S. Gollapinni - MicroBooNE Collaboration

S. Gollapinni
Are you S. Gollapinni?

Claim your profile, edit publications, add additional information:

Contact Details

Name
S. Gollapinni
Affiliation
MicroBooNE Collaboration
Location

Pubs By Year

Pub Categories

 
Physics - Instrumentation and Detectors (11)
 
High Energy Physics - Experiment (11)
 
High Energy Physics - Phenomenology (2)

Publications Authored By S. Gollapinni

2017May
Authors: MicroBooNE collaboration, R. Acciarri, C. Adams, R. An, J. Anthony, J. Asaadi, M. Auger, L. Bagby, S. Balasubramanian, B. Baller, C. Barnes, G. Barr, M. Bass, F. Bay, M. Bishai, A. Blake, T. Bolton, B. Bullard, L. Camilleri, D. Caratelli, B. Carls, R. Castillo Fernandez, F. Cavanna, H. Chen, E. Church, D. Cianci, E. Cohen, G. H. Collin, J. M. Conrad, M. Convery, J. I. Crespo-Anadon, G. De Geronimo, M. Del Tutto, D. Devitt, S. Dytman, B. Eberly, A. Ereditato, L. Escudero Sanchez, J. Esquivel, A. A. Fadeeva, B. T. Fleming, W. Foreman, A. P. Furmanski, D. Garcia-Gamez, G. T. Garvey, V. Genty, D. Goeldi, S. Gollapinni, N. Graf, E. Gramellini, H. Greenlee, R. Grosso, R. Guenette, A. Hackenburg, P. Hamilton, O. Hen, J. Hewes, C. Hill, J. Ho, G. Horton-Smith, A. Hourlier, E. -C. Huang, C. James, J. Jan de Vries, C. -M. Jen, L. Jiang, R. A. Johnson, J. Joshi, H. Jostlein, D. Kaleko, G. Karagiorgi, W. Ketchum, B. Kirby, M. Kirby, T. Kobilarcik, I. Kreslo, A. Laube, S. Li, Y. Li, A. Lister, B. R. Littlejohn, S. Lockwitz, D. Lorca, W. C. Louis, M. Luethi, B. Lundberg, X. Luo, A. Marchionni, C. Mariani, J. Marshall, D. A. Martinez Caicedo, V. Meddage, T. Miceli, G. B. Mills, J. Moon, M. Mooney, C. D. Moore, J. Mousseau, R. Murrells, D. Naples, P. Nienaber, J. Nowak, O. Palamara, V. Paolone, V. Papavassiliou, S. F. Pate, Z. Pavlovic, E. Piasetzky, D. Porzio, G. Pulliam, X. Qian, J. L. Raaf, V. Radeka, A. Rafique, S. Rescia, L. Rochester, C. Rudolf von Rohr, B. Russell, D. W. Schmitz, A. Schukraft, W. Seligman, M. H. Shaevitz, J. Sinclair, A. Smith, E. L. Snider, M. Soderberg, S. Soldner-Rembold, S. R. Soleti, P. Spentzouris, J. Spitz, J. St. John, T. Strauss, A. M. Szelc, N. Tagg, K. Terao, M. Thomson, C. Thorn, M. Toups, Y. -T. Tsai, S. Tufanli, T. Usher, W. Van De Pontseele, R. G. Van de Water, B. Viren, M. Weber, D. A. Wickremasinghe, S. Wolbers, T. Wongjirad, K. Woodruff, T. Yang, L. Yates, B. Yu, G. P. Zeller, J. Zennamo, C. Zhang

The low-noise operation of readout electronics in a liquid argon time projection chamber (LArTPC) is critical to properly extract the distribution of ionization charge deposited on the wire planes of the TPC, especially for the induction planes. This paper describes the characteristics and mitigation of the observed noise in the MicroBooNE detector. The MicroBooNE's single-phase LArTPC comprises two induction planes and one collection sense wire plane with a total of 8256 wires. Read More

