Your search keyword '"S. Katunin"' showing total 12 results

1. Study of damages induced on ATLAS silicon by fast extracted and intense proton beam irradiation

Author

A. Gaudiello, C. Bertella, S. Katunin, G. Gemme, M. Miñano, Carlos Escobar, G. Gariano, A. Sbrizzi, E. Ruscino, A. Rovani, and A. Lapertosa

Subjects

Nuclear and High Energy Physics, Silicon, Physics::Instrumentation and Detectors, chemistry.chemical_element, 01 natural sciences, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Planar, Optics, Atlas (anatomy), 0103 physical sciences, medicine, Irradiation, Instrumentation, Radiation hardening, Physics, Large Hadron Collider, 010308 nuclear & particles physics, business.industry, Detector, medicine.anatomical_structure, chemistry, Physics::Accelerator Physics, business, Beam (structure)

Abstract

The ATLAS silicon tracker detectors are designed to sustain a high dose integrated over several years of operation. The radiation hardness should also favor the survival of the detector in case of accidental beam losses. In 2006, a measurement published for the ATLAS Pixel detector modules (silicon planar hybridly coupled with FE-I3 electronics) established that they could survive to beam losses (1.5 × 1 0 10 protons/cm2 in a single bunch) with minimal or no deterioration of performance. In this paper, preliminary results are shown, reporting the effect of a very intensive proton beam releasing a high instantaneous dose in two IBL pixel and one ITk strip module detectors at the HiRadMat facility at CERN.

Published

2019

2. Beam-loss damage experiment on ATLAS-like silicon strip modules using an intense proton beam

Author

A. Lapertosa, Miguel Ullan, G. Gariano, E. Ruscino, A. Rovani, M. Miñano, J. Fernandez-Tejero, A. Sbrizzi, C. Bertella, C. Fleta, C. Gemme, Carlos Escobar, and S. Katunin

Subjects

Physics, Nuclear and High Energy Physics, Large Hadron Collider, Silicon, Proton, Physics::Instrumentation and Detectors, business.industry, Detector, chemistry.chemical_element, Super Proton Synchrotron, Optics, Upgrade, Bunches, chemistry, Physics::Accelerator Physics, High Energy Physics::Experiment, business, Instrumentation, Beam (structure)

Abstract

The ATLAS detector community is entering in the final stages of sensor development for the future upgrade of the Large Hadron Collider (LHC). An increase by an order of magnitude of the LHC luminosity, up to 1035 cm−2s−1, will lead to an increased radiation dose delivered to the detector, especially for the devices located in the Inner Tracker. In 2018, an experimental study of the damages induced by a beam-loss over silicon strip detectors was done in the High-Radiation to Materials facility at CERN. A progressive number of proton bunches was extracted from the CERN Super Proton Synchrotron, and focused directly over the strip sensor, in order to emulate the large amount of charge typically generated in a beam-loss failure. This work presents the results obtained during this experiment, showing that Punch-Through Protection effectively protects the AC-coupling capacitors of the silicon sensors from large charge accumulations, but still this scenario could induce damages on the read-out electronics.

Published

2020

3. A Custom Online Ultrasonic Gas Mixture Analyzer With Simultaneous Flowmetry, Developed for the Upgraded Evaporative Cooling System of the ATLAS Silicon Tracker

Author

B. DiGirolamo, P. Bonneau, G. Bozza, Steve McMahon, S. Katunin, C. Degeorge, J. Berthoud, E. Da Riva, J. Botelho-Direito, M. Battistin, M. Mathieu, G. D. Hallewell, A. Bitadze, Vic Vacek, Martin Doubek, Koichi Nagai, Cecile Deterre, G. Boyd, Richard Bates, Alexandre Rozanov, Lukasz Zwalinski, O. Crespo-Lopez, M. Vitek, Jan Godlewski, N. Langevin, N. Bousson, G. Favre, S. Berry, David Robinson, D. Lombard, and C. Rossi

Subjects

Physics, Nuclear and High Energy Physics, Spectrum analyzer, Silicon, business.industry, Octafluoropropane, chemistry.chemical_element, Flow measurement, chemistry.chemical_compound, Optics, Nuclear Energy and Engineering, chemistry, Hexafluoroethane, Water cooling, Ultrasonic sensor, Electrical and Electronic Engineering, business, Evaporative cooler

