Your search keyword '"Torun Y"' showing total 354 results

51. Strangeness Enhancement in p-A Collisions: Consequences for the Interpretation of Strangeness Production in A-A Collisions

Author

Cole, B. A., Yang, X. H., Cianciolo, V., Frawley, A., Hartouni, E. P., Hiejima, H., Lebedev, A., Maeda, N., Mioduszewski, S., Read, K., Rosati, M., Soltz, R. A., Sorensen, S., Thomas, J. H., Torun, Y., Winter, D., and Zajc, W. A.

Subjects

Nuclear Experiment

Abstract

Published measurements of semi-inclusive Lambda production in p-Au collisions at the AGS are used to estimate the yields of singly strange hadrons in nucleus-nucleus A-A collisions. Results of a described extrapolation technique are shown and compared to measurements of K+ production in Si-Al, Si-Au, and Au-Au collisions at the AGS and net Lambda production in Su-Su, S-Ag, Pb-Pb, and inclusive p-A collisions at the SPS. The extrapolations can account for more than 75% of the measured strange particle yields in all of the studied systems except for very central Au-Au collisions at the AGS where RQMD comparisons suggest large re-scattering contributions., Comment: 9 pages, 4 figures

Published

2005

52. Inclusive Soft Pion Production from 12.3 and 17.5 GeV/c Protons on Be, Cu and Au

Author

Chemakin, I., Cianciolo, V., Cole, B. A., Fernow, R. C., Frawley, A. D., Gilkes, M., Gushue, S., Hartouni, E. P., Hiejima, H., Justice, M., Kang, J. H., Kirk, H. G., Maeda, N., McGrath, R. L., Mioduszewski, S., Morrison, D., Moulson, M., Namboodiri, M. N., Palmer, R. B., Rai, G., Read, K., Remsberg, L., Rosati, M., Shin, Y., Soltz, R. A., Sorensen, S., Thomas, J. H., Torun, Y., Winter, D. L., Yang, X., Zajc, W. A., and Zhang, Y.

Subjects

Nuclear Experiment

Abstract

Differential cross-sections are presented for the inclusive production of charged pions in the momentum range 0.1 to 1.2 GeV/c in interactions of 12.3 and 17.5 GeV/c protons with Be, Cu, and Au targets. The measurements were made by Experiment 910 at the Alternating Gradient Synchrotron in Brookhaven National Laboratory. The cross-sections are presented as a function of pion total momentum and production polar angle $\theta$ with respect to the beam., Comment: 14 pages, 8 figures

Published

2001

53. Antiproton Production in $p+A$ Collisions at AGS Energies

Author

Chemakin, I., Cianciolo, V., Cole, B. A., Fernow, R., Frawley, A., Gilkes, M., Gushue, S., Hartouni, E., Hiejima, H., Justice, M., Kang, J. H., Keane, D., Kirk, H., Kreisler, M., Maeda, N., McGrath, R. L., Mioduszewski, S., Morrison, D., Moulson, M., Namboodiri, N., Rai, G., Read, K., Remsberg, L., Rosati, M., Shin, Y., Soltz, R., Sorensen, S., Thomas, J., Torun, Y., Winter, D., Yang, X., Zajc, W. A., and Zhang, Y.

Subjects

Nuclear Experiment

Abstract

Inclusive and semi-inclusive measurements are presented for antiproton ($\bar{p}$) production in proton-nucleus collisions at the AGS. The inclusive yields per event increase strongly with increasing beam energy and decrease slightly with increasing target mass. The $\bar{p}$ yield in 17.5 GeV/c p+Au collisions decreases with grey track multiplicity, $N_g$, for $N_g>0$, consistent with annihilation within the target nucleus. The relationship between $N_g$ and the number of scatterings of the proton in the nucleus is used to estimate the $\bar{p}$ annihilation cross section in the nuclear medium. The resulting cross section is at least a factor of five smaller than the free $\bar{p}-p$ annihilation cross section when assuming a small or negligible formation time. Only with a long formation time can the data be described with the free $\bar{p}-p$ annihilation cross section., Comment: 8 pages, 6 figures

Published

2001

54. Semi-Inclusive Lambda and Kshort Production in p-Au Collisions at 17.5 GeV/c

Author

Chemakin, I., Cianciolo, V., Cole, B. A., Fernow, R., Frawley, A. D., Gilkes, M., Gushue, S., Hartouni, E. P., Hiejima, H., Justice, M., Kang, J. H., Kirk, H., Maeda, N., Mioduszewski, S., Morrison, D., Moulson, M., Namboodiri, M. N., Rai, G., Read, K., Remsberg, L., Rosati, M., Shin, Y., Soltz, R. A., Sorensen, S., Thomas, J. H., Torun, Y., Winter, D., Yang, X., Zajc, W. A., and Zhang, Y.

Subjects

Nuclear Experiment

Abstract

The first detailed measurements of the centrality dependence of strangeness production in p-A collisions are presented. Lambda and Kshort dn/dy distributions from 17.5 GeV/c p-Au collisions are shown as a function of "grey" track multiplicity and the estimated number of collisions, nu, made by the proton. The nu dependence of the Lambda yield deviates from a scaling of p-p data by the number of participants, increasing faster than this scaling for nu<=5 and saturating for larger nu. A slower growth in Kshort multiplicity with nu is observed, consistent with a weaker nu dependence of K-Kbar production than Y-K production., Comment: 5 pages, 3 figures, formatted with RevTex, current version has enlarged figure catpions

Published

2000

55. Centrality dependence of Pi- Production and Stopping in p-A Collisions at 18 GeV/c

Author

Chemakin, I., Cianciolo, V., Cole, B. A., Fernow, R., Frawley, A., Gilkes, M., Gushue, S., Hartouni, E. P., Hiejima, H., Justice, M., Kang, J. H., Kirk, H., Maeda, N., Mioduszewski, S., Morrison, D., Moulson, M., Namboodiri, M. N., Rai, G., Read, K., Remsberg, L., Rosati, M., Shin, Y., Soltz, R. A., Sorensen, S., Thomas, J., Torun, Y., Winter, D., Yang, X., Zajc, W. A., and Zhang, Y.

Subjects

Nuclear Experiment

Abstract

First results are presented from BNL experiment E910 on pion production and stopping in proton-Be, Cu, and Au collisions at a beam momentum of 18 GeV/c. We characterize the centrality of the collisions using the measured number of "grey" tracks, Ngrey,and a derived quantity, nu, the number of inelastic nucleon-nucleon scatterings suffered by the projectile during the collision. We find that for the three targets the average backward rapidity shift of the leading proton follows a common trend versus nu with the projectile losing, on average, 2 units of rapidity in the first 2-3 scatterings. The average rapidity shift increases more slowly with subsequent scatterings reaching a maximum of 2.5 units. The pi- multiplicity measured within the E910 acceptance saturates with increasing nu in p-Au collisions while the pi- multiplicity in p-Be collisions increases faster with nu than expected from the wounded-nucleon model. Comparisons of our data with the RQMD cascade model suggest that in very central p-Au collisions most of the pions are produced near zero rapidity in the lab., Comment: 5 pages, 13 figures, submitted for publication to Phys. Rev. Lett., Formatted with RevTex

Published

1999

56. Measuring centrality with slow protons in proton-nucleus collisions at the AGS

Author

Chemakin, I., Cianciolo, V., Cole, B. A., Fernow, R., Frawley, A., Gilkes, M., Gushue, S., Hartouni, E. P., Hiejima, H., Justice, M., Kang, J. H., Kirk, H., Maeda, N., Mioduszewski, S., Morrison, D., Moulson, M., Namboodiri, M. N., Rai, G., Read, K., Remsberg, L., Rosati, M., Shin, Y., Soltz, R. A., Sorensen, S., Thomas, J., Torun, Y., Winter, D., Yang, X., Zajc, W. A., and Zhang, Y.

Subjects

Nuclear Experiment

Abstract

Experiment 910 has measured slow protons and deuterons from collisions of 18 GeV/c protons with Be, Cu, and Au targets at the BNL AGS. These correspond to the ``grey tracks'' first observed in emulsion experiments. We report on their momentum and angular distributions and investigate their use in measuring the centrality of a collision, as defined by the mean number of projectile-nucleon interactions. The relation between the measured Ngrey and the mean number of interactions, nu(Ngrey), is studied using several simple models, one newly proposed, as well as the RQMD event generator. RQMD is shown to reproduce the Ngrey distribution, and exhibits a dependence of Ngrey on centrality that is similar to the behavior of the simple models. We find a strong linear dependence of average Ngrey on nu, with a constant of proportionality that varies with target. For the Au target, we report a relative systematic error for extracting nu(Ngrey) that lies between 10% and 20% over all Ngrey., Comment: 24 pages, 19 figures, submitted for publication to Phys. Rev. C, Formatted with RevTex Replacement: Fix typos, improve display figures, twocolumn format

Published

1999

57. Recent RF Results from the MuCool Test Area

Author

Norem, J., Bross, A., Moretti, A., Qian, Z., Huang, D., Torun, Y., Rimmer, R., Li, D., and Zisman, M.

Subjects

Particle accelerators, RF

Abstract

The MuCool Experiment has been continuing to take data with 805 and 201 MHz cavities in the MuCool Test Area. The system uses rf power sources from the Fermilab Linac. Although the experimental program isprimarily aimed at the Muon Ionization Cooling Experiment (MICE), we have been studying the dependence of rf limits on frequency, cavity material, high magnetic fields, gas pressure, coatings, etc. with the general aim of understanding the basic mechanisms involved. The 201 MHz cavity, essentially a prototype for the MICE experiment, was made using cleaning techniques similar to those employed for superconducting cavities and operates at its design field with very little conditioning.

Published

2007

58. Decreased serum tweak and IFN- © levels may be related to attention deficit/hyperactivity disorder in children

Author

Unal, K., Tas Torun, Y., Ibrahimkhanli, L., and Kurt, Z.K.