2017Apr
Authors: MicroBooNE collaboration, R. Acciarri, C. Adams, R. An, J. Anthony, J. Asaadi, M. Auger, L. Bagby, S. Balasubramanian, B. Baller, C. Barnes, G. Barr, M. Bass, F. Bay, M. Bishai, A. Blake, T. Bolton, L. Bugel, L. Camilleri, D. Caratelli, B. Carls, R. Castillo Fernandez, F. Cavanna, H. Chen, E. Church, D. Cianci, E. Cohen, G. H. Collin, J. M. Conrad, M. Convery, J. I. Crespo-Anadon, M. Del Tutto, D. Devitt, S. Dytman, B. Eberly, A. Ereditato, L. Escudero Sanchez, J. Esquivel, B. T. Fleming, W. Foreman, A. P. Furmanski, D. Garcia-Gamez, G. T. Garvey, V. Genty, D. Goeldi, S. Gollapinni, N. Graf, E. Gramellini, H. Greenlee, R. Grosso, R. Guenette, A. Hackenburg, P. Hamilton, O. Hen, J. Hewes, C. Hill, J. Ho, G. Horton-Smith, E. -C. Huang, C. James, J. Jan de Vries, C. -M. Jen, L. Jiang, R. A. Johnson, J. Joshi, H. Jostlein, D. Kaleko, G. Karagiorgi, W. Ketchum, B. Kirby, M. Kirby, T. Kobilarcik, I. Kreslo, A. Laube, Y. Li, A. Lister, B. R. Littlejohn, S. Lockwitz, D. Lorca, W. C. Louis, M. Luethi, B. Lundberg, X. Luo, A. Marchionni, C. Mariani, J. Marshall, D. A. Martinez Caicedo, V. Meddage, T. Miceli, G. B. Mills, J. Moon, M. Mooney, C. D. Moore, J. Mousseau, R. Murrells, D. Naples, P. Nienaber, J. Nowak, O. Palamara, V. Paolone, V. Papavassiliou, S. F. Pate, Z. Pavlovic, E. Piasetzky, D. Porzio, G. Pulliam, X. Qian, J. L. Raaf, A. Rafique, L. Rochester, C. Rudolf von Rohr, B. Russell, D. W. Schmitz, A. Schukraft, W. Seligman, M. H. Shaevitz, J. Sinclair, E. L. Snider, M. Soderberg, S. Soldner-Rembold, S. R. Soleti, P. Spentzouris, J. Spitz, J. St. John, T. Strauss, K. A. Sutton, A. M. Szelc, N. Tagg, K. Terao, M. Thomson, M. Toups, Y. -T. Tsai, S. Tufanli, T. Usher, R. G. Van de Water, B. Viren, M. Weber, D. A. Wickremasinghe, S. Wolbers, T. Wongjirad, K. Woodruff, T. Yang, L. Yates, G. P. Zeller, J. Zennamo, C. Zhang

The MicroBooNE liquid argon time projection chamber (LArTPC) has been taking data at Fermilab since 2015 collecting, in addition to neutrino beam, cosmic-ray muons. Results are presented on the reconstruction of Michel electrons produced by the decay at rest of cosmic-ray muons. Michel electrons are abundantly produced in the TPC, and given their well known energy spectrum can be used to study MicroBooNE's detector response to low-energy electrons (electrons with energies up to ~50 MeV). Read More

2017Mar
Authors: MicroBooNE collaboration, P. Abratenko, R. Acciarri, C. Adams, R. An, J. Asaadi, M. Auger, L. Bagby, S. Balasubramanian, B. Baller, C. Barnes, G. Barr, M. Bass, F. Bay, M. Bishai, A. Blake, T. Bolton, L. Bugel, L. Camilleri, D. Caratelli, B. Carls, R. Castillo Fernandez, F. Cavanna, H. Chen, E. Church, D. Cianci, E. Cohen, G. H. Collin, J. M. Conrad, M. Convery, J. I. Crespo-Anadon, M. Del Tutto, D. Devitt, S. Dytman, B. Eberly, A. Ereditato, L. Escudero Sanchez, J. Esquivel, B. T. Fleming, W. Foreman, A. P. Furmanski, D. Garcia-Gamez, G. T. Garvey, V. Genty, D. Goeldi, S. Gollapinni, N. Graf, E. Gramellini, H. Greenlee, R. Grosso, R. Guenette, A. Hackenburg, P. Hamilton, O. Hen, J. Hewes, C. Hill, J. Ho, G. Horton-Smith, E. -C. Huang, C. James, J. Jan de Vries, C. -M. Jen, L. Jiang, R. A. Johnson, B. J. P. Jones, J. Joshi, H. Jostlein, D. Kaleko, L. N. Kalousis, G. Karagiorgi, W. Ketchum, B. Kirby, M. Kirby, T. Kobilarcik, I. Kreslo, A. Laube, Y. Li, A. Lister, B. R. Littlejohn, S. Lockwitz, D. Lorca, W. C. Louis, M. Luethi, B. Lundberg, X. Luo, A. Marchionni, C. Mariani, J. Marshall, D. A. Martinez Caicedo, V. Meddage, T. Miceli, G. B. Mills, J. Moon, M. Mooney, C. D. Moore, J. Mousseau, R. Murrells, D. Naples, P. Nienaber, J. Nowak, O. Palamara, V. Paolone, V. Papavassiliou, S. F. Pate, Z. Pavlovic, E. Piasetzky, D. Porzio, G. Pulliam, X. Qian, J. L. Raaf, A. Rafique, L. Rochester, C. Rudolf von Rohr, B. Russell, D. W. Schmitz, A. Schukraft, W. Seligman, M. H. Shaevitz, J. Sinclair, E. L. Snider, M. Soderberg, S. Soldner-Rembold, S. R. Soleti, P. Spentzouris, J. Spitz, J. St. John, T. Strauss, A. M. Szelc, N. Tagg, K. Terao, M. Thomson, M. Toups, Y. -T. Tsai, S. Tufanli, T. Usher, R. G. Van de Water, B. Viren, M. Weber, J. Weston, D. A. Wickremasinghe, S. Wolbers, T. Wongjirad, K. Woodruff, T. Yang, L. Yates, G. P. Zeller, J. Zennamo, C. Zhang

