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Polarization 1 Polarisation XY – Plane: Plane of polarisation S =(E x B)/μo Unpolarized light Polaroid: Transmits along the pass axis and absorbs along the perpendicular axis Malus law I E ( Eo cos ) I o cos 2 2 2 Unpolarized light Io I I o cos 2 2 Degree of polarisation If the incident light is a mixture of unpolarised light of intensity Iu and polarised light of intensity Ip, then the transmitted light is given by: I max Iu 2 I I p cos 2 Iu Iu I p; I min 2 2 I max I min P I max I min Polarisation by scattering Rayleigh scattering Blue sky Red Sunset / Sunrise Convention - Polarisation Plane of polarisation is same as plane of incidence - Polarisation Plane of polarisation is perpendicular to the plane of incidence Polarisation by reflection Brewster angle unpolarised polarised linearly polarised partially polarised Glass Brewster angle Brewster’s law = Brewster angle Polarisation by reflection Polarisation by double refraction - Two refracted beams emerge instead of one - Two images instead of one Optic Axis: Uniaxial crystals exhibit cylindrical symmetry. There is a unique direction in a uniaxial crystal called the optic axis. Values of physical parameters along optic axis are different from the values perpendicular to it. Calcite Quartz Ordinary ray Principal Plane: Extraordinary ray Optic axis Plane contains optic axis and the direction of propagation Calcite Ordinary ray σ - polarised Calcite Polariser/ Analyser Extraordinary ray π - polarised Calcite Polarisation by double refraction Isotropic Medium : Velocity Spherical Anisotropic Medium : Velocity ellipsoid Uniaxial and Biaxial Crystals Uniaxial : Calcite, Quartz Biaxial: Mica - Polarisation Plane of polarisation is same as plane of incidence (principal plane) This definition is considered in absence of Principal Plane - Polarisation Plane of polarisation is perpendicular to the plane of incidence (principal plane) Plane of incidence : plane contains incident ray, reflected/refracted ray, surface normal Plane of polarisation : plane contains electric field vector and direction of propagation Principal plane : Plane contains optic axis and the direction of propagation e-ray : Plane of polarisation is same as principal plane e-ray in general does not obey the laws of refraction except in case of special cut of crystal (optic axis) o-ray : Plane of polarisation is perpendicular to the principal plane o-ray always obeys the laws of refraction Always e-ray carries -polarisation and o-ray carries -polarisation Linear polarisation by double refraction Positive and Negative uniaxial crystals Quartz - no = 1.5443 Positive ne = 1.5534 For sodium D lines (ne - no)>0 ne > no v e < vo Calcite - Negative (ne - no)<0 ne < no no = 1.6584 ne = 1.4864 v > v e o Velocity or Refractive index is the same along the OPTIC AXIS for o-ray and e-ray. Wave surface is the locus of all points reached by the ray at a given instant Velocity ellipsoid Positive crystal Quartz Sphere Spheroid ne > no v e < vo Positive crystal Quartz ne > no Sphere ve < vo Spheroid Positive crystal Quartz ne > no Sphere ve < vo Spheroid Calcite Negative crystal ne < no v e > vo Spheroid Sphere Calcite Negative crystal ne < no ve > vo Spheroid Sphere Calcite Negative crystal ne < no ve > vo Spheroid Sphere Biaxial Huygens’ construction Calcite ne < no ve > vo Special cuts of uniaxial crystal Optic axis normal to the surface of incidence No double refraction Optic axis parallel to the surface of incidence No double refraction Oblique Incidence Optic axis parallel to the surface of incidence, normal to the plane of incidence Nicol prism Calcite no = 1.6584 ne = 1.4864 Canada balsam n = 1.55 Rochon prism Wollaston prism Elliptical and circular polarisation Plane polarised Etc. Circularly polarised Production of elliptically polarised light E A O O= E= Retarders Quarter wave, Half wave and Full wave GLASS Quartz Half wave plate Quartz Babinet Compensator is a Variable retarder C . .. .. . .. . . . . . . . . .. .. .. .. . . . . . 2 o (d1 d 2 )( no ne ) Interference of polarised light Fresnel-Arago laws 1. Two coherent rays polarised at right angles do not interfere 2. Two parallel coherent polarised rays will interfere in the same way as will ordinary light Optically active medium Rotation of the plane of vibration & Rotatary dispersion Dextrorotatary or right handed medium Levorotatary or left handed medium Specific rotation = 21.72 Deg/mm for Sodium lines Sugar, Glucose and Fructose Specific rotation Sugar (Sucrose or Cane sugar) Glucose-D ( Dextrose or Grape sugar) Fructose (Levulose or Fruit sugar) 66.47 52.7 - 92 o o o Rotation in liquids Specific rotation is defined as the observed rotation of light of wavelength 589 nm (the d line of a sodium lamp) passing through 10 cm of a 1 g ml-1 solution of a sample. One can find out the density of substance in solution Specific rotation, [ρ] = 10 θ / ld θ = angle of rotation l = Length of the liquid column in cm d = density in gm/cm3 Fresnel’s explanation of rotation Induced Optical Effects Isotropic medium can be made optically anisotropic applying 1. Stress : Photoelastic Effect 2. Magnetic field : Faraday Effect 3. Electric field : Kerr effect Faraday effect d B =Verdet cosntant 0.00001-0.01 min /Gauss-cm Kerr effect An isotropic medium becomes birefringent by an application of electric field. It behaves like an uniaxial crystal with optic axis in the direction of applied field. K = Kerr Constant