Abstract

We describe a combined ultrasonic instrument for continuous gas flow measurement and simultaneous real-time binary gas mixture analysis. In the instrument, sound bursts are transmitted in opposite directions, which may be aligned with the gas flow path or at an angle to it, the latter configuration being the best adapted to high flow rates. The combined flow measurement and mixture analysis algorithm exploits the phenomenon whereby the sound velocity in a binary gas mixture at known temperature and pressure is a unique function of the molar concentration of the two components. The instrument is central to a possible upgrade to the present ATLAS silicon tracker cooling system in which octafluoropropane (C F ) evaporative cooling fluid would be replaced by a blend containing up to 25% hexafluoroethane (C 2 F 6 ). The instrument has been developed in two geometries following computational fluid dynamics studies of various mechanical layouts. An instrument with 45 crossing angle has been installed for commissioning in the ATLAS silicon tracker cooling system. It can be used in gas flows up to 20 000 l.min -1 and has demonstrated a flow resolution of 2.3% of full scale for linear flow velocities up to 10 m.s in preliminary studies with air. Other instruments are currently used to detect low levels of C 2 F 8 vapor leaking into the N 2 environmental gas surrounding the ATLAS silicon tracker. A long-duration continuous study of more than a year has demonstrated a sensitivity to mixture variation of better than 5.10 -5 .

Published

2014

4. Implementations of Custom Sonar Instruments for Binary Gas Mixture and Flow Analysis in the ATLAS Experiment at the CERN LHC

Author

B. DiGirolamo, David Robinson, A. Hasib, Richard Bates, G. Favre, A. Bitadze, G. D. Hallewell, S. McMahon, Lukasz Zwalinski, Vaclav Vacek, D. Lombard, J. Young, Muhammad Alhroob, Jan Godlewski, C. Rossi, Michael A. Strauss, Martin Doubek, O. Crespo-Lopez, C. Degeorge, S. Katunin, P. Bonneau, Benjamin Pearson, N. Bousson, S. Berry, G. Boyd, Koichi Nagai, Romain Vaglio, Michele Battistin, Alexandre Rozanov, G. Bozza, Abigail O'Rourke, Cecile Deterre, Centre de Physique des Particules de Marseille (CPPM), and Aix Marseille Université (AMU)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics, Nuclear and High Energy Physics, Large Hadron Collider, 010308 nuclear & particles physics, Acoustics, ATLAS experiment, Binary number, 01 natural sciences, 7. Clean energy, Temperature measurement, Sonar, Volumetric flow rate, Nuclear Energy and Engineering, Flow (mathematics), 0103 physical sciences, Electronic engineering, [PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex], Ultrasonic sensor, Electrical and Electronic Engineering, 010306 general physics

Abstract

International audience; Precision ultrasonic measurements in binary gas systems provide continuous real-time monitoring of mixture composition and flow. Using custom microcontroller-based electronics, we have developed sonar instruments, with numerous potential applications, capable of making continuous high-precision sound velocity measurements. The instrument measures sound transit times along two opposite directions aligned parallel to - or obliquely crossing - the gas flow. The difference between the two measured times yields the gas flow rate while their average gives the sound velocity, which can be compared with sound velocity vs. molar composition look-up curves to obtain the binary mixture at a given temperature and pressure. The look-up curves may be generated from prior measurements in known mixtures of the two components, from theoretical calculations, or from a combination of the two. We describe the instruments and their performance within numerous applications in the ATLAS experiment at the CERN Large Hadron Collider (LHC). The instruments can be of interest in other areas where continuous in-situ binary gas analysis and flowmetry are required.

Published

2016

5. Custom real-time ultrasonic instrumentation for simultaneous mixture and flow analysis of binary gases in the CERN ATLAS experiment

