Baturin, P., Bertin, P. Y., Benaoum, H., Blomqvist, K. I., Boeglin, W. U., Breuer, H., Brindza, P., Bydzovsky, P., Camsonne, A., Chang, C. C., Chen, J. -P., Choi, Seonho, Chudakov, E. A., Cisbani, E., Colilli, S., Coman, L., Craver, B. J., De Cataldo, G., de Jager, C. W., De Leo, R., Deur, A. P., Ferdi, C., Feuerbach, R. J., Folts, E., Fratoni, R., Frullani, S., Garibaldi, F., Gayou, O., Giuliani, F., Gomez, J., Gricia, M., Hansen, J. O., Hayes, D., Higinbotham, D. W., Holmstrom, T. K., Hyde, C. E., Ibrahim, H. F., Iodice, M., Jiang, X., Kaufman, L. J., Kino, K., Kross, B., Lagamba, L., LeRose, J. J., Lindgren, R. A., Lucentini, M., Margaziotis, D. J., Markowitz, P., Marrone, S., Meziani, Z. E., McCormick, K., Michaels, R. W., Millener, D. J., Miyoshi, T., Moffit, B., Monaghan, P. A., Moteabbed, M., Camacho, C. Munoz, Nanda, S., Nappi, E., Nelyubin, V. V., Norum, B. E., Okasyasu, Y., Paschke, K. D., Perdrisat, C. F., Piasetzky, E., Punjabi, V. A., Qiang, Y., Raue, B., Reimer, P. E., Reinhold, J., Reitz, B., Roche, R. E., Rodriguez, V. M., Saha, A., Santavenere, F., Sarty, A. J., Segal, J., Shahinyan, A., Singh, J., Sirca, S., Snyder, R., Solvignon, P. H., Sotona, M., Subedi, R., Sulkosky, V. A., Suzuki, T., Ueno, H., Ulmer, P. E., Veneroni, P., Voutier, E., Wojtsekhowski, B. B., Zeng, X., and Zorn, C.

Subjects

Nuclear Experiment

Abstract

An experimental study of the 16O(e,e'K^+)16N_Lambda reaction has been performed at Jefferson Lab. A thin film of falling water was used as a target. This permitted a simultaneous measurement of the p(e,e'K^+)Lambda,Sigma_0 exclusive reactions and a precise calibration of the energy scale. A ground-state binding energy of 13.76 +/- 0.16 MeV was obtained for 16N_Lambda with better precision than previous measurements on the mirror hypernucleus 16O_Lambda. Precise energies have been determined for peaks arising from a Lambda in s and p orbits coupled to the p_{1/2} and p_{3/2} hole states of the 15N core nucleus., Comment: 5 pages, 3 figures, 2 tables

Published

2008

39. A CF3I-based SDD Prototype for Spin-independent Dark Matter Searches

Author

Morlata, T., Felizardo, M., Giuliani, F., Girard, TA, Waysand, G., Payne, R. F., Miley, H. S., Ramos, A. R., Marques, J. G., Martins, R. C., and Limagne, D.

Subjects

Astrophysics

Abstract

The application of Superheated Droplet Detectors (SDDs) to dark matter searches has so far been confined to the light nuclei refrigerants C2ClF5 and C4F10 (SIMPLE and PICASSO, respectively), with a principle sensitivity to spin-dependent interactions. Given the competitive results of these devices, as a result of their intrinsic insensitivity to backgrounds, we have developed a prototype trifluoroiodomethane (CF3I)-loaded SDD with increased sensitivity to spin-independent interactions as well. A low (0.102 kgd) exposure test operation of two high concentration, 1 liter devices is described, and the results compared with leading experiments in both spin-dependent and -independent sectors. Although competitive in both sectors when the difference in exposures is accounted for, a problem with fracturing of the detector gel must be addressed before significantly larger exposures can be envisioned., Comment: revised and updated; accepted Astrop. Phys

Published

2007

40. Can Light-nuclei Search Experiments Constrain the Spin-independent Dark Matter Phase Space?

Author

Giuliani, F., Girard, TA, and Morlat, T.