We discuss a technique for measuring a charged particle's momentum by means of multiple Coulomb scattering (MCS) in the MicroBooNE liquid argon time projection chamber (LArTPC). This method does not require the full particle ionization track to be contained inside of the detector volume as other track momentum reconstruction methods do (range-based momentum reconstruction and calorimetric momentum reconstruction). We motivate use of this technique, describe a tuning of the underlying phenomenological formula, quantify its performance on fully contained beam-neutrino-induced muon tracks both in simulation and in data, and quantify its performance on exiting muon tracks in simulation. Read More

2016Dec
Authors: MicroBooNE Collaboration, R. Acciarri, C. Adams, R. An, A. Aparicio, S. Aponte, J. Asaadi, M. Auger, N. Ayoub, L. Bagby, B. Baller, R. Barger, G. Barr, M. Bass, F. Bay, K. Biery, M. Bishai, A. Blake, V. Bocean, D. Boehnlein, V. D. Bogert, T. Bolton, L. Bugel, C. Callahan, L. Camilleri, D. Caratelli, B. Carls, R. Castillo Fernandez, F. Cavanna, S. Chappa, H. Chen, K. Chen, C. Y. Chi, C. S. Chiu, E. Church, D. Cianci, G. H. Collin, J. M. Conrad, M. Convery, J. Cornele, P. Cowan, J. I. Crespo-Anadon, G. Crutcher, C. Darve, R. Davis, M. Del Tutto, D. Devitt, S. Duffin, S. Dytman, B. Eberly, A. Ereditato, D. Erickson, L. Escudero Sanchez, J. Esquivel, S. Farooq, J. Farrell, D. Featherston, B. T. Fleming, W. Foreman, A. P. Furmanski, V. Genty, M. Geynisman, D. Goeldi, B. Goff, S. Gollapinni, N. Graf, E. Gramellini, J. Green, A. Greene, H. Greenlee, T. Griffin, R. Grosso, R. Guenette, A. Hackenburg, R. Haenni, P. Hamilton, P. Healey, O. Hen, E. Henderson, J. Hewes, C. Hill, K. Hill, L. Himes, J. Ho, G. Horton-Smith, D. Huffman, C. M. Ignarra, C. James, E. James, J. Jan de Vries, W. Jaskierny, C. M. Jen, L. Jiang, B. Johnson, M. Johnson, R. A. Johnson, B. J. P. Jones, J. Joshi, H. Jostlein, D. Kaleko, L. N. Kalousis, G. Karagiorgi, T. Katori, P. Kellogg, W. Ketchum, J. Kilmer, B. King, B. Kirby, M. Kirby, E. Klein, T. Kobilarcik, I. Kreslo, R. Krull, R. Kubinski, G. Lange, F. Lanni, A. Lathrop, A. Laube, W. M. Lee, Y. Li, D. Lissauer, A. Lister, B. R. Littlejohn, S. Lockwitz, D. Lorca, W. C. Louis, G. Lukhanin, M. Luethi, B. Lundberg, X. Luo, G. Mahler, I. Majoros, D. Makowiecki, A. Marchionni, C. Mariani, D. Markley, J. Marshall, D. A. Martinez Caicedo, K. T. McDonald, D. McKee, A. McLean, J. Mead, V. Meddage, T. Miceli, G. B. Mills, W. Miner, J. Moon, M. Mooney, C. D. Moore, Z. Moss, J. Mousseau, R. Murrells, D. Naples, P. Nienaber, B. Norris, N. Norton, J. Nowak, M. OBoyle, T. Olszanowski, O. Palamara, V. Paolone, V. Papavassiliou, S. F. Pate, Z. Pavlovic, R. Pelkey, M. Phipps, S. Pordes, D. Porzio, G. Pulliam, X. Qian, J. L. Raaf, V. Radeka, A. Rafique, R. A Rameika, B. Rebel, R. Rechenmacher, S. Rescia, L. Rochester, C. Rudolf von Rohr, A. Ruga, B. Russell, R. Sanders, W. R. Sands III, M. Sarychev, D. W. Schmitz, A. Schukraft, R. Scott, W. Seligman, M. H. Shaevitz, M. Shoun, J. Sinclair, W. Sippach, T. Smidt, A. Smith, E. L. Snider, M. Soderberg, M. Solano-Gonzalez, S. Soldner-Rembold, S. R. Soleti, J. Sondericker, P. Spentzouris, J. Spitz, J. St. John, T. Strauss, K. Sutton, A. M. Szelc, K. Taheri, N. Tagg, K. Tatum, J. Teng, K. Terao, M. Thomson, C. Thorn, J. Tillman, M. Toups, Y. T. Tsai, S. Tufanli, T. Usher, M. Utes, R. G. Van de Water, C. Vendetta, S. Vergani, E. Voirin, J. Voirin, B. Viren, P. Watkins, M. Weber, T. Wester, J. Weston, D. A. Wickremasinghe, S. Wolbers, T. Wongjirad, K. Woodruff, K. C. Wu, T. Yang, B. Yu, G. P. Zeller, J. Zennamo, C. Zhang, M. Zuckerbrot

