STUDIES OF PARASITIC CAVITY MODES FOR PROPOSED ESS LINAC LATTICES

Rob Ainsworth; Stephen Molloy

STUDIES OF PARASITIC CAVITY MODES FOR PROPOSED ESS LINAC LATTICES

Rob Ainsworth, Stephen Molloy

Research output: Contribution to conference › Paper

Abstract

The European Spallation Source (ESS) planned for con- struction in Lund, Sweden, will be the worlds most intense source of pulsed neutrons. The neutrons will be generated by the collision of a 2.5 GeV proton beam with a heavy- metal target. The superconducting section of the proton linac is split into three different types of cavities, and a question for the lattice designers is at which points in the beamline these splits should occur. This note studies vari- ous proposed designs for the ESS lattice from the point of view of the effect on the beam dynamics of the parasitic cavity modes lying close in frequency to the fundamental accelerating mode. Each linac design is characterised by the initial kinetic energy of the beam, as well as by the ve- locity of the beam at each of the points at which the cavity style changes. The scale of the phase-space disruption of the proton pulse is discussed, and some general conclusions for lattice designers are stated.

Original language	English
Publication status	Published - 2012
Event	LINAC12 - Tel Aviv, Israel Duration: 9 Sept 2012 → 14 Sept 2012

Conference

Conference	LINAC12
Country/Territory	Israel
City	Tel Aviv
Period	9/09/12 → 14/09/12

Cite this

@conference{c369bfb941f2479faf1cd3fef71f3a0f,

title = "STUDIES OF PARASITIC CAVITY MODES FOR PROPOSED ESS LINAC LATTICES",

abstract = "The European Spallation Source (ESS) planned for con- struction in Lund, Sweden, will be the worlds most intense source of pulsed neutrons. The neutrons will be generated by the collision of a 2.5 GeV proton beam with a heavy- metal target. The superconducting section of the proton linac is split into three different types of cavities, and a question for the lattice designers is at which points in the beamline these splits should occur. This note studies vari- ous proposed designs for the ESS lattice from the point of view of the effect on the beam dynamics of the parasitic cavity modes lying close in frequency to the fundamental accelerating mode. Each linac design is characterised by the initial kinetic energy of the beam, as well as by the ve- locity of the beam at each of the points at which the cavity style changes. The scale of the phase-space disruption of the proton pulse is discussed, and some general conclusions for lattice designers are stated.",

author = "Rob Ainsworth and Stephen Molloy",

year = "2012",

language = "English",

note = "LINAC12 ; Conference date: 09-09-2012 Through 14-09-2012",

}

TY - CONF

T1 - STUDIES OF PARASITIC CAVITY MODES FOR PROPOSED ESS LINAC LATTICES

AU - Ainsworth, Rob

AU - Molloy, Stephen

PY - 2012

Y1 - 2012

N2 - The European Spallation Source (ESS) planned for con- struction in Lund, Sweden, will be the worlds most intense source of pulsed neutrons. The neutrons will be generated by the collision of a 2.5 GeV proton beam with a heavy- metal target. The superconducting section of the proton linac is split into three different types of cavities, and a question for the lattice designers is at which points in the beamline these splits should occur. This note studies vari- ous proposed designs for the ESS lattice from the point of view of the effect on the beam dynamics of the parasitic cavity modes lying close in frequency to the fundamental accelerating mode. Each linac design is characterised by the initial kinetic energy of the beam, as well as by the ve- locity of the beam at each of the points at which the cavity style changes. The scale of the phase-space disruption of the proton pulse is discussed, and some general conclusions for lattice designers are stated.

AB - The European Spallation Source (ESS) planned for con- struction in Lund, Sweden, will be the worlds most intense source of pulsed neutrons. The neutrons will be generated by the collision of a 2.5 GeV proton beam with a heavy- metal target. The superconducting section of the proton linac is split into three different types of cavities, and a question for the lattice designers is at which points in the beamline these splits should occur. This note studies vari- ous proposed designs for the ESS lattice from the point of view of the effect on the beam dynamics of the parasitic cavity modes lying close in frequency to the fundamental accelerating mode. Each linac design is characterised by the initial kinetic energy of the beam, as well as by the ve- locity of the beam at each of the points at which the cavity style changes. The scale of the phase-space disruption of the proton pulse is discussed, and some general conclusions for lattice designers are stated.

M3 - Paper

T2 - LINAC12

Y2 - 9 September 2012 through 14 September 2012

ER -