Published

2024

59. Muon Collider Design

Author

Palmer, R., Sessler, A., Skrinsky, A., Tollestrup, A., Baltz, A., Caspi, S., Chen, P., Cheng, W-H., Cho, Y., Cline, D., Courant, E., Fernow, R., Gallardo, J., Garren, A., Gordon, H., Green, M., Gupta, R., Hershcovitch, A., Johnstone, C., Kahn, S., Kirk, H., Kycia, T., Lee, Y., Lissauer, D., Luccio, A., McInturff, A., Mills, F., Mokhov, N., Morgan, G., Neuffer, D., Ng, K-Y., Noble, R., Norem, J., Norum, B., Oide, K., Parsa, Z., Polychronakos, V., Popovic, M., Rehak, P., Roser, T., Rossmanith, R., Scanlan, R., Schachinger, L., Silvestrov, G., Stumer, I., Summers, D., Syphers, M., Takahashi, H., Torun, Y., Trbojevic, D., Turner, W., Van Ginneken, A., Vsevolozhskaya, T., Weggel, R., Willen, E., Willis, W., Winn, D., Wurtele, J., and Zhao, Y.

Subjects

Physics - Accelerator Physics

Abstract

Muon Colliders have unique technical and physics advantages and disadvantages when compared with both hadron and electron machines. They should thus be regarded as complementary. Parameters are given of 4 TeV and 0.5 TeV high luminosity \mu^+ \mu^- colliders, and of a 0.5 TeV lower luminosity demonstration machine. We discuss the various systems in such muon colliders, starting from the proton accelerator needed to generate the muons and proceeding through muon cooling, acceleration and storage in a collider ring. Detector background, polarization, and nonstandard operating conditions are discussed., Comment: 42 pages TeX file (aipproc style), 25 postscript figures. Submitted to the Proceedings of the Symposium on Physics Potential and Development of $\mu^+ \mu^-$ Colliders, San Francisco, CA Dec 13-15, 1995. Edited by D. Cline and D. Sanders

Published

1996

60. Beam Dynamics problems in a muon collider

Author

Palmer, R. B., Gallardo, J. C., Fernow, R. C., Kirk, H., Stumer, I., Lee, Y. Y., Syphers, M., Torun, Y., Winn, D., Neuffer, D., Cho, Y., Norem, J., Mokhov, N., Noble, R., Tollestrup, A., Scanlan, R., Caspi, S., and Napoly, O.

Subjects

Physics - Accelerator Physics

Abstract

We discuss the various beam dynamics problems in muon collider systems, starting from the proton accelerator needed to generate the muon beams and proceeding through the muon storage ring., Comment: Latex, 11 pages, submitted to ICFA Beam Dynamics Newsletter

Published

1995

61. MONTE CARLO SIMULATIONS OF MUON PRODUCTION

Author

Palmer, R. B., Gallardo, J. C., Fernow, R. C., Torun, Y., Neuffer, D., and Winn, D.

Subjects

Physics - Accelerator Physics

Abstract

Muon production requirements for a muon collider are presented. Production of muons from pion decay is studied. Lithium lenses and solenoids are considered for focussing pions from a target, and for matching the pions into a decay channel. Pion decay channels of alternating quadrupoles and long solenoids are compared. Monte Carlo simulations are presented for production of $\pi \rightarrow \mu $ by protons over a wide energy range, and criteria for choosing the best proton energy are discussed., Comment: Latex uses mu95.sty, 19 pages, 5 postscript figures. A postscript file can be seen at URL http://www.cap.bnl.gov/~cap/mumu/important.html Search for Publications

Published

1995

62. The rf experimental program in the fermilab mucool test area

Author

Norem, J., Sandstrom, R., Bross, A., Moretti, A., Qian, Z., Torun, Y., Rimmer, R., Li, D., Zisman, M.S., and Johnson, R.

Subjects

radio-frequency, rf, high-gradient

Abstract

The rf R&D program for high-gradient, low frequency cavities to be used in muon cooling systems is underway in the Fermilab MUCOOL Test Area. Cavities at 805 and 201 MHz are used for tests of conditioning techniques, surface modification and breakdown studies. This work has the Muon Ionization Cooling Experiment (MICE) as its immediate goal and efficient muon cooling systems for neutrino sources and muon colliders as the long term goal. We study breakdown and dark current production under a variety of conditions.

Published

2005

63. RF tests of an 805 MHz pillbox cavity at Lab G of Fermilab

Author

Li, Derun, Corlett, J., MacGill, R., Wallig, J., Zisman, M., Moretti, A., Qian, Z., Wu, V., Rimmer, R., Norem, J., and Torun, Y.

Subjects

Particle accelerators, muon cooling RF cavities magnet

Published

2003

64. Search for CP violation in hyperon decays.

Author

Zyla, Piotr, Chan, A., Chen, Y.C., Ho, C., Teng, P.K., Choong, W.S., Gidal, G., Fu, Y., Gu, P., Jones, T.D., Luk, K.B., Turko, B., James, C., Volk, J., Felix, J., Burnstein, R.A., Chakrovorty, A., Kaplan, D.M., Lederman, L.M., Luebke, W., Rajaram, D., Rubin, H.A., Solomey, N., Torun, Y., White, C.G., White, S.L., Leros, N., Perroud, J.P., Gustafson, H.R., Longo, M.J., Lopez, F., Park, H.K., Clark, K., Jenkins, M., Dukes, E.C., Durandet, C., Holmstrom, T., Huang, M., Lu, L., and Nelson, K.S.

Subjects

Physics of elementary particles and fields, Symmetry CP Hyperons

Abstract

Direct CP violation in nonleptonic hyperon decays can be established by comparing the decays of hyperons and anti-hyperons. For Xi decay to Lambda pi followed by Lambda to p pi, the proton distribution in the rest frame of Lambda is governed by the product of the decay parameters alXi alLam. The asymmetry A_Xi Lambda, proportional to the difference of alXi alLam of the hyperon and anti-hyperon decays, vanishes if CP is conserved. We report on an analysis of a fraction of 1997 and 1999 data collected by the Hyper CP (E871) collaboration during the fixed-target runs at Fermilab. The preliminary measurement of the asymmetry is AXiLam = [ -7 pm 12(rm stat) pm 6.2(rm sys) ] times 10-4, an order of magnitude better than the present limit.

Published

2002

65. 805 MHz and 201 MHz RF cavity development for MUCOOL

Author

Li, Derun, Corlett, J., Ladran, A., MacGill, R., Wallig, J., Zisman, M., Moretti, A., Rowe, A., Qian, Z.B., Wu, V., Rimmer, R.A., Norem, J., Summers, D., and Torun, Y.

Subjects

Particle accelerators, RF Cavity

Abstract

A muon cooling channel calls for very high accelerating gradient RF structures to restore the energy lost by muons in the absorbers. The RF structures have to be operated in a strong magnetic field and thus the use of superconducting RF cavities is excluded. To achieve a high shunt impedance while maintaining a large enough aperture to accommodate a large transverse emittance muon beam, the cavity design adopted is a pillbox-like geometry with thin Be foils to terminate the electromagnetic field at the cavity iris. The possibility of using grids of thin-walled metallic tubes for the termination is also being explored. Many of the RF-related issues for muon cooling channels are being studied both theoretically and experimentally using an 805 MHz cavity that has a pillbox-like geometry with thin Be windows to terminate the cavity aperture. The design and performance of this cavity are reported here. High-power RF tests of the 805 MHz cavity are in progress at Lab G in Fermilab. The cavity has exceeded its design gradient of 30 MV/m, reaching 34 MV/m without external magnetic field. No surface damage was observed at this gradient. The cavity is currently under conditioning at Lab G with an external magnetic field of 2.5 T. We also present here a 201 MHz cavity design for muoncooling channels. The proposed cavity design is also suitable for use in a proof-of-principle Muon Ionization Cooling Experiment (MICE).

Published

2002

66. Measurement of the <math><mrow><msub><mrow><mi>ν</mi></mrow><mrow><mi>e</mi></mrow></msub></mrow></math>-Nucleus Charged-Current Double-Differential Cross Section at <math><mrow><mo>⟨</mo><msub><mrow><mi>E</mi></mrow><mrow><mi>ν</mi></mrow></msub><mo>⟩</mo><mo>=</mo><mn>2.4</mn><mtext> </mtext><mtext> </mtext><mi>GeV</mi></mrow></math> Using NOvA

Author

Acero, M. A., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bernstein, R., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Booth, A. C., Bowles, R., Brahma, B., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Childress, S., Chatla, A., Chirco, R., Choudhary, B. C., Christensen, A., Coan, T. E., Colo, M., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Dueñas Tonguino, D., Dukes, E. C., Ehrlich, R., Elkins, M., Ewart, E., Feldman, G. J., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hausner, H., He, M., Heller, K., Hewes, V., Himmel, A., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kaplan, D. M., Kalitkina, A., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kralik, R., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lasorak, P., Lesmeister, J., Lin, S., Lister, A., Liu, J., Lokajicek, M., Lopez, J. M. C., Mahji, R., Magill, S., Manrique Plata, M., Mann, W. A., Manoharan, M. T., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Messier, M. D., Meyer, H., Miao, T., Mikola, V., Miller, W. H., Mishra, S., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mulder, K., Naples, D., Nath, A., Nayak, N., Nelleri, S., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ott, J., Pal, A., Paley, J., Panda, L., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Pobedimov, A., Porter, J. C. C., Rafique, A., Prais, L. R., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Rojas, P., Roy, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Sánchez Falero, S., Shanahan, P., Shukla, S., Sheshukov, A., Singh, I., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Sztuc, A., Talaga, R. L., Tapia Oregui, B., Tas, P., Temizel, B. N., Thakore, T., Thayyullathil, R. B., Thomas, J., Tiras, E., Tripathi, J., Trokan-Tenorio, J., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wieber, T., Wolcott, J., Wu, W., Xiao, Y., Yaeggy, B., Yallappa Dombara, A., Yankelevich, A., Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Abstract

The inclusive electron neutrino charged-current cross section is measured in the NOvA near detector using 8.02×1020 protons-on-target in the NuMI beam. The sample of GeV electron neutrino interactions is the largest analyzed to date and is limited by ≃17% systematic rather than the ≃7.4% statistical uncertainties. The double-differential cross section in final-state electron energy and angle is presented for the first time, together with the single-differential dependence on Q2 (squared four-momentum transfer) and energy, in the range 1 GeV≤Eν<6 GeV. Detailed comparisons are made to the predictions of the GENIE, GiBUU, NEUT, and NuWro neutrino event generators. The data do not strongly favor a model over the others consistently across all three cross sections measured, though some models have especially good or poor agreement in the single differential cross section vs Q2.

