D
D. J. Boehnlein
Researcher at Fermilab
Publications - 49
Citations - 5993
D. J. Boehnlein is an academic researcher from Fermilab. The author has contributed to research in topics: MINOS & Neutrino. The author has an hindex of 35, co-authored 49 publications receiving 5505 citations.
Papers
More filters
Journal ArticleDOI
Improved search for muon-neutrino to electron-neutrino oscillations in MINOS
P. Adamson,D. J. Auty,D. S. Ayres,C. Backhouse,G.D. Barr,M. Betancourt,M. Bishai,Andrew Blake,G. J. Bock,D. J. Boehnlein,D. Bogert,S. V. Cao,S. Cavanaugh,D. Cherdack,S. Childress,Joao A B Coelho,L. Corwin,D. Cronin-Hennessy,I. Z. Danko,J. K. de Jong,N. E. Devenish,M. V. Diwan,M. Dorman,Carlos Escobar,J. J. Evans,E. Falk,G. J. Feldman,M. V. Frohne,H. R. Gallagher,R. A. Gomes,Maury Goodman,P. Gouffon,N. Graf,R. Gran,K. Grzelak,Alec Habig,J. Hartnell,R. Hatcher,A. Himmel,A. Holin,Xian-Rong Huang,J. Hylen,G. M. Irwin,Z. Isvan,D. E. Jaffe,C. James,D. A. Jensen,T. Kafka,S. M. S. Kasahara,G. Koizumi,Sacha E Kopp,M. Kordosky,A. E. Kreymer,Karol Lang,G. Lefeuvre,P. J. Litchfield,L. Loiacono,P. Lucas,W. A. Mann,Marvin L Marshak,M. Mathis,N. Mayer,A. M. McGowan,R. Mehdiyev,J. R. Meier,M. D. Messier,D. G. Michael,W. H. Miller,S. R. Mishra,John C. Mitchell,C. D. Moore,L. Mualem,S. L. Mufson,J. A. Musser,D. Naples,J. K. Nelson,Harvey B Newman,R. J. Nichol,J. A. Nowak,Juan Pedro Ochoa-Ricoux,W. P. Oliver,M. Orchanian,J. M. Paley,R. B. Patterson,Gregory J Pawloski,G. F. Pearce,S. Phan-Budd,R. K. Plunkett,X. Qiu,J. Ratchford,B. Rebel,C. Rosenfeld,H. A. Rubin,M. C. Sanchez,J. Schneps,A. Schreckenberger,P. Schreiner,P. Shanahan,Rohit Sharma,A. Sousa,N. Tagg,R. L. Talaga,J. C. Thomas,M. A. Thomson,R. Toner,D. Torretta,G. Tzanakos,J. Urheim,P. Vahle,B. Viren,J. Walding,A. C. Weber,R. C. Webb,C. White,L. H. Whitehead,Stanley G. Wojcicki,T. Yang,R. Zwaska +117 more
TL;DR: The results of a search for ν(e) appearance in a ν (μ) beam in the MINOS long-baseline neutrino experiment find that 2 sin(2) (θ(23))sin(2)(2θ (13))<0.12 at 90% confidence level for δ = 0 and the normal (inverted) neutrinos mass hierarchy.
