CERN Accelerating science

CERN Document Server 199 registres trobats  1 - 10següentfinal  anar al registre: La cerca s'ha fet en 0.63 segons. 
1.
Cryogenic thermosiphon used for indirect cooling of superconducting magnets / Głuchowska, Weronika (CERN ; Wroclaw Tech. U.) ; Banaszkiewicz, Tomasz (Wroclaw Tech. U.) ; Mentink, Matthias (CERN) ; Cure, Benoit (CERN) ; Dudarev, Alexey (CERN) ; Singh, Shuvay (CERN)
A thermosiphon is a thermodynamic phenomenon that facilitates the circulation of cryogen within a cooling system, relying solely on gravitational forces and phase change. This mechanism leverages the variations in the density of the cryogenic fluid throughout the entire cooling loop, creating a pressure gradient. [...]
2024 - 10 p. - Published in : Cryogenics 143 (2024) 103951 Fulltext: PDF;
2.
HTS Detector Magnet Demonstrator Based on a 3D-Printed Partially-Insulated Support Cylinder / Eijnden, Joep L Van den (CERN ; Eindhoven, Tech. U.) ; Vaskuri, Anna K (CERN) ; Curé, Benoit (CERN) ; Dudarev, Alexey (CERN) ; Mentink, Matthias (CERN)
In this work, we extend the experimental demonstration of partially-insulated, ultra-radiation transparent detector magnet technology based on a 3D-printed aluminium alloy support structure containing 10% of silicon. This demonstrator magnet has a bore diameter of 390 mm, effective wall thickness of 3.7 mm, and it has 15 turns corresponding to 19 meters of HTS conductor. [...]
2024 - 4 p. - Published in : IEEE Trans. Appl. Supercond. 34 (2024) 4604804 Fulltext: PDF;
3.
Characteristics of Aluminium-Stabilized HTS Detector Magnet Cable at 4 K and 5 T / Vaskuri, Anna K (CERN) ; Van den Eijnden, Joep L (CERN ; Eindhoven, Tech. U.) ; Curé, Benoit (CERN) ; Dudarev, Alexey (CERN) ; Mentink, Matthias (CERN)
A high-temperature superconducting (HTS) cable for future particle detector magnets has been developed using a 99.3% pure aluminium alloy as a stabilizer for the HTS. This HTS conductor features a stack of four ReBCO tapes (4 mm wide, SuperOx) soldered to a tin-coated copper-clad aluminium alloy cable profile using tin–lead solder at 188 °C. [...]
2024 - 6 p. - Published in : IEEE Trans. Appl. Supercond. 34 (2024) 1-6 Fulltext: PDF;
4.
Towards Ultra-Thin Detector Magnet Designs by Insulating Coil Windings With V$_2$0$_3$-Epoxy Composite / Vaskuri, Anna (CERN) ; Curé, Benoit (CERN) ; Dudarev, Alexey (CERN) ; Mentink, Matthias (CERN) ; Pfeiffer, Stephan (CERN) ; Teissandier, Benoit (CERN)
We have measured temperature dependent resistivity of two types of vanadium oxide (V 2 O 3 ) epoxy composites from 77 K to room temperature. Such a composite could be used as an insulating layer between the windings of a superconducting magnet. [...]
2023 - 4 p. - Published in : IEEE Trans. Appl. Supercond. 33 (2023) 1-4
5.
Annual Report 2023 and Phase-I Closeout / Aglieri Rinella, Gianluca
This report summarises the activities of the CERN strategic R&D programme on technologies for future experiments during the year 2023, and highlights the achievements of the programme during its first phase 2020-2023..
CERN-EP-RDET-2024-001 - 208.