Published

2023

67. Measurement of νμ charged-current inclusive π0 production in the NOvA near detector

Author

Acero, M. A., Adamson, P., Agam, G., Aliaga, L., Alion, T., Allakhverdian, V., Altakarli, S., Anfimov, N., Antoshkin, A., Asquith, L., Arrieta-Diaz, E., Aurisano, A., Back, A., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bour, P., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Campbell, M., Carroll, T. J., Catano-Mur, E., Childress, S., Choudhary, B. C., Chowdhury, B., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Dharmapalan, R., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Dukes, E. C., Dueñas Tonguino, D., Dung, P., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Filip, P., Flanagan, W., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Hewes, V., Himmel, A., Holin, A., Howard, B., Huang, J., Hylen, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kreymer, A., Kubu, M., Kullenberg, Ch., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Li, L., Lin, S., Lister, A., Lokajicek, M., Luchuk, S., Maan, K., Magill, S., Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mufson, S., Mulder, K., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Nikseresht, G., Niner, E., Norman, A., Norrick, A., Nosek, T., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Pershey, D., Petrova, O., Petti, R., Phan, D. D., Phan-Budd, S., Plunkett, R. K., Potukuchi, B., Principato, C., Psihas, F., Radovic, A., Rafique, A., Raj, V., Rameika, R. A., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Sánchez Falero, S., Seong, I. S., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Talaga, R. L., Tapia Oregui, B., Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., While, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Yallappa Dombara, A., Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Abstract

Cross sections for the interaction νμA→μ−π0X with neutrino energies between 1 and 5 GeV are measured using a sample of 165,000 selected events collected in the NOvA experiment’s near detector, a hydrocarbon-based detector exposed to the Neutrinos from the Main Injector beam at the Fermi National Accelerator Laboratory. Results are presented as a flux-averaged total cross section and as differential cross sections in the momenta and angles of the outgoing muon and π0, the total four-momentum transfer, and the invariant mass of the hadronic system. Comparisons are made with predictions from a reference version of the genie neutrino interaction generator. The measured total cross section of (3.57±0.44)×10−39 cm2 is 7.5% higher than the genie prediction, but is consistent within experimental errors.

Published

2023

68. Results from the Daya Bay Reactor Neutrino Experiment

Author

Tsang, K.V., An, F.P., An, Q., Bai, J.Z., Balantekin, A.B., Band, H.R., Beriguete, W., Bishai, M., Blyth, S., Brown, R.L., Cao, G.F., Cao, J., Carr, R., Chan, W.T., Chang, J.F., Chang, Y., Chasman, C., Chen, H.S., Chen, H.Y., Chen, S.J., Chen, S.M., Chen, X.C., Chen, X.H., Chen, X.S., Chen, Y., Chen, Y.X., Cherwinka, J.J., Chu, M.C., Cummings, J.P., Deng, Z.Y., Ding, Y.Y., Diwan, M.V., Draeger, E., Du, X.F., Dwyer, D., Edwards, W.R., Ely, S.R., Fang, S.D., Fu, J.Y., Fu, Z.W., Ge, L.Q., Gill, R.L., Gonchar, M., Gong, G.H., Gong, H., Gornushkin, Y.A., Gu, W.Q., Guan, M.Y., Guo, X.H., Hackenburg, R.W., Hahn, R.L., Hans, S., Hao, H.F., He, M., He, Q., Heeger, K.M., Heng, Y.K., Hinrichs, P., Hor, Y.K., Hsiung, Y.B., Hu, B.Z., Hu, T., Huang, H.X., Huang, H.Z., Huang, X.T., Huber, P., Issakov, V., Isvan, Z., Jaffe, D.E., Jetter, S., Ji, X.L., Ji, X.P., Jiang, H.J., Jiao, J.B., Johnson, R.A., Kang, L., Kettell, S.H., Kramer, M., Kwan, K.K., Kwok, M.W., Kwok, T., Lai, C.Y., Lai, W.C., Lai, W.H., Lau, K., Lebanowski, L., Lee, J., Lei, R.T., Leitner, R., Leung, J.K.C., Leung, K.Y., Lewis, C.A., Li, F., Li, G.S., Li, Q.J., Li, W.D., Li, X.B., Li, X.N., Li, X.Q., Li, Y., Li, Z.B., Liang, H., Lin, C.J., Lin, G.L., Lin, S.K., Lin, Y.C., Ling, J.J., Link, J.M., Littenberg, L., Littlejohn, B.R., Liu, D.W., Liu, J.C., Liu, J.L., Liu, Y.B., Lu, C., Lu, H.Q., Luk, A., Luk, K.B., Ma, Q.M., Ma, X.B., Ma, X.Y., Ma, Y.Q., McDonald, K.T., McFarlane, M.C., McKeown, R.D., Meng, Y., Mohapatra, D., Nakajima, Y., Napolitano, J., Naumov, D., Nemchenok, I., Ngai, H.Y., Ngai, W.K., Nie, Y.B., Ning, Z., Ochoa-Ricoux, J.P., Olshevski, A., Patton, S., Pec, V., Peng, J.C., Piilonen, L.E., Pinsky, L., Pun, C.S.J., Qi, F.Z., Qi, M., Qian, X., Raper, N., Ren, J., Rosero, R., Roskovec, B., Ruan, X.C., Shao, B.B., Shih, K., Steiner, H., Sun, G.X., Sun, J.L., Tagg, N., Tam, Y.H., Tanaka, H.K., Tang, X., Themann, H., Torun, Y., Trentalange, S., Tsai, O., Tsang, R.H.M., Tull, C.E., Tung, Y.C., Viren, B., Vorobel, V., Wang, C.H., Wang, L.S., Wang, L.Y., Wang, L.Z., Wang, M., Wang, N.Y., Wang, R.G., Wang, W., Wang, X., Wang, Y.F., Wang, Z., Wang, Z.M., Webber, D.M., Wei, H.Y., Wei, Y.D., Wen, L.J., Whisnant, K., White, C.G., Whitehead, L., Williamson, Y., Wise, T., Wong, H.L.H., Worcester, E.T., Wu, F.F., Wu, Q., Xi, J.B., Xia, D.M., Xing, Z.Z., Xu, J., Xu, J.L., Xu, Y., Xue, T., Yang, C.G., Yang, L., Ye, M., Yeh, M., Yeh, Y.S., Young, B.L., Yu, Z.Y., Zhan, L., Zhang, C., Zhang, F.H., Zhang, J.W., Zhang, Q.M., Zhang, S.H., Zhang, Y.C., Zhang, Y.H., Zhang, Y.X., Zhang, Z.J., Zhang, Z.P., Zhang, Z.Y., Zhao, J., Zhao, Q.W., Zhao, Y.B., Zheng, L., Zhong, W.L., Zhou, L., Zhou, Z.Y., Zhuang, H.L., and Zou, J.H.

Published

2014

69. Improved measurement of neutrino oscillation parameters by the NOvA experiment

Author

Acero, M. A., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bernstein, R., Bhatnagar, V., Bhattarai, D., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Choudhary, B. C., Christensen, A., Coan, T. E., Colo, M., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dukes, E. C., Duyang, H., Ehrlich, R., Elkins, M., Ewart, E., Feldman, G. J., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hausner, H., He, M., Heller, K., Hewes, J., Himmel, A., Holin, A., Huang, J., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kaplan, D. M., Kalitkina, A., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kralik, R., Kullenberg, Ch, Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lasorak, P., Lesmeister, J., Lin, S., Lister, A., Liu, J., Lokajicek, M., Magill, S., Plata, M. Manrique, Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mufson, S., Mulder, K., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ott, J., Paley, J., Patterson, R. B., Pawloski, G., Olga Petrova, Petti, R., Phan, D. D., Plunkett, R. K., Porter, J. C. C., Rafique, A., Psihas, F., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Rojas, P., Roy, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Sztuc, A., Talaga, R. L., Oregui, B. Tapia, Tas, P., Thakore, T., Thayyullathil, R. B., Thomas, J., Tiras, E., Tripathi, J., Trokan-Tenorio, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Wu, W., Xiao, Y., Dombara, A. Yallappa, Yankelevich, A., Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., Zwaska, R., and Group, R. C.

Subjects

High Energy Physics - Experiment (hep-ex), High Energy Physics::Phenomenology, FOS: Physical sciences, High Energy Physics::Experiment, High Energy Physics - Experiment

Abstract

We present new $\nu_\mu\rightarrow\nu_e$, $\nu_\mu\rightarrow\nu_\mu$, $\overline{\nu}_\mu\rightarrow\overline{\nu}_e$, and $\overline{\nu}_\mu\rightarrow\overline{\nu}_\mu$ oscillation measurements by the NOvA experiment, with a 50% increase in neutrino-mode beam exposure over the previously reported results. The additional data, combined with previously published neutrino and antineutrino data, are all analyzed using improved techniques and simulations. A joint fit to the $\nu_e$, $\nu_\mu$, $\overline{\nu}_e$, and $\overline{\nu}_\mu$ candidate samples within the 3-flavor neutrino oscillation framework continues to yield a best-fit point in the normal mass ordering and the upper octant of the $\theta_{23}$ mixing angle, with $\Delta m^{2}_{32} = (2.41\pm0.07)\times 10^{-3}$ eV$^2$ and $\sin^2\theta_{23} = 0.57^{+0.03}_{-0.04}$. The data disfavor combinations of oscillation parameters that give rise to a large asymmetry in the rates of $\nu_e$ and $\overline{\nu}_e$ appearance. This includes values of the CP-violating phase in the vicinity of $\delta_\text{CP} = \pi/2$ which are excluded by $>3\sigma$ for the inverted mass ordering, and values around $\delta_\text{CP} = 3\pi/2$ in the normal ordering which are disfavored at 2$\sigma$ confidence., Comment: 11 pages, 6 figures. Supplementary material attached (7 figures)

Published

2022

70. H Dibaryon Search in p-A Collisions at the AGS

Author

Frawley, Anthony D., Chemakin, I., Cianciolo, V., Cole, B. A., Fernow, R., Frawley, A. D., Gilkes, M., Gushue, S., Hartouni, E., Hiejima, H., Justice, M., Kang, J. H., Keane, D., Kreisler, M., Kirk, H., Maeda, N., McGrath, R. L., Mioduszewski, S., Morrison, D., Moulson, M., Namboodiri, N., Read, K., Remsberg, L. R., Rai, G., Rosati, M., Shin, Y. H., Soltz, R., Sorenson, S., Thomas, J., Torun, Y., Winter, D., Yang, X., Zajc, W. A., Zhang, Y., Bauer, Wolfgang, editor, and Ritter, Hans-Georg, editor