Subjects

Astrophysics

Abstract

At present, restrictions on the spin-independent parameter space of WIMP dark matter searches have been limited to the results provided by relatively heavy nuclei experiments, based on the conventional wisdom that only such experiments can provide significant spin-independent limits. We examine this wisdom, showing that light nuclei experiments can in fact provide comparable limits given comparable exposures, and indicating the potential of light nuclei detectors to simultaneously and competitively contribute to the search for both spin-independent and -dependent WIMP dark matter., Comment: 4 pages, 5 figures

Published

2007

41. Heavy Superheated Droplet Detectors as a Probe of Spin-independent WIMP Dark Matter Existence

Author

Giuliani, F., Morlat, T., and Girard, T. A.

Subjects

Physics - Instrumentation and Detectors

Abstract

At present, application of Superheated Droplet Detectors (SDDs) in WIMP dark matter searches has been limited to the spin-dependent sector, owing to the general use of fluorinated refrigerants which have high spin sensitivity. Given their recent demonstration of a significant constraint capability with relatively small exposures and the relative economy of the technique, we consider the potential impact of heavy versions of such devices on the spin-independent sector. Limits obtainable from a $\mathrm{CF_{3}I}$-loaded SDD are estimated on the basis of the radiopurity levels and backgrounds already achieved by the SIMPLE and PICASSO experiments. With 34 kgd exposure, equivalent to the current CDMS, such a device may already probe to below 10$^{-6}$ pb in the spin-independent cross section., Comment: 9 pages, 4 figures, accepted Phys. Rev. D

Published

2005

42. On the direct search for spin-dependent WIMP interactions

Author

Girard, T. A. and Giuliani, F.

Subjects

High Energy Physics - Experiment

Abstract

We examine the current directions in the search for spin-dependent dark matter. We discover that, with few exceptions, the search activity is concentrated towards constraints on the WIMP-neutron spin coupling, with significantly less impact in the WIMP-proton sector. We review the situation of those experiments with WIMP-proton spin sensitivity, toward identifying those capable of reestablishing the balance., Comment: 7 pages, 4 figures

Published

2005

43. SIMPLE Dark Matter Search Results

Author

Girard, TA, Giuliani, F., Morlat, T., da Costa, M. Felizardo, Collar, J. I., Limagne, D., Waysand, G., Puibasset, J., Miley, H. S., Auguste, M., Boyer, D., Cavaillou, A., Marques, J. G., Oliveira, C., Felizardo, M., Fernandes, A. C., Ramos, A. R., and Martins, R. C.

Subjects

High Energy Physics - Experiment

Abstract

We report an improved SIMPLE experiment comprising four superheated droplet detectors with a total exposure of 0.42 kgd. The result yields ~ factor 10 improvement in the previously-reported results, and -- despite the low exposure -- is seen to provide restrictions on the allowed phase space of spin-dependent coupling strengths almost equivalent to those from the significantly larger exposure NAIADCDMS/ZEPLIN searches., Comment: 8 pages, 2 figures, submitted to Phys. Lett. B

Published

2005

44. Are direct search experiments sensitive to all spin-independent WIMP candidates?

Author

Giuliani, F.

Subjects

High Energy Physics - Phenomenology, Astrophysics

Abstract

The common analysis of direct searches for spin-independent Weakly Interacting Massive Particles (WIMPs) assumes that a spin-independent WIMP couples with the same strength with both nucleons, \textit{i.e.} that the spin-independent interaction is also fully isospin-independent. Though in a fully isospin-dependent interaction scenario the spin-independent WIMP-nucleus cross section is strongly quenched, the leading experiments are still sensitive enough to set limits 1-2 orders of magnitude less stringent than those traditionally presented. In the isospin-dependent scenario the difference between the limits of CDMS-II and ZEPLIN-I is significantly reduced. Here, a model-independent framework is discussed and applied to obtain the current general model-independent limits., Comment: 4 pages, 4 figures, revtex4.0, submitted to Phys. Rev. Lett

Published

2005

45. Recent Results from the SIMPLE Dark Matter Search

Author

Girard, TA, Giuliani, F., and Collar, J. I.