Journal ArticleDOI
Observation of muon neutrino disappearance with the MINOS detectors in the NuMI neutrino beam
D. G. Michael,P. Adamson,P. Adamson,P. Adamson,T. Alexopoulos,W.W.M. Allison,G. J. Alner,Kevin Anderson,C. Andreopoulos,M. P. Andrews,R. Andrews,K. E. Arms,R. Armstrong,C. Arroyo,D. J. Auty,S. Avvakumov,D. S. Ayres,B. Baller,B. C. Barish,M. A. Barker,Peter D. Barnes,G.D. Barr,William L. Barrett,E. Beall,E. Beall,B. R. Becker,A. Belias,T. Bergfeld,R. H. Bernstein,D. Bhattacharya,M. Bishai,Andrew Blake,V. Bocean,B. Bock,G. J. Bock,J. Boehm,D. J. Boehnlein,D. Bogert,P. M. Border,C. R. Bower,S. Boyd,E. Buckley-Geer,C. Bungau,A. Byon-Wagner,Anatael Cabrera,John Derek Chapman,Thomas R. Chase,D. Cherdack,S. Chernichenko,S. Childress,B. C. Choudhary,B. C. Choudhary,J. H. Cobb,J. D. Cossairt,H. Courant,D. Crane,A. J. Culling,J. W. Dawson,J. K. de Jong,D. M. DeMuth,A. De Santo,M. Dierckxsens,M. V. Diwan,M. Dorman,M. Dorman,G. Drake,D. Drakoulakos,R. Ducar,T. Durkin,A. R. Erwin,Carlos Escobar,J. J. Evans,O. Fackler,E. Falk Harris,G. J. Feldman,N. Felt,T. H. Fields,R. Ford,M. V. Frohne,H. R. Gallagher,M. Gebhard,G. A. Giurgiu,A. Godley,J. Gogos,M. C. Goodman,Yu. A. Gornushkin,P. Gouffon,R. Gran,E. Grashorn,N. Grossman,J. J. Grudzinski,K. Grzelak,V. J. Guarino,Alec Habig,R. Halsall,J. Hanson,D. A. Harris,Philip Harris,J. Hartnell,J. Hartnell,E. P. Hartouni,R. Hatcher,Ken Heller,N. Hill,Y. Ho,A. Holin,C. Howcroft,C. Howcroft,J. Hylen,M. Ignatenko,D. Indurthy,G. M. Irwin,M. Ishitsuka,D. E. Jaffe,C. James,L. Jenner,D. A. Jensen,T. Joffe-Minor,T. Kafka,H. J. Kang,S. M S Kasahara,J. Kilmer,Hyun-Chul Kim,M. S. Kim,G. Koizumi,Sacha E Kopp,M. Kordosky,M. Kordosky,D. J. Koskinen,D. J. Koskinen,M. Kostin,S. K. Kotelnikov,D. Krakauer,A. E. Kreymer,S. Kumaratunga,A. S. Ladran,Karol Lang,C. Laughton,A. Lebedev,R. Lee,Weonjong Lee,M. Libkind,Ji-Yong Liu,P. J. Litchfield,P. J. Litchfield,R. P. Litchfield,N. P. Longley,P. Lucas,W. Luebke,S. Madani,E. Maher,V. Makeev,W. A. Mann,A. Marchionni,A. D. Marino,Marvin L Marshak,John Marshall,N. Mayer,J. McDonald,A. M. McGowan,A. M. McGowan,J. R. Meier,G. I. Merzon,M. D. Messier,M. D. Messier,R. H. Milburn,John Miller,John Miller,Warner A. Miller,S.R. Mishra,S.R. Mishra,A. Mislivec,P. S. Miyagawa,C. D. Moore,Jorge G. Morfin,R. Morse,L. Mualem,S. L. Mufson,S. Murgia,M. J. Murtagh,J. A. Musser,D. Naples,C. Nelson,J. K. Nelson,J. K. Nelson,J. K. Nelson,Harvey B Newman,F. A. Nezrick,R. J. Nichol,T. C. Nicholls,Juan Pedro