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High-Energy Polarized Proton Beams : A Modern View /

By: Hoffstaetter, Georg Heinz [author.].
Contributor(s): SpringerLink (Online service).
Material type: materialTypeLabelBookSeries: Springer Tracts in Modern Physics: 218Publisher: New York, NY : Springer New York, 2006.Description: X, 177 p. online resource.Content type: text Media type: computer Carrier type: online resourceISBN: 9780387347547.Subject(s): Physics | Nuclear physics | Heavy ions | Hadrons | Particle acceleration | Physics | Nuclear Physics, Heavy Ions, Hadrons | Particle Acceleration and Detection, Beam PhysicsDDC classification: 539.7092 Online resources: Click here to access online
Contents:
Introduction -- Spin Dynamics: The Equation of Spin Motion. Spin Motion in Circular Accelerators -- First-Order Spin Motion: Linearized Spin-Option Motion. First-Order Resonance Spectrum. Optimal Choices of Siberian Snakes -- Higher-Order Spin Motion: Higher-Order Resonances and Snake Schemes. Obtaining N(Z) by Stroboscopic Averaging. Obtaining N(Z) by Anti-Damping -- Polarized Beams in Other Very-High-Energy Proton Accelerators: The Relativistic Heavy Ion Collider (RHIC). TEVATRON.LHC -- Index.
In: Springer eBooksSummary: This monograph begins with a review of the basic equations of spin motion in particle accelerators. It then reviews how polarized protons can be accelerated to several tens of GeV using as examples the preaccelerators of HERA, a 6.3 km long cyclic accelerator at DESY / Hamburg. Such techniques have already been used at the AGS of BNL / New York, to accelerate polarized protons to 25 GeV. But for acceleration to energies of several hundred GeV as in RHIC, TEVATRON, HERA, LHC, or a VLHC, new problems can occur which can lead to a significantly diminished beam polarization. For these high energies, it is necessary to look in more detail at the spin motion, and for that the invariant spin field has proved to be a useful tool. This is already widely used for the description of high-energy electron beams that become polarized by the emission of spin-flip synchrotron radiation. It is shown that this field gives rise to an adiabatic invariant of spin-orbit motion and that it defines the maximum time average polarization available to a particle physics experiment. These concepts make it possible to optimize a high-energy accelerator for storing highly polarized beams. The utility of the invariant spin field is illustrated by simulations of spin motion in HERA and in other high-energy accelerators. Various methods for computing the invariant spin field, the adiabatic spin invariant, and the amplitude dependent spin tune are presented. Moreover, several high-energy spin-orbit dynamical effects will be discussed which go beyond conventional models of spin dynamics and were observed in simulations with these novel methods. The book is suitable for researchers of the field and for introducing students to this field of research.
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Introduction -- Spin Dynamics: The Equation of Spin Motion. Spin Motion in Circular Accelerators -- First-Order Spin Motion: Linearized Spin-Option Motion. First-Order Resonance Spectrum. Optimal Choices of Siberian Snakes -- Higher-Order Spin Motion: Higher-Order Resonances and Snake Schemes. Obtaining N(Z) by Stroboscopic Averaging. Obtaining N(Z) by Anti-Damping -- Polarized Beams in Other Very-High-Energy Proton Accelerators: The Relativistic Heavy Ion Collider (RHIC). TEVATRON.LHC -- Index.

This monograph begins with a review of the basic equations of spin motion in particle accelerators. It then reviews how polarized protons can be accelerated to several tens of GeV using as examples the preaccelerators of HERA, a 6.3 km long cyclic accelerator at DESY / Hamburg. Such techniques have already been used at the AGS of BNL / New York, to accelerate polarized protons to 25 GeV. But for acceleration to energies of several hundred GeV as in RHIC, TEVATRON, HERA, LHC, or a VLHC, new problems can occur which can lead to a significantly diminished beam polarization. For these high energies, it is necessary to look in more detail at the spin motion, and for that the invariant spin field has proved to be a useful tool. This is already widely used for the description of high-energy electron beams that become polarized by the emission of spin-flip synchrotron radiation. It is shown that this field gives rise to an adiabatic invariant of spin-orbit motion and that it defines the maximum time average polarization available to a particle physics experiment. These concepts make it possible to optimize a high-energy accelerator for storing highly polarized beams. The utility of the invariant spin field is illustrated by simulations of spin motion in HERA and in other high-energy accelerators. Various methods for computing the invariant spin field, the adiabatic spin invariant, and the amplitude dependent spin tune are presented. Moreover, several high-energy spin-orbit dynamical effects will be discussed which go beyond conventional models of spin dynamics and were observed in simulations with these novel methods. The book is suitable for researchers of the field and for introducing students to this field of research.

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