Rubin-LSST

Searches for light- and heavy-flavour three-jet resonances in pp collisions at √s=8TeV

Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics 730 (2014) 193-214

Authors:

S Chatrchyan, V Khachatryan, AM Sirunyan, A Tumasyan, W Adam, T Bergauer, M Dragicevic, J Erö, C Fabjan, M Friedl, R Frühwirth, VM Ghete, N Hörmann, J Hrubec, M Jeitler, W Kiesenhofer, V Knünz, M Krammer, I Krätschmer, D Liko, I Mikulec, D Rabady, B Rahbaran, H Rohringer, R Schöfbeck, J Strauss, A Taurok, W Treberer-Treberspurg, W Waltenberger, CE Wulz, V Mossolov, N Shumeiko, J Suarez Gonzalez, S Alderweireldt, M Bansal, S Bansal, T Cornelis, EA De Wolf, X Janssen, A Knutsson, S Luyckx, L Mucibello, S Ochesanu, B Roland, R Rougny, Z Staykova, H Van Haevermaet, P Van Mechelen, N Van Remortel, A Van Spilbeeck, F Blekman, S Blyweert, J D'Hondt, N Heracleous, A Kalogeropoulos, J Keaveney, S Lowette, M Maes, A Olbrechts, S Tavernier, W Van Doninck, P Van Mulders, GP Van Onsem, I Villella, C Caillol, B Clerbaux, G De Lentdecker, L Favart, APR Gay, T Hreus, A Léonard, PE Marage, A Mohammadi, L Perniè, T Reis, T Seva, L Thomas, C Vander Velde, P Vanlaer, J Wang, V Adler, K Beernaert, L Benucci, A Cimmino, S Costantini, S Dildick, G Garcia, B Klein, J Lellouch, A Marinov, J Mccartin, AA Ocampo Rios, D Ryckbosch, M Sigamani, N Strobbe, F Thyssen, M Tytgat, S Walsh, E Yazgan, N Zaganidis

Abstract:

A search for three-jet hadronic resonance production in pp collisions at a centre-of-mass energy of 8 TeV has been conducted by the CMS Collaboration at the LHC with a data sample corresponding to an integrated luminosity of 19.4fb-1. The search method is model independent, and events are selected that have high jet multiplicity and large values of jet transverse momenta. The signal models explored assume R-parity-violating supersymmetric gluino pair production and have final states with either only light-flavour jets or both light- and heavy-flavour jets. No significant deviation is found between the selected events and the expected standard model multijet and tt- background. For a gluino decaying into light-flavour jets, a lower limit of 650 GeV on the gluino mass is set at a 95% confidence level, and for a gluino decaying into one heavy- and two light-flavour jets, gluino masses between 200 and 835 GeV are, for the first time, likewise excluded. © 2014 The Authors.

Planning the Future of U.S. Particle Physics (Snowmass 2013): Chapter 1: Summary

ArXiv 1401.6075 (2014)

Authors:

JL Rosner, M Bardeen, W Barletta, LAT Bauerdick, RH Bernstein, R Brock, D Cronin-Hennessy, M Demarteau, M Dine, JL Feng, M Gilchriese, S Gottlieb, N Graf, N Hadley, JL Hewett, R Lipton, P McBride, H Nicholson, ME Peskin, P Ramond, S Ritz, I Shipsey, N Varelas, H Weerts, K Yurkewicz

Abstract:

These reports present the results of the 2013 Community Summer Study of the APS Division of Particles and Fields ("Snowmass 2013") on the future program of particle physics in the U.S. Chapter 1 contains the Executive Summary and the summaries of the reports of the nine working groups.