Author

David Robinson, J. Young, Michael A. Strauss, C. Rossi, A. Hasib, A. O'Rourke, C. Degeorge, O. Crespo-Lopez, E. Stanecka, Vaclav Vacek, S. Katunin, B. Di Girolamo, G. D. Hallewell, Alexandre Rozanov, Lukasz Zwalinski, Muhammad Alhroob, S. Berry, S. McMahon, Benjamin Pearson, R. Vaglio, Martin Doubek, G. Boyd, G. Favre, Koichi Nagai, A. Bitadze, Cecile Deterre, M. Battistin, Alexander Madsen, P. Bonneau, D. Lombard, Centre de Physique des Particules de Marseille (CPPM), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Aix Marseille Université (AMU), and Aix Marseille Université (AMU)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Nuclear and High Energy Physics, admixture [gas], Acoustics, Instrumentation, measurement methods, Sonar, 01 natural sciences, 7. Clean energy, Flow measurement, Particle detector, nitrogen, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, carbon: oxygen, 0302 clinical medicine, Nuclear magnetic resonance, Ultrasonic binary gas analysis, fluorine [carbon], Thermosiphon operation, 0103 physical sciences, acoustic [velocity], ddc:530, Gas composition, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], Detectors and Experimental Techniques, Condenser (heat transfer), gas: admixture, Physics, Evaporative cooling, 010308 nuclear & particles physics, Detector, Ultrasonic flowmetry, resolution, ATLAS, velocity: acoustic, ATLAS detector control system, acoustic [detector], Measuring instrument, carbon: fluorine, Ultrasonic sensor, oxygen [carbon], control system, detector: acoustic

Abstract

Custom ultrasonic instruments have been developed for simultaneous monitoring of binary gas mixture and flow in the ATLAS Inner Detector. Sound transit times are measured in opposite directions in flowing gas. Flow rate and sound velocity are respectively calculated from their difference and average. Gas composition is evaluated in real-time by comparison with a sound velocity/composition database, based on the direct dependence of sound velocity on component concentrations in a mixture at known temperature and pressure. Five devices are integrated into the ATLAS Detector Control System. Three instruments monitor coolant leaks into N2 envelopes of the silicon microstrip and Pixel detectors. Resolutions better than ±2×10−5±2×10−5 and ±2×10−4±2×10−4 are seen for C3F8 and CO2 leak concentrations in N2 respectively. A fourth instrument detects sub-percent levels of air ingress into the C3F8 condenser of the new thermosiphon coolant recirculator. Following extensive studies a fifth instrument was built as an angled sound path flowmeter to measure the high returning C3F8 vapour flux View the MathML source(∼1.2kgs−1). A precision of

Published

2016

6. The ATLAS transition radiation tracker

Author

S. Kovalenko, A. S. Romanyuk, Vadim Kantserov, E. G. Novodvorskii, S. Yu. Smirnov, D. M. Seliverstov, Lidia Smirnova, S.B. Oleshko, V. Sosnovtsev, Igor Gavrilenko, Victor Maleev, S. Katunin, B. Dolgoshein, S. Yu. Sivoklokov, S. Muraviev, N V Kondratieva, S. Patrichev, S.P. Konovalov, S. V. Morozov, Nikolay Nikitin, V. V. Mialkovskii, O Novgorodova, L. F. Vasilieva, V. Bondarenko, I. Kudryashov, Vladimir Peshekhonov, Alexey Boldyrev, V. N. Bychkov, S. I. Suchkov, N V Klopov, N. A. Korotkova, E. Sedykh, Vladimir Sulin, L.G. Kudin, Konstantin Zhukov, E. M. Khabarova, Y. F. Ryabov, S Lobastov, F. Kayumov, Yu. V. Gusakov, G. D. Kekelidze, N. Grigalashvili, Vladimir Tikhomirov, Oleg Fedin, A. A. Savenkov, R. Yu. Mashinistov, Viktor Kramarenko, Alevtina Shmeleva, V. M. Lysan, Ya. V. Grishkevich, K Levterov, and A. V. Nadtochii

Subjects

Physics, Particle physics, Large Hadron Collider, Muon, COSMIC cancer database, Physics::Instrumentation and Detectors, Detector, Nuclear physics, medicine.anatomical_structure, Transition radiation, Atlas (anatomy), medicine, Physics::Accelerator Physics, High Energy Physics::Experiment, Instrumentation

Abstract

The transition radiation tracker of the ATLAS setup, which is one of the two multipurpose detectors at the Large Hadron Collider (LHC), its design, and the tasks it performs are described. The tracker is fully assembled and commissioned. The first physical results obtained by the tracker in the ATLAS cosmic muon runs are presented.

