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Classical linear crystal optics
International Tables for Crystallography (2013). Vol. D, ch. 1.6, pp. 153-180 [ doi:10.1107/97809553602060000905 ]
... devoted to the linear optical properties of crystals, starting with a description of the main generalized optical, electro-optic and magneto ... analyse the conditions for the practical observation of crystals with a polarizing microscope: the determination of linear birefringence, and uniaxial and ... with the growth in optical communications technologies, there has been a revival of interest in the optical properties of crystals, ...
The acousto-optic effect
International Tables for Crystallography (2013). Vol. D, Section 1.6.7.3, pp. 178-179 [ doi:10.1107/97809553602060000905 ]
... optic effect The acousto-optic effect (Sapriel, 1976) is really a variant of the elasto-optic effect, in that the strain field is created by the passage of a sound wave through the crystal. If this wave has frequency , the resulting polarization in the presence of a light wave of frequency is given by , where . ...
[more results from section 1.6.7 in volume D]
Example of LiNbO3
International Tables for Crystallography (2013). Vol. D, Section 1.6.6.2, pp. 175-176 [ doi:10.1107/97809553602060000905 ]
... by an applied electric field, it is instructive to take a particular example and work out the change in refractive index for a given electric field. LiNbO3 is the most widely used electro-optic material in industry and so this forms a useful example for calculation purposes. This material crystallizes in ...
[more results from section 1.6.6 in volume D]
Optical rotation perpendicular to the optic axis of a uniaxial crystal
International Tables for Crystallography (2013). Vol. D, Section 1.6.5.6, pp. 173-175 [ doi:10.1107/97809553602060000905 ]
Optical rotation perpendicular to the optic axis of a uniaxial crystal 1.6.5.6. Optical rotation perpendicular to the optic axis of a uniaxial crystal The magnitude of circular birefringence is typically about ... best known case where optical rotation has been measured in a linearly birefringent section is that of quartz. It has ...
[more results from section 1.6.5 in volume D]
Dispersion
International Tables for Crystallography (2013). Vol. D, Section 1.6.4.16, p. 169 [ doi:10.1107/97809553602060000905 ]
... to say variation of refractive index depending on wavelength, is a common phenomenon in crystals, and occasionally an important aid in ... minerals chlorite, zoisite and epidote). Dispersion also results in a lack of definition of extinction positions, because in biaxial crystals ... the extinction position with any accuracy. As an example of a milder case, the very common mineral plagioclase (triclinic) shows ...
[more results from section 1.6.4 in volume D]
The dielectric impermeability tensor
International Tables for Crystallography (2013). Vol. D, Section 1.6.3.3, p. 157 [ doi:10.1107/97809553602060000905 ]
... been seen how the refractive indices can be described in a crystal in terms of an ellipsoid, known as the indicatrix. ... the coordinate axesThus the dielectric impermeability tensor is described by a second-rank tensor, related inversely to the dielectric tensor. References ...
[more results from section 1.6.3 in volume D]
Linear acousto-optic effect
International Tables for Crystallography (2013). Vol. D, Section 1.6.2.13, p. 155 [ doi:10.1107/97809553602060000905 ]
... an acoustic frequency , i.e. the relevant susceptibility is . Thus a sound wave passing through an acousto-optic crystal modulates the refractive index via A beam of light of frequency passing through the crystal can ... be diffracted by the refractive index modulation, and so such a crystal is a useful device for converting sound waves ...
[more results from section 1.6.2 in volume D]
Introduction
International Tables for Crystallography (2013). Vol. D, Section 1.6.1, p. 153 [ doi:10.1107/97809553602060000905 ]
... with the growth in optical communications technologies, there has been a revival of interest in the optical properties of crystals, both ... linear and nonlinear optical effects will be introduced briefly in a generalized way. Then the classical derivation of the refractive index surface for a crystal will be derived. This leads on to a ...
Glossary
International Tables for Crystallography (2013). Vol. D, Section 1.6.8, p. 179 [ doi:10.1107/97809553602060000905 ]
Glossary 1.6.8. Glossary , , refractive indices of biaxial indicatrix, polarizability operator ith component of magnetic induction c velocity of light component of elastic stiffness tensor component of generalized susceptibility d density ith component of dielectric displacement phase difference of light unit antisymmetric pseudotensor of rank 3 ith component of electric field , ijth ...