Published

1998

71. Extended search for supernovalike neutrinos in NOvA coincident with LIGO/Virgo detections

Author

Acero, M. A., Adamson, P., Aliaga, L., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Choudhary, B. C., Christensen, A., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Dueñas Tonguino, D., Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Elkins, M., Ewart, E., Feldman, G. J., Filip, P., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Hausner, H., Heller, K., Hewes, J., Himmel, A., Holin, A., Huang, J., Jargowsky, B., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Kalitkina, A., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kralik, R., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lasorak, P., Lesmeister, J., Lin, S., Lister, A., Liu, J., Lokajicek, M., Magill, S., Manrique Plata, M., Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mu, W., Mualem, L., Muether, M., Mufson, S., Mulder, K., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Oh, H., Olshevskiy, A., Olson, T., Ott, J., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Phan, D. D., Plunkett, R. K., Porter, J. C. C., Rafique, A., Psihas, F., Raj, V., Rajaoalisoa, M., Ramson, B., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Sánchez Falero, S., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Tapia Oregui, B., Tas, P., Thakore, T., Thayyullathil, R. B., Thomas, J., Tiras, E., Tripathi, J., Trokan-Tenorio, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Wu, W., Xiao, Y., Yallappa Dombara, A., Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

Physics, High Energy Astrophysical Phenomena (astro-ph.HE), Gravitational wave, Research areas, Physics::Instrumentation and Detectors, Astrophysics::High Energy Astrophysical Phenomena, Detector, Astronomy, FOS: Physical sciences, Nova (laser), Astrophysics::Cosmology and Extragalactic Astrophysics, LIGO, High Energy Physics - Experiment, General Relativity and Quantum Cosmology, High Energy Physics - Experiment (hep-ex), Neutrino detector, Coincident, High Energy Physics::Experiment, Neutrino, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics::Galaxy Astrophysics

Abstract

A search is performed for supernova-like neutrino interactions coincident with 76 gravitational wave events detected by the LIGO/Virgo Collaboration. For 40 of these events, full readout of the time around the gravitational wave is available from the NOvA Far Detector. For these events, we set limits on the fluence of the sum of all neutrino flavors of $F < 7(4)\times 10^{10}\mathrm{cm}^{-2}$ at 90% C.L. assuming energy and time distributions corresponding to the Garching supernova models with masses 9.6(27)$\mathrm{M}_\odot$. Under the hypothesis that any given gravitational wave event was caused by a supernova, this corresponds to a distance of $r > 29(50)$kpc at 90% C.L. Weaker limits are set for other gravitational wave events with partial Far Detector data and/or Near Detector data., 10 pages, 2 figures

Published

2021

72. Demonstration of cooling by the Muon Ionization Cooling Experiment

Author

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

Subjects

Physics::Instrumentation and Detectors, General Science & Technology, Library science, 01 natural sciences, 7. Clean energy, Article, PHYSICS, DESIGN, 0103 physical sciences, media_common.cataloged_instance, Ionization cooling, High Energy Physics, Physics::Atomic Physics, European union, Experimental nuclear physics, 010306 general physics, QC, media_common, physics.acc-ph, Multidisciplinary, Science & Technology, 010308 nuclear & particles physics, hep-ex, MICE collaboration, Chinese academy of sciences, Accelerators and Storage Rings, Mechanical engineering, Multidisciplinary Sciences, Experimental High Energy Physics, Science & Technology - Other Topics, Physics::Accelerator Physics, Christian ministry, High Energy Physics::Experiment, Experimental particle physics, Particle Physics - Experiment

Abstract

The use of accelerated beams of electrons, protons or ions has furthered the development of nearly every scientific discipline. However, high-energy muon beams of equivalent quality have not yet been delivered. Muon beams can be created through the decay of pions produced by the interaction of a proton beam with a target. Such ‘tertiary’ beams have much lower brightness than those created by accelerating electrons, protons or ions. High-brightness muon beams comparable to those produced by state-of-the-art electron, proton and ion accelerators could facilitate the study of lepton–antilepton collisions at extremely high energies and provide well characterized neutrino beams1–6. Such muon beams could be realized using ionization cooling, which has been proposed to increase muon-beam brightness7,8. Here we report the realization of ionization cooling, which was confirmed by the observation of an increased number of low-amplitude muons after passage of the muon beam through an absorber, as well as an increase in the corresponding phase-space density. The simulated performance of the ionization cooling system is consistent with the measured data, validating designs of the ionization cooling channel in which the cooling process is repeated to produce a substantial cooling effect9–11. The results presented here are an important step towards achieving the muon-beam quality required to search for phenomena at energy scales beyond the reach of the Large Hadron Collider at a facility of equivalent or reduced footprint6., Ionization cooling, a technique that delivers high-brightness muon beams for the study of phenomena at energy scales beyond those of the Large Hadron Collider, is demonstrated by the Muon Ionization Cooling Experiment.

Published

2020

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

Author

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

Subjects

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

Abstract

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

Published

2019

74. Search for slow magnetic monopoles with the NOvA detector on the surface

Author

NOvA Collaboration, Acero, M. A., Adamson, P., Aliaga, L., Alion, T., Allakhverdian, V., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bour, P., Bowles, R., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Childress, S., Choudhary, B. C., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Dolce, M., Doyle, D., Tonguino, D. Dueñas, Dung, P., Dukes, E. C., Duyang, H., Edayath, S., Ehrlich, R., Elkins, M., Feldman, G. J., Filip, P., Flanagan, W., Franc, J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hall, A., Hartnell, J., Hatcher, R., Heller, K., Hewes, V, Himmel, A., Holin, A., Huang, J., Hylen, J., Jarosz, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kullenberg, Ch., Kubu, M., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Li, L., Lin, S., Lister, A., Lokajicek, M., Luchuk, S., Magill, S., Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Morozova, A., Mualem, L., Muether, M., Mufson, S., Mulder, K., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Plunkett, R. K., Rafique, A., Raj, V., Ramson, B., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Falero, S. Sánchez, Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Swain, S., Sweeney, C., Oregui, B. Tapia, Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Trokan-Tenorio, J., Torun, Y., Urheim, J., Vahle, P., Vallari, Z., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Wang, Z., Warburton, T. K., Wetstein, M., Whittington, D., Wickremasinghe, D. A., Wojcicki, S. G., Wolcott, J., Xiao, Y., Dombara, A. Yallappa, Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Physics, Physics - Instrumentation and Detectors, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Detector, Magnetic monopole, FOS: Physical sciences, Flux, Instrumentation and Detectors (physics.ins-det), Electron, Nova (laser), Scintillator, 01 natural sciences, High Energy Physics - Experiment, Nuclear physics, High Energy Physics - Experiment (hep-ex), Overburden, 0103 physical sciences, Neutrino, Astrophysics - High Energy Astrophysical Phenomena, 010306 general physics

Abstract

We report a search for a magnetic monopole component of the cosmic-ray flux in a 95-day exposure of the NOvA experiment's Far Detector, a 14 kt segmented liquid scintillator detector designed primarily to observe GeV-scale electron neutrinos. No events consistent with monopoles were observed, setting an upper limit on the flux of $2\times 10^{-14} \mathrm{cm^{-2}s^{-1}sr^{-1}}$ at 90% C.L. for monopole speed $6\times 10^{-4} < β< 5\times 10^{-3}$ and mass greater than $5\times 10^{8}$ GeV. Because of NOvA's small overburden of 3 meters-water equivalent, this constraint covers a previously unexplored low-mass region., 8 pages, 7 figures

Published

2021

75. Performance of the MICE diagnostic system

Author

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

Published

2021

76. Measurement of neutrino-induced neutral-current coherent π⁰ production in the NOvA near detector

Author

Acero, M. A., Adamson, P., Aliaga, L., Alion, T., Allakhverdian, V., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Basher, S., Bays, K., Behera, B., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bolshakova, A., Bour, P., Bromberg, C., Buchanan, N., Butkevich, A., Campbell, M., Carroll, T. J., Catano-Mur, E., Childress, S., Choudhary, B. C., Chowdhury, B., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Cronin-Hennessy, D., Davies, G. S., Derwent, P. F., Ding, P., Djurcic, Z., Doyle, D., Dukes, E. C., Dung, P., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Flanagan, W., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Himmel, A., Holin, A., Howard, B., Huang, J., Hylen, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kreymer, A., Kullenberg, Ch., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Lin, S., Lokajicek, M., Lozier, J., Luchuk, S., Maan, K., Magill, S., Mann, W. A., Marshak, M. L., Matveev, V., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mulder, K., Mufson, S., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Nosek, T., Oksuzian, Y., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Pershey, D., Petrova, O., Petti, R., Plunkett, R. K., Potukuchi, B., Principato, C., Psihas, F., Raj, V., Radovic, A., Rameika, R. A., Rebel, B., Rojas, P., Ryabov, V., Sachdev, K., Samoylov, O., Sanchez, M. C., Seong, I. S., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Talaga, R. L., Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vasel, J., Vinton, L., Vokac, P., Vrba, T., Wang, B., Warburton, T. K., Wetstein, M., While, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Yadav, N., Yallappa Dombara, A., Yang, S., Yonehara, K., Yu, S., Zalesak, J., Zamorano, B., and Zwaska, R.

Subjects

Physics::Instrumentation and Detectors, Astrophysics::High Energy Astrophysical Phenomena, High Energy Physics::Experiment

Abstract

The cross section of neutrino-induced neutral-current coherent π⁰ production on a carbon-dominated target is measured in the NOvA near detector. This measurement uses a narrow-band neutrino beam with an average neutrino energy of 2.7 GeV, which is of interest to ongoing and future long-baseline neutrino oscillation experiments. The measured, flux-averaged cross section is σ = 13.8±0.9(stat)±2.3(syst)×10⁻⁴⁰ cm²/nucleus, consistent with model prediction. This result is the most precise measurement of neutral-current coherent π⁰ production in the few-GeV neutrino energy region.

