Published January 1, 2016
| Version v1
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Search for invisible decays of a Higgs boson using vector-boson fusion in pp collisions at s = 8 $$ \sqrt{s}=8 $$ TeV with the ATLAS detector
Creators
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Georges Aad1, 2, 3
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B. Abbott4
- J. Abdallah5
- O. Abdinov6
- R. Aben7, 8
- M. Abolins9
- Ossama Abouzeid10
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H. Abramowicz11
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Henso Abreu12
- R. Abreu13
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Yiming Abulaiti14
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Bobby Samir Acharya15
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L. Adamczyk16
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D. L. Adams17
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J. Adelman18
- S. Adomeit19
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T. Adye20
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Tony Affolder21
- T. Agatonović-Jovin22
- J. Agricola23
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J. A. Aguilar-Saavedra24
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S. P. Ahlen25
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Faig Ahmadov6
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Giulio Aielli26
- H. Åkerstedt14
- T. P. A. Åkesson27
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Андрей Акимов28
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Gian Luigi Alberghi29
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J. Albert30
- S. Albrand31, 32, 2, 3
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M. J. Alconada Verzini33, 34, 35
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Martin Aleksa36
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И. Н. Александров37
- C. Alexa
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G. Alexander11
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Theodoros Alexopoulos38
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Muhammad Alhroob4
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G. Alimonti39
- L. Alio1, 2, 3
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John Alison40, 41
- Steven Patrick Alkire42
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Benedict Allbrooke43
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P. P. Allport21
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A. Aloisio44
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A. Alonso45
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Francisco Alonso33, 34, 35
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Cristiano Alpigiani46
- A. Altheimer42
- B. Alvarez Gonzalez36
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D. Álvarez Piqueras47, 48, 49
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Mariagrazia Alviggi44
- Brian Thomas Amadio50, 51
- K. Amako52
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Yara Amaral Coutinho53
- Christoph Amelung54
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D. Amidei55
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Susana Patricia Amor dos Santos24
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A. Amorim24
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Simone Amoroso56
- N. Amram11
- G. Amundsen54
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Christos Anastopoulos57
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L. S. Ancu58
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Nansi Andari18
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T. Andeen42
- Christoph Falk Anders59
- G. Anders36
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John Kenneth Anders21
- K. J. Anderson40, 41
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A. Andreazza39
- V. Andrei59
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Stylianos Angelidakis60
- I. Angelozzi7, 8
- P. Anger61
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Aaron Angerami42
- F. Anghinolfi36
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Alexey Anisenkov62, 63
- N. Anjos64, 65
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A. Annovi66
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M. Antonelli67
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А. Антонов68
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J. Antoš69, 70
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F. Anulli71
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Masato Aoki52
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L. Aperio Bella72
- G. Arabidze9
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Y. Arai52
- J. P. Araque24
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Ayana Tamu Arce73
- Francisco Anuar Arduh33, 34, 35
- J-F. Arguin74, 75
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Spyridon Argyropoulos76
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M. Arık77
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Aaron James Armbruster36
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Olivier Arnaez36
- V. Arnal78
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Hannah Arnold56
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M. Arratia79
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O. Arslan80
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A. Artamonov81
- 1. Aix-Marseille University
- 2. Institut National de Physique Nucléaire et de Physique des Particules
- 3. French National Centre for Scientific Research
- 4. University of Oklahoma
- 5. Institute of Physics, Academia Sinica
- 6. Azerbaijan National Academy of Sciences
- 7. National Institute for Subatomic Physics
- 8. University of Amsterdam
- 9. Michigan State University
- 10. University of Toronto
- 11. Tel Aviv University
- 12. Technion – Israel Institute of Technology
- 13. University of Oregon
- 14. Stockholm University
- 15. INFN Sezione di Trieste
- 16. AGH University of Krakow
- 17. Brookhaven National Laboratory
- 18. Northern Illinois University
- 19. Ludwig-Maximilians-Universität München
- 20. Rutherford Appleton Laboratory
- 21. University of Liverpool
- 22. University of Belgrade
- 23. University of Göttingen
- 24. LIP - Laboratory of Instrumentation and Experimental Particle Physics
- 25. Boston University
- 26. INFN Sezione di Roma II
- 27. Lund University
- 28. P.N. Lebedev Physical Institute of the Russian Academy of Sciences
- 29. INFN Sezione di Bologna
- 30. University of Victoria
- 31. Laboratory of Subatomic Physics and Cosmology
- 32. Université Grenoble Alpes
- 33. Instituto de Física La Plata
- 34. Consejo Nacional de Investigaciones Científicas y Técnicas
- 35. Universidad Nacional de La Plata
- 36. European Organization for Nuclear Research
- 37. Joint Institute for Nuclear Research
- 38. National Technical University of Athens
- 39. INFN Sezione di Milano
- 40. Fermi National Accelerator Laboratory
- 41. University of Chicago
- 42. Columbia University
- 43. University of Sussex
- 44. INFN Sezione di Napoli
- 45. University of Copenhagen
- 46. Queen Mary University of London
- 47. Instituto de Física Corpuscular
- 48. Institut de Microelectrònica de Barcelona
- 49. Universitat de València
- 50. Lawrence Berkeley National Laboratory
- 51. University of California, Berkeley
- 52. High Energy Accelerator Research Organization
- 53. Universidade Federal do Rio de Janeiro
- 54. Brandeis University
- 55. University of Michigan–Ann Arbor
- 56. University of Freiburg
- 57. University of Sheffield
- 58. University of Geneva
- 59. Heidelberg University
- 60. National and Kapodistrian University of Athens
- 61. TU Dresden
- 62. Budker Institute of Nuclear Physics
- 63. Siberian Branch of the Russian Academy of Sciences
- 64. Institute for High Energy Physics
- 65. Universitat Autònoma de Barcelona
- 66. INFN Sezione di Pisa
- 67. National Laboratory of Frascati
- 68. Moscow Engineering Physics Institute
- 69. Slovak Academy of Sciences
- 70. Institute of Experimental Physics
- 71. INFN Sezione di Roma I
- 72. University of Birmingham
- 73. Duke University
- 74. Institute of Particle Physics
- 75. Université de Montréal
- 76. University of Iowa
- 77. Boğaziçi University
- 78. Autonomous University of Madrid
- 79. University of Cambridge
- 80. University of Bonn
- 81. Institute for Theoretical and Experimental Physics
Description
A search for a Higgs boson produced via vector-boson fusion and decaying into invisible particles is presented, using 20.3 fb$^{-1}$ of proton--proton collision data at a centre-of-mass energy of 8 TeV recorded by the ATLAS detector at the LHC. For a Higgs boson with a mass of 125 GeV, assuming the Standard Model production cross section, an upper bound of 0.28 is set on the branching fraction of $H\to$ invisible at 95% confidence level, where the expected upper limit is 0.31. The results are interpreted in models of Higgs-portal dark matter where the branching fraction limit is converted into upper bounds on the dark-matter--nucleon scattering cross section as a function of the dark-matter particle mass, and compared to results from the direct dark-matter detection experiments.