Planning the Future of U.S. Particle Physics (Snowmass 2013): Chapter 8: Instrumentation Frontier

ArXiv 1401.6116 (2014)

Authors:

M Demarteau, R Lipton, H Nicholson, I Shipsey, D Akerib, A Albayrak-Yetkin, J Alexander, J Anderson, M Artuso, D Asner, R Ball, M Battaglia, C Bebek, J Beene, Y Benhammou, E Bentefour, M Bergevin, A Bernstein, B Bilki, E Blucher, G Bolla, D Bortoletto, N Bowden, G Brooijmans, K Byrum, B Cabrera, G Cancelo, J Carlstrom, B Casey, C Chang, J Chapman, CH Chen, I Childres, D Christian, M Convery, W Cooper J Corso, J Cumalat, P Cushman, C Da Via, S Dazeley, P Debbins, G Deptuch, S Dhawan, V Di Benedetto, B DiGiovene, Z Djurcic, S Dye, A Elagin, J Estrada, H Evans, E Etzion, J Fast, C Ferretti, P Fisher, B Fleming, K Francis, P Friedman, H Frisch, M Garcia-Sciveres, C Gatto, G Geronim, G Gilchriese, S Golwala, C Grant, A Grillo, E Grünendahl, P Gorham, L Guan, G Gutierrez, C Haber, J Hall, G Haller, C Hast, U Heintz, T Hemmick, DG Hitlin, C Hogan, M Hohlmann, E Hoppe, L Hsu, M Huffer, K Irwin, F Izraelevitch, G Jennings, M Johnson, A Jung, H Kagan, C Kenney, S Kettell, R Khanna, V Khristenko, F Krennrich, K Kuehn, R Kutschke, J Learned, AT Lee, D Levin, T Liu, ATK Liu, D Lissauer, J Love, D Lynn, D MacFarlane, S Magill, S Majewski, J Mans, J Maricic, P Marleau, A Mazzacane, D McKinsey, J Mehl, A Mestvirisvilli, S Meyer, N Mokhov, M Moshe, A Mukherjee, P Murat, S Nahn, M Narain, P Nadel-Turonski, M Newcomer, K Nishimura, D Nygren, E Oberla, Y Onel, M Oreglia, J Orrell, J Paley, A Para, S Parker, V Polychronakos, S Pordes, P Privitera, A Prosser, M Pyle, J Raaf, E Ramberg, R Rameika, B Rebel, J Repond, D Reyna, L Ristori, R Rivera, A Ronzhin, R Rusack, J Russ, A Ryd, H Sadrozinski, H Sahoo, MC Sanchez, C Sanzeni, S Schnetzer, S Seidel, A Seiden, I Schmidt, A Shenai, T Shutt, Y Silver, W Smith, D Snowden-Ifft, A Sonnenschein, D Southwick, L Spiegel, M Stanitzki, S Striganov, D Su, R Sumner, R Svoboda, M Sweany, R Talaga, R Tayloe, S Tentindo, N Terentiev, J Thom-Levy, C Thorn, J Tiffenberg, W Trischuk, R Tschirhart, M Turner, D Underwood, L Uplegger, J Urheim, M Vagins, K Van Bibber, G Varner, R Varner, J Va'vra, H Von der Lippe, R Wagner, S Wagner, C Weaverdyck, H Wenzel, A Weinstein, M Wetstein, A White, R Wigman, P Wilson, D Winn, P Winter, C Woody, L Xia, JQ Xie, Z Ye, MF Yeh, T Yetkin, JH Yoo, J Yu, JM Yu, S Zeller, JL Zhang, JJ Zhu, B Zhou, RY Zhu, B Zitzer

Abstract:

These reports present the results of the 2013 Community Summer Study of the APS Division of Particles and Fields ("Snowmass 2013") on the future program of particle physics in the U.S. Chapter 8, on the Instrumentation Frontier, discusses the instrumentation needs of future experiments in the Energy, Intensity, and Cosmic Frontiers, promising new technologies for particle physics research, and issues of gathering resources for long-term research in this area.