Published

2020

77. Search for multimessenger signals in NOvA coincident with LIGO/Virgo detections

Author

Acero, M. A., Adamson, P., Aliaga, L., Alion, T., Allakhverdian, V., Anfimov, N., Antoshkin, A., Asquith, L., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Baldi, P., Bambah, B. A., Bashar, S., Bays, K., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blair, J., Booth, A. C., Bour, P., Bromberg, C., Buchanan, N., Butkevich, A., Calvez, S., Carroll, T. J., Catano-Mur, E., Childress, S., Choudhary, B. C., Coan, T. E., Colo, M., Corwin, L., Cremonesi, L., Davies, G. S., Derwent, P. F., Dharmapalan, R., Ding, P., Djurcic, Z., Doyle, D., Dukes, E. C., Dung, P., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Filip, P., Flanagan, W., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Guo, B., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., Heller, K., Hewes, J., Himmel, A., Holin, A., Huang, J., Hylen, J., Jediny, F., Johnson, C., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kullenberg, Ch., Kumar, A., Kuruppu, C. D., Kus, V., Lackey, T., Lang, K., Li, L., Lin, S., Lokajicek, M., Luchuk, S., Magill, S., Mann, W. A., Marshak, M. L., Martinez-Casales, M., Matveev, V., Mayes, B., Méndez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mufson, S., Mulder, K., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Norrick, A., Nosek, T., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Petrova, O., Petti, R., Plunkett, R. K., Rafique, A., Psihas, F., Raj, V., Rebel, B., Rojas, P., Ryabov, V., Samoylov, O., Sanchez, M. C., Sánchez Falero, S., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Sutton, A., Talaga, R. L., Tapia Oregui, B., Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Torbunov, D., Tripathi, J., Torun, Y., Urheim, J., Vahle, P., Vasel, J., Vokac, P., Vrba, T., Wallbank, M., Warburton, T. K., Wetstein, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Yallappa Dombara, A., Yonehara, K., Yu, S., Yu, Y., Zadorozhnyy, S., Zalesak, J., Zhang, Y., and Zwaska, R.

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Physics, Gravitational wave, Astrophysics::High Energy Astrophysical Phenomena, Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astronomy, Particle Astrophysics, Cosmic ray, Nova (laser), LIGO, High Energy Physics - Experiment, High Energy Physics - Experiment (hep-ex), Neutron star, General Relativity and Quantum Cosmology, Neutrino detector, Coincident, Neutrino Detectors, Particle Astrophysics, Neutrinos, Neutrino Detectors, High Energy Physics::Experiment, Neutrino, Neutrinos, Astrophysics - High Energy Astrophysical Phenomena

Abstract

Using the NOvA neutrino detectors, a broad search has been performed for any signal coincident with 28 gravitational wave events detected by the LIGO/Virgo Collaboration between September 2015 and July 2019. For all of these events, NOvA is sensitive to possible arrival of neutrinos and cosmic rays of GeV and higher energies. For five (seven) events in the NOvA Far (Near) Detector, timely public alerts from the LIGO/Virgo Collaboration allowed recording of MeV-scale events. No signal candidates were found., 11 pages, 6 figures; Corrected fluence limits

Published

2020

78. Muon Cooling: MuCool and MICE

Author

Torun, Y.

Published

2006

79. Adjusting neutrino interaction models and evaluating uncertainties using NOvA near detector data

Author

Acero, M. A., primary, Adamson, P., additional, Agam, G., additional, Aliaga, L., additional, Alion, T., additional, Allakhverdian, V., additional, Anfimov, N., additional, Antoshkin, A., additional, Asquith, L., additional, Aurisano, A., additional, Back, A., additional, Backhouse, C., additional, Baird, M., additional, Balashov, N., additional, Baldi, P., additional, Bambah, B. A., additional, Bashar, S., additional, Bays, K., additional, Bending, S., additional, Bernstein, R., additional, Bhatnagar, V., additional, Bhuyan, B., additional, Bian, J., additional, Blair, J., additional, Booth, A. C., additional, Bour, P., additional, Bowles, R., additional, Bromberg, C., additional, Buchanan, N., additional, Butkevich, A., additional, Calvez, S., additional, Carroll, T. J., additional, Catano-Mur, E., additional, Childress, S., additional, Choudhary, B. C., additional, Coan, T. E., additional, Colo, M., additional, Corwin, L., additional, Cremonesi, L., additional, Davies, G. S., additional, Derwent, P. F., additional, Ding, P., additional, Djurcic, Z., additional, Doyle, D., additional, Dukes, E. C., additional, Dung, P., additional, Duyang, H., additional, Edayath, S., additional, Ehrlich, R., additional, Elkins, M., additional, Feldman, G. J., additional, Filip, P., additional, Flanagan, W., additional, Franc, J., additional, Frank, M. J., additional, Gallagher, H. R., additional, Gandrajula, R., additional, Gao, F., additional, Germani, S., additional, Giri, A., additional, Gomes, R. A., additional, Goodman, M. C., additional, Grichine, V., additional, Groh, M., additional, Group, R., additional, Guo, B., additional, Habig, A., additional, Hakl, F., additional, Hartnell, J., additional, Hatcher, R., additional, Hatzikoutelis, A., additional, Heller, K., additional, Hewes, J., additional, Himmel, A., additional, Holin, A., additional, Howard, B., additional, Huang, J., additional, Hylen, J., additional, Jediny, F., additional, Johnson, C., additional, Judah, M., additional, Kakorin, I., additional, Kalra, D., additional, Kaplan, D. M., additional, Keloth, R., additional, Klimov, O., additional, Koerner, L. W., additional, Kolupaeva, L., additional, Kotelnikov, S., additional, Kullenberg, Ch., additional, Kumar, A., additional, Kuruppu, C. D., additional, Kus, V., additional, Lackey, T., additional, Lang, K., additional, Li, L., additional, Lin, S., additional, Lokajicek, M., additional, Luchuk, S., additional, Maan, K., additional, Magill, S., additional, Mann, W. A., additional, Marshak, M. L., additional, Martinez-Casales, M., additional, Matveev, V., additional, Mayes, B., additional, Méndez, D. P., additional, Messier, M. D., additional, Meyer, H., additional, Miao, T., additional, Miller, W. H., additional, Mishra, S. R., additional, Mislivec, A., additional, Mohanta, R., additional, Moren, A., additional, Morozova, A., additional, Mualem, L., additional, Muether, M., additional, Mufson, S., additional, Mulder, K., additional, Murphy, R., additional, Musser, J., additional, Naples, D., additional, Nayak, N., additional, Nelson, J. K., additional, Nichol, R., additional, Nikseresht, G., additional, Niner, E., additional, Norman, A., additional, Norrick, A., additional, Nosek, T., additional, Olshevskiy, A., additional, Olson, T., additional, Paley, J., additional, Patterson, R. B., additional, Pawloski, G., additional, Petrova, O., additional, Petti, R., additional, Plunkett, R. K., additional, Rafique, A., additional, Psihas, F., additional, Radovic, A., additional, Raj, V., additional, Ramson, B., additional, Rebel, B., additional, Rojas, P., additional, Ryabov, V., additional, Samoylov, O., additional, Sanchez, M. C., additional, Falero, S. Sánchez, additional, Seong, I. S., additional, Shanahan, P., additional, Sheshukov, A., additional, Singh, P., additional, Singh, V., additional, Smith, E., additional, Smolik, J., additional, Snopok, P., additional, Solomey, N., additional, Sousa, A., additional, Soustruznik, K., additional, Strait, M., additional, Suter, L., additional, Sutton, A., additional, Sweeney, C., additional, Talaga, R. L., additional, Oregui, B. Tapia, additional, Tas, P., additional, Thayyullathil, R. B., additional, Thomas, J., additional, Tiras, E., additional, Torbunov, D., additional, Tripathi, J., additional, Torun, Y., additional, Urheim, J., additional, Vahle, P., additional, Vallari, Z., additional, Vasel, J., additional, Vokac, P., additional, Vrba, T., additional, Wallbank, M., additional, Warburton, T. K., additional, Wetstein, M., additional, Whittington, D., additional, Wojcicki, S. G., additional, Wolcott, J., additional, Dombara, A. Yallappa, additional, Yonehara, K., additional, Yu, S., additional, Yu, Y., additional, Zadorozhnyy, S., additional, Zalesak, J., additional, Zhang, Y., additional, and Zwaska, R., additional

