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International Tables for Crystallography (2006). Vol. F. ch. 9.1, pp. 177-195
https://doi.org/10.1107/97809553602060000671 |
Chapter 9.1. Principles of monochromatic data collection
Chapter index
Anomalous scattering (dispersion)
data-collection strategies 9.1.13.2
Asymmetric unit
choice of 9.1.7.1
Atomic resolution
data collection 9.1.13.6
Blind region 9.1.7.3
Bragg's law 9.1.6.1
Crystal-to-detector distance, choice of 9.1.8
Data collection
exposure time 9.1.11.2
fine slicing 9.1.6.6
geometries 9.1.5
monochromatic 9.1.1
precession method 9.1.5.2
rotation method 9.1.6
still exposure 9.1.6.2
strategies 9.1.13
use of single-counter diffractometers 9.1.5.3
Weissenberg method 9.1.5.2
wide slicing 9.1.6.7
Detector overloads 9.1.11.3
Detectors
two-dimensional 9.1.5.4
Diffractometer, single-counter 9.1.5.3
Ewald sphere 9.1.6.1
Exposure time 9.1.11.2
Fine slicing 9.1.6.6
Fully recorded reflections 9.1.6.5
Isomorphous replacement
data-collection strategies 9.1.13.1
Low-resolution data
importance of 9.1.14
Lunes 9.1.6.4
Molecular replacement
data-collection strategies 9.1.13.3
Monochromatic data collection 9.1.1
data-collection geometries 9.1.5
detectors 9.1.5.4
exposure time 9.1.11.2
fine slicing 9.1.6.6
precession method 9.1.5.2
still exposure 9.1.6.2
use of single-counter diffractometers 9.1.5.3
Weissenberg method 9.1.5.2
wide slicing 9.1.6.7
Multiwavelength anomalous diffraction (MAD)
data-collection strategies 9.1.13.2
Partially recorded reflections 9.1.6.5
Precession method of data collection 9.1.5.2
Reflection profiles 9.1.11.1
Rocking curve 9.1.6.3
Rotation method of data collection 9.1.6
Single-counter diffractometer 9.1.5.3
Single-wavelength anomalous scattering (dispersion)
data-collection strategies 9.1.13.2
Still exposure 9.1.6.2
Synchrotron radiation 9.1.4.2
Wavelength bandpass 9.1.6.3
Weissenberg camera 9.1.6.8
Weissenberg method 9.1.5.2
Wide slicing 9.1.6.7
X-ray sources
for monochromatic data collection 9.1.4
X-ray wavelength, choice of 9.1.9