Ochoa-Ricoux,J. Oliver,W. P. Oliver,V.A. Onuchin,T. Osiecki,R. Ospanov,J. M. Paley,V. Paolone,A. Para,T. Patzak,Ž Pavlović,G. F. Pearce,N. Pearson,C. W. Peck,Carole C. Perry,E. A. Peterson,D. A. Petyt,D. A. Petyt,D. A. Petyt,H. Ping,R. Piteira,R. Pittam,A. Pla-Dalmau,R. K. Plunkett,L. E. Price,M. Proga,D. Pushka,D. Rahman,R. A. Rameika,T. M. Raufer,A. L. Read,B. Rebel,B. Rebel,J. Reichenbacher,D. E. Reyna,C. Rosenfeld,H. A. Rubin,K. Ruddick,V. A. Ryabov,Ruben Saakyan,Mcd Sanchez,Mcd Sanchez,Niki Saoulidou,J. Schneps,Paul Schoessow,P. Schreiner,Reinhard Schwienhorst,V. K. Semenov,S. M. Seun,P. Shanahan,P.D. Shield,W. Smart,V. Smirnitsky,Caleb Smith,Caleb Smith,Caleb Smith,P. N. Smith,A. Sousa,A. Sousa,B. Speakman,P. Stamoulis,A. Stefanik,P. Sullivan,J. M. Swan,P. A. Symes,N. Tagg,N. Tagg,R. L. Talaga,Alexander Terekhov,E. Tetteh-Lartey,Juergen Thomas,Juergen Thomas,Juergen Thomas,J. A. Thompson,M. A. Thomson,J. L. Thron,G. Tinti,R. Trendler,J. Trevor,I. Trostin,V. A. Tsarev,G. Tzanakos,J. Urheim,J. Urheim,P. Vahle,P. Vahle,M. Vakili,K. Vaziri,C. Velissaris,V. Verebryusov,B. Viren,L. Wai,C. P. Ward,D. R. Ward,M. Watabe,A. C. Weber,A. C. Weber,R. C. Webb,A. A. Wehmann,N. West,C. White,Randall White,Stanley G. Wojcicki,Douglas Wright,Q. K. Wu,W. G. Yan,T. Yang,Francisco Yumiceva,J. C. Yun,H. Zheng,M. Zois,R. Zwaska,R. Zwaska +302 more
TL;DR: In this article, the MINOS experiment reported results from its initial exposure to neutrinos from the Fermilab NuMI beam, and the rate and energy spectra of charged current muon neutrino interactions are compared in two detectors located along the beam axis at distances of 1 km and 735 km.
Journal ArticleDOI
Observation of tau neutrino interactions
Koichi Kodama,N. Ushida,C. Andreopoulos,Niki Saoulidou,G. Tzanakos,P. M. Yager,B. Baller,D. J. Boehnlein,Walter Freeman,B. Lundberg,Jorge G. Morfin,R. Rameika,Jae Chul Yun,J. S. Song,C. S. Yoon,S. H. Chung,P. Berghaus,M. A. Kubantsev,N. W. Reay,R. A. Sidwell,N. R. Stanton,S. Yoshida,Shigeki Aoki,T. Hara,J. T. Rhee,D. P. Ciampa,C. Erickson,Matt W. Graham,Ken Heller,Roger Rusack,Reinhard Schwienhorst,J. Sielaff,J. Trammell,J. Wilcox,K. Hoshino,H. Jiko,Motoaki Miyanishi,Masahiro Komatsu,M. Nakamura,Toshiyuki Nakano,K. Niwa,N. Nonaka,K. Okada,Osamu Sato,T. Akdogan,V. Paolone,C. Rosenfeld,A. Kulik,A. Kulik,T. Kafka,W. P. Oliver,T. Patzak,J. Schneps +52 more
TL;DR: The DONUT experiment has analyzed 203 neutrino interactions recorded in nuclear emulsion targets as discussed by the authors, with an estimated background of 0.34 events, consistent with the Standard Model expectation.