Published

2012

7. Implementation of an ultrasonic instrument for simultaneous mixture and flow analysis of binary gas systems

Author

D. Lombard, S. McMahon, R. Vaglio, Martin Doubek, M. Mathieu, M. Battistin, David Robinson, P. Bonneau, Cecile Deterre, G. Favre, Michael A. Strauss, Ahmed Hasib, Lukasz Zwalinski, J. Young, G. Boyd, Jan Godlewski, G. Bozza, A. O'Rourke, C. Rossi, Richard Bates, Alexandre Rozanov, Koichi Nagai, B. DiGirolamo, N. Langevin, S. Katunin, S. Berry, Vaclav Vacek, G. D. Hallewell, Benjamin Pearson, A. Bitadze, N. Bousson, C. Degeorge, M. Alhroob, and O. Crespo-Lopez

Subjects

Physics, Microcontroller, Large Hadron Collider, Flow (mathematics), Acoustics, ATLAS experiment, Binary number, Ultrasonic sensor, Electronics, Volumetric flow rate

Abstract

Precision ultrasonic measurements in binary gas systems provide continuous real-time monitoring of mixture composition and flow. Using custom microcontroller-based electronics, we have developed an ultrasonic instrument, with numerous potential applications, capable of making continuous high-precision sound velocity measurements. The instrument measures sound transit times along two opposite directions aligned parallel to — or obliquely crossing — the gas flow. The difference between the two measured times yields the gas flow rate while their average gives the sound velocity, which can be compared with a sound velocity vs. molar composition look-up table for the binary mixture at a given temperature and pressure. The look-up table may be generated from prior measurements in known mixtures of the two components, from theoretical calculations, or from a combination of the two. We describe the instrument and its performance within numerous applications in the ATLAS experiment at the CERN Large Hadron Collider (LHC). The instrument can be of interest in other areas where continuous in-situ binary gas analysis and flowmetry are required.

Published

2015

8. Acceptance tests and criteria of the ATLAS transition radiation tracker

Author

P. Cwetanski, T. Akesson, F. Anghinolfi, E. Arik, O.K. Baker, E. Banas, S. Baron, D. Benjamin, H. Bertelsen, V. Bondarenko, V. Bytchkov, J. Callahan, M. Capeans, L. Cardiel-Sas, A. Catinaccio, S.A. Cetin, J.T. Chandler, M. Dam, H. Danielsson, F. Dittus, B. Dolgoshein, N. Dressnandt, W.L. Ebenstein, P. Eerola, K. Egorov, P. Farthouat, O. Fedin, D. Froidevaux, P. Gagnon, C. Gay, N. Ghodbane, Y. Grichkevitch, N. Grigalashvili, J. Grognuz, Z. Hajduk, P. Hansen, S. Katunin, F. Kayumov, P.T. Keener, G. Kekelidze, A. Khristatchev, T. Kittelmann, S. Konovalov, L. Koudine, S. Kovalenko, T. Kowalski, V.A. Kramarenko, K. Kruger, A. Laritchev, B.C. LeGeyt, P. Lichard, F. Luehring, B. Lundberg, R. Mackeprang, V. Maleev, I. Markina, A.J. Martin, K.W. McFarlane, V. Mialkowski, S. Michine, B. Mindur, V.A. Mitsou, U. Mjornmark, S. Morozov, A. Munar, S. Muraviev, A. Nadtochy, S. Nesterov, F.M. Newcomer, N. Nikitine, H. Ogren, S.H. Oh, S. Oleshko, J. Olszowska, S. Patritchev, V. Peshekhonov, R. Petti, M. Price, C. Rembser, O. Rohne, A. Romaniouk, D.R. Rust, Y. Ryabov, V. Ryjov, V. Schegelsky, M.P. Schmidt, D. Seliverstov, T. Shin, A. Shmeleva, S. Smirnov, V. Sosnovtsev, S. Soutchkov, G. Sprachmann, V. Tikhomirov, R. Van Berg, V.I. Vassilakopoulos, L. Vassilieva, C. Wang, H.H. Williams, A. Zalite, and Y. Zalite

Subjects

Physics, Nuclear and High Energy Physics, Large Hadron Collider, business.industry, Detector, Charged particle, Optics, Nuclear Energy and Engineering, Transition radiation, Neutron flux, Acceptance testing, Nuclear electronics, Electronic engineering, Dosimetry, Electrical and Electronic Engineering, business

