357,998 research outputs found

    Searches for scalar top and scalar bottom quarks at LEP2

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    complete author list: Barate R.; Buskulic D.; Decamp D.; Ghez P.; Goy C.; Lees J.; Lucotte A.; Minard M.; Nief J.; Pietrzyk B.; Casado M.; Chmeissani M.; Comas P.; Crespo J.; Delfino M.; Fernandez E.; Fernandez-Bosman M.; Garrido L.; Juste A.; Martinez M.; Merino G.; Miquel R.; Mir L.; Padilla C.; Park I.; Pascual A.; Perlas J.; Riu I.; Sanchez F.; Teubert F.; Colaleo A.; Creanza D.; de Palma M.; Gelao G.; Iaselli G.; Maggi G.; Maggi M.; Marinelli N.; Nuzzo S.; Ranieri A.; Raso G.; Ruggieri F.; Selvaggi G.; Silvestris L.; Tempesta P.; Tricomi A.; Zito G.; Huang X.; Lin J.; Ouyang Q.; Wang T.; Xie Y.; Xu R.; Xue S.; Zhang J.; Zhang L.; Zhao W.; Abbaneo D.; Alemany R.; Bazarko A.; Becker U.; Bright-Thomas P.; Cattaneo M.; Cerutti F.; Dissertori G.; Drevermann H.; Forty R.; Frank M.; Hagelberg R.; Hansen J.; Harvey J.; Janot P.; Jost B.; Kneringer E.; Knobloch J.; Lehraus I.; Mato P.; Minten A.; Moneta L.; Pacheco A.; Pusztaszeri J.; Ranjard F.; Rizzo G.; Rolandi L.; Rousseau D.; Schlatter D.; Schmitt M.; Schneider O.; Tejessy W.; Tomalin I.; Wachsmuth H.; Wagner A.; Ajaltouni Z.; Barrès A.; Boyer C.; Falvard A.; Ferdi C.; Gay P.; Guicheney C.; Henrard P.; Jousset J.; Michel B.; Monteil S.; Montret J.; Pallin D.; Perret P.; Podlyski F.; Proriol J.; Rosnet P.; Rossignol J.; Fearnley T.; Hansen J.; Hansen J.; Hansen P.; Nilsson B.; Rensch B.; Wäänänen A.; Daskalakis G.; Kyriakis A.; Markou C.; Simopoulou E.; Vayaki A.; Blondel A.; Brient J.; Machefert F.; Rougé A.; Rumpf M.; Valassi A.; Videau H.; Focardi E.; Parrini G.; Zachariadou K.; Cavanaugh R.; Corden M.; Georgiopoulos C.; Huehn T.; Jaffe D.; Antonelli A.; Bencivenni G.; Bologna G.; Bossi F.; Campana P.; Capon G.; Casper D.; Chiarella V.; Felici G.; Laurelli P.; Mannocchi G.; Murtas F.; Murtas G.; Passalacqua L.; Pepe-Altarelli M.; Curtis L.; Dorris S.; Halley A.; Knowles I.; Lynch J.; O'Shea V.; Raine C.; Scarr J.; Smith K.; Teixeira-Dias P.; Thompson A.; Thomson E.; Thomson F.; Turnbull R.; Buchmüller O.; Dhamotharan S.; Geweniger C.; Graefe G.; Hanke P.; Hansper G.; Hepp V.; Kluge E.; Putzer A.; Sommer J.; Tittel K.; Werner S.; Wunsch M.; Beuselinck R.; Binnie D.; Cameron W.; Dornan P.; Girone M.; Goodsir S.; Martin E.; Morawitz P.; Moutoussi A.; Nash J.; Sedgbeer J.; Spagnolo P.; Stacey A.; Williams M.; Ghete V.; Girtler P.; Kuhn D.; Rudolph G.; Betteridge A.; Bowdery C.; Colrain