Journal ArticleDOI
Design and Construction of the MicroBooNE Detector
R. Acciarri,C. Adams,R. An,A. Aparicio,S. Aponte,J. Asaadi,M. Auger,N. Ayoub,L. Bagby,B. Baller,R. Barger,G.D. Barr,M. Bass,F. Bay,K. Biery,M. Bishai,Andrew Blake,V. Bocean,D. J. Boehnlein,V. D. Bogert,T. Bolton,L. Bugel,C. Callahan,L. Camilleri,D. Caratelli,B. Carls,R. Castillo Fernandez,F. Cavanna,S. Chappa,H. S. Chen,Kai Chen,C.-Y. Chi,Christie S. Chiu,E. Church,D. Cianci,D. Cianci,G. H. Collin,Janet Conrad,M. E. Convery,J. Cornele,P. Cowan,J. I. Crespo-Anadón,G. Crutcher,Christine Darve,R. Davis,M. Del Tutto,D. Devitt,S. Duffin,S. Dytman,B. Eberly,Antonio Ereditato,D. Erickson,L. Escudero Sanchez,J. Esquivel,S. Farooq,J. Farrell,D. Featherston,B.T. Fleming,W. Foreman,A. P. Furmanski,V. Genty,M. Geynisman,D. Goeldi,B. Goff,S. Gollapinni,N. Graf,E. Gramellini,J. Green,A. Greene,H. Greenlee,T. Griffin,R. Grosso,R. Guenette,A. Hackenburg,R. Haenni,P. M. Hamilton,P. Healey,Or Hen,E. Henderson,J. Hewes,Colin Hill,K. Hill,L. Himes,J. Ho,G. A. Horton-Smith,D. Huffman,C. M. Ignarra,C. James,E. James,J. Jan de Vries,W. Jaskierny,C.-M. Jen,L. Jiang,B. Johnson,Marvin Johnson,R. A. Johnson,B. J. P. Jones,J. Joshi,H. Jöstlein,D. Kaleko,L. N. Kalousis,G. Karagiorgi,G. Karagiorgi,Teppei Katori,P. Kellogg,W. Ketchum,J. Kilmer,Barry King,B. Kirby,Michael H Kirby,E. Klein,T. Kobilarcik,I. Kreslo,R. Krull,Robert M. Kubinski,G. Lange,Francesco Lanni,A. Lathrop,A. Laube,W. M. Lee,Yang Li,D. Lissauer,A. Lister,B. R. Littlejohn,S. Lockwitz,D. Lorca,W. C. Louis,Gennadiy Lukhanin,M. Luethi,B. Lundberg,X. Luo,G. Mahler,I. Majoros,D. Makowiecki,A. Marchionni,C. Mariani,D. Markley,John Marshall,D. A. Martinez Caicedo,Kirk T. McDonald,D. McKee,A.I.L. McLean,Joseph Mead,V. Meddage,T. Miceli,G. B. Mills,W. Miner,J. Moon,M. Mooney,C.D. Moore,Z. Moss,J. Mousseau,R. Murrells,D. Naples,P. Nienaber,B. Norris,N. Norton,J. A. Nowak,M. O'Boyle,T. Olszanowski,Ornella Palamara,V. Paolone,V. Papavassiliou,S. F. Pate,Z. Pavlovic,R. Pelkey,M. Phipps,S. Pordes,D. Porzio,G. Pulliam,Xin Qian,J. L. Raaf,Veljko Radeka,A. Rafique,R. A. Rameika,B. Rebel,R. Rechenmacher,S. Rescia,L. Rochester,C. Rudolf von Rohr,A. Ruga,B. Russell,R. Sanders,W. Sands,M. Sarychev,D. W. Schmitz,A. Schukraft,R. Scott,W. G. Seligman,M. H. Shaevitz,M. Shoun,J. Sinclair,W. Sippach,Tess Smidt,A.D. Smith,E.L. Snider,M. Soderberg,M. Solano-Gonzalez,S. Söldner-Rembold,S.R. Soleti,J. Sondericker,Panagiotis Spentzouris,J. Spitz,J. St. John,Thomas Strauss,K. Sutton,A. M. Szelc,K. Taheri,N. Tagg,K. Tatum,J. Teng,Kazuhiro Terao,M. A. Thomson,C. E. Thorn,J. Tillman,M. Toups,Y.-T. Tsai,S. Tufanli,T. Usher,M. Utes,R. G. Van de Water,C. Vendetta,S. Vergani,E. Voirin,J. Voirin,B. Viren,P. Watkins,Marc Weber,T. Wester,Jason Weston,D.A. Wickremasinghe,S. Wolbers,T. Wongjirad,K. Woodruff,K. C. Wu,T. Yang,Bo Yu,G. P. Zeller,J. Zennamo,Chao Zhang,M. Zuckerbrot +240 more
TL;DR: MicroBooNE as discussed by the authors is the first phase of the Short Baseline Neutrino program, located at Fermilab, and will utilize the capabilities of liquid argon detectors to examine a rich assortment of physics topics.
