2011 Particle Accelerator Conference - List of Authors (Carneiro, J.-P.)

Paper	Title	Page
MOP145	Physics Design of the Project X CW Linac	364
	N. Solyak, J.-P. Carneiro, J.S. Kerby, V.A. Lebedev, S. Nagaitsev, J.-F. Ostiguy, A. Saini, A. Vostrikov, V.P. Yakovlev Fermilab, Batavia, USA
	The general design of the 3 GeV superconducting CW linac of the Project X is presented. Different physical and technical issues and limitations that determine the linac concept are discussed. The results of the RF system optimization are presented as well as the lattice design and beam dynamics analysis.

WEP091	Implementation of H⁻ Intrabeam Stripping into TRACK	1642
	J.-P. Carneiro Fermilab, Batavia, USA B. Mustapha, P.N. Ostroumov ANL, Argonne, USA
	H⁻ intrabeam stripping has been presented* as potentially harmful to MW scale H⁻ linacs. If not taken properly into account, intrabeam stripping of the H⁻ beam could lead to losses in excess of the 1 W/m limit and result in non-tolerable beamline elements activation. This paper describes the implementation of the H⁻ intrabeam stripping effect into the beam dynamics code TRACK*. Simulations results and numerical applications will be presented for the SNS linac and the FNAL ProjectX. V. Lebedev, "Intrabeam Stripping in H⁻ Linacs", LINAC2010 ** P. Ostroumov, "TRACK, The Beam Dynamics Code", PAC2005

WEP095	Analysis of the Beam Loss Mechanism in the Project-X Linac	1651
	N. Solyak, J.-P. Carneiro, V.A. Lebedev, S. Nagaitsev, J.-F. Ostiguy Fermilab, Batavia, USA
	Minimization of the beam losses in a multi-MW H-minus linac of the Project X to the level below 1W/m is a challenging task. Analysis of different mechanisms of beam stripping, including stripping in electric and magnetic fields, residual gas, black-body radiation and intra-beam stripping, is analyzed. Other sources of beam losses are misalignment of beamline elements and errors in RF fields and phase. We presented the requirements for dynamics errors and correction schemes to keep beam losses under control

Paper

Title

Page

Physics Design of the Project X CW Linac

364

N. Solyak, J.-P. Carneiro, J.S. Kerby, V.A. Lebedev, S. Nagaitsev, J.-F. Ostiguy, A. Saini, A. Vostrikov, V.P. Yakovlev
Fermilab, Batavia, USA

The general design of the 3 GeV superconducting CW linac of the Project X is presented. Different physical and technical issues and limitations that determine the linac concept are discussed. The results of the RF system optimization are presented as well as the lattice design and beam dynamics analysis.

WEP091

Implementation of H⁻ Intrabeam Stripping into TRACK

1642

J.-P. Carneiro
Fermilab, Batavia, USA
B. Mustapha, P.N. Ostroumov
ANL, Argonne, USA

H⁻ intrabeam stripping has been presented* as potentially harmful to MW scale H⁻ linacs. If not taken properly into account, intrabeam stripping of the H⁻ beam could lead to losses in excess of the 1 W/m limit and result in non-tolerable beamline elements activation. This paper describes the implementation of the H⁻ intrabeam stripping effect into the beam dynamics code TRACK**. Simulations results and numerical applications will be presented for the SNS linac and the FNAL ProjectX.
* V. Lebedev, "Intrabeam Stripping in H⁻ Linacs", LINAC2010
** P. Ostroumov, "TRACK, The Beam Dynamics Code", PAC2005

WEP095

Analysis of the Beam Loss Mechanism in the Project-X Linac

1651

N. Solyak, J.-P. Carneiro, V.A. Lebedev, S. Nagaitsev, J.-F. Ostiguy
Fermilab, Batavia, USA

Minimization of the beam losses in a multi-MW H-minus linac of the Project X to the level below 1W/m is a challenging task. Analysis of different mechanisms of beam stripping, including stripping in electric and magnetic fields, residual gas, black-body radiation and intra-beam stripping, is analyzed. Other sources of beam losses are misalignment of beamline elements and errors in RF fields and phase. We presented the requirements for dynamics errors and correction schemes to keep beam losses under control