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- Another test
- Applications of SANS in nanoscience
- Applications of neutron imaging
- Basic crystallography
- Basic properties of the neutron
- Basic statistical tools
- Basics of neutron scattering
- Beam attenuation due to scattering and absorption
- Beam optical components
- Coherent and incoherent scattering
- Computed tomography
- Correlation between nuclear and magnetic scattering
- Data analysis in neutron scattering
- Data analysis packages
- Determining the incoming neutron wavelength
- Diffraction from a powder
- Diffraction from crystalline materials
- Diffraction from crystals
- Diffraction from nano-sized systems
- Diffraction from single crystals with monochromatic radiation
- Elastic magnetic scattering
- Exercises in Basics of neutron scattering
- Exercises in Diffraction from crystals
- Exercises in Elastic magnetic scattering
- Exercises in Instrumentation
- Exercises in Magnetic neutron scattering
- Exercises in Monte Carlo simulations
- Exercises in Neutron sources and moderators
- Exercises in Reflection and Refraction
- Exercises in Scattering from phonons
- Exercises in Small angle neutron scattering
- Five reasons for using neutrons
- Imaging
- Inelastic magnetic neutron scattering
- Inelastic magnetic scattering
- Inelastic nuclear neutron scattering
- Instrument example: The two axis diffractometer
- Instrumentation
- Instrumentation for investigation of magnetic diffraction
- Instrumentation for investigation of magnetic excitation
- Instruments for inelastic neutron scattering
- Introduction to imaging
- Introduction to neutron scattering
- Introduction to the Monte Carlo technique
- Lattice vibrations, classical treatment
- Laue diffraction
- Magnetic diffraction
- Magnetic excitations
- Magnetic ions
- Magnetic neutron scattering
- Magnetism in materials
- Main Page
- McStas simulation projects
- Moderators
- Monte Carlo ray-tracing packages for neutrons
- Monte Carlo simulation of neutron instrumentation
- Neutron cross section from ferromagnetic spin waves
- Neutron cross section of antiferromagnetic spin waves
- Neutron detectors
- Neutron guide systems
- Neutron reflectivity
- Neutron scattering facilities
- Neutron sources
- Neutron sources and moderators
- On these notes
- Page of all exercises
- Particle-wave duality
- Phonons, quantum mechanical treatment
- Powder scattering instruments
- Problem:A classical antiferromagnet in two dimensions
- Problem:Attenuation of the neutron beam
- Problem:Bragg scattering from non-Bravais lattices
- Problem:Classical lattice vibrations in one dimension
- Problem:Classical vibrations with a two-atom unit cell
- Problem:Derivation of the cartesian formulation of the perpendicular spin component
- Problem:Fourier transform
- Problem:Hydrogen as a moderator
- Problem:Neutron velocity selector
- Problem:Pinhole collimation
- Problem:Polydisperse spheres
- Problem:SANS q-range and resolution
- Problem:Scattering form factor for spheres
- Problem:Scattering from an antiferromagnet
- Problem:Selection of materials for neutron scattering experiments
- Problem:Simple Bragg scattering, the monochromator
- Problem:The Be filter
- Problem:The beam port
- Problem:The collimator
- Problem:The moderator temperature
- Problem:The neutron guide system
- Problem: A neutron guide system
- Problem: Attenuation of the neutron beam
- Problem: Bragg scattering from Bravais lattices
- Problem: Critical edge
- Problem: Estimating the circle area
- Problem: Magnetic reflectivity
- Problem: Phospholipid bilayer liposomes
- Problem: Reflectivity coefficient
- Problem: Reflectivity in magnetic materials
- Problem: Refractive index for "light" and "heavy" water
- Problem: SANS and SAXS from spherical surfactant micelles
- Problem: Scattering length density for "light" and "heavy" water
- Problem: Simulation of SANS scattering
- Problem: Simulation of incoherent scattering
- Problem: Snell's Law
- Problem: The cross section
- Problem: The structure factor for dilute systems
- Problem: Use of International Tables for Crystallography
- Problem: Validity of the semiclassical approximation
- Quantum mechanical derivation of neutron-phonon scattering
- Quantum mechanics of magnetic diffraction
- Quantum mechanics of nuclear diffraction
- Quantum mechanics of scattering
- Quantum treatment of elastic neutron scattering
- Quantum treatment of inelastic neutron scattering
- Radiography
- Reflection from a smooth, flat interface
- Reflectivity of periodically stratified media
- Reflectivity of stratified media
- Rough and diffuse interfaces
- Scattering from lattice vibrations
- Scattering from magnetic dynamics
- Scattering from nuclear dynamics
- Scattering of neutrons from magnetic ions
- Scattering theory for magnetic dynamics
- Scattering theory for nuclear dynamics
- Simple simulation problems
- Simulation Project SANS-2: A full virtual experiment - Liposome sample
- Simulation Project SANS-2: A full virtual experiment - spheres sample
- Simulation Project SANS-2: Data analysis
- Simulation Project SANS-2: Detector
- Simulation Project SANS-2: Normalizing data
- Simulation Project SANS-2: Pinhole collimation
- Simulation Project SANS-2: Resolution of the SANS instrument
- Simulation Project SANS-2: The effect of gravity
- Simulation Project SANS-2: The source-guide system
- Simulation Project SANS-2: Velocity selector
- Simulation Project powder: A full virtual experiment
- Simulation Project powder: Collimator
- Simulation Project powder: DMC multi-detector
- Simulation Project powder: Determine the crystal structure of the sample
- Simulation Project powder: Emulating real experimental data
- Simulation Project powder: Improve your instrument
- Simulation Project powder: Monochromator
- Simulation Project powder: Sample
- Simulation Project powder: The guide system
- Simulation Project tripleaxis: A focusing monochromator
- Simulation Project tripleaxis: A full virtual experiment
- Simulation Project tripleaxis: Analyzer and detector
- Simulation Project tripleaxis: Collimator
- Simulation Project tripleaxis: Determine the full phonon dispersion of the sample
- Simulation Project tripleaxis: Energy resolution
- Simulation Project tripleaxis: Filter
- Simulation Project tripleaxis: Phonon sample
- Simulation Project tripleaxis: The resolution function
- Simulation Project tripleaxis: The source-guide system
- Simulation Project tripleaxis: Tuning the RITA-2 monochromator
- Simulation project SANS-2: A small angle neutron scattering instrument
- Simulation project powder: A powder diffractometer
- Simulation project reflectometer: A neutron reflectometer
- Simulation project tripleaxis: A triple-axis spectrometer
- Small-angle scattering instruments
- Small angle neutron scattering, SANS
- Spectrometers: Instruments for inelastic neutron scattering
- TOC limit/styles.css
- Techniques for neutron ray-tracing
- Test page
- The magnetic scattering length
- The neutron cross sections
- The neutron scattering cross section from nano-sized particles
- The refractive index
- The scattering cross section for phonons
- The total cross section for a system of particles
- Thin films and interfaces
- Useful model-free approximations in SANS
- Wave description of nuclear scattering