Published

2020

80. Supernova neutrino detection in NOvA

Author

Acero, M.A., primary, Adamson, P., additional, Agam, G., additional, Aliaga, L., additional, Alion, T., additional, Allakhverdian, V., additional, Anfimov, N., additional, Antoshkin, A., additional, Arrieta-Diaz, E., additional, Asquith, L., additional, Aurisano, A., additional, Back, A., additional, Backhouse, C., additional, Baird, M., additional, Balashov, N., additional, Baldi, P., additional, Bambah, B.A., additional, Bashar, S., additional, Bays, K., additional, Bending, S., additional, Bernstein, R., additional, Bhatnagar, V., additional, Bhuyan, B., additional, Bian, J., additional, Blair, J., additional, Booth, A.C., additional, Bour, P., additional, Bowles, R., additional, Bromberg, C., additional, Buchanan, N., additional, Butkevich, A., additional, Bychkov, V., additional, Calvez, S., additional, Carroll, T.J., additional, Catano-Mur, E., additional, Childress, S., additional, Choudhary, B.C., additional, Coan, T. E., additional, Colo, M., additional, Corwin, L., additional, Cremonesi, L., additional, Davies, G.S., additional, Derwent, P.F., additional, Ding, P., additional, Djurcic, Z., additional, Dolce, M., additional, Doyle, D., additional, Tonguino, D. Dueñas, additional, Dukes, E.C., additional, Dung, P., additional, Duyang, H., additional, Edayath, S., additional, Ehrlich, R., additional, Elkins, M., additional, Feldman, G.J., additional, Filip, P., additional, Flanagan, W., additional, Franc, J., additional, Frank, M.J., additional, Gallagher, H.R., additional, Gandrajula, R., additional, Gao, F., additional, Germani, S., additional, Giri, A., additional, Gomes, R.A., additional, Goodman, M.C., additional, Grichine, V., additional, Groh, M., additional, Group, R., additional, Guo, B., additional, Habig, A., additional, Hakl, F., additional, Hall, A., additional, Hartnell, J., additional, Hatcher, R., additional, Hatzikoutelis, A., additional, Heller, K., additional, Hewes, J., additional, Himmel, A., additional, Holin, A., additional, Howard, B., additional, Huang, J., additional, Hylen, J., additional, Jediny, F., additional, Johnson, C., additional, Judah, M., additional, Kakorin, I., additional, Kalra, D., additional, Kaplan, D. M., additional, Keloth, R., additional, Klimov, O., additional, Koerner, L.W., additional, Kolupaeva, L., additional, Kotelnikov, S., additional, Kubu, M., additional, Kullenberg, Ch., additional, Kumar, A., additional, Kuruppu, C.D., additional, Kus, V., additional, Lackey, T., additional, Lang, K., additional, Li, L., additional, Lin, S., additional, Lister, A., additional, Lokajicek, M., additional, Luchuk, S., additional, Magill, S., additional, Mann, W.A., additional, Marshak, M.L., additional, Martinez-Casales, M., additional, Matveev, V., additional, Mayes, B., additional, Méndez, D.P., additional, Messier, M.D., additional, Meyer, H., additional, Miao, T., additional, Miller, W.H., additional, Mishra, S.R., additional, Mislivec, A., additional, Mohanta, R., additional, Moren, A., additional, Morozova, A., additional, Mualem, L., additional, Muether, M., additional, Mufson, S., additional, Mulder, K., additional, Murphy, R., additional, Musser, J., additional, Naples, D., additional, Nayak, N., additional, Nelson, J.K., additional, Nichol, R., additional, Nikseresht, G., additional, Niner, E., additional, Norman, A., additional, Norrick, A., additional, Nosek, T., additional, Olshevskiy, A., additional, Olson, T., additional, Paley, J., additional, Patterson, R.B., additional, Pawloski, G., additional, Petrova, O., additional, Petti, R., additional, Plunkett, R.K., additional, Psihas, F., additional, Rafique, A., additional, Raj, V., additional, Ramson, B., additional, Rebel, B., additional, Rojas, P., additional, Ryabov, V., additional, Samoylov, O., additional, Sanchez, M.C., additional, Falero, S. Sánchez, additional, Seong, I. S., additional, Shanahan, P., additional, Sheshukov, A., additional, Singh, P., additional, Singh, V., additional, Smith, E., additional, Smolik, J., additional, Snopok, P., additional, Solomey, N., additional, Sousa, A., additional, Soustruznik, K., additional, Strait, M., additional, Suter, L., additional, Sutton, A., additional, Sweeney, C., additional, Talaga, R. L., additional, Oregui, B. Tapia, additional, Tas, P., additional, Thayyullathil, R.B., additional, Thomas, J., additional, Tiras, E., additional, Torbunov, D., additional, Tripathi, J., additional, Tsaris, A., additional, Torun, Y., additional, Urheim, J., additional, Vahle, P., additional, Vallari, Z., additional, Vasel, J., additional, Vokac, P., additional, Vrba, T., additional, Wallbank, M., additional, Warburton, T. K., additional, Wetstein, M., additional, Whittington, D., additional, Wickremasinghe, D.A., additional, Wojcicki, S.G., additional, Wolcott, J., additional, Dombara, A. Yallappa, additional, Yonehara, K., additional, Yu, S., additional, Yu, Y., additional, Zadorozhnyy, S., additional, Zalesak, J., additional, Zhang, Y., additional, and Zwaska, R., additional

Published

2020

81. Operation of normal-conducting rf cavities in multi-Tesla magnetic fields for muon ionization cooling: A feasibility demonstration

Author

Bowring, D., primary, Bross, A., additional, Lane, P., additional, Leonova, M., additional, Moretti, A., additional, Neuffer, D., additional, Pasquinelli, R., additional, Peterson, D., additional, Popovic, M., additional, Stratakis, D., additional, Yonehara, K., additional, Kochemirovskiy, A., additional, Torun, Y., additional, Adolphsen, C., additional, Ge, L., additional, Haase, A., additional, Li, Z., additional, Martin, D., additional, Chung, M., additional, Li, D., additional, Luo, T., additional, Freemire, B., additional, Liu, A., additional, and Palmer, M., additional

Published

2020

82. Summary of Working Group 3: Machine Design and R&D

Author

Torun, Y., Haseroth, H., Machida, S., and Yokoi, T.

Published

2005

83. Search for CP violation in hyperon decays

Author

Zyla, Piotr, Chan, A., Chen, Y.C., Ho, C., Teng, P.K., Choong, W.S., Gidal, G., Fu, Y., Gu, P., Jones, T., Luk, K.B., Turko, B., Zyla, P., James, C., Volk, J., Felix, J., Burnstein, R.A., Chakrovorty, A., Kaplan, D.M., Lederman, L.M., Luebke, W., Rajaram, D., Rubin, H.A., Solomey, N., Torun, Y., White, C.G., White, S.L., Leros, N., Perroud, J.P., Gustafson, H.R., Longo, M.J., Lopez, F., Park, H.K., Clark, K., Jenkins, M., Dukes, E.C., Durandet, C., Holmstrom, T., Huang, M., Lu, L., and Nelson, K.S.

Published

2003

84. New constraints on oscillation parameters from <math><msub><mi>ν</mi><mi>e</mi></msub></math> appearance and <math><msub><mi>ν</mi><mi>μ</mi></msub></math> disappearance in the NOvA experiment

Author

Acero, M. A., Adamson, P., Aliaga, L., Alion, T., Allakhverdian, V., Anfimov, N., Antoshkin, A., Arrieta-Diaz, E., Aurisano, A., Back, A., Backhouse, C., Baird, M., Balashov, N., Bambah, B. A., Bays, K., Behera, B., Bending, S., Bernstein, R., Bhatnagar, V., Bhuyan, B., Bian, J., Blackburn, T., Blair, J., Bolshakova, A., Bour, P., Bromberg, C., Brown, J., Buchanan, N., Butkevich, A., Bychkov, V., Campbell, M., Carroll, T. J., Catano-Mur, E., Cedeno, A., Childress, S., Choudhary, B. C., Chowdhury, B., Coan, T. E., Colo, M., Cooper, J., Corwin, L., Cremonesi, L., Cronin-Hennessy, D., Davies, G. S., Davies, J. P., De Rijck, S., Derwent, P. F., Dharmapalan, R., Ding, P., Djurcic, Z., Dukes, E. C., Dung, P., Duyang, H., Edayath, S., Ehrlich, R., Feldman, G. J., Frank, M. J., Gallagher, H. R., Gandrajula, R., Gao, F., Germani, S., Giri, A., Gomes, R. A., Goodman, M. C., Grichine, V., Groh, M., Group, R., Grover, D., Guo, B., Habig, A., Hakl, F., Hartnell, J., Hatcher, R., Hatzikoutelis, A., Heller, K., Himmel, A., Holin, A., Howard, B., Huang, J., Hylen, J., Jediny, F., Judah, M., Kakorin, I., Kalra, D., Kaplan, D. M., Keloth, R., Klimov, O., Koerner, L. W., Kolupaeva, L., Kotelnikov, S., Kourbanis, I., Kreymer, A., Kulenberg, C., Kumar, A., Kuruppu, C., Kus, V., Lackey, T., Lang, K., Lin, S., Lokajicek, M., Lozier, J., Luchuk, S., Maan, K., Magill, S., Mann, W. A., Marshak, M. L., Matveev, V., Mendez, D. P., Messier, M. D., Meyer, H., Miao, T., Miller, W. H., Mishra, S. R., Mislivec, A., Mohanta, R., Moren, A., Mualem, L., Muether, M., Mufson, S., Murphy, R., Musser, J., Naples, D., Nayak, N., Nelson, J. K., Nichol, R., Niner, E., Norman, A., Nosek, T., Oksuzian, Y., Olshevskiy, A., Olson, T., Paley, J., Patterson, R. B., Pawloski, G., Pershey, D., Petrova, O., Petti, R., Phan-Budd, S., Plunkett, R. K., Potukuchi, B., Principato, C., Psihas, F., Radovic, A., Rameika, R. A., Rebel, B., Rojas, P., Ryabov, V., Sachdev, K., Samoylov, O., Sanchez, M. C., Sepulveda-Quiroz, J., Shanahan, P., Sheshukov, A., Singh, P., Singh, V., Smith, E., Smolik, J., Snopok, P., Solomey, N., Song, E., Sousa, A., Soustruznik, K., Strait, M., Suter, L., Talaga, R. L., Tas, P., Thayyullathil, R. B., Thomas, J., Tiras, E., Tognini, S. C., Torbunov, D., Tripathi, J., Tsaris, A., Torun, Y., Urheim, J., Vahle, P., Vasel, J., Vinton, L., Vokac, P., Vold, A., Vrba, T., Wang, B., Warburton, T. K., Wetstein, M., Whittington, D., Wojcicki, S. G., Wolcott, J., Yang, S., Yu, S., Zalesak, J., Zamorano, B., and Zwaska, R.

Abstract

We present updated results from the NOvA experiment for νμ→νμ and νμ→νe oscillations from an exposure of 8.85×1020 protons on target, which represents an increase of 46% compared to our previous publication. The results utilize significant improvements in both the simulations and analysis of the data. A joint fit to the data for νμ disappearance and νe appearance gives the best-fit point as normal mass hierarchy, Δm322=2.44×10−3 eV2/c4, sin2θ23=0.56, and δCP=1.21π. The 68.3% confidence intervals in the normal mass hierarchy are Δm322∈[2.37,2.52]×10−3 eV2/c4, sin2θ23∈[0.43,0.51]∪[0.52,0.60], and δCP∈[0,0.12π]∪[0.91π,2π]. The inverted mass hierarchy is disfavored at the 95% confidence level for all choices of the other oscillation parameters.