P.; Crawford G.; Finch A.; Foster F.; Hughes G.; Jones R.; Sloan T.; Whelan E.; Williams M.; Hoffmann C.; Jakobs K.; Kleinknecht K.; Quast G.; Renk B.; Rohne E.; Sander H.; van Gemmeren P.; Zeitnitz C.; Aubert J.; Benchouk C.; Bonissent A.; Bujosa G.; Carr J.; Coyle P.; Diaconu C.; Ealet A.; Fouchez D.; Konstantinidis N.; Leroy O.; Motsch F.; Payre P.; Talby M.; Sadouki A.; Thulasidas M.; Tilquin A.; Trabelsi K.; Aleppo M.; Antonelli M.; Ragusa F.; Berlich R.; Blum W.; Büscher V.; Dietl H.; Ganis G.; Gotzhein C.; Kroha H.; Lütjens G.; Lutz G.; Manner W.; Moser H.; Richter R.; Rosado-Schlosser A.; Schael S.; Settles R.; Seywerd H.; Denis R.; Stenzel H.; Wiedenmann W.; Wolf G.; Boucrot J.; Callot O.; Chen S.; Cordier A.; Davier M.; Duflot L.; Grivaz J.; Heusse P.; Höcker A.; Jacholkowska A.; Jacquet M.; Kim D.; Le Diberder F.; Lefrançois J.; Lutz A.; Nikolic I.; Schune M.; Serin L.; Simion S.; Tournefier E.; Veillet J.; Videau I.; Zerwas D.; Azzurri P.; Bagliesi G.; Bettarini S.; Bozzi C.; Calderini G.; Ciulli V.; Dell'Orso R.; Fantechi R.; Ferrante I.; Giassi A.; Gregorio A.; Ligabue F.; Lusiani A.; Marrocchesi P.; Messineo A.; Palla F.; Sanguinetti G.; Sciabà A.; Sguazzoni G.; Steinberger J.; Tenchini R.; Vannini C.; Venturi A.; Verdini P.; Blair G.; Bryant L.; Chambers J.; Gao Y.; Green M.; Medcalf T.; Perrodo P.; Strong J.; von Wimmersperg-Toeller J.; Botterill D.; Clifft R.; Edgecock T.; Haywood S.; Maley P.; Norton P.; Thompson J.; Wright A.; Bloch-Devaux B.; Colas P.; Fabbro B.; Kozanecki W.; Lançon E.; Lemaire M.; Locci E.; Perez P.; Rander J.; Renardy J.; Rosowsky A.; Roussarie A.; Schuller J.; Schwindling J.; Trabelsi A.; Vallage B.; Black S.; Dann J.; Kim H.; Litke A.; McNeil M.; Taylor G.; Booth C.; Boswell R.; Brew C.; Cartwright S.; Combley F.; Kelly M.; Lehto M.; Newton W.; Reeve J.; Thompson L.; Affholderbach K.; Böhrer A.; Brandt S.; Cowan G.; Foss J.; Grapen C.; Lutters G.; Saraiva P.; Smolik L.; Stephan F.; Apollonio M.; Bosisio L.; Delia Marina R.; Giannini G.; Gobbo B.; Musolino G.; Putz J.; Rothberg J.; Wasserbaech S.; Williams R.; Armstrong S.; Charles E.; Elmer P.; Ferguson D.; Gonzalez S.; Greening T.; Hayes O.; Hu H.; Jin S.; McNamara P.; Nachtman J.; Nielsen J.; Orejudos W.; Pan Y.; Saadi Y.; Scott I.; Walsh J.; Wu S.; Wu X.; Yamartino J.; Zobernig G.; Barate R.; Buskulic D.; Saadi Y.; Scott I.; Walsh J.; Wu S.; Wu X.; Yamartino J.; Zobernig G.; Hu H.; Hayes O.; McNamara P.; Jin S.; Nielsen J.; Nachtman J.; Pan Y.; Orejudos W.; Greening T.; Barate R.</p

