Presentation is loading. Please wait.

Presentation is loading. Please wait.

2015-5-20Fundamentals of Photonics 1 NONLINEAR OPTICS- III.

Published byEmmeline Parks Modified over 9 years ago

Similar presentations

Presentation on theme: "2015-5-20Fundamentals of Photonics 1 NONLINEAR OPTICS- III."— Presentation transcript:

1 2015-5-20Fundamentals of Photonics 1 NONLINEAR OPTICS- III

2 2015-5-20Fundamentals of Photonics 2 Question: Is it possible to change the color of a monochromatic light? output NLO sample input Answer: Not without a laser light

3 2015-5-20Fundamentals of Photonics 3 Nicolaas Bloembergen (born 1920) has carried out pioneering studies in nonlinear optics since the early 1960s. He shared the 1981 Nobel Prize with Arthur Schawlow.

4 2015-5-20Fundamentals of Photonics 4 Part 0 : Comparison Linear optics: ★ Optical properties, such as the refractive index and the absorption coefficient independent of light intensity. ★ The principle of superposition, a fundamental tenet of classical, holds. ★ The frequency of light cannot be altered by its passage through the medium. ★ Light cannot interact with light; two beams of light in the same region of a linear optical medium can have no effect on each other. Thus light cannot control light.

5 2015-5-20Fundamentals of Photonics 5 Part 0 : Comparison Nonlinear optics: change ★ The refractive index, and consequently the speed of light in an optical medium, does change with the light intensity. ★ The principle of superposition is violated. ★ Light can alter its frequency as it passes through a nonlinear optical material (e.g., from red to blue!). ★ Light can control light; photons do interact Light interacts with light via the medium. The presence of an optical field modifies the properties of the medium which, in turn, modify another optical field or even the original field itself.

6 2015-5-20Fundamentals of Photonics 6 Part 1 : phenomena involved frequency conversion Second-harmonic generation (SHG) Parametric amplification Parametric oscillation third-harmonic generation self-phase modulation self-focusing four-wave mixing Stimulated Brillouin Scatteirng Stimulated Raman Scatteirng Optical solitons Optical bistability Second- order Third-order

7 2015-5-20Fundamentals of Photonics 7 19.1 Nonlinear optical media Origin of Nonlinear if Hooke’s law is satisfied Linear! if Hooke’s law is not satisfied Noninear! the dependence of the number density N on the optical field the number of atoms occupying the energy levels involved in the absorption and emission

8 2015-5-20Fundamentals of Photonics 8 Figure 19.1-1 The P-E relation for (a) a linear dielectric medium, and (b) a nonlinear medium. P P E E

9 2015-5-20Fundamentals of Photonics 9 The nonlinearity is usually weak. The relation between P and E is approximately linear for small E, deviating only slightly from linearity as E increases. basic description for a nonlinear optical medium In centrosymmetric media, d vanish, and the lowest order nonlinearity is of third order

10 2015-5-20Fundamentals of Photonics 10 In centrosymmetric media: d=0 the lowest order nonlinearity is of third order Typical values

11 2015-5-20Fundamentals of Photonics 11 The Nonlinear Wave Equation nonlinear wave equation

12 2015-5-20Fundamentals of Photonics 12 There are two approximate approaches to solving the nonlinear wave equation: ★ The first is an iterative approach known as the Born approximