- + Frequently Asked Questions
- + Crystals Primer
- - Crystals User Guide
- 1. The Crystals User Guide
- 2. Getting Started
- 3. Atoms And Peaks, Parameters, And Parameter Values.
- 4. Fourier And Patterson Functions
- 5. Generalised Fourier Sections
- 6. Regularisation
- 7. Hydrogen Placing
- 8. Refinement
- 9. Results
- 10. Conclusion
- 2. Getting Started
- + Crystals Manual
- + Cameron Manual
- + Index
- Fri Jun 2 2000
- + Crystals Primer
Crystals User Guide
Chapter 6: Regularisation
As explained above (Part 4), Fourier techniques provide a powerfull way
for initiating the refinement of a structure. When the geometry of fragments
are well known from previous analyses, for example phenyl groups, the initial
refinement can be speeded even futher by forcing the observed fragment to
adopt an idealised geometry. This process, common in protein crystallography,
is known as regularisation, and can be used not only to tidy up a poor
geometry, but also to postulate sites for missing atoms.
6.1: EXAMPLE
Regularising a cyclopentadienyl ring. The idealised coordinates are from the literature.
\REGULARISE REPLACE GROUP 5 OLD C(1) C(2) C(3) C(4) C(5) ATOM 0 0 0 ATOM .846 1.165 0 ATOM .846 -1.165 0 ATOM 2.216 0.72 0 ATOM 2.216 -0.72 0
Completing and reguarising a phenyl ring. C(3) is very poorly placed, and so will first be deleted, and C(6) has not been found at all. New atoms will be generated for them.
\EDIT DELETE C(3) \REGULARISE REPLACE OLD C(1) C(2) C(3) C(4) C(5) C(6) PHENYL END
BE SURE THAT THE GIVEN ATOMS ARE ALL IN THE SAME MOLECULAR FRAGMENT, OTHERWISE YOU WILL NEED TO GIVE SYMMETRY OPERATORS.