Birefringence: Difference between revisions

From CCP4 wiki
Jump to navigation Jump to search
(New page: The birefringence of a crystal is determined by a three dimensional shape (the indicatrix) describing how refractive index varies with direction within the crystal. You can think of this a...)
 
(No difference)

Latest revision as of 09:47, 12 June 2008

The birefringence of a crystal is determined by a three dimensional shape (the indicatrix) describing how refractive index varies with direction within the crystal. You can think of this as a 3d ellipse and the birefringence is given by the difference in length of the two axes of the ellipse 'seen' by light as it passes through the crystal.

The orientation and shape of the indicatrix are constrained by the point group symmetry of the crystal. In the case of cubic crystals, the indicatrix is characterised by four 3-fold axes. The indicatrix for all cubic crystals is thus a sphere and cubic crystals are non-birefringent. Hexagonal, trigonal and tetragonal crystals are uniaxial and the indicatrix is an ellipsoid of revolution - there is one direction in which the crystal appears non-birefringent. Orthorhombic, monoclinic and triclinic systems are biaxial -two axes in which the crystal appears non-birefringent.


Useful references

Morphologie et proprietes optiques des cristaux de lysozyme de poule de type quadratique et orthorhombique. Cervelle, P. B., Cesbron, F., Berthou, J. & Jolles, P. (1974). Acta Cryst. A30, 645-648.

Assessing crystallisation droplets using birefringence Echalier, A., Glazer, R. L., Fulop, V. & Geday, M. A. (2004). Acta Cryst. D60, 696-702.

Physical Properties of crystals. Their representation by tensors and matrices. Clarendon Press, Oxford. Nye (1984)

A new method for predetermining the diffraction quality of protein crystals: using SOAP as a selection tool. R. L. Owen and E. Garman. (2005) Acta. Cryst. D61, 130-140.