Abstract

The Transition Radiation Tracker (TRT) sits at the outermost part of the ATLAS Inner Detector, encasing the Pixel Detector and the Semi-Conductor Tracker (SCT). The TRT combines charged particle track reconstruction with electron identification capability. This is achieved by layers of xenon-filled straw tubes with periodic radiator foils or fibers providing TR photon emission. The design and choice of materials have been optimized to cope with the harsh operating conditions at the LHC, which are expected to lead to an accumulated radiation dose of 10 Mrad and a neutron fluence of up to 2middot1014 n/cm2 after ten years of operation. The TRT comprises a barrel containing 52 000 axial straws and two end-cap parts with 320 000 radial straws. The total of 420 000 electronic channels (two channels per barrel straw) allows continuous tracking with many projective measurements (more than 30 straw hits per track). The assembly of the barrel modules in the US has recently been completed, while the end-cap wheel construction in Russia has reached the 50% mark. After testing at the production sites and shipment to CERN, all modules and wheels undergo a series of quality and conformity measurements. These acceptance tests survey dimensions, wire tension, gas-tightness, high-voltage stability and gas-gain uniformity along each individual straw. This paper gives details on the acceptance criteria and measurement methods. An overview of the most important results obtained to-date is also given

Published

2005

9. Development of a custom on-line ultrasonic vapour analyzer and flow meter for the ATLAS inner detector, with application to Cherenkov and gaseous charged particle detectors

Author

Michael A. Strauss, N. Bousson, A. O'Rourke, Koichi Nagai, N. Langevin, Muhammad Alhroob, A. Hasib, Benjamin Pearson, Martin Doubek, G. Favre, Richard Bates, G. Bozza, Lukasz Zwalinski, S. McMahon, S. Berry, A. Bitadze, P. Bonneau, C. Degeorge, Vaclav Vacek, David Robinson, B. DiGirolamo, O. Crespo-Lopez, M. Battistin, J. Godlewski, Cecile Deterre, S. Katunin, D. Lombard, C. Rossi, Alexandre Rozanov, Gregory David Hallewell, M. Mathieu, and G. Boyd

Subjects

Physics, Spectrum analyzer, business.industry, Detector, Electrical engineering, Flow measurement, Particle detector, Coolant, Optics, Measuring instrument, Detectors and Experimental Techniques, business, Instrumentation, Condenser (heat transfer), Mathematical Physics, Cherenkov radiation

Abstract

Precision sound velocity measurements can simultaneously determine binary gas composition and flow. We have developed an analyzer with custom microcontroller-based electronics, currently used in the ATLAS Detector Control System, with numerous potential applications. Three instruments monitor C(3)F(8) and CO(2) coolant leak rates into the nitrogen envelopes of the ATLAS silicon microstrip and Pixel detectors. Two further instruments will aid operation of the new thermosiphon coolant recirculator: one of these will monitor air leaks into the low pressure condenser while the other will measure return vapour flow along with C(3)F(8)/C(2)F(6) blend composition, should blend operation be necessary to protect the ATLAS silicon tracker under increasing LHC luminosity. We describe these instruments and their electronics.

Published

2015

10. A custom on-line ultrasonic gas mixture analyzer with simultaneous flowmetry developed for use in the LHC-ATLAS experiment, with wide application in high and low flow gas delivery systems

Author

Richard Bates, N. Bousson, G. Favre, David Robinson, P. Bonneau, S. Katunin, B. DiGirolamo, D. Lombard, S. Berry, C. Rossi, O. Crespo-Lopez, C. Degeorge, G. Bozza, Steve McMahon, Martin Doubek, Vic Vacek, G. D. Hallewell, J. Berthoud, Koichi Nagai, Jan Godlewski, M. Vitek, M. Battistin, G. Boyd, Cecile Deterre, J. Botelho-Direito, Alexandre Rozanov, A. Bitadze, N. Langevin, Lukasz Zwalinski, E. Da Riva, and M. Mathieu

Subjects

Physics, business.industry, Acoustics, ATLAS experiment, Electrical engineering, Flow measurement, chemistry.chemical_compound, chemistry, Hexafluoroethane, Water cooling, Fluid dynamics, Ultrasonic sensor, Gas composition, business, Evaporative cooler