    Measurement of the hadronic photon structure function at LEP 1 for 〈Q2〉 values between 9.9 and 284 GeV2

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    complete author list: Barate R.; Decamp D.; Ghez P.; Goy C.; Lees J.; Merle E.; Minard M.; Pietrzyk B.; Alemany R.; Casado M.; Chmeissani M.; Crespo J.; Fernandez E.; Fernandez-Bosman M.; Garrido L.; Graugès E.; Juste A.; Martinez M.; Merino G.; Miquel R.; Mir L.; Pacheco A.; Park I.; Riu I.; Colaleo A.; Creanza D.; de Palma M.; Gelao G.; Iaselli G.; Maggi G.; Maggi M.; Nuzzo S.; Ranieri A.; Raso G.; Ruggieri F.; Selvaggi G.; Silvestris L.; Tempesta P.; Tricomi A.; Zito G.; Huang X.; Lin J.; Ouyang Q.; Wang T.; Xie Y.; Xu R.; Xue S.; Zhang J.; Zhang L.; Zhao W.; Abbaneo D.; Becker U.; Boix G.; Cattaneo M.; Cerutti F.; Ciulli V.; Dissertori G.; Drevermann H.; Forty R.; Frank M.; Halley A.; Hansen J.; Harvey J.; Janot P.; Jost B.; Lehraus I.; Leroy O.; Mato P.; Minten A.; Moutoussi A.; Ranjard F.; Rolandi L.; Rousseau D.; Schlatter D.; Schmitt M.; Schneider O.; Spagnolo P.; Tejessy W.; Teubert F.; Tomalin I.; Tournefier E.; Wright A.; Ajaltouni Z.; Badaud F.; Chazelle G.; Deschamps O.; Falvard A.; Ferdi C.; Gay P.; Guicheney C.; Henrard P.; Jousset J.; Michel B.; Monteil S.; Montret J.; Pallin D.; Perret P.; Podlyski F.; Hansen J.; Hansen J.; Hansen P.; Nilsson B.; Rensch B.; Wäänänen A.; Daskalakis G.; Kyriakis A.; Markou C.; Simopoulou E.; Siotis I.; Vayaki A.; Blondel A.; Bonneaud G.; Brient J.; Rougé A.; Rumpf M.; Swynghedauw M.; Verderi M.; Videau H.; Focardi E.; Parrini G.; Zachariadou K.; Cavanaugh R.; Corden M.; Georgiopoulos C.; Antonelli A.; Bencivenni G.; Bologna G.; Bossi F.; Campana P.; Capon G.; Chiarella V.; Laurelli P.; Mannocchi G.; Murtas F.; Murtas G.; Passalacqua L.; Pepe-Altarelli M.; Curtis L.; Lynch J.; Negus P.; O'Shea V.; Raine C.; Teixeira-Dias P.; Thompson A.; Buchmüller O.; Dhamotharan S.; Geweniger C.; Hanke P.; Hansper G.; Hepp V.; Kluge E.; Putzer A.; Sommer J.; Tittel K.; Werner S.; Wunsch M.; Beuselinck R.; Binnie D.; Cameron W.; Dornan P.; Girone M.; Goodsir S.; Martin E.; Marinelli N.; Sciabà A.; Sedgbeer J.; Thomson E.; Williams M.; Ghete V.; Girtler P.; Kneringer E.; Kuhn D.; Rudolph G.; Bowdery C.; Buck P.; Finch A.; Foster F.; Hughes G.; Jones R.; Robertson N.; Williams M.; Giehl I.; Jakobs K.; Kleinknecht K.; Quast G.; Renk B.; Rohne E.; Sander H.; Wachsmuth H.; Zeitnitz C.; Aubert J.; Benchouk C.; Bonissent A.; Carr J.; Coyle P.; Etienne F.; Motsch F.; Payre P.; Talby M.; Thulasidas M.; Aleppo M.; Antonelli M.; Ragusa F.; Büscher V.; Dietl H.; Ganis G.; Hüttmann K.; Lütjens G.; Mannert C.; Männer W.; Moser H.; Schael S.; Settles R.; Seywerd H.; Stenzel H.; Wiedenmann W.; Wolf G.; Azzurri P.; Boucrot J.; Callot O.; Chen S.; Cordier A.; Davier M.; Duflot L.; Grivaz J.; Heusse P.; Jacholkowska A.; Le Diberder F.; Lefrançois J.; Lutz A.; Schune M.; Veillet J.; Videau I.; Zerwas D.; Bagliesi G.; Bettarini S.; Boccali T.; Bozzi C.; Calderini G.; Dell'Orso R.; Ferrante I.; Foà L.; Giassi A.; Gregorio A.; Ligabue F.; Lusiani A.; Marrocchesi P.; Messineo A.; Palla F.; Rizzo G.; Sanguinetti G.; Sguazzoni G.; Tenchini R.; Vannini C.; Venturi A.; Verdini P.; Blair G.; Cowan G.; Green M.; Medcalf T.; Strong J.; von Wimmersperg-Toeller J.; Botterill D.; Clifft R.; Edgecock T.; Norton P.; Thompson J.; Bloch-Devaux B.; Colas P.; Emery S.; Kozanecki W.; Lançon E.; Lemaire M.; Locci E.; Perez P.; Rander J.; Renardy J.; Roussarie A.; Schuller J.; Schwindling J.; Trabelsi A.; Vallage B.; Black S.; Dann J.; Johnson R.; Kim H.; Konstantinidis N.; Litke A.; McNeil M.; Taylor G.; Booth C.; Cartwright S.; Combley F.; Kelly M.; Lehto M.; Thompson L.; Affholderbach K.; Böhrer A.; Brandt S.; Grupen C.; Prange G.; Giannini G.; Gobbo B.; Rothberg J.; Wasserbaech S.; Armstrong S.; Charles E.; Elmer P.; Ferguson D.; Gao Y.; González S.; Greening T.; Hayes O.; Hu H.; Jin S.; McNamara P.; Nachtman J.; Nielsen J.; Orejudos W.; Pan Y.; Saadi Y.; Scott I.; Walsh J.; Wu S.; Wu X.; Zobernig G.; Wu S.; Walsh J.; Zobernig G.; Wu X.; Orejudos W.; Pan Y.; Saadi Y.; Scott I.; Barate R.</p