This paper describes the design and construction of the MicroBooNE liquid argon time projection chamber and associated systems. MicroBooNE is the first phase of the Short Baseline Neutrino program, located at Fermilab, and will utilize the capabilities of liquid argon detectors to examine a rich assortment of physics topics. In this document details of design specifications, assembly procedures, and acceptance tests are reported. Read More

2016Nov
Authors: MicroBooNE collaboration, R. Acciarri, C. Adams, R. An, J. Asaadi, M. Auger, L. Bagby, B. Baller, G. Barr, M. Bass, F. Bay, M. Bishai, A. Blake, T. Bolton, L. Bugel, L. Camilleri, D. Caratelli, B. Carls, R. Castillo Fernandez, F. Cavanna, H. Chen, E. Church, D. Cianci, G. H. Collin, J. M. Conrad, M. Convery, J. I. Crespo-Anadón, M. Del Tutto, D. Devitt, S. Dytman, B. Eberly, A. Ereditato, L. Escudero Sanchez, J. Esquivel, B. T. Fleming, W. Foreman, A. P. Furmanski, G. T. Garvey, V. Genty, D. Goeldi, S. Gollapinni, N. Graf, E. Gramellini, H. Greenlee, R. Grosso, R. Guenette, A. Hackenburg, P. Hamilton, O. Hen, J. Hewes, C. Hill, J. Ho, G. Horton-Smith, C. James, J. Jan de Vries, C. -M. Jen, L. Jiang, R. A. Johnson, B. J. P. Jones, J. Joshi, H. Jostlein, D. Kaleko, G. Karagiorgi, W. Ketchum, B. Kirby, M. Kirby, T. Kobilarcik, I. Kreslo, A. Laube, Y. Li, A. Lister, B. R. Littlejohn, S. Lockwitz, D. Lorca, W. C. Louis, M. Luethi, B. Lundberg, X. Luo, A. Marchionni, C. Mariani, J. Marshall, D. A. Martinez Caicedo, V. Meddage, T. Miceli, G. B. Mills, J. Moon, M. Mooney, C. D. Moore, J. Mousseau, R. Murrells, D. Naples, P. Nienaber, J. Nowak, O. Palamara, V. Paolone, V. Papavassiliou, S. F. Pate, Z. Pavlovic, D. Porzio, G. Pulliam, X. Qian, J. L. Raaf, A. Rafique, L. Rochester, C. Rudolf von Rohr, B. Russell, D. W. Schmitz, A. Schukraft, W. Seligman, M. H. Shaevitz, J. Sinclair, E. L. Snider, M. Soderberg, S. Söldner-Rembold, S. R. Soleti, P. Spentzouris, J. Spitz, J. St. John, T. Strauss, A. M. Szelc, N. Tagg, K. Terao, M. Thomson, M. Toups, Y. -T. Tsai, S. Tufanli, T. Usher, R. G. Van de Water, B. Viren, M. Weber, J. Weston, D. A. Wickremasinghe, S. Wolbers, T. Wongjirad, K. Woodruff, T. Yang, G. P. Zeller, J. Zennamo, C. Zhang