Published

2018

85. PB1670 ANXIETY, DEPRESSION, SELF-ESTEEM, AND ATTITUDE TOWARD ILLNESS AMONG CHILDREN WITH LEUKEMIA AND LYMPHOMA IN REMISSION

Author

Yılmaz, O., primary, Zehra, B., additional, Torun, Y. Altuner, additional, and Karakukcu, M., additional

Published

2019

86. MAUS: the MICE analysis user software

Author

Asfandiyarov, R., primary, Bayes, R., additional, Blackmore, V., additional, Bogomilov, M., additional, Colling, D., additional, Dobbs, A.J., additional, Drielsma, F., additional, Drews, M., additional, Ellis, M., additional, Fedorov, M., additional, Franchini, P., additional, Gardener, R., additional, Greis, J.R., additional, Hanlet, P.M., additional, Heidt, C., additional, Hunt, C., additional, Kafka, G., additional, Karadzhov, Y., additional, Kurup, A., additional, Kyberd, P., additional, Littlefield, M., additional, Liu, A., additional, Long, K., additional, Maletic, D., additional, Martyniak, J., additional, Middleton, S., additional, Mohayai, T., additional, Nebrensky, J.J., additional, Nugent, J.C., additional, Overton, E., additional, Pec, V., additional, Pidcott, C.E., additional, Rajaram, D., additional, Rayner, M., additional, Reid, I.D., additional, Rogers, C.T., additional, Santos, E., additional, Savic, M., additional, Taylor, I., additional, Torun, Y., additional, Tunnell, C.D., additional, Uchida, M.A., additional, Verguilov, V., additional, Walaron, K., additional, Winter, M., additional, and Wilbur, S., additional

Published

2019

87. Hadronic Cross Sections for Neutrino Production in MIPP

Author

Paley, Jonathan M., Abrams, R.L., Akgun, U., Aydin, G., Baker, W., Barnes, P.D., Jr., Bergfeld, T., Bujak, A., Carey, D., Dukes, C., Duru, F., Feldman, G., Fisyak, Y., Graf, N., Godley, A., Gunaydin, Y., Gustafson, H.R., Gutay, L., Hartouni, E., Hanlet, P., Heffner, M., Hylen, J., Johnstone, C., Kaplan, D., Kamaev, O., Klay, J., Kostin, M., Lange, D., Lebedev, A., Longo, M., Maternick, C., Messier, M., Meyer, H., Miller, D.E., Mishra, S.R., Mokhov, N., Nelson, K., Nigmanov, T., Norman, A., Onel, Y., Paley, J., Para, A., Park, H.K., Penzo, A., Peterson, R.J., Raja, R., Rajaram, D., Ratnikov, D., Rosenfeld, C., Rubin, H., Seun, S., Solomey, N., Soltz, R., Swallow, E., Torun, Y., Winston, R., Wright, D., and Wu, K.

Published

2011

88. Lattice design and expected performance of the Muon Ionization Cooling Experiment demonstration of ionization cooling

Author

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

Subjects

Nuclear and High Energy Physics, beam dynamics, Physics and Astronomy (miscellaneous), Physics::Instrumentation and Detectors, 01 natural sciences, 7. Clean energy, Physics, Particles & Fields, Nuclear physics, secondary beams, 0103 physical sciences, lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, Ionization cooling, Thermal emittance, High Energy Physics, Physics::Atomic Physics, 010306 general physics, QC, physics.acc-ph, Physics, Science & Technology, Muon, 010308 nuclear & particles physics, beam techniques, Surfaces and Interfaces, BEAMS, Accelerators and Storage Rings, Physics, Nuclear, Muon collider, Physical Sciences, Experimental High Energy Physics, lcsh:QC770-798, Physics::Accelerator Physics, High Energy Physics::Experiment, Neutrino Factory, International Muon Ionization Cooling Experiment, Neutrino, beam processes, Beam (structure)

Abstract

Muon beams of low emittance provide the basis for the intense, well-characterized neutrino beams necessary to elucidate the physics of flavor at a neutrino factory and to provide lepton-antilepton collisions at energies of up to several TeV at a muon collider. The international Muon Ionization Cooling Experiment (MICE) aims to demonstrate ionization cooling, the technique by which it is proposed to reduce the phase-space volume occupied by the muon beam at such facilities. In an ionization-cooling channel, the muon beam passes through a material in which it loses energy. The energy lost is then replaced using rf cavities. The combined effect of energy loss and reacceleration is to reduce the transverse emittance of the beam (transverse cooling). A major revision of the scope of the project was carried out over the summer of 2014. The revised experiment can deliver a demonstration of ionization cooling. The design of the cooling demonstration experiment will be described together with its predicted cooling performance. Muon beams of low emittance provide the basis for the intense, well-characterised neutrino beams necessary to elucidate the physics of flavour at a neutrino factory and to provide lepton-antilepton collisions at energies of up to several TeV at a muon collider. The international Muon Ionization Cooling Experiment (MICE) aims to demonstrate ionization cooling, the technique by which it is proposed to reduce the phase-space volume occupied by the muon beam at such facilities. In an ionization-cooling channel, the muon beam passes through a material in which it loses energy. The energy lost is then replaced using RF cavities. The combined effect of energy loss and re-acceleration is to reduce the transverse emittance of the beam (transverse cooling). A major revision of the scope of the project was carried out over the summer of 2014. The revised experiment can deliver a demonstration of ionization cooling. The design of the cooling demonstration experiment will be described together with its predicted cooling performance.

Published

2017

89. Proposal to upgrade the MIPP experiment

Author

Isenhower, D., primary, Sadler, M., additional, Towell, R., additional, Watson, S., additional, Peterson, R. J., additional, Baker, W., additional, Carey, D., additional, Christian, D., additional, Demarteau, M., additional, Jensen, D., additional, Johnstone, C., additional, Meyer, H., additional, Raja, R., additional, Ronzhin, A., additional, Solomey, N., additional, Wester, W., additional, Gutbrod, H., additional, Peters, K., additional, Feldman, G., additional, Torun, Y., additional, Messier, M. D., additional, and Paley, J., additional

Published

2006

90. The First Reported Case of Down Syndrome Co-existing with Glycogen Storage Disease

Author

Ergul, A. B., Alper Ozcan, Torun, Y. A., and Sevinc, E.

Abstract

Although the association of Down syndrome with many diseases, such as autoimmune disorders and congenital malformation, has been frequently reported, association with metabolic diseases has not been reported in the literature thus far. Here, we presented a patient with Down syndrome coexisting with glycogen storage disease who could not be extubated due to marked hypotonia to emphasize that a wide spectrum of clinical entities can accompany Down syndrome.

Published

2016

91. The experimental program for high pressure gas filled radio frequency cavities for muon cooling channels

Author

Freemire, B., primary, Chung, M., additional, Hanlet, P.M., additional, Johnson, R.P., additional, Moretti, A., additional, Torun, Y., additional, and Yonehara, K., additional

Published

2018

92. RF system for the MICE demonstration of ionisation cooling

Author

Ronald, K., primary, Whyte, C. G., additional, Dick, A. J., additional, Young, A. R., additional, Li, D., additional, DeMello, A. J., additional, Lambert, A. R., additional, Luo, T., additional, Anderson, T., additional, Bowring, D., additional, Bross, A., additional, Moretti, A., additional, Pasquinelli, R., additional, Peterson, D., additional, Popovic, M., additional, Schultz, R., additional, Volk, J., additional, Torun, Y., additional, Hanlet, P., additional, Freemire, B., additional, Moss, A., additional, Dumbell, K., additional, Grant, A., additional, White, C., additional, Griffiths, S., additional, Stanley, T., additional, Anderson, R., additional, Alsari, S., additional, Long, K., additional, Kurup, A., additional, Summers, D., additional, and Smith, P. J., additional

Published

2017

93. Monte Carlo simulations of muon production

Author

Palmer, R.B., primary, Gallardo, J.C., additional, Fernow, R.C., additional, Torun, Y., additional, Neuffer, D., additional, and Winn, D., additional

Published

1995

94. Spirometry in children with asthma and/or allergic rhinitis: comparison of FEF25-75% with the standard measures

Author

Sahiner Um, Altuner Torun Y, and Eke Gungor H

Subjects

Spirometry, Male, medicine.medical_specialty, Vital capacity, Adolescent, Vital Capacity, Maximal Midexpiratory Flow Rate, Gastroenterology, 03 medical and health sciences, FEV1/FVC ratio, 0302 clinical medicine, 030225 pediatrics, Internal medicine, Forced Expiratory Volume, Bronchodilation, medicine, Humans, Albuterol, Child, Asthma, medicine.diagnostic_test, business.industry, Case-control study, respiratory system, medicine.disease, Control subjects, Rhinitis, Allergic, respiratory tract diseases, Bronchodilator Agents, 030228 respiratory system, Case-Control Studies, Pediatrics, Perinatology and Child Health, Salbutamol, Female, business, circulatory and respiratory physiology, medicine.drug

Abstract

BACKGROUND Forced expiratory flow between 25% and 75% of vital capacity (FEF25-75%), a spirometric measure of small airways, may predict the presence of airway responsiveness both in asthmatics and in allergic rhinitis (AR). We aimed to search the correlation between FEF25-75% and standard measures of spirometry (forced expiratory volume in the first second [FEV1%] and FEV1/FVC [forced vital capacity]) in different clinical conditions, that is in children with asthma, in children with asthma and AR, in children with AR and in healthy children. METHODS Children with asthma (N.=116), asthma plus AR (N.=25), AR (N.=75) and healthy controls (N.=52) were evaluated. Clinical examinations, spirometry and bronchodilation tests were performed. RESULTS In asthmatics there was a strong correlation between FEF25-75% and FEV1% (r=0.596, P

Published

2015

95. Position estimates for existing trenchless installations

Author

Broere, W., Achterhuis, EJ, Torun, Y, and Choi, D

Subjects

+3+pag%22">Conf.proc. > 3 pag

Abstract

The position and alignment of existing cables and ducts, previously installed by trenchless technologies, has not always been recorded with sufficient accuracy for new works to be safely conducted close to existing installations. Inaccurate or missing registration in the past, manual data entry, previous activities in the same areas, can all lead to deviations between recorded and actual location. Location detection is often hampered by the depth of installations, especially in the case of HDD. The Netherlands Society for Trenchless Technologies (NSTT) has conducted a survey of the accuracy of trenchless installation techniques over the past decades, and of external factors influencing the position of existing cables and ducts, to get an estimate of the positional accuracy of older TT installations. This paper gives an overview of estimated accuracies for cables and ducts installed by HDD, micro-tunnelling, impact moling/ramming, auger boring and other TT installation techniques, taking soil conditions and the state of technology at the time of installation into account. The paper also gives an overview of which TT came to the Dutch market in which period.

