Inelastic Neutron Scattering B. Fultz, J. Lin, O. Delaire, M. Kresch Caltech Science interests Where is the field going? Tasks and goals of the DANSE subproject Looking for new scientific opportunities
Excitations in Solids: An Optical Illusion of Space-Time Correlations
ARCS software is going well
ARCS reduction software demo…
WBS 10: Science Scope for Inelastic Scattering 1) spin correlations in magnets, superconductors, and materials close to metal-insulator transitions 2) vibrational excitations in solids and their relationship to phase diagrams and equations of state of materials 3) tunneling and reorientation transitions of small molecules on surfaces 4) vibrational spectra of molecules or individual atoms such as hydrogen 5) diffusional motions and relaxation processes studied by quasielastic scattering
Tasks for Inelastic Scattering WBS Data reduction for CNCS 08/31/06 02/15/ Data reduction for SEQUOIA 03/01/08 08/16/ Data reduction for HYSPEC 05/06/10 07/06/ Data reduction for Backscatter 02/07/07 03/16/ Gilat-Raubenheimer method 01/05/08 03/08/ Pack and Monkhorst method 03/11/10 05/08/ Polycrystal 07/31/07 01/06/ Single Crystal 11/13/08 06/14/ Dispersion Algorithms 08/12/08 11/14/ Separation of Nuclear and Spin Scattering 11/23/09 03/16/ CLIMAX 04/21/07 08/11/ Chemical Spectroscopy Preprocessing 03/01/10 02/28/ Coherent Inelastic Scattering Kernel 03/11/07 04/21/ Incoherent Inelastic Scattering Kernel 04/06/07 04/21/ G(r,t) from individual neutron scatterings 03/25/08 11/09/ G(r,t) from dynamics simulation 07/03/10 09/18/ Multiple scattering correction 04/21/09 12/06/ Disordered Spin Dynamics 04/13/09 02/28/11
Science Activity for Physical Chemistry: Dynamics of Excited Materials and Molecules Density-functional methods have revolutionized the calculation of electronic structure They are not justified for excited states, however. New effort to study excited states of molecules by pump- probe Raman spectrometry
Science Activity for Physical Chemistry: Hydrogen Molecule Dynamics in Physisorption RotationalLibrational Ground Excited
Entropy W is the number of equivalent ways of finding a system with the same macrostate. Ways of “what”?
Classical Limit 1 2 p 1 …p 3N–3 q 1 …q 3N–3 S = k B ln V1V1 V2V2 ( ) ~1/
Phonon DOS of V with 3d-series solutes increasing stiffening along 3d series Ti: softening, Cr-Ni: stiffening impurity masses ~ host trend opposite to mass increase electronic / size effect
Entropy of Alloying
Use Case Inelastic Scattering with Fermi Chopper Instruments Approach: - Reduce NeXus file to “S(Q,E)” - S(Q,E) to phonon DOS, g(E) - Goal: Obtain phonon partition function, Z(T).
Today – Three Problems /M differs between atoms (neutron weighting) Q information will be rich, but neglected in analysis Errors in Z are unknown - reliability of thermodynamic quantities? Computation will Solve These
Today (Neutron De-weighting Solution)
Near Future: Fits with Q information
New Capability
Error Bars in Thermodynamic Quantities
Test Case – Use Known Force Constants from Ni
Resolution of a Fermi Chopper Spectrometer (e.g., Windsor) ~4.2 for ARCS
ARCS Has Moveable Fermi Choppers
Typical ARCS Resolution (Energy Dependent)
Multiple Energies Give Higher Resolution
Summary of WBS 10: Inelastic Scattering 1)Scope for: - physical chemistry of small molecules - phonon excitations in solids - magnetic excitations in solids 2)Progress with ARCS and other inelastic instruments has been crucial for establishing the science scope 3)Experience in materials theory is essential too
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