Journal ArticleDOI
Measurement of neutrino oscillations with the MINOS detectors in the NuMI beam.
P. Adamson,C. Andreopoulos,K. E. Arms,R. Armstrong,D. J. Auty,D. S. Ayres,B. Baller,Peter D. Barnes,G.D. Barr,William L. Barrett,B. R. Becker,A. Belias,R. H. Bernstein,D. Bhattacharya,M. Bishai,Andrew Blake,G. J. Bock,J. Boehm,D. J. Boehnlein,D. Bogert,C. R. Bower,E. Buckley-Geer,S. Cavanaugh,John Derek Chapman,D. Cherdack,S. Childress,Brajesh C Choudhary,J. H. Cobb,S. J. Coleman,A. J. Culling,J. K. de Jong,M. Dierckxsens,M. V. Diwan,M. Dorman,M. Dorman,S. A. Dytman,Carlos Escobar,J. J. Evans,J. J. Evans,E. Falk Harris,G. J. Feldman,M. V. Frohne,H. R. Gallagher,A. Godley,M. C. Goodman,P. Gouffon,R. Gran,E. Grashorn,N. Grossman,K. Grzelak,K. Grzelak,Alec Habig,D. A. Harris,Philip Harris,J. Hartnell,J. Hartnell,R. Hatcher,Ken Heller,A. Himmel,A. Holin,J. Hylen,G. M. Irwin,M. Ishitsuka,D. E. Jaffe,C. James,D. A. Jensen,T. Kafka,S. M S Kasahara,J. J. Kim,M. S. Kim,G. Koizumi,Sacha E Kopp,M. Kordosky,M. Kordosky,D. J. Koskinen,S. K. Kotelnikov,A. E. Kreymer,S. Kumaratunga,Karol Lang,P. J. Litchfield,R. P. Litchfield,L. Loiacono,Philippe Lucas,Jian Ma,W. A. Mann,A. Marchionni,Marvin L Marshak,John Marshall,N. Mayer,A. M. McGowan,A. M. McGowan,J. R. Meier,G. I. Merzon,M. D. Messier,C. J. Metelko,D. G. Michael,John Miller,Warner A. Miller,S. R. Mishra,C. D. Moore,Jorge G. Morfin,L. Mualem,S. L. Mufson,S. Murgia,J. A. Musser,D. Naples,J. K. Nelson,Harvey B Newman,R. J. Nichol,T. C. Nicholls,Juan Pedro Ochoa-Ricoux,W. P. Oliver,R. Ospanov,J. M. Paley,V. Paolone,A. Para,T. Patzak,Ž Pavlović,Gregory J Pawloski,G. F. Pearce,C. W. Peck,E. A. Peterson,David Petyt,R. Pittam,R. K. Plunkett,A. Rahaman,R. A. Rameika,T. M. Raufer,B. Rebel,J. Reichenbacher,P. A. Rodrigues,C. Rosenfeld,H. A. Rubin,K. Ruddick,V. A. Ryabov,M. C. Sanchez,M. C. Sanchez,Niki Saoulidou,J. Schneps,P. Schreiner,S. M. Seun,P. Shanahan,W. Smart,Caleb Smith,A. Sousa,B. Speakman,P. Stamoulis,Matthew L Strait,P. A. Symes,N. Tagg,R. L. Talaga,M. A. Tavera,Juergen Thomas,J. A. Thompson,M. A. Thomson,J. L. Thron,G. Tinti,I. Trostin,V. A. Tsarev,G. Tzanakos,J. Urheim,P. Vahle,P. Vahle,B. Viren,C. P. Ward,D. R. Ward,M. Watabe,A. C. Weber,R. C. Webb,A. A. Wehmann,N. West,C. White,Stanley G. Wojcicki,Douglas Wright,T. Yang,M. Zois,K. Zhang,R. Zwaska +177 more
TL;DR: The data disfavor two alternative explanations for the disappearance of neutrinos in flight: namely, neutrino decays into lighter particles and quantum decoherence of neutRinos, at the 3.7 and 5.7 standard-deviation levels, respectively.