G. Suberlucq
CERN
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Featured researches published by G. Suberlucq.
Archive | 2000
T. Raubenheimer; H Trautner; F Perriollat; Gilles Carron; Paul A. Pearce; J.C. Godot; Daniel Schulte; Philippe Royer; Steffen Döbert; Rudolf Bossart; A. Ferrari; G. Suberlucq; R. Assmann; Gunther Geschonke; L Groening; L. Thorndahl; Francesco Ruggiero; Louis Rinolfi; T. Kamitani; Olivier Napoly; F. Zhou; Erk Jensen; R. Corsini; Thys Risselada; Antonio Millich; H. Braun; J P Delahaye; Frederick F. Becker; Williame Coosemans; A Verdier
A possible design of a multi-TeV e+e- linear collider is presented. The design is based on the CLIC (Compact Linear Collider) two-beam technology proposed and developed at CERN. Though the study has shown that this technology is applicable to a linear collider with centre-of-mass energies from 500 GeV or less up to 5 TeV, the present report focuses on the nominal energy of 3 Te V. First, a short overview is given of the physics that could possibly be done with such a collider. Then, the description of the main-beam complex covers the injection system, the 30 GHz main linac, and the beam delivery system. The presentation of the RF power source includes the beam-generation scheme, the drive-beam decelerator, which consists of several 625 m long units running parallel to the main linac, and the power-extraction system. Finally, brief outlines are given of all the CLIC test facilities. They cover in particular the new CLIC test facility CTF3 which will demonstrate the feasibility of the power production technique, albeit on a reduced scale, and a first full-scale single-drive-beam unit, CLICI, to establish the overall feasibility of the scheme.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 1994
E. Chevallay; J. Durand; S. Hutchins; G. Suberlucq; M. Wurgel
Abstract In the framework of the CERN linear collider project (CLIC) the CLIC test facility (CTF) uses a laser driven photocathode in an rf gun as an electron source. Photocathode properties are measured in the photoemission laboratory, which contains a preparation chamber and a dc electron gun, followed by a beam measurement line. Cathodes are illuminated by a nanosecond UV YAG laser. The present note concerns the present installation and summarises different photocathode tests on metallic as well as alkali cathodes. Those used in the rf gun of the CTF are particularly emphasized.
Journal of Applied Physics | 1996
A. di Bona; F. Sabary; S. Valeri; P. Michelato; D. Sertore; G. Suberlucq
Thin films of Cs2Te have been produced and analyzed by Auger depth profiling and x‐ray photoemission spectroscopy (XPS). The formation of the photoemissive material passes through different phases, each of them has been characterized by XPS and by its total yield in the spectral region 3.5–5 eV. Copper and molybdenum substrates have been considered. While Mo behaves to all practical purposes like an ideal support for Cs2Te, strong diffusion from the substrate material into the photoemissive film has been observed on photocathodes fabricated on Cu. The ruggedness of the photocathodes has been tested by exposing them to a few hundred Langmuirs of different gases, namely O2, CO2, CO, N2, and CH4. The last three have no effect on the photocathode lifetime, while a substantial reduction of the quantum efficiency has been observed after the exposure to oxygen. The main reason for this is the formation of a thick cesium oxide layer at the surface of the photocathode. However, the oxygen pollution can be partiall...
Proceedings Particle Accelerator Conference | 1995
Rudolf Bossart; H. Braun; F. Chautard; M. Comunian; J P Delahaye; J.C. Godot; I. Kamber; J. H. B. Madsen; Louis Rinolfi; S. Schreiber; G. Suberlucq; Ian H Wilson; Walter Wuensch
The objectives of the CLIC Test Facility (CTF) are to study the generation of short intense electron bunches using a laser driven photocathode in an RF gun, to generate 30 GHz RF power for high gradient tests of prototype CLIC components, and to test beam position monitors. The performance of the CTF has improved dramatically in the course of the past year and highlights are presented.
High energy density microwaves | 1999
Rudolf Bossart; H. Braun; G. Carron; M. Chanudet; F. Chautard; J P Delahaye; J.C. Godot; S. Hutchins; C. Martinez; G. Suberlucq; P. Tenenbaum; L. Thorndahl; H. Trautner; M. Valentini; Ian H Wilson; Walter Wuensch
The Compact Linear Collider (CLIC) Test Facility (CTF II) at CERN has recently demonstrated Two-Beam power production and acceleration at 30 GHz. With 41 MW of 30 GHz power produced in 14 ns pulses at a repetition rate of 5 Hz, the main beam has been accelerated by 28 MeV. The 30 GHz RF power is extracted in low impedance decelerating structures from a low-energy, high-current “drive beam” which runs parallel to the main beam. The average current in the drive-beam train is 25 A, while the peak current exceeds 2 kA. Crosschecks between measured drive-beam charge, 30 GHz power and main-beam energy gain are in good agreement. In this paper, some relevant experimental and technical issues on drive-beam generation, two-beam power production and acceleration are presented.
Prepared for | 1996
Hans-Heinrich Braun; Louis Rinolfi; I. Kamber; R. Corsini; Walter Wuensch; G. Suberlucq; S. Hutchins; L. Thorndahl; J.C. Godot; F. Chautard; J. H. B. Madsen; G. Rossat; S. Schreiber; K. Aulenbacher; J P Delahaye; Rudolf Bossart; Ian H Wilson
Archive | 1994
Rudolf Bossart; Jonathan P H Sladen; J. H. B. Madsen; Walter Wuensch; S. Schreiber; J.C. Godot; Louis Rinolfi; H. Braun; J P Delahaye; Kryno K Geissler; G. Suberlucq; Ian H Wilson
Archive | 1998
E. Chevallay; J. Durand; S. Hutchins; G. Suberlucq; H. Trautner
Acta Physica Polonica B | 1998
Jean-Pierre Delahaye; Rudolf Bossart; H. Braun; G. Carron; F. Chautard; W. Coosemans; R. Corsini; E. D'Amico; M. Dehler; J.C. Godot; Gilbert Guignard; J. Hagel; S. Hutchins; C.D. Johnson; E. Jensen; I. Kamber; A. Millich; P. Pearce; J.P. Potier; A.J. Riche; Louis Rinolfi; Daniel Schulte; G. Suberlucq; L. Thorndahl; M. Valentini; D.J. Warner; Ian H Wilson; Walter Wuensch; T. Raubenheimer; R. Ruth
CLIC Note 298/NLC-Note-20 | 1996
K. Aulenbacher; R. Bossart; H. Braun; J. E. Clendenin; J.P. Delahaye; J. Madsen; G.A. Mulhollan; J. Sheppard; G. Suberlucq; H. Tang
