2011 Particle Accelerator Conference - List of Authors (Etxebarria, V.)

Paper

Title

Page

Beam Dynamics Simulations on the ESS Bilbao RFQ

100

D. de Cos, I. Bustinduy, O. Gonzalez, J.L. Munoz, A. Velez
ESS Bilbao, Bilbao, Spain
F.J. Bermejo
Bilbao, Faculty of Science and Technology, Bilbao, Spain
V. Etxebarria, J. Portilla
University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain
J. Feuchtwanger
ESS-Bilbao, Zamudio, Spain
S. Jolly, P. Savage
Imperial College of Science and Technology, Department of Physics, London, United Kingdom
A.P. Letchford
STFC/RAL/ISIS, Chilton, Didcot, Oxon, United Kingdom

Funding: European Spallation Source - Bilbao
The Bilbao Accelerator RFQ is aimed to accelerate a 75 mA proton beam from 75 keV to 3 MeV, while keeping the beam both transversely and longitudinally focused, and presenting a minimum emittance growth. We report on the current status of the project, mainly focusing on the Beam Dynamics aspects of the design. Several particle simulations are carried out with RFQSIM, GPT and TRACK codes, in order to study the particle transmission of the RFQ under several circumstances, such as different current levels, vane geometry changes due to thermal stress, and different input beam characteristics obtained by changing the LEBT operation settings.

Slides MOODS6 [3.264 MB]

TUP042

RF Measurements and Numerical Simulations for the Model of the Bilbao Linac Double Spoke Cavity

886

J.L. Munoz, I. Bustinduy, N. Garmendia, V. Toyos
ESS Bilbao, Derio, Spain
E. Asua
UPV-EHU, Leioa, Spain
F.J. Bermejo
Bilbao, Faculty of Science and Technology, Bilbao, Spain
V. Etxebarria, J. Portilla
University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain
J. Feuchtwanger
ESS-Bilbao, Zamudio, Spain
J. Lucas
Elytt Energy, Madrid, Spain

A model of a double spoke resonant cavity (operating frequency 352.2 MHz, β_g=0.39) has been designed and fabricated in aluminium. The RF characteristics of the cavity have been measured in our laboratory. Experimental measurements have involved the determination of the main cavity parameters, and the characterization of the accelerating electric field profile along the cavity axis by means of a fully automated bead-pullmethod. Additionally, numerical simulations using COMSOL code have been used to fully characterize the cavity. Electromagnetic numerical simulations of the cavity have been also performed to determine its main figures of merit and to identify the most suitable position for opening a port to install a power coupler. In this paper we report the cavity cold model description, the experimental setup and corresponding techniques, together with the numerical methods. The obtained results are described and discussed in detail.

WEOBN4

Multipurpose Controller Based on a FPGA with EPICS Integration

1407

P. Echevarria, I. Arredondo, N. Garmendia, H. Hassanzadegan, L. Muguira
ESS Bilbao, Bilbao, Spain
D. Belver, M. del Campo
ESS-Bilbao, Zamudio, Spain
V. Etxebarria, J. Jugo
University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain

In this work a multipurpose configurable control system is presented. This controller is based on a high performance FPGA for a fast control connected to a Host PC which works as an EPICS server to allow a remote control. The communication between both parts is made by a register bank implemented in the FPGA and which is accessible by the Host PC by means of a Compact PCI bus. The initialization values, the numeric representation of the digital signals and the EPICS database are configured by an XML file. This control scheme has been prototyped for two applications: Low Level RF and Beam Position Monitoring. The former contains three digital loops to control the amplitude and phase of the RF supply and the geometry of the cavity. The latter processes the information from four capacitive buttons to calculate the position of the beam. In both systems, the necessary parameters for the digital processing of the acquired signals (using fast ADCs) and intermediate calculations are stored in the register bank connected to the cPCI bus. These systems are being developed for the ESS-Bilbao facility which will be built in Bilbao, Spain.

