IPAC2011 - List of Authors (Nagorny, B.)

Paper	Title	Page
THPZ015	Synchrotron Radiation in the Interaction Region for a Ring-Ring and Linac-Ring LHeC	3717
	N.R. Bernard UCLA, Los Angeles, California, USA R. Appleby, L.N.S. Thompson UMAN, Manchester, United Kingdom N.R. Bernard ETH, Zurich, Switzerland B.J. Holzer, R. Tomás, F. Zimmermann CERN, Geneva, Switzerland M. Klein The University of Liverpool, Liverpool, United Kingdom P. Kostka DESY Zeuthen, Zeuthen, Germany B. Nagorny, U. Schneekloth DESY, Hamburg, Germany
	The Large Hadron electron Collider (LHeC) aims at bringing hadron-lepton collisions to CERN with center of mass energies in the TeV scale. The LHeC will utilize the existing LHC storage ring with the addition of a 60 GeV electron accelerator. The electron beam will be stored and accelerated in either a storage ring in the LHC tunnel (Ring-Ring) or a linac tangent to the LHC tunnel (Linac-Ring). Synchrotron Radiation (SR) in the Interaction Region (IR) of this machine requires an iterative design process in which luminosity is optimized while the SR is minimized. This process also requires attention to be given to the detector as the beam pipe must be designed such that damaging effects, such as out-gasing, are minimized while the tracking remains close to the IP. The machinery of GEANT4 has been used to simulate the SR load in the IR and also to design absorbers/masks to shield SR from backscattering into the detector or propagating with the electron beam. The outcome of these simulations, as well as cross checks, are described in the accompanying poster which characterizes the current status of the IR design for both the Ring-Ring and Linac-Ring options of the LHeC in terms of SR.

THPS066	Technical Overview of the SIEMENS Particle Therapy Accelerator	3577
	V. Lazarev, O. Chubarov, S. Emhofer, G. Franzini, S. Göller, B. Nagorny, A. Robin, H. Rohdjess, R. Rottenbach, A.C. Sauer, R. Schedler, T. Sieber, B. Steiner, J. Tacke, D.B. Thorn, T. Uhl, P. Urschütz, O. Wilhelmi Siemens Med, Erlangen, Germany M. Budde, J.S. Gretlund, H.B. Jeppesen, C.V. Nielsen, C.G. Pedersen, Ka.T. Therkildsen, S.V. Weber Siemens DK, Jyllinge, Denmark
	Siemens has developed an accelerator system for particle therapy. It consists of an injector (7 MeV/u protons and light ions) and a compact synchrotron able to accelerate proton beams up to 250 MeV and carbon ions up to 430 MeV/u. These beams are extracted slowly from the synchrotron and delivered to a number of beam ports. The first accelerator system has been built and commissioned up to the first two beam outlets. An overview of the achieved performance of the system is presented. *Particle therapy is a work in progress and requires country-specific regulatory approval prior to clinical use.

Paper

Title

Page

Synchrotron Radiation in the Interaction Region for a Ring-Ring and Linac-Ring LHeC

3717

N.R. Bernard
UCLA, Los Angeles, California, USA
R. Appleby, L.N.S. Thompson
UMAN, Manchester, United Kingdom
N.R. Bernard
ETH, Zurich, Switzerland
B.J. Holzer, R. Tomás, F. Zimmermann
CERN, Geneva, Switzerland
M. Klein
The University of Liverpool, Liverpool, United Kingdom
P. Kostka
DESY Zeuthen, Zeuthen, Germany
B. Nagorny, U. Schneekloth
DESY, Hamburg, Germany

The Large Hadron electron Collider (LHeC) aims at bringing hadron-lepton collisions to CERN with center of mass energies in the TeV scale. The LHeC will utilize the existing LHC storage ring with the addition of a 60 GeV electron accelerator. The electron beam will be stored and accelerated in either a storage ring in the LHC tunnel (Ring-Ring) or a linac tangent to the LHC tunnel (Linac-Ring). Synchrotron Radiation (SR) in the Interaction Region (IR) of this machine requires an iterative design process in which luminosity is optimized while the SR is minimized. This process also requires attention to be given to the detector as the beam pipe must be designed such that damaging effects, such as out-gasing, are minimized while the tracking remains close to the IP. The machinery of GEANT4 has been used to simulate the SR load in the IR and also to design absorbers/masks to shield SR from backscattering into the detector or propagating with the electron beam. The outcome of these simulations, as well as cross checks, are described in the accompanying poster which characterizes the current status of the IR design for both the Ring-Ring and Linac-Ring options of the LHeC in terms of SR.

THPS066

Technical Overview of the SIEMENS Particle Therapy Accelerator

3577

V. Lazarev, O. Chubarov, S. Emhofer, G. Franzini, S. Göller, B. Nagorny, A. Robin, H. Rohdjess, R. Rottenbach, A.C. Sauer, R. Schedler, T. Sieber, B. Steiner, J. Tacke, D.B. Thorn, T. Uhl, P. Urschütz, O. Wilhelmi
Siemens Med, Erlangen, Germany
M. Budde, J.S. Gretlund, H.B. Jeppesen, C.V. Nielsen, C.G. Pedersen, Ka.T. Therkildsen, S.V. Weber
Siemens DK, Jyllinge, Denmark

Siemens has developed an accelerator system for particle therapy. It consists of an injector (7 MeV/u protons and light ions) and a compact synchrotron able to accelerate proton beams up to 250 MeV and carbon ions up to 430 MeV/u. These beams are extracted slowly from the synchrotron and delivered to a number of beam ports. The first accelerator system has been built and commissioned up to the first two beam outlets. An overview of the achieved performance of the system is presented.
*Particle therapy is a work in progress and requires country-specific regulatory approval prior to clinical use.