We present several studies of convolutional neural networks applied to data coming from the MicroBooNE detector, a liquid argon time projection chamber (LArTPC). The algorithms studied include the classification of single particle images, the localization of single particle and neutrino interactions in an image, and the detection of a simulated neutrino event overlaid with cosmic ray backgrounds taken from real detector data. These studies demonstrate the potential of convolutional neural networks for particle identification or event detection on simulated neutrino interactions. Read More

In this paper we describe how the readout planes for the MicroBooNE Time Projection Chamber were constructed, assembled and installed. We present the individual wire preparation using semi-automatic winding machines and the assembly of wire carrier boards. The details of the wire installation on the detector frame and the tensioning of the wires are given. Read More

The study of neutrino-nucleus interactions has recently received renewed attention due to their importance in interpreting the neutrino oscillation data. Over the past few years, there has been continuous disagreement between neutrino cross section data and predictions due to lack of accurate nuclear models suitable for modern experiments which use heavier nuclear targets. Also, the current short and long-baseline neutrino oscillation experiments focus in the few GeV region where several distinct neutrino processes come into play resulting in complex nuclear effects. Read More

Over the last two decades, several experiments have reported anomalous results that could be hinting at the exciting possibility of sterile neutrino states in the $eV^{2}$ mass scale. Liquid Argon Time Projection Chambers (LArTPCs) are a particularly promising technology to explore this physics due to their fine-grained tracking and exceptional calorimetric capabilities. The MicroBooNE experiment, a 170 ton LArTPC scheduled to start taking data very soon with Fermilab's Booster Neutrino Beam (BNB), will combine LArTPC development with the main physics goal of understanding the low-energy electromagnetic anomaly seen by the MiniBooNE experiment. Read More