Slides WEOBN4 [0.621 MB]

WEP010

Design of the Bilbao Accelerator Low Energy Extraction Lines

1519

Z. Izaola, I. Rodríguez
ESS-Bilbao, Zamudio, Spain
E. Abad, I. Bustinduy, R. Martinez, F. Sordo Balbin, D. de Cos
ESS Bilbao, Bilbao, Spain
D.J. Adams, S.J.S. Jago
STFC/RAL/ISIS, Chilton, Didcot, Oxon, United Kingdom
F.J. Bermejo
Bilbao, Faculty of Science and Technology, Bilbao, Spain
V. Etxebarria, J. Portilla
University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain

Funding: European Spallation Source - Bilbao
The ESS-Bilbao linac will accelerate H+ and H− beams up to 50 MeV, which need to be transported to three laboratories, where different types of experiments will be conducted. This paper reports on the preliminary design of the transfer line, which is mainly performed based on beam dynamics simulations.

WEP011

Low Energy Beam Transport Developments for the Bilbao Accelerator

1522

I. Bustinduy, D. de Cos
ESS Bilbao, Bilbao, Spain
F.J. Bermejo
Bilbao, Faculty of Science and Technology, Bilbao, Spain
V. Etxebarria, J. Portilla
University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain
J. Feuchtwanger, Z. Izaola, J.L. Munoz, I. Rodríguez
ESS-Bilbao, Zamudio, Spain

Funding: European Spallation Source - Bilbao
In this work we present a future upgrade of the ESS-Bilbao multi-source Low Energy Transport System (LEBT). It consists of a set of solenoids and steering dipoles used to match the characteristics of both ion source beams i.e., the Electron Cyclotron Resonance (ECR) H+/D+ source and the H− Penning source, to the input specifications of the RFQ. Different configurations of the geometry and magnetic fields are studied in order to minimize the emittance growth along the LEBT, while providing the beam specifications required by the RFQ.

Paper	Title	Page
MOODS6	Beam Dynamics Simulations on the ESS Bilbao RFQ	100
	D. de Cos, I. Bustinduy, O. Gonzalez, J.L. Munoz, A. Velez ESS Bilbao, Bilbao, Spain F.J. Bermejo Bilbao, Faculty of Science and Technology, Bilbao, Spain V. Etxebarria, J. Portilla University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain J. Feuchtwanger ESS-Bilbao, Zamudio, Spain S. Jolly, P. Savage Imperial College of Science and Technology, Department of Physics, London, United Kingdom A.P. Letchford STFC/RAL/ISIS, Chilton, Didcot, Oxon, United Kingdom
	Funding: European Spallation Source - Bilbao The Bilbao Accelerator RFQ is aimed to accelerate a 75 mA proton beam from 75 keV to 3 MeV, while keeping the beam both transversely and longitudinally focused, and presenting a minimum emittance growth. We report on the current status of the project, mainly focusing on the Beam Dynamics aspects of the design. Several particle simulations are carried out with RFQSIM, GPT and TRACK codes, in order to study the particle transmission of the RFQ under several circumstances, such as different current levels, vane geometry changes due to thermal stress, and different input beam characteristics obtained by changing the LEBT operation settings.
	Slides MOODS6 [3.264 MB]