6.
Fifteen Years of Operation of the Compact Muon Solenoid Detector Superconducting Magnet / Curé, Benoit (CERN) ; Le Godec, Gilles (CERN) ; Ostrega, Maciej (CERN) ; Wagner, Udo (CERN)
The Compact Muon Solenoid (CMS) detector magnet has been in operation since 2008 at CERN's Large Hadron Collider (LHC). It will have to operate until the end of the High-Luminosity LHC run, beyond 2040. [...]
2024 - 8 p. - Published in : IEEE Trans. Appl. Supercond. 34 (2024) 1-8 Fulltext: PDF;
7.
Self-protected high-temperature superconducting demonstrator magnet for particle detectors / Van den Eijnden, Joep L (CERN ; Eindhoven, Tech. U.) ; Vaskuri, Anna K (CERN) ; Curé, Benoit (CERN) ; Dudarev, Alexey (CERN) ; Mentink, Matthias (CERN)
A high temperature superconducting (HTS) demonstration coil has been developed in the frame of the Experimental Physics department Research and Development program at CERN The magnet extends the recent experimental demonstration of aluminium-stabilised HTS conductors and supports the development of future large scale detector magnets. The HTS magnet has five turns and an open bore diameter of 230 mm. [...]
2023 - 14 p. - Published in : Supercond. Sci. Technol. 37 (2024) 015007 Fulltext: PDF;
8.
Comparison of Two Detector Magnetic Systems for the Future Circular Hadron-Hadron Collider / Klyukhin, Vyacheslav (SINP, Moscow ; CERN) ; Ball, Austin (CERN) ; Berriaud, Christophe Paul (IRFU, Saclay) ; Curé, Benoit (CERN) ; Dudarev, Alexey (CERN) ; Gaddi, Andrea (CERN) ; Gerwig, Hubert (CERN) ; Hervé, Alain (Wisconsin U., Madison) ; Mentink, Matthias (CERN) ; Riegler, Werner (CERN) et al.
The conceptual design study of a Future Circular hadron-hadron Collider (FCC-hh) to be con-structed at CERN with a center-of-mass energy of the order of 100 TeV requires superconducting magnetic systems with a central magnetic flux density of an order of 4 T for the experimental detectors. The developed concept of the FCC-hh detector involves the use of an iron-free magnetic system consisting of three superconducting solenoids. [...]
arXiv:2401.02835.- 2023-09-17 - 11 p. - Published in : Appl. Sciences 13 (2023) 10387 Fulltext: document - PDF; 2401.02835 - PDF;
9.
MOSFET-based HTS flux pump / Jurčo, Róbert (CERN ; Charles U.) ; Vaskuri, Anna (CERN) ; Curé, Benoit (CERN) ; Dudarev, Alexey (CERN) ; Mentink, Matthias (CERN)
We have developed a high-temperature superconducting (HTS) flux pump using high-power metal-oxide-semiconductor field-effect transistors (MOSFETs) for switching. For its primary coil, two commercial transformers are utilized, each consisting of two copper coils wound on a single iron core, which enables changing the load current over primary current ratio (101 or 194) between the primary and secondary coils. [...]
2023 - 11 p. - Published in : Supercond. Sci. Technol. 36 (2023) 115025 Fulltext: PDF;
10.
Development of the CMS detector for the CERN LHC Run 3 / CMS Collaboration
Since the initial data taking of the CERN LHC, the CMS experiment has undergone substantial upgrades and improvements. This paper discusses the CMS detector as it is configured for the third data-taking period of the CERN LHC, Run 3, which started in 2022. [...]
arXiv:2309.05466; CMS-PRF-21-001; CERN-EP-2023-136; CMS-PRF-21-001-003.- Geneva : CERN, 2024-05-23 - 257 p. - Published in : JINST 19 (2024) P05064 Fulltext: CMS-PRF-21-001-arXiv - PDF; 2309.05466 - PDF; Fulltext from Publisher: PDF; External links: Additional information for the analysis; CMS AuthorList
In : The Large Hadron Collider and The Experiments for Run 3

CERN Document Server : 199 registres trobats   1 - 10següentfinal  anar al registre:
Vegeu també: autors amb noms similars
59 Cure, B
15 Cure, B.
135 Cure, Benoit
135 Curè, Benoit
15 Curé, B.
135 Curé, Benoit
135 Curé, Benoît
Us interessa rebre alertes sobre nous resultats d'aquesta cerca?
Definiu una alerta personal via correu electrònic o subscribiu-vos al canal RSS.
No heu trobat el que estaveu cercant? Proveu la vostra cerca a:
Curé, B dins Amazon
Curé, B dins CERN EDMS
Curé, B dins CERN Intranet
Curé, B dins CiteSeer
Curé, B dins Google Books
Curé, B dins Google Scholar
Curé, B dins Google Web
Curé, B dins IEC
Curé, B dins IHS
Curé, B dins INSPIRE
Curé, B dins ISO
Curé, B dins KISS Books/Journals
Curé, B dins KISS Preprints
Curé, B dins NEBIS
Curé, B dins SLAC Library Catalog
Curé, B dins Scirus