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• The High Intensity Frontier of Particle Physics (Robert S Tschirhart)
• Intensity Frontier of Accelerators for Nuclear Physics (Kenichi Imai)
• Radioactive Ion Beamsand Radiopharmaceuticals (R E Laxdal, A C Morton and P Schaffer)
• Spallation Neutron Sources and Accelerator Driven Systems (Stuart D Henderson)
• Accelerators for Inertial Fusion Energy Production (R O Bangerter, A Faltens and P A Seidl)
• Particle Beam Radiography (Ken Peachand Carl Ekdahl)
• Rapid Cycling Synchrotrons and Accumulator Rings for High-Intensity Hadron Beams (Jingyu Tang)
• Superconducting Hadron Linacs (Peter Ostroumov and Frank Gerigk)
• Ion Injectors for High Intensity Accelerators (Martin P Stockli and Takahide Nakagawa)
• Charge Strippers of Heavy Ions for High-Intensity Accelerators (Jerry A. Nolen and Felix Marti)
• Targets and Secondary Beam Extraction (Etam Noah)
• High Intensity Neutron Beamlines (Phillip M Bentley, Carsten P Cooper-Jensen and Ken H Andersen)
• Beam-Materials Interactions (Nikolai V Mokhov)
• John Adams and CERN: Personal Recollections (G Brianti and D E Plane).
• (source: Nielsen Book Data)

As particle accelerators strive forever increasing performance, high intensity particle beams become one of the critical demands requested across the board by a majority of accelerator users (proton, electron and ion) and for most applications. Much effort has been made by our community to pursue high intensity accelerator performance on a number of fronts. Recognizing its importance, we devote this volume to Accelerators for High Intensity Beams. High intensity accelerators have become a frontier and a network for innovation. They are responsible for many scientific discoveries and technological breakthroughs that have changed our way of life, often taken for granted. A wide range of topics is covered in the fourteen articles in this volume.
(source: Nielsen Book Data)

• Introduction
• Part I: Laser Cooling and Manipulation of Atoms and Molecules
• Atomic and Molecular Optics and Applications
• Part II: Alignment, Relaxation and Condensation in Supersonic Free Jets
• Part III: Spectroscopy, State Imaging and Photodissociation in Molecular Beams
• Part IV: Dynamics of Elementary Molecular Collisions
• Theory, Crossed-Beams Experiments, Probing and Imaging
• Part V: Theory, Production and Properties of Clusters and Nanoparticles
• Part VI: Spectroscopy and Reaction Dynamics of Molecules in, on, or from Clusters
• Part VII: Gas-Surface Interaction Studies using Molecular and Cluster Beams.

"Atomic and Molecular Beams" reviews the state of the art in this field both theoretically and experimentally, while simultaneously investigating the many possible applications. The topics covered include among others: - laser cooling and manipulation of atoms and molecules - alignment, relaxation and condensation in supersonic jets - spectroscopy, state imaging and photodissociation in molecular beams - elementary molecular collisions and reaction dynamics production and properties of clusters and nanoparticles - beam interactions with surfaces. With many contributions from leading researchers, including several Nobel Prize laureates, this volume will serve as a long-lasting source of reference on all aspects of fundamental research into or using atomic and molecular beams

Status of the H-jet polarimeter development is reviewed. The preliminary results of atomic beam intensity and density measurements are presented.

The status of the H-jet polarimeter development is reviewed. The preliminary results of atomic beam intensity and density measurements are presented.

A source of thermal atoms that emits 100% of its atoms into a narrow beam with small angular divergence is described. It uses both surface ionization and surface neutralization in conjunction with electric fields to selectively emit a highly directional (orthotropic) beam of neutral atoms. The ion recycling process can be modulated electronically and lends itself to scanning. This orthotropic source is ideal for the efficient use of rare atomic species, well suited for atomic clocks, essential in the efficient delivery of radioactive atoms to optical traps, and has potential to produce ultra high intensity beams of stable atoms.

• Lecture day
• Polarized electron and positron sources
• Polarized gas targets
• Polarized ion sources and beams
• Polarized radioactive beams
• Polarized solid targets
• Polarimetry.

Concepts which guide the design of atomic cluster supersonic beam sources have been developed. These ideas are founded on the knowledge of laser ablation dynamics and are structured in order to take advantage of certain features of the ablation event. Some of the drawbacks of previous cluster source designs become apparent when the sequence of events following laser ablation are clarified. Key features of the new cluster source design include control of the cluster size distribution, uniform performance with a variety of solid materials and elements, high beam intensity, and significant removal of internal energy during the supersonic expansion.