TUP042	RF Measurements and Numerical Simulations for the Model of the Bilbao Linac Double Spoke Cavity	886
	J.L. Munoz, I. Bustinduy, N. Garmendia, V. Toyos ESS Bilbao, Derio, Spain E. Asua UPV-EHU, Leioa, Spain F.J. Bermejo Bilbao, Faculty of Science and Technology, Bilbao, Spain V. Etxebarria, J. Portilla University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain J. Feuchtwanger ESS-Bilbao, Zamudio, Spain J. Lucas Elytt Energy, Madrid, Spain
	A model of a double spoke resonant cavity (operating frequency 352.2 MHz, β_g=0.39) has been designed and fabricated in aluminium. The RF characteristics of the cavity have been measured in our laboratory. Experimental measurements have involved the determination of the main cavity parameters, and the characterization of the accelerating electric field profile along the cavity axis by means of a fully automated bead-pullmethod. Additionally, numerical simulations using COMSOL code have been used to fully characterize the cavity. Electromagnetic numerical simulations of the cavity have been also performed to determine its main figures of merit and to identify the most suitable position for opening a port to install a power coupler. In this paper we report the cavity cold model description, the experimental setup and corresponding techniques, together with the numerical methods. The obtained results are described and discussed in detail.

WEOBN4	Multipurpose Controller Based on a FPGA with EPICS Integration	1407
	P. Echevarria, I. Arredondo, N. Garmendia, H. Hassanzadegan, L. Muguira ESS Bilbao, Bilbao, Spain D. Belver, M. del Campo ESS-Bilbao, Zamudio, Spain V. Etxebarria, J. Jugo University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain
	In this work a multipurpose configurable control system is presented. This controller is based on a high performance FPGA for a fast control connected to a Host PC which works as an EPICS server to allow a remote control. The communication between both parts is made by a register bank implemented in the FPGA and which is accessible by the Host PC by means of a Compact PCI bus. The initialization values, the numeric representation of the digital signals and the EPICS database are configured by an XML file. This control scheme has been prototyped for two applications: Low Level RF and Beam Position Monitoring. The former contains three digital loops to control the amplitude and phase of the RF supply and the geometry of the cavity. The latter processes the information from four capacitive buttons to calculate the position of the beam. In both systems, the necessary parameters for the digital processing of the acquired signals (using fast ADCs) and intermediate calculations are stored in the register bank connected to the cPCI bus. These systems are being developed for the ESS-Bilbao facility which will be built in Bilbao, Spain.
	Slides WEOBN4 [0.621 MB]

WEP010	Design of the Bilbao Accelerator Low Energy Extraction Lines	1519
	Z. Izaola, I. Rodríguez ESS-Bilbao, Zamudio, Spain E. Abad, I. Bustinduy, R. Martinez, F. Sordo Balbin, D. de Cos ESS Bilbao, Bilbao, Spain D.J. Adams, S.J.S. Jago STFC/RAL/ISIS, Chilton, Didcot, Oxon, United Kingdom F.J. Bermejo Bilbao, Faculty of Science and Technology, Bilbao, Spain V. Etxebarria, J. Portilla University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain
	Funding: European Spallation Source - Bilbao The ESS-Bilbao linac will accelerate H+ and H− beams up to 50 MeV, which need to be transported to three laboratories, where different types of experiments will be conducted. This paper reports on the preliminary design of the transfer line, which is mainly performed based on beam dynamics simulations.

WEP011	Low Energy Beam Transport Developments for the Bilbao Accelerator	1522
	I. Bustinduy, D. de Cos ESS Bilbao, Bilbao, Spain F.J. Bermejo Bilbao, Faculty of Science and Technology, Bilbao, Spain V. Etxebarria, J. Portilla University of the Basque Country, Faculty of Science and Technology, Bilbao, Spain J. Feuchtwanger, Z. Izaola, J.L. Munoz, I. Rodríguez ESS-Bilbao, Zamudio, Spain
	Funding: European Spallation Source - Bilbao In this work we present a future upgrade of the ESS-Bilbao multi-source Low Energy Transport System (LEBT). It consists of a set of solenoids and steering dipoles used to match the characteristics of both ion source beams i.e., the Electron Cyclotron Resonance (ECR) H+/D+ source and the H− Penning source, to the input specifications of the RFQ. Different configurations of the geometry and magnetic fields are studied in order to minimize the emittance growth along the LEBT, while providing the beam specifications required by the RFQ.