1 / 33

Nonlinear Optics (비선형 광학)

200 7 봄학기. Nonlinear Optics (비선형 광학). 담당 교수 : 오 차 환 교 재 : A. Yariv, Optical Electronics in Modern Communications, 5 th Ed., Oxford university Press, 1997 부교재 : R. W. Boyd, Nonlinear Optics, Academic Press, 1992

nero
Download Presentation

Nonlinear Optics (비선형 광학)

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. 2007 봄학기 Nonlinear Optics (비선형 광학) 담당 교수 : 오 차 환 교 재 : A. Yariv, Optical Electronics in Modern Communications, 5th Ed., Oxford university Press, 1997 부교재 : R. W. Boyd, Nonlinear Optics, Academic Press, 1992 A. Yariv, P. Yeh, Optical waves in Crystals, John Wiley & Sons, 1984

  2. Chapter 1. Electromagnetic Theory 1.0 Introduction Propagation of plane, single-frequency electromagnetic waves in - Homogeneous isotropic media - Anisotropic crystal media 1.1 Complex-Function Formalism Expression for the sinusoidally varying time functions ; Typical expression ;

  3. Distinction between the real and complex forms 1) 2) * Time averaging of sinusoidal products

  4. 1.2 Considerations of Energy and Power in Electromagnetic Field Maxwell’s curl equations (in MKS units) ; [ , ] Vector identity ;

  5. Divergence theorem ; : Poynting theorem Total power flow into the volume bounded by s Power expended by the field on the moving charges Rate of increase of the vacuum electromagnetic stored energy Power per unit volume expended by the field on electric and magnetic dipoles

  6. Dipolar dissipation in harmonic fields The average power per unit volume expended by the field on the medium electric polarization ; Assume, field and polarization are parallel to each other Put, : Isotropic media : Anisotropic media

  7. Ex) single localized electric dipole, power DF Let, position of electron : electric field : power DF power 1) : The dipole(electron) continually loses power to the field DF power 2) : The field continually gives power to the dipole DF  Power exchange between the field and medium via dipole interaction

  8. 1.3 Wave Propagation in Isotropic Media Electromagnetic plane wave propagating along the z-axis in homogeneous, isotropic, and lossless media Put, General solutions : * Phase velocity : * wavelength : * Relative amplitude :

  9. Power flow in harmonic fields Intensity (average power per unit area carried in the propagation direction by a wave) : (1.3-17)  Electromagnetic energy density : (1.3-17)  For positive traveling wave :

  10. 1.4 Wave Propagation in Crystals-The Index Ellipsoid In general, the induced polarization is related to the electric field as : electric susceptibility tensor If we choose the principal axes, (Diagonalization)

  11. Secular equation For a monochromatic plane wave ; From Maxwell’s curl equations, In principal coordinate,

  12. ) : wave propagating along the x-axis Simple example ( : transverse wave !! For nontrivial solution to exist, Det=0 ;

  13. Normal surface ) Simple example ( , determinant equation  Optic axis : circle : ellipse

  14. (poynting vector) Wave propagation in anisotropic media Maxwell equations  Define the unit vector along the propagation direction as ( : wave vector) Put, m=1, and Taking scalar product, on both sides : : propagation direction is perpendicular to the electric displacement vector not to the electric field vector

  15. Index ellipsoid Energy density : The surface of constant energy density in D space : or : Index ellipsoid

  16. Classification of anisotropic media 1) Isotropic : ex) CdTe, NaCl, Diamond, GaAs, Glass, … 2) Uniaxial : Fast/Slow axis (1) Positive uniaxial : ex) Ice, Quartz, ZnS, … (2) Negative uniaxial : ex) KDP, ADP, LiIO3, LiNbO3, BBO, … 3) Biaxial : ex) LBO, Mica, NaNO2, …

  17. propagation direction Example of index ellipsoid (positive uniaxial)

  18. Intersection of the index ellipsoid Birefringence :

  19. Normal index surface : The surface in which the distance of a given point from the origin is equal to the index of refraction of a wave propagating along this direction. 1) Positive uniaxial (ne>no) 2) negative uniaxial (ne<no) 3) biaxial ( )

  20. 1.5 Jones Calculus and Its Application in Optical Systems with Birefringence Crystals Jones Calculus (1940, R.C. Jones) : - The state of polarization is represented by a two-component vector - Each optical element is represented by a 2 x 2 matrix. - The overall transfer matrix for the whole system is obtained by multiplying all the individual element matrices. - The polarization state of the transmitted light is computed by multiplying the vector representing the input beam by the overall matrix. Examples) - Polarization state : - Linear polarizer (horizontal) : - Relative phase changer : Report) matrix expressions - Linear polarizers (horizontal, vertical) - Phase retarder - Quarter wave plate (fast horizontel, vertical) - Half wave plate

  21. Retardation plate (wave plate) : Polarization-state converter (transformer) Polarization state of incident beam : where, : complex field amplitudes along x and y s, f axes components : Polarization state of the emerging beam :

  22. Define, - Difference of the phase delays : - Mean absolute phase change : Polarization state of the emerging beam in the xy coordinate system : where,

  23. Transfer matrix for a retardation plate (wave plate) Transfer matrix is a unitary ( ) : Physical properties are invariant under unitary transformation => If the polarization states of two beams are mutually orthogonal, they will remain orthogonal after passing through an arbitrary wave plate.

  24. Ex) Half wave plate : x-polarized beam Report : Problem 1.7

  25. Ex) Quarter wave plate : y-pol. : left circularly polarized beam : x-pol. : right circularly polarized beam

  26. Intensity transmission In many cases, we need to determine the transmitted intensity, since the combination of retardation plates and polarizers is often used to control or modulate the transmitted optical intensity. Incident beam intensity : Output beam intensity : Transmissivity :

  27. Ex) A birefringent plate sandwiched between parallel polarizers : fn. of d and l Ex) A birefringent plate sandwiched between a pair of crossed polarizers

  28. Circular polarization representation It is often more convenient to express the field in terms of “basis” vectors that are circularly polarized ; : constitute a complete set that can be used to describe a field of arbitrary polarization. Left circularly polarized Right circularly polarized Circular representation : Rectangular representation :

  29. Transformation examples) Report :

  30. Faraday rotation In certain optical materials containing magnetic atoms or ions, the two counter-rotating, circularly-polarized modes have different indices of refraction when an external magnetic field is applied along the beam propagation direction. This difference is due to the fact that the individual atomic magnetic moments process in a unique sense about the z-axis (magnetic field direction) and thus interact differently with the two counter-rotating modes.

  31. Ignoring the prefactor, exp[-(i/2)(q++q-], where, Why (Faraday) rotation angle ? In rectangular representation,

  32. CW for +z CW for +z B CW for -z CCW for -z Basic difference between propagation in a magnetic medium and in a dielectric birefringent medium : <dielectric birefringent medium> <magnetic medium> Report : proof by calculating Jones matrix.

  33. Optical isolator

More Related