Abstract

We describe a combined ultrasonic instrument for continuous gas flow measurement and simultaneous real-time binary gas mixture analysis. In the instrument, sound bursts are transmitted in opposite directions, which may be aligned with the gas flow path or at an angle to it, the latter configuration being the best adapted to high flow rates. Custom electronics based on Microchip® dsPIC and ADuC847 microcontrollers transmits 50kHz ultrasound pulses and measures transit times in the two directions together with the process gas temperature and pressure. The combined flow measurement and mixture analysis algorithm exploits the phenomenon whereby the sound velocity in a binary gas mixture at known temperature and pressure is a unique function of the molar concentration of the two components. The instrument is central to a possible upgrade to the present ATLAS silicon tracker cooling system in which octafluoropropane (C3F8) evaporative cooling fluid would be replaced by a blend containing up to 25% hexafluoroethane (C2F6). Such a blend will allow a lower evaporation temperature and will afford the tracker silicon substrates a better safety margin against leakage current-induced thermal runaway caused by cumulative radiation damage as the luminosity profile at the CERN Large Hadron Collider (LHC) increases. The instrument has been developed in two geometries following computational fluid dynamics studies of various mechanical layouts. An instrument with 45° crossing angle has been built in stainless steel and installed for commissioning in the ATLAS silicon tracker evaporative fluorocarbon cooling system. It can be used in gas flows up to 20000 l.min-1, and has demonstrated a flow resolution of 2.3% of full scale for linear flow velocities up to 10 m.s-1 in preliminary studies with air. Other instruments are currently used to detect low levels of C3F8 vapour leaking into the N2 environmental gas surrounding the ATLAS silicon tracker. Gas from several parts of the tracker is aspirated through two instruments and analyzed. A long duration continuous study of more than a year has demonstrated a sensitivity to mixture variation of better than 5.10-5. The developed instrument has many applications where continuous knowledge of binary gas composition is required. Such applications include anaesthesia, the analysis of hydrocarbon mixtures, and vapour mixtures for semiconductor manufacture.

Published

2013

11. Aging effects in the ATLAS transition radiation tracker and gas filtration studies

Author

T. Akesson, F. Anghinolfi, E. Arik, O.K. Baker, E. Banas, S. Baron, D. Benjamin, H. Bertelsen, V. Bondarenko, V. Bytchkov, J. Callahan, M. Capeans, L. Cardiel-Sas, A. Catinaccio, S.A. Cetin, J.T. Chandler, P. Cwetanski, M. Dam, H. Danielsson, F. Dittus, B. Dolgoshein, N. Dressnandt, C. Driouichi, W.L. Ebenstein, P. Eerola, K. Egorov, P. Farthouat, O. Fedin, D. Froidevaux, P. Gagnon, null C. Gay, N. Ghodbane, Y. Grichkevitch, N. Grigalashvili, J. Grognuz, Z. Hajduk, P. Hansen, S. Katunin, F. Kayumov, P.T. Keener, G. Kekelidze, A. Khristatchev, T.H. Kittelmann, S. Konovalov, L. Koudine, S. Kovalenko, T. Kowalski, V.A. Kramarenko, K. Kruger, A. Laritchev, B. LeGeyt, P. Lichard, F. Luehring, B. Lundberg, R. Mackeprang, V. Maleev, I. Markina, A.J. Martin, K.W. McFarlane, V. Mialkowski, S. Michine, B. Mindur, V.A. Mitsou, U. Mjornmark, S. Morozov, A. Munar, S. Muraviev, A. Nadtochy, S. Nesterov, F.M. Newcomer, N. Nikitine, H. Ogren, null S. H. Oh, S. Oleshko, J. Olszowska, S. Patritchev, V. Peshekhonov, R. Petti, M. Price, C. Rembser, O. Rohne, A. Romaniouk, D.R. Rust, Yu. Ryabov, V. Ryjov, V. Schegelsky, M.P. Schmidt, D. Seliverstov, null T. Shin, A. Shmeleva, S. Smirnov, V. Sosnovtsev, S. Soutchkov, G. Sprachmann, V. Tikhomirov, R. Van Berg, V.I. Vassilakopoulos, L. Vassilieva, null C. Wang, H.H. Williams, A. Zalite, and Yu. Zalite