Search for the standard model Higgs boson produced in association with a W or a Z boson and decaying to bottom quarks

Physical Review D - Particles, Fields, Gravitation and Cosmology 89:1 (2014)

Authors:

S Chatrchyan, V Khachatryan, AM Sirunyan, A Tumasyan, W Adam, T Bergauer, M Dragicevic, J Erö, C Fabjan, M Friedl, R Frühwirth, VM Ghete, N Hörmann, J Hrubec, M Jeitler, W Kiesenhofer, V Knünz, M Krammer, I Krätschmer, D Liko, I Mikulec, D Rabady, B Rahbaran, C Rohringer, H Rohringer, R Schöfbeck, J Strauss, A Taurok, W Treberer-Treberspurg, W Waltenberger, CE Wulz, V Mossolov, N Shumeiko, J Suarez Gonzalez, S Alderweireldt, M Bansal, S Bansal, T Cornelis, EA De Wolf, X Janssen, A Knutsson, S Luyckx, L Mucibello, S Ochesanu, B Roland, R Rougny, Z Staykova, H Van Haevermaet, P Van Mechelen, N Van Remortel, A Van Spilbeeck, F Blekman, S Blyweert, J D'Hondt, N Heracleous, A Kalogeropoulos, J Keaveney, S Lowette, M Maes, A Olbrechts, S Tavernier, W Van Doninck, P Van Mulders, GP Van Onsem, I Villella, C Caillol, B Clerbaux, G De Lentdecker, L Favart, APR Gay, T Hreus, A Léonard, PE Marage, A Mohammadi, L Perniè, T Reis, T Seva, L Thomas, C Vander Velde, P Vanlaer, J Wang, V Adler, K Beernaert, L Benucci, A Cimmino, S Costantini, S Dildick, G Garcia, B Klein, J Lellouch, A Marinov, J McCartin, AA Ocampo Rios, D Ryckbosch, M Sigamani, N Strobbe, F Thyssen, M Tytgat, S Walsh, E Yazgan

Abstract:

A search for the standard model Higgs boson (H) decaying to bb̄ when produced in association with a weak vector boson (V) is reported for the following channels: W(μν)H, W(eν)H, W(τν)H, Z(μμ)H, Z(ee)H, and Z(νν)H. The search is performed in data samples corresponding to integrated luminosities of up to 5.1 inverse femtobarns at √s=7 TeV and up to 18.9 fb-1 at √s=8 TeV, recorded by the CMS experiment at the LHC. An excess of events is observed above the expected background with a local significance of 2.1 standard deviations for a Higgs boson mass of 125 GeV, consistent with the expectation from the production of the standard model Higgs boson. The signal strength corresponding to this excess, relative to that of the standard model Higgs boson, is 1.0±0.5. © 2014 CERN. Published by the American Physical Society under the terms of the Creative Commons Attribution 3.0 License. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.

A JVLA 10~degree^2 deep survey

(2014)

Authors:

Matthew Jarvis, Sanjay Bhatnagar, Marcus Brüggen, Chiara Ferrari, Ian Heywood, Martin Hardcastle, Eric Murphy, Russ Taylor, Oleg Smirnov, Chris Simpson, Vernesa Smolcic, Jeroen Stil, K van der Heyden

Abstract:

(Abridged)One of the fundamental challenges for astrophysics in the 21st century is finding a way to untangle the physical processes that govern galaxy formation and evolution. Given the importance and scope of this problem, the multi-wavelength astronomical community has used the past decade to build up a wealth of information over specific extragalactic deep fields to address key questions in galaxy formation and evolution. These fields generally cover at least 10square degrees to facilitate the investigation of the rarest, typically most massive, galaxies and AGN. Furthermore, such areal coverage allows the environments to be fully accounted for, thereby linking the single halo to the two-halo terms in the halo occupation distribution. Surveys at radio wavelengths have begun to lag behind those at other wavelengths, especially in this medium-deep survey tier. However, the survey speed offered by the JVLA means that we can now reach a point where we can begin to obtain commensurate data at radio wavelengths to those which already exists from the X-ray through to the far-infrared over ~10 square degrees. We therefore present the case for a 10 square degree survey to 1.5uJy at L-band in A or B Array, requiring ~4000 hours to provide census of star-formation and AGN-accretion activity in the Universe. For example, the observations will allow galaxies forming stars at 10Msolar/yr to be detected out to z~1 and luminous infrared galaxies (1000Msolar/yr to be found out to z~6. Furthermore, the survey area ensures that we will have enough cosmic volume to find these rare sources at all epochs. The bandwidth will allow us to determine the polarisation properties galaxies in the high-redshift Universe as a function of stellar mass, morphology and redshift.