Subjects

High Energy Physics - Experiment

Abstract

SIMPLE is an experimental search for evidence of spin-dependent dark matter, based on superheated droplet detectors using C$_{2}$ClF$_{5}$. We report preliminary results of a 0.6 kgdy exposure of five one liter devices, each containing $\sim$10 g active mass, in the 1500 mwe LSBB (Rustrel, France). In combination with improvements in detector sensitivity, the results exclude a WIMP--proton interaction above 5 pb at M$_{\chi}$ = 50 GeV/c$^{2}$., Comment: 6 pages, 2 figures,contribution to IDM2004, Sept. 6-10, 2004, Edinburgh, UK

Published

2005

46. Model-independent Limits from Spin-dependent WIMP Dark Matter Experiments

Author

Giuliani, F. and Girard, TA

Subjects

High Energy Physics - Phenomenology, Astrophysics

Abstract

Spin-dependent WIMP searches have traditionally presented results within an odd group approximation and by suppressing one of the spin-dependent interaction cross sections. We here elaborate on a model-independent analysis in which spin-dependent interactions with both protons and neutrons are simultaneously considered. Within this approach, equivalent current limits on the WIMP-nucleon interaction at WIMP mass of 50 GeV/c$^{2}$ are either $\sigma_{p}\leq0.7$ pb, $\sigma_{n}\leq0.2$ pb or $|a_{p}|\leq0.4$, $|a_{n}|\leq0.7$ depending on the choice of cross section or coupling strength representation. These limits become less restrictive for either larger or smaller masses; they are less restrictive than those from the traditional odd group approximation regardless of WIMP mass. Combination of experimental results are seen to produce significantly more restrictive limits than those obtained from any single experiment. Experiments traditionally considered spin-independent are moreover found to severely limit the spin-dependent phase space. The extension of this analysis to the case of positive signal experiments is explored., Comment: 12 pages, 12 figures, submitted to Phys. Rev. D

Published

2005

47. Model-independent assessment of current direct searches for spin-dependent dark matter

Author

Giuliani, F.

Subjects

High Energy Physics - Phenomenology, Astrophysics

Abstract

I evaluate the current results of spin-dependent weakly interacting massive particle (WIMP) searches within a model-independent framework, showing the most restrictive limits to date derive from the combination of xenon and sodium iodide experiments. The extension of this analysis to the case of positive signal experiments is elaborated., Comment: 4 pages, 4 figures, revised and accepted for publication on Phys. Rev. Lett

Published

2004

48. Exclusion limits on spin dependent WIMP-nucleon couplings from the SIMPLE experiment

Author

Giuliani, F. and Girard, TA

Subjects

Astrophysics, High Energy Physics - Phenomenology

Abstract

The SIMPLE experiment is reanalyzed within the context of the WIMP model independent framework of Tovey et. al.. The results are compared with those of the UK NAIAD and NaF experiments as recently reported by the Tokyo group, together with those of the latest UK NAIAD results in 2003, and further constrain the allowed parameter space., Comment: 4 pages, submitted to Phys. Lett. B

Published

2003

49. Allopregnanolone reversion of estrogen and progesterone memory impairment: interplay with serotonin release

Author

Escudero, C., Giuliani, F., Bernedo, M. Mulle, Yunes, Roberto, and Cabrera, R.

Published

2019

50. RAS testing of liquid biopsy correlates with the outcome of metastatic colorectal cancer patients treated with first-line FOLFIRI plus cetuximab in the CAPRI-GOIM trial

Author

Normanno, N., Esposito Abate, R., Lambiase, M., Forgione, L., Cardone, C., Iannaccone, A., Sacco, A., Rachiglio, A.M., Martinelli, E., Rizzi, D., Pisconti, S., Biglietto, M., Bordonaro, R., Troiani, T., Latiano, T.P., Giuliani, F., Leo, S., Rinaldi, A., Maiello, E., and Ciardiello, F.

Published

2018