2015Mar
Authors: R. Acciarri1, C. Adams2, R. An3, C. Andreopoulos4, A. M. Ankowski5, M. Antonello6, J. Asaadi7, W. Badgett8, L. Bagby9, B. Baibussinov10, B. Baller11, G. Barr12, N. Barros13, M. Bass14, V. Bellini15, P. Benetti16, S. Bertolucci17, K. Biery18, H. Bilokon19, M. Bishai20, A. Bitadze21, A. Blake22, F. Boffelli23, T. Bolton24, M. Bonesini25, J. Bremer26, S. J. Brice27, C. Bromberg28, L. Bugel29, E. Calligarich30, L. Camilleri31, D. Caratelli32, B. Carls33, F. Cavanna34, S. Centro35, H. Chen36, C. Chi37, E. Church38, D. Cianci39, A. G. Cocco40, G. H. Collin41, J. M. Conrad42, M. Convery43, G. De Geronimo44, A. Dermenev45, R. Dharmapalan46, S. Dixon47, Z. Djurcic48, S. Dytmam49, B. Eberly50, A. Ereditato51, J. Esquivel52, J. Evans53, A. Falcone54, C. Farnese55, A. Fava56, A. Ferrari57, B. T. Fleming58, W. M. Foreman59, J. Freestone60, T. Gamble61, G. Garvey62, V. Genty63, M. Geynisman64, D. Gibin65, S. Gninenko66, D. Göldi67, S. Gollapinni68, N. Golubev69, M. Graham70, E. Gramellini71, H. Greenlee72, R. Grosso73, R. Guenette74, A. Guglielmi75, A. Hackenburg76, R. Hänni77, O. Hen78, J. Hewes79, J. Ho80, G. Horton-Smith81, J. Howell82, A. Ivashkin83, C. James84, C. M. Jen85, R. A. Johnson86, B. J. P. Jones87, J. Joshi88, H. Jostlein89, D. Kaleko90, L. N. Kalousis91, G. Karagiorgi92, W. Ketchum93, B. Kirby94, M. Kirby95, M. Kirsanov96, J. Kisiel97, J. Klein98, J. Klinger99, T. Kobilarcik100, U. Kose101, I. Kreslo102, V. A. Kudryavtsev103, Y. Li104, B. Littlejohn105, D. Lissauer106, P. Livesly107, S. Lockwitz108, W. C. Louis109, M. Lüthi110, B. Lundberg111, F. Mammoliti112, G. Mannocchi113, A. Marchionni114, C. Mariani115, J. Marshall116, K. Mavrokoridis117, N. McCauley118, N. McConkey119, K. McDonald120, V. Meddage121, A. Menegolli122, G. Meng123, I. Mercer124, T. Miao125, T. Miceli126, G. B. Mills127, D. Mladenov128, C. Montanari129, D. Montanari130, J. Moon131, M. Mooney132, C. Moore133, Z. Moss134, M. H. Moulai135, S. Mufson136, R. Murrells137, D. Naples138, M. Nessi139, M. Nicoletto140, P. Nienaber141, B. Norris142, F. Noto143, J. Nowak144, S. Pal145, O. Palamara146, V. Paolone147, V. Papavassiliou148, S. Pate149, J. Pater150, Z. Pavlovic151, J. Perkin152, P. Picchi153, F. Pietropaolo154, P. Płoński155, S. Pordes156, R. Potenza157, G. Pulliam158, X. Qian159, L. Qiuguang160, J. L. Raaf161, V. Radeka162, R. Rameika163, A. Rappoldi164, G. L. Raselli165, P. N. Ratoff166, B. Rebel167, M. Richardson168, L. Rochester169, M. Rossella170, C. Rubbia171, C. Rudolf von Rohr172, B. Russell173, P. Sala174, A. Scaramelli175, D. W. Schmitz176, A. Schukraft177, W. Seligman178, M. H. Shaevitz179, B. Sippach180, E. Snider181, J. Sobczyk182, M. Soderberg183, S. Söldner-Rembold184, M. Spanu185, J. Spitz186, N. Spooner187, D. Stefan188, J. St. John189, T. Strauss190, R. Sulej191, C. M. Sutera192, A. M. Szelc193, N. Tagg194, C. E. Taylor195, K. Terao196, M. Thiesse197, L. Thompson198, M. Thomson199, C. Thorn200, M. Torti201, F. Tortorici202, M. Toups203, C. Touramanis204, Y. Tsai205, T. Usher206, R. Van de Water207, F. Varanini208, S. Ventura209, C. Vignoli210, T. Wachala211, M. Weber212, D. Whittington213, P. Wilson214, S. Wolbers215, T. Wongjirad216, K. Woodruff217, M. Xu218, T. Yang219, B. Yu220, A. Zani221, G. P. Zeller222, J. Zennamo223, C. Zhang224