Translated Descriptions
⚠️
This is an automatic machine translation with an accuracy of 90-95%
Translated Description (Arabic)
يتم تقديم بحث عن بوزون هيغز ينتج عن طريق اندماج بوزون متجه ويتحلل إلى جزيئات غير مرئية، باستخدام 20.3 fb$^{-1 }$ من بيانات تصادم البروتون- البروتون في طاقة مركز الكتلة البالغة 8 تيرا إلكترون فولت التي سجلها كاشف أطلس في مصادم الهدرونات الكبير. بالنسبة لبوزون هيغز بكتلة 125 جيجا فولت، بافتراض المقطع العرضي لإنتاج النموذج القياسي، يتم تعيين حد أعلى قدره 0.28 على الكسر المتفرع من $H\إلى$ غير مرئي عند مستوى ثقة 95 ٪، حيث يكون الحد الأعلى المتوقع هو 0.31. يتم تفسير النتائج في نماذج هيغز - المادة المظلمة البابية حيث يتم تحويل حد الكسر المتفرع إلى حدود عليا على المادة المظلمة - المقطع العرضي لتشتت النواة كدالة لكتلة جسيمات المادة المظلمة، ومقارنتها بالنتائج من تجارب الكشف المباشر عن المادة المظلمة.Translated Description (French)
Une recherche d'un boson de Higgs produit par fusion vecteur-boson et se désintégrant en particules invisibles est présentée, en utilisant 20,3 fb$^{-1}$ de données de collision proton-proton à une énergie de centre de masse de 8 TeV enregistrée par le détecteur ATLAS au LHC. Pour un boson de Higgs d'une masse de 125 GeV, en supposant la section efficace de production du modèle standard, une limite supérieure de 0,28 est définie sur la fraction de branchement de $H\à$ invisible à un niveau de confiance de 95 %, où la limite supérieure attendue est de 0,31. Les résultats sont interprétés dans des modèles de matière noire du portail de Higgs où la limite de la fraction de ramification est convertie en limites supérieures sur la section efficace de diffusion de la matière noire - nucléon en fonction de la masse des particules de matière noire, et comparés aux résultats des expériences de détection directe de la matière noire.Translated Description (Spanish)
Se presenta una búsqueda de un bosón de Higgs producido a través de la fusión vector-bosón y que se descompone en partículas invisibles, utilizando 20.3 fb$^{-1}$ de datos de colisión protón-protón a una energía del centro de masa de 8 TeV registrada por el detector ATLAS en el LHC. Para un bosón de Higgs con una masa de 125 GeV, suponiendo la sección transversal de producción del Modelo Estándar, se establece un límite superior de 0.28 en la fracción de ramificación de $H\a$ invisible al nivel de confianza del 95%, donde el límite superior esperado es 0.31. Los resultados se interpretan en modelos de materia oscura del portal de Higgs donde el límite de la fracción de ramificación se convierte en límites superiores en la sección transversal de dispersión de nucleones de materia oscura en función de la masa de partículas de materia oscura, y se comparan con los resultados de los experimentos directos de detección de materia oscura.Files
10.1007%2FJHEP01%282016%29172.pdf.pdf
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Additional details
Additional titles
- Translated title (Arabic)
- ابحث عن الاضمحلال غير المرئي لبوزون هيغز باستخدام اندماج المتجهات والبوزون في تصادمات البولي بروبيلين في الصورة = 8 $$\ sqrt{s}=8 $$ TeV مع كاشف أطلس
- Translated title (French)
- Rechercher les désintégrations invisibles d'un boson de Higgs en utilisant la fusion vecteur-boson dans les collisions pp à s = 8 $$ \sqrt{s}=8 $$ TeV avec le détecteur ATLAS
- Translated title (Spanish)
- Busque desintegraciones invisibles de un bosón de Higgs utilizando la fusión vector-bosón en colisiones pp en s = 8 $$ \sqrt{s}=8 $$ TeV con el detector ATLAS
Identifiers
- Other
- https://openalex.org/W2137309708
- DOI
- 10.1007/jhep01(2016)172
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