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Stopping power (Nuclear physics) --- Helium ions --- Effective range (Nuclear physics) --- Atomic stopping power --- Average ionization potential --- Kinetic energy of particles (Nuclear physics) --- Stopping cross section --- Collisions (Nuclear physics) --- Ionization --- Matter --- Nuclear reactions --- Particles (Nuclear physics) --- Radioactivity --- Linear energy transfer --- Particle range (Nuclear physics) --- Ions --- Heliosphere (Ionosphere) --- Range, Effective (Nuclear physics) --- Potential scattering --- Properties --- Measurement --- Helium ions. --- Effective range (Nuclear physics). --- Stopping power (Nuclear physics).

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Helium ions --- -Hydrogen ions --- -Stopping power (Nuclear physics) --- Atomic stopping power --- Average ionization potential --- Kinetic energy of particles (Nuclear physics) --- Stopping cross section --- Collisions (Nuclear physics) --- Ionization --- Matter --- Nuclear reactions --- Particles (Nuclear physics) --- Radioactivity --- Linear energy transfer --- Particle range (Nuclear physics) --- Monovalent cations --- Ions --- Heliosphere (Ionosphere) --- Scattering --- Properties --- Measurement --- Hydrogen ions --- Stopping power (Nuclear physics) --- Stopping power (Nuclear physics). --- Scattering.

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Mechanical properties of solids --- Stopping power (Nuclear physics) --- Effective range (Nuclear physics) --- Ions --- Indexes --- Scattering --- -Ions --- -Stopping power (Nuclear physics) --- -Atomic stopping power --- Average ionization potential --- Kinetic energy of particles (Nuclear physics) --- Stopping cross section --- Collisions (Nuclear physics) --- Ionization --- Matter --- Nuclear reactions --- Particles (Nuclear physics) --- Radioactivity --- Linear energy transfer --- Particle range (Nuclear physics) --- Intermediates (Chemistry) --- Physics --- Solution (Chemistry) --- Electrolysis --- Electrons --- Range, Effective (Nuclear physics) --- Potential scattering --- -Indexes --- Properties --- Measurement --- Indexes. --- Atomic stopping power --- Scattering&delete&

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Ion bombardment --- Solids --- Stopping power (Nuclear physics) --- Surfaces (Physics) --- Congresses --- Effect of radiation on --- 538.91 --- -Solids --- -Stopping power (Nuclear physics) --- -Surfaces (Physics) --- -538.97 --- Physics --- Surface chemistry --- Surfaces (Technology) --- Atomic stopping power --- Average ionization potential --- Kinetic energy of particles (Nuclear physics) --- Stopping cross section --- Collisions (Nuclear physics) --- Ionization --- Matter --- Nuclear reactions --- Particles (Nuclear physics) --- Radioactivity --- Linear energy transfer --- Particle range (Nuclear physics) --- Solid state physics --- Transparent solids --- Beams, Ion --- Bombardment, Ion --- Impact, Ion --- Ion beams --- Ion impact --- Ionic bombardment --- Ions --- Structures, including transitions --- -Congresses --- Special geometry and interaction with particles and radiation --- Properties --- Measurement --- 538.97 Special geometry and interaction with particles and radiation --- 538.91 Structures, including transitions --- 538.97

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This monograph focusses on the influence of a strong magnetic field on the interactions between charged particles in a many-body system. Two complementary approaches, the binary collision model and the dielectric theory are investigated in both analytical and numerical frameworks. In the binary collision model, the Coulomb interaction between the test and the target particles is screened because of the polarization of the target. In the continuum dielectric theory one considers the interactions between the test particle and its polarization cloud. In the presence of a strong magnetic field, there exists no suitable parameter of smallness. Linearized and perturbative treatments are not more valid and must be replaced by numerical grid or particle methods. Applications include the electron cooling of ion beams in storage rings and the final deceleration of antiprotons and heavy ion beams in traps.

Stopping power (Nuclear physics) --- Energy dissipation. --- Plasma (Ionized gases) --- Particle range (Nuclear physics) --- Magnetic fields. --- Mathematical models. --- Fields, Magnetic --- Field theory (Physics) --- Geomagnetism --- Magnetics --- Energy loss of nuclear particles --- Range of particles (Nuclear physics) --- Ion bombardment --- Particle tracks (Nuclear physics) --- Particles (Nuclear physics) --- Straggling (Nuclear physics) --- Gaseous discharge --- Gaseous plasma --- Magnetoplasma --- Ionized gases --- Degradation, Energy --- Dissipation (Physics) --- Energy degradation --- Energy losses --- Losses, Energy --- Force and energy --- Atomic stopping power --- Average ionization potential --- Kinetic energy of particles (Nuclear physics) --- Stopping cross section --- Collisions (Nuclear physics) --- Ionization --- Matter --- Nuclear reactions --- Radioactivity --- Linear energy transfer --- Properties --- Measurement --- Classical Electrodynamics. --- Atomic, Molecular, Optical and Plasma Physics. --- Atoms and Molecules in Strong Fields, Laser Matter Interaction. --- Plasma Physics. --- Optics. --- Electrodynamics. --- Atoms. --- Physics. --- Plasma (Ionized gases). --- Natural philosophy --- Philosophy, Natural --- Physical sciences --- Dynamics --- Chemistry, Physical and theoretical --- Stereochemistry --- Physics --- Light --- Constitution