Affiliations: 1MicroBooNE Collaboration, 2LAr1-ND Collaboration, 3MicroBooNE Collaboration, 4LAr1-ND Collaboration, 5LAr1-ND Collaboration, 6ICARUS-WA104 Collaboration, 7LAr1-ND Collaboration, 8LAr1-ND Collaboration, 9LAr1-ND Collaboration, 10ICARUS-WA104 Collaboration, 11LAr1-ND Collaboration, 12MicroBooNE Collaboration, 13LAr1-ND Collaboration, 14LAr1-ND Collaboration, 15ICARUS-WA104 Collaboration, 16ICARUS-WA104 Collaboration, 17ICARUS-WA104 Collaboration, 18ICARUS-WA104 Collaboration, 19ICARUS-WA104 Collaboration, 20LAr1-ND Collaboration, 21LAr1-ND Collaboration, 22MicroBooNE Collaboration, 23ICARUS-WA104 Collaboration, 24MicroBooNE Collaboration, 25ICARUS-WA104 Collaboration, 26ICARUS-WA104 Collaboration, 27MicroBooNE Collaboration, 28MicroBooNE Collaboration, 29LAr1-ND Collaboration, 30ICARUS-WA104 Collaboration, 31LAr1-ND Collaboration, 32MicroBooNE Collaboration, 33MicroBooNE Collaboration, 34LAr1-ND Collaboration, 35ICARUS-WA104 Collaboration, 36LAr1-ND Collaboration, 37LAr1-ND Collaboration, 38LAr1-ND Collaboration, 39LAr1-ND Collaboration, 40ICARUS-WA104 Collaboration, 41LAr1-ND Collaboration, 42LAr1-ND Collaboration, 43MicroBooNE Collaboration, 44LAr1-ND Collaboration, 45ICARUS-WA104 Collaboration, 46LAr1-ND Collaboration, 47LAr1-ND Collaboration, 48LAr1-ND Collaboration, 49MicroBooNE Collaboration, 50MicroBooNE Collaboration, 51LAr1-ND Collaboration, 52LAr1-ND Collaboration, 53LAr1-ND Collaboration, 54ICARUS-WA104 Collaboration, 55ICARUS-WA104 Collaboration, 56ICARUS-WA104 Collaboration, 57ICARUS-WA104 Collaboration, 58LAr1-ND Collaboration, 59LAr1-ND Collaboration, 60LAr1-ND Collaboration, 61LAr1-ND Collaboration, 62LAr1-ND Collaboration, 63LAr1-ND Collaboration, 64ICARUS-WA104 Collaboration, 65ICARUS-WA104 Collaboration, 66ICARUS-WA104 Collaboration, 67LAr1-ND Collaboration, 68MicroBooNE Collaboration, 69ICARUS-WA104 Collaboration, 70MicroBooNE Collaboration, 71LAr1-ND Collaboration, 72LAr1-ND Collaboration, 73MicroBooNE Collaboration, 74LAr1-ND Collaboration, 75ICARUS-WA104 Collaboration, 76LAr1-ND Collaboration, 77LAr1-ND Collaboration, 78MicroBooNE Collaboration, 79MicroBooNE Collaboration, 80LAr1-ND Collaboration, 81MicroBooNE Collaboration, 82LAr1-ND Collaboration, 83ICARUS-WA104 Collaboration, 84LAr1-ND Collaboration, 85LAr1-ND Collaboration, 86MicroBooNE Collaboration, 87LAr1-ND Collaboration, 88MicroBooNE Collaboration, 89MicroBooNE Collaboration, 90MicroBooNE Collaboration, 91LAr1-ND Collaboration, 92LAr1-ND Collaboration, 93LAr1-ND Collaboration, 94MicroBooNE Collaboration, 95MicroBooNE Collaboration, 96ICARUS-WA104 Collaboration, 97ICARUS-WA104 Collaboration, 98LAr1-ND Collaboration, 99LAr1-ND Collaboration, 100MicroBooNE Collaboration, 101ICARUS-WA104 Collaboration, 102LAr1-ND Collaboration, 103LAr1-ND Collaboration, 104MicroBooNE Collaboration, 105MicroBooNE Collaboration, 106LAr1-ND Collaboration, 107LAr1-ND Collaboration, 108MicroBooNE Collaboration, 109LAr1-ND Collaboration, 110LAr1-ND Collaboration, 111MicroBooNE Collaboration, 112ICARUS-WA104 Collaboration, 113ICARUS-WA104 Collaboration, 114MicroBooNE Collaboration, 115LAr1-ND Collaboration, 116MicroBooNE Collaboration, 117LAr1-ND Collaboration, 118LAr1-ND Collaboration, 119LAr1-ND Collaboration, 120MicroBooNE Collaboration, 121MicroBooNE Collaboration, 122ICARUS-WA104 Collaboration, 123ICARUS-WA104 Collaboration, 124LAr1-ND Collaboration, 125LAr1-ND Collaboration, 126MicroBooNE Collaboration, 127LAr1-ND Collaboration, 128ICARUS-WA104 Collaboration, 129ICARUS-WA104 Collaboration, 130LAr1-ND Collaboration, 131LAr1-ND Collaboration, 132MicroBooNE Collaboration, 133LAr1-ND Collaboration, 134LAr1-ND Collaboration, 135MicroBooNE Collaboration, 136LAr1-ND Collaboration, 137MicroBooNE Collaboration, 138MicroBooNE Collaboration, 139ICARUS-WA104 Collaboration, 140ICARUS-WA104 Collaboration, 141MicroBooNE Collaboration, 142LAr1-ND Collaboration, 143ICARUS-WA104 Collaboration, 144LAr1-ND Collaboration, 145LAr1-ND Collaboration, 146LAr1-ND Collaboration, 147MicroBooNE Collaboration, 