Neutron Scattering Data Analysis 1990, Proceedings of the Conference on Neutron Scattering, 14-16 March 1990, Rutherford Appleton Laboratory, UKM. W. Johnson |
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Page 105
... corresponding to better statistics . This is due to the fact that Fm ( K ) ' s corresponding to symmetry related Ẩ's are essentially the same within a known phase factor . In the centrosymmetrical case considered here , this phase ...
... corresponding to better statistics . This is due to the fact that Fm ( K ) ' s corresponding to symmetry related Ẩ's are essentially the same within a known phase factor . In the centrosymmetrical case considered here , this phase ...
Page 258
... corresponding requirements in the repositioning part of the scan , is then totally determined by the two analytical functions eq . ( 1 ) and eq . ( 6 ) , or , more convenient for modern electronics , written as numerical arrays for ( t ) ...
... corresponding requirements in the repositioning part of the scan , is then totally determined by the two analytical functions eq . ( 1 ) and eq . ( 6 ) , or , more convenient for modern electronics , written as numerical arrays for ( t ) ...
Page 263
... correspond to neutron energies of E = 44 meV and E - 16 meV at the correspon- ding time channels of 4.6 msec and 7.6 msec ... corresponding derivatives , i.e. the angular speed and accelaration versus time . The dashed lines in fig . 8 ...
... correspond to neutron energies of E = 44 meV and E - 16 meV at the correspon- ding time channels of 4.6 msec and 7.6 msec ... corresponding derivatives , i.e. the angular speed and accelaration versus time . The dashed lines in fig . 8 ...
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Acta Cryst algorithm applications approach atoms Bayesian beam Bragg peaks calculated configuration constraints coordinates corresponding cost function cross-section crystallographic Data Anal data analysis data set defined determined diffraction data diffractometer distribution elastic scattering energy error bars example experiment experimental Figure Fourier transform Gaussian GENIE GENIE-V3 histogram inelastic instrument intensity interpolation inverse ISIS likelihood function magnetic structure Markov chain matrix MaxEnt Reconstruction Maximum Entropy McGreevy measured method molecular MoO3 neutron diffraction neutron scattering normalisation normalization obtained optimisation optimization problems parameters Patterson map performed Phys plot positive powder diffraction presented at Neutron prior probability procedure quasielastic refinement reflectivity data resolution function ROTAX Rutherford Appleton Laboratory sample scan Scatt scattering law shown simulated annealing single crystal solution spectra spectrometer spectrum statistical structure factor symmetry temperature time-of-flight truncation UNIRAS unit cell vanadium vector wavelength workspace