International Tables for Crystallography (2013). Vol. D, ch. 1.6, pp. 153-180 [ doi:10.1107/97809553602060000905 ]
... devoted to the linear optical properties of crystals, starting with a description of the main generalized optical, electro-optic and magneto ... analyse the conditions for the practical observation of crystals with a polarizing microscope: the determination of linear birefringence, and uniaxial and ... with the growth in optical communications technologies, there has been a revival of interest in the optical properties of crystals, ...
The acousto-optic effect
International Tables for Crystallography (2013). Vol. D, Section 1.6.7.3, pp. 178-179 [ doi:10.1107/97809553602060000905 ]
... optic effect The acousto-optic effect (Sapriel, 1976) is really a variant of the elasto-optic effect, in that the strain field is created by the passage of a sound wave through the crystal. If this wave has frequency , the resulting polarization in the presence of a light wave of frequency is given by , where . ...
[more results from section 1.6.7 in volume D]
Example of LiNbO3
International Tables for Crystallography (2013). Vol. D, Section 1.6.6.2, pp. 175-176 [ doi:10.1107/97809553602060000905 ]
... by an applied electric field, it is instructive to take a particular example and work out the change in refractive index for a given electric field. LiNbO3 is the most widely used electro-optic material in industry and so this forms a useful example for calculation purposes. This material crystallizes in ...
[more results from section 1.6.6 in volume D]
Optical rotation perpendicular to the optic axis of a uniaxial crystal
International Tables for Crystallography (2013). Vol. D, Section 1.6.5.6, pp. 173-175 [ doi:10.1107/97809553602060000905 ]
Optical rotation perpendicular to the optic axis of a uniaxial crystal 1.6.5.6. Optical rotation perpendicular to the optic axis of a uniaxial crystal The magnitude of circular birefringence is typically about ... best known case where optical rotation has been measured in a linearly birefringent section is that of quartz. It has ...
[more results from section 1.6.5 in volume D]
Dispersion
International Tables for Crystallography (2013). Vol. D, Section 1.6.4.16, p. 169 [ doi:10.1107/97809553602060000905 ]
... to say variation of refractive index depending on wavelength, is a common phenomenon in crystals, and occasionally an important aid in ... minerals chlorite, zoisite and epidote). Dispersion also results in a lack of definition of extinction positions, because in biaxial crystals ... the extinction position with any accuracy. As an example of a milder case, the very common mineral plagioclase (triclinic) shows ...
[more results from section 1.6.4 in volume D]
The dielectric impermeability tensor
International Tables for Crystallography (2013). Vol. D, Section 1.6.3.3, p. 157 [ doi:10.1107/97809553602060000905 ]
... been seen how the refractive indices can be described in a crystal in terms of an ellipsoid, known as the indicatrix. ... the coordinate axesThus the dielectric impermeability tensor is described by a second-rank tensor, related inversely to the dielectric tensor. References ...
[more results from section 1.6.3 in volume D]
Linear acousto-optic effect
International Tables for Crystallography (2013). Vol. D, Section 1.6.2.13, p. 155 [ doi:10.1107/97809553602060000905 ]
... an acoustic frequency , i.e. the relevant susceptibility is . Thus a sound wave passing through an acousto-optic crystal modulates the refractive index via A beam of light of frequency passing through the crystal can ... be diffracted by the refractive index modulation, and so such a crystal is a useful device for converting sound waves ...
[more results from section 1.6.2 in volume D]
Introduction
International Tables for Crystallography (2013). Vol. D, Section 1.6.1, p. 153 [ doi:10.1107/97809553602060000905 ]
... with the growth in optical communications technologies, there has been a revival of interest in the optical properties of crystals, both ... linear and nonlinear optical effects will be introduced briefly in a generalized way. Then the classical derivation of the refractive index surface for a crystal will be derived. This leads on to a ...
Glossary
International Tables for Crystallography (2013). Vol. D, Section 1.6.8, p. 179 [ doi:10.1107/97809553602060000905 ]
Glossary 1.6.8. Glossary , , refractive indices of biaxial indicatrix, polarizability operator ith component of magnetic induction c velocity of light component of elastic stiffness tensor component of generalized susceptibility d density ith component of dielectric displacement phase difference of light unit antisymmetric pseudotensor of rank 3 ith component of electric field , ijth ...
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