Subjects

Physics, Wire chamber, Luminosity (scattering theory), Large Hadron Collider, Transition radiation, Physics::Instrumentation and Detectors, Nuclear engineering, Detector, ATLAS experiment, Gas detector, Detectors and Experimental Techniques, Tracking (particle physics)

Abstract

The transition radiation tracker (TRT) is one of three particle tracking detectors now under construction for the ATLAS experiment, whose goal is to exploit the highly exciting new physics potential at CERN's next accelerator, the so called Large Hadron Collider (LHC). The TRT consists of 370000 straw proportional tubes of 4 mm diameter with a 30 micron thick anode wire, which will be operated with a Xe/CO2 /O2 gas mixture at a high voltage of approximately 1.5 kV. While the construction of the TRT is now well under way, a number of interesting and challenging questions need to be solved with regard to wire aging phenomena, which are induced by pollution originating from very small amounts of silicon-based vacuum materials in some components of the gas system. Finally a guideline to avoid aging in wire chamber detectors in high luminosity experiments is given

Published

2005

12. The evaporative cooling system for the ATLAS inner detector

Author

C. Menot, E. Vigeolas, F. McEwan, R. Apsimon, V. Sopko, Siegfried Wenig, J. Thadome, H. Sandaker, S L Nielsen, K. Fowler, A C Smith, J. Tarrant, Danilo Giugni, R. Nicholson, P Ferrari, A. Nichols, S W Lindsay, F Perez-Gomez, S Butterworth, M D Gibson, J. T. Fraser, S. McMahon, P Feraudet, E. Perrin, O. Dorholt, J P Bizzel, Tim Jones, F. Doherty, E. Anderssen, L E Batchelor, L. Luisa, A A Carter, P Bonneau, Leonardo Paolo Rossi, M. Turala, K. Egorov, Richard French, E Danilevich, P. Barclay, Jonathan Butterworth, N. Dixon, J. Kaplon, DJ Attree, Britt Anderson, S. Stapnes, Andrea Catinaccio, G Gariano, P S Wells, B. T. Gorski, John Verlin Morris, M. Doubrava, N. Massol, Koichi Nagai, M. Olcese, A. C. Falou, J N Jackson, P. Werneke, R. J. Hawkings, S Infante, J. R. Carter, P E Nordahl, Jan Godlewski, Stephen Haywood, S Katunin, J. Bendotti, M. Battistin, E. van der Kraaij, Daniel Tovey, H. O. Danielsson, M. Tyndel, A Rovani, A. Bitadze, S. D. Dixon, Richard Nickerson, N. Hartman, M. G. D. Gilchriese, M. Parodi, J. Mistry, M Galuska, Gregory David Hallewell, Heinz Pernegger, F Corbaz, S Berry, D. Muskett, N P Hessey, Vaclav Vacek, Kevin Einsweiler, I Gousakov, E Ruscino, Fred Gannaway, Richard Bates, Marek Stodulski, V Akhnazarov, G. H. A. Viehhauser, M Bosteels, I. Ilyashenko, Centre de Physique des Particules de Marseille (CPPM), Aix Marseille Université (AMU)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Laboratoire d'Annecy de Physique des Particules (LAPP), Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS), and ATLAS

Subjects

Physics::Instrumentation and Detectors, Mechanical engineering, Cryogenics, 01 natural sciences, 7. Clean energy, Particle detector, Atlas (anatomy), 0103 physical sciences, medicine, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], Detectors and Experimental Techniques, 010306 general physics, Instrumentation, Mathematical Physics, Physics, Large Hadron Collider, 010308 nuclear & particles physics, business.industry, ATLAS experiment, Detector, Electrical engineering, Semiconductor detector, medicine.anatomical_structure, High Energy Physics::Experiment, business, Evaporative cooler

Abstract

This paper describes the evaporative system used to cool the silicon detector structures of the inner detector sub-detectors of the ATLAS experiment at the CERN Large Hadron Collider. The motivation for an evaporative system, its design and construction are discussed. In detail the particular requirements of the ATLAS inner detector, technical choices and the qualification and manufacture of final components are addressed. Finally results of initial operational tests are reported. Although the entire system described, the paper focuses on the on-detector aspects. Details of the evaporative cooling plant will be discussed elsewhere. © 2008 IOP Publishing Ltd and SISSA.

Published

2008