148MicroBooNE Collaboration, 149MicroBooNE Collaboration, 150LAr1-ND Collaboration, 151LAr1-ND Collaboration, 152LAr1-ND Collaboration, 153ICARUS-WA104 Collaboration, 154ICARUS-WA104 Collaboration, 155ICARUS-WA104 Collaboration, 156MicroBooNE Collaboration, 157MicroBooNE Collaboration, 158LAr1-ND Collaboration, 159LAr1-ND Collaboration, 160LAr1-ND Collaboration, 161MicroBooNE Collaboration, 162LAr1-ND Collaboration, 163LAr1-ND Collaboration, 164ICARUS-WA104 Collaboration, 165ICARUS-WA104 Collaboration, 166LAr1-ND Collaboration, 167MicroBooNE Collaboration, 168LAr1-ND Collaboration, 169MicroBooNE Collaboration, 170ICARUS-WA104 Collaboration, 171ICARUS-WA104 Collaboration, 172LAr1-ND Collaboration, 173LAr1-ND Collaboration, 174ICARUS-WA104 Collaboration, 175ICARUS-WA104 Collaboration, 176LAr1-ND Collaboration, 177MicroBooNE Collaboration, 178MicroBooNE Collaboration, 179LAr1-ND Collaboration, 180LAr1-ND Collaboration, 181ICARUS-WA104 Collaboration, 182ICARUS-WA104 Collaboration, 183LAr1-ND Collaboration, 184LAr1-ND Collaboration, 185ICARUS-WA104 Collaboration, 186LAr1-ND Collaboration, 187LAr1-ND Collaboration, 188ICARUS-WA104 Collaboration, 189MicroBooNE Collaboration, 190LAr1-ND Collaboration, 191ICARUS-WA104 Collaboration, 192ICARUS-WA104 Collaboration, 193LAr1-ND Collaboration, 194MicroBooNE Collaboration, 195LAr1-ND Collaboration, 196LAr1-ND Collaboration, 197LAr1-ND Collaboration, 198LAr1-ND Collaboration, 199LAr1-ND Collaboration, 200LAr1-ND Collaboration, 201ICARUS-WA104 Collaboration, 202ICARUS-WA104 Collaboration, 203LAr1-ND Collaboration, 204LAr1-ND Collaboration, 205MicroBooNE Collaboration, 206MicroBooNE Collaboration, 207LAr1-ND Collaboration, 208ICARUS-WA104 Collaboration, 209ICARUS-WA104 Collaboration, 210ICARUS-WA104 Collaboration, 211ICARUS-WA104 Collaboration, 212LAr1-ND Collaboration, 213LAr1-ND Collaboration, 214MicroBooNE Collaboration, 215MicroBooNE Collaboration, 216LAr1-ND Collaboration, 217MicroBooNE Collaboration, 218MicroBooNE Collaboration, 219MicroBooNE Collaboration, 220LAr1-ND Collaboration, 221ICARUS-WA104 Collaboration, 222LAr1-ND Collaboration, 223LAr1-ND Collaboration, 224MicroBooNE Collaboration

A Short-Baseline Neutrino (SBN) physics program of three LAr-TPC detectors located along the Booster Neutrino Beam (BNB) at Fermilab is presented. This new SBN Program will deliver a rich and compelling physics opportunity, including the ability to resolve a class of experimental anomalies in neutrino physics and to perform the most sensitive search to date for sterile neutrinos at the eV mass-scale through both appearance and disappearance oscillation channels. Using data sets of 6. Read More

We characterized a sample of metal-oxide resistors and measured their breakdown voltage in liquid argon by applying high voltage (HV) pulses over a 3 second period. This test mimics the situation in a HV-divider chain when a breakdown occurs and the voltage across resistors rapidly rise from the static value to much higher values. All resistors had higher breakdown voltages in liquid argon than their vendor ratings in air at room temperature. Read More

In this paper we demonstrate the capability of high voltage varistors and gas discharge tube arrestors for use as surge protection devices in liquid argon time projection chamber detectors. The insulating and clamping behavior of each type of device is characterized in air (room temperature), and liquid argon (90~K), and their robustness under high voltage and high energy surges in cryogenic conditions is verified. The protection of vulnerable components in liquid argon during a 150 kV high voltage discharge is also demonstrated. Read More