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Linear optical properties of dielectrics

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Presentation on theme: "Linear optical properties of dielectrics"— Presentation transcript:

1 Linear optical properties of dielectrics
Introduction to crystal optics Introduction to nonlinear optics Relationship between nonlinear optics and electro-optics Bernard Kippelen

2 Maxwell's Equations and the Constitutive Equations
Light beams are represented by electromagnetic waves propagating in space. An electromagnetic wave is described by two vector fields: the electric field E(r, t) and the magnetic field H(r, t). In free space (i.e. in vacuum or air) they satisfy a set of coupled partial differential equations known as Maxwell's equations. 0 and 0 are called the free space electric permittivity and the free space magnetic permeability, respectively, and satisfy the condition c2 = (1 / (0 0)), where c is the speed of light. MKS

3 In a dielectric medium: two more field vectors
D(r,t) the electric displacement field, and B(r,t) the magnetic induction field Constitutive equations:  is the electric permittivity (also called dielectric function) and P = P (r, t) is the polarization vector of the medium. MKS  and j are the electric charge density (density of free conduction carriers) and the current density vector in the medium, respectively. For a transparent dielectric  and j =0.

4 Linear, Nondispersive, Homogeneous, and Isotropic Dielectric Media
Linear: the vector field P(r, t) is linearly related to the vector field E(r, t). Nondispersive: its response is instantaneous, meaning that the polarization at time t depends only on the electric field at that same time t and not by prior values of E Homogeneous: the response of the material to an electric field is independent of r. Isotropic: if the relation between E and P is independent of the direction of the field vector E.  is called the optical susceptibility

5 Wave equation From Maxwell’s equations and by using the identity:

6 Solutions of Wave Equation Dispersion relationship
Real number Complex number Complex conjugate Period T = 2/ Dispersion relationship Time Wavelength  = 2/k Space

7 Which can be rewritten in the frequency domain
In real materials: polarization induced by an electric field is not instantaneous Which can be rewritten in the frequency domain the susceptibility is a complex number: has a real and imaginary part (absorption) the optical properties are frequency dependent

8 Lorentz oscillator model
Electron Nucleus Displacement around equilibrium position due to Coulomb force exerted by electric field

9 Optics of Anisotropic Media
Optical properties (refractive index depend on the orientation of electric field vector E with respect to optical axis of material X Y Z Need to define tensors to describe relationships between field vectors

10 Uniaxial crystals – Index ellipsoid
nX = nY ordinary index nZ = extraordinary index Refractive index for arbitrary direction of propagation can be derived from the index ellipsoid

11 Introduction to Nonlinear Optics
Linear term Nonlinear corrections Example of second-order effect: second harmonic generation (Franken 1961): Symmetry restriction for second-order processes

12 Several electric fields are present
Nonlinear polarization Tensorial relationship between field and polarization

13 Second-order nonlinear susceptibility tensor
Contracted notation for last two indices: xx = 1; yy = 2, zz = 3; zy or yz = 4; zx or xz = 5; xy or yx = 6 18 independent tensor elements but can be reduced by invoking group theory Example: tensor for poled electro-optic polymers

14 Introduction to Electro-optics
John Kerr and Friedrich Pockels discovered in 1875 and 1893, respectively, that the refractive index of a material could be changed by applying a dc or low frequency electric field In this formalism, the effect of the applied electric field was to deform the index ellipsoid Corrections to the coefficients Index ellipsoid equation

15 Example of tensor for electro-optic polymers
Electro-optic tensor Relationship with second-order susceptibility tensor: Example of tensor for electro-optic polymers Simplification of the tensor due to group theory

16 Application of Electro-Optic Properties
Light Applied voltage changes refractive index

17 Electro-Optic Properties of Organics
If the molecules are randomly oriented inversion symmetry nonlinear susceptibilities hyperpolarizabilities

18 Convert an intensity distribution into a refractive index distribution
The Photorefractive Effect Convert an intensity distribution into a refractive index distribution

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