Published

2015

96. Reduction in serum paraoxonase level in newborns with hyperbilirubinemia as a marker of oxidative stress

Author

Altuner Torun, Y., primary, Ertural, U., additional, Ergul, A. B., additional, Karakukcu, C., additional, and Akin, M. A., additional

Published

2016

97. Pressurized rf cavities in ionizing beams

Author

Freemire, B., primary, Tollestrup, A. V., additional, Yonehara, K., additional, Chung, M., additional, Torun, Y., additional, Johnson, R. P., additional, Flanagan, G., additional, Hanlet, P. M., additional, Collura, M. G., additional, Jana, M. R., additional, Leonova, M., additional, Moretti, A., additional, and Schwarz, T., additional

Published

2016

98. The detector system of the Daya Bay reactor neutrino experiment

Author

An, F.P., primary, Bai, J.Z., additional, Balantekin, A.B., additional, Band, H.R., additional, Beavis, D., additional, Beriguete, W., additional, Bishai, M., additional, Blyth, S., additional, Brown, R.L., additional, Butorov, I., additional, Cao, D., additional, Cao, G.F., additional, Cao, J., additional, Carr, R., additional, Cen, W.R., additional, Chan, W.T., additional, Chan, Y.L., additional, Chang, J.F., additional, Chang, L.C., additional, Chang, Y., additional, Chasman, C., additional, Chen, H.Y., additional, Chen, H.S., additional, Chen, M.J., additional, Chen, Q.Y., additional, Chen, S.J., additional, Chen, S.M., additional, Chen, X.C., additional, Chen, X.H., additional, Chen, X.S., additional, Chen, Y.X., additional, Chen, Y., additional, Cheng, J.H., additional, Cheng, J., additional, Cheng, Y.P., additional, Cherwinka, J.J., additional, Chidzik, S., additional, Chow, K., additional, Chu, M.C., additional, Cummings, J.P., additional, de Arcos, J., additional, Deng, Z.Y., additional, Ding, X.F., additional, Ding, Y.Y., additional, Diwan, M.V., additional, Dong, L., additional, Dove, J., additional, Draeger, E., additional, Du, X.F., additional, Dwyer, D.A., additional, Edwards, W.R., additional, Ely, S.R., additional, Fang, S.D., additional, Fu, J.Y., additional, Fu, Z.W., additional, Ge, L.Q., additional, Ghazikhanian, V., additional, Gill, R., additional, Goett, J., additional, Gonchar, M., additional, Gong, G.H., additional, Gong, H., additional, Gornushkin, Y.A., additional, Grassi, M., additional, Greenler, L.S., additional, Gu, W.Q., additional, Guan, M.Y., additional, Guo, R.P., additional, Guo, X.H., additional, Hackenburg, R.W., additional, Hahn, R.L., additional, Han, R., additional, Hans, S., additional, He, M., additional, He, Q., additional, He, W.S., additional, Heeger, K.M., additional, Heng, Y.K., additional, Higuera, A., additional, Hinrichs, P., additional, Ho, T.H., additional, Hoff, M., additional, Hor, Y.K., additional, Hsiung, Y.B., additional, Hu, B.Z., additional, Hu, L.M., additional, Hu, L.J., additional, Hu, T., additional, Hu, W., additional, Huang, E.C., additional, Huang, H.Z., additional, Huang, H.X., additional, Huang, P.W., additional, Huang, X., additional, Huang, X.T., additional, Huber, P., additional, Hussain, G., additional, Isvan, Z., additional, Jaffe, D.E., additional, Jaffke, P., additional, Jen, K.L., additional, Jetter, S., additional, Ji, X.P., additional, Ji, X.L., additional, Jiang, H.J., additional, Jiang, W.Q., additional, Jiao, J.B., additional, Johnson, R.A., additional, Joseph, J., additional, Kang, L., additional, Kettell, S.H., additional, Kohn, S., additional, Kramer, M., additional, Kwan, K.K., additional, Kwok, M.W., additional, Kwok, T., additional, Lai, C.Y., additional, Lai, W.C., additional, Lai, W.H., additional, Langford, T.J., additional, Lau, K., additional, Lebanowski, L., additional, Lee, J., additional, Lee, M.K.P., additional, Lei, R.T., additional, Leitner, R., additional, Leung, J.K.C., additional, Lewis, C.A., additional, Li, B., additional, Li, C., additional, Li, D.J., additional, Li, F., additional, Li, G.S., additional, Li, J., additional, Li, N.Y., additional, Li, Q.J., additional, Li, S.F., additional, Li, S.C., additional, Li, W.D., additional, Li, X.B., additional, Li, X.N., additional, Li, X.Q., additional, Li, Y., additional, Li, Y.F., additional, Li, Z.B., additional, Liang, H., additional, Liang, J., additional, Lin, C.J., additional, Lin, G.L., additional, Lin, P.Y., additional, Lin, S.X., additional, Lin, S.K., additional, Lin, Y.C., additional, Ling, J.J., additional, Link, J.M., additional, Littenberg, L., additional, Littlejohn, B.R., additional, Liu, B.J., additional, Liu, C., additional, Liu, D.W., additional, Liu, H., additional, Liu, J.L., additional, Liu, J.C., additional, Liu, S., additional, Liu, S.S., additional, Liu, X., additional, Liu, Y.B., additional, Lu, C., additional, Lu, H.Q., additional, Lu, J.S., additional, Luk, A., additional, Luk, K.B., additional, Luo, T., additional, Luo, X.L., additional, Ma, L.H., additional, Ma, Q.M., additional, Ma, X.Y., additional, Ma, X.B., additional, Ma, Y.Q., additional, Mayes, B., additional, McDonald, K.T., additional, McFarlane, M.C., additional, McKeown, R.D., additional, Meng, Y., additional, Mitchell, I., additional, Mohapatra, D., additional, Monari Kebwaro, J., additional, Morgan, J.E., additional, Nakajima, Y., additional, Napolitano, J., additional, Naumov, D., additional, Naumova, E., additional, Newsom, C., additional, Ngai, H.Y., additional, Ngai, W.K., additional, Nie, Y.B., additional, Ning, Z., additional, Ochoa-Ricoux, J.P., additional, Olshevskiy, A., additional, Pagac, A., additional, Pan, H.-R., additional, Patton, S., additional, Pearson, C., additional, Pec, V., additional, Peng, J.C., additional, Piilonen, L.E., additional, Pinsky, L., additional, Pun, C.S.J., additional, Qi, F.Z., additional, Qi, M., additional, Qian, X., additional, Raper, N., additional, Ren, B., additional, Ren, J., additional, Rosero, R., additional, Roskovec, B., additional, Ruan, X.C., additional, Sands, W.R., additional, Seilhan, B., additional, Shao, B.B., additional, Shih, K., additional, Song, W.Y., additional, Steiner, H., additional, Stoler, P., additional, Stuart, M., additional, Sun, G.X., additional, Sun, J.L., additional, Tagg, N., additional, Tam, Y.H., additional, Tanaka, H.K., additional, Tang, W., additional, Tang, X., additional, Taychenachev, D., additional, Themann, H., additional, Torun, Y., additional, Trentalange, S., additional, Tsai, O., additional, Tsang, K.V., additional, Tsang, R.H.M., additional, Tull, C.E., additional, Tung, Y.C., additional, Viaux, N., additional, Viren, B., additional, Virostek, S., additional, Vorobel, V., additional, Wang, C.H., additional, Wang, L.S., additional, Wang, L.Y., additional, Wang, L.Z., additional, Wang, M., additional, Wang, N.Y., additional, Wang, R.G., additional, Wang, T., additional, Wang, W., additional, Wang, W.W., additional, Wang, X.T., additional, Wang, X., additional, Wang, Y.F., additional, Wang, Z., additional, Wang, Z.M., additional, Webber, D.M., additional, Wei, H.Y., additional, Wei, Y.D., additional, Wen, L.J., additional, Wenman, D.L., additional, Whisnant, K., additional, White, C.G., additional, Whitehead, L., additional, Whitten, C.A., additional, Wilhelmi, J., additional, Wise, T., additional, Wong, H.C., additional, Wong, H.L.H., additional, Wong, J., additional, Wong, S.C.F., additional, Worcester, E., additional, Wu, F.F., additional, Wu, Q., additional, Xia, D.M., additional, Xia, J.K., additional, Xiang, S.T., additional, Xiao, Q., additional, Xing, Z.Z., additional, Xu, G., additional, Xu, J.Y., additional, Xu, J.L., additional, Xu, J., additional, Xu, W., additional, Xu, Y., additional, Xue, T., additional, Yan, J., additional, Yang, C.G., additional, Yang, L., additional, Yang, M.S., additional, Yang, M.T., additional, Ye, M., additional, Yeh, M., additional, Yeh, Y.S., additional, Yip, K., additional, Young, B.L., additional, Yu, G.Y., additional, Yu, Z.Y., additional, Zeng, S., additional, Zhan, L., additional, Zhang, C., additional, Zhang, F.H., additional, Zhang, H.H., additional, Zhang, J.W., additional, Zhang, K., additional, Zhang, Q.X., additional, Zhang, Q.M., additional, Zhang, S.H., additional, Zhang, X.T., additional, Zhang, Y.C., additional, Zhang, Y.H., additional, Zhang, Y.M., additional, Zhang, Y.X., additional, Zhang, Z.J., additional, Zhang, Z.Y., additional, Zhang, Z.P., additional, Zhao, J., additional, Zhao, Q.W., additional, Zhao, Y.F., additional, Zhao, Y.B., additional, Zheng, L., additional, Zhong, W.L., additional, Zhou, L., additional, Zhou, N., additional, Zhou, Z.Y., additional, Zhuang, H.L., additional, Zimmerman, S., additional, and Zou, J.H., additional

Published

2016

99. Pion contamination in the MICE muon beam

Author

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

Published

2016

100. The RF System for the International Muon Ionisation Cooling Experiment

Author

Ronald, K., Whyte, C.G., Dick, A.J., Speirs, D.C., Moss, A., Grant, A., White, C., Griffiths, S., Stanley, T., Li, D., DeMello, A.J., Virostek, S., Moretti, A., Pasquinelli, R., Peterson, D., Schultz, R., Volk, J., Popovic, M., Torun, Y., Hanlet, P., Alsari, S., Long, K., Pasternak, J., Hunt, C., Summers, D., Luo, T., and Smith, P.J.

Subjects

Physics::Accelerator Physics, ICTF R&D Infrastructure [7], Accelerators and Storage Rings, RFP ICTF RF power infrastructure [7.1]

Abstract

The International Muon Ionisation Cooling Experiment (MICE) is designed to demonstrate the effectiveness of ionisation cooling to reduce the phase space footprint of a charged particle beam, principally to allow the subsequent acceleration of muons for next generation colliders and/or neutrino factories. The experiment (and indeed any subsequent accelerator cooling channel based on the same principles) poses certain unusual requirements on its RF system, whilst the precision measurement of the ionisation cooling process demands special diagnostics. This paper shall outline the key features of the RF system, including the low level RF control, the power amplifier chain, distribution network, cavities, tuners and couplers, many parts of which are required to operate in a high magnetic field environment. The RF diagnostics which, in conjunction with the other MICE diagnostics, shall allow detailed knowledge of the amplitude and phase of the acceleration field during the transit of each individual muon will also be discussed.

Published

2014