    RSS Discovery Cruise 341, 08 Jul – 13 Aug 2009. Porcupine Abyssal Plain time series process study

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    The Biological Carbon Pump (BCP) is a major feature of the global carbon transporting approximately 10GT C yr-1 from the ocean surface to the interior mainly via the sinking of particles with an organic component. The scale of the BCP requires good year-round measurements of its functioning. Moreover, the BCP’s susceptibility to global change means that we need better information on how its climate sensitive elements function and how its poorly parameterised elements operate. These three requirements map directly onto the objectives of this cruise, which will be undertaken using Oceans 2025 funding at the Porcupine Abyssal Plain (PAP) site. The PAP site (47oN, 16.5oW) is the location of a time series of observations from surface to seafloor compiled by IOS, GDD and now NOCS over the last 20 years (Lampitt et al., 2001). A summary of these observations, together with descriptions of surface water biogeochemistry in the region from a cruise in 2005, is currently being published as a special issue of Deep-Sea Research II. The PAP site is close to the site of the JGOFS north Atlantic Bloom experiment and the French POMME programme and is a waypoint on the Atlantic Meridional Transect programme (SO1 in Oceans 2025). There is therefore a rich wealth of previous observations in which our 2009 observations can be grounded.Objectives:1) To recover and redeploy the PAP site observatory (Theme 10 of Oceans 2025)2) To compile a vertical carbon budget for the PAP site with particular focus on the process of remineralisation in the mesopelagic (100 – 1000 m) and on the mechanisms leading to export from the upper ocean (Themes 2, 5 of Oceans 2025)3) To quantify climate sensitive elements of the BCP at the PAP site, particularly the physical processes responsible for introducing nutrients to the upper water column, which combine to set the maximum level of export (Theme 2 of Oceans 2025)Of these, 1) was partially successful, 2) was successful, 3) was unsuccessful

    Measurements of R(d) - R(p) and R(Ca) - R(C) in deep inelastic muon scattering

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    Amaudruz P, Arneodo M, Arvidson A, et al. Measurements of R(d) - R(p) and R(Ca) - R(C) in deep inelastic muon scattering. Phys.Lett. B. 1992;294(1):120-126

    The SU(3)-invariant sector of new maximal supergravity

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    We investigate the SU(3)-invariant sector of the one-parameter family of SO(8) gauged maximal supergravities that has been recently discovered. To this end, we construct the N = 2 truncation of this theory and analyse its full vacuum structure. The number of critical point is doubled and includes new N = 0 and N = 1 branches. We numerically exhibit the parameter dependence of the location and cosmological constant of all extrema. Moreover, we provide their analytic expressions for cases of special interest. Finally, while the mass spectra are found to be parameter independent in most cases, we show that the novel non-supersymmetric branch with SU(3) invariance provides the first counterexample to this.

    Perturbations in the Earth's rotation induced by internal density anomalies: implications for sea-level fluctuations

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    The effects of internal mass anomalies on the Earth's rotation are analyzed within the framework of linearized Liouville equations and Maxwell rheology for the mantle. Our approach is appropriate for a simplified modeling of subduction. Sea-level fluctuations induced by long-term rotational instabilities are also considered. -from Author

    KMGlaser/Kienle-et-al: Kienle_et_al_2021

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    R script for data analysis and visualization in Kienle et al

    RSS James Clark Ross Cruise 221, 26 May – 05 Jun 2010. PAP observatory development

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    This very short cruise was primarily to deploy a novel moored observatory at PAP (NE Atlantic), a long term study site at which a variety of observations have been made over the past 20 years with increasing levels of intensity and sophistication. This new design was in collaboration with the UK Met Office.In addition to this, a benthic lander was to be deployed which would transmit data by an acoustic link to the surface buoy and hence to land by satellite link. Unfortunately this was lost due to an imploding sphere.A number of equipment trials were also carried out to good effect. In addition studies were made on the effects of high CO2 of calcifying phytoplankton. A team of photographers were present to in order to increase public awareness of observational oceanography and numerous interviews were completed. In addition a daily web diary was maintained by the EuroSITES outreach team

    DarrahLab/Curran-et-al-2022_Cit_AgProc: Initial Release

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    R scripts and data associated with the manuscript by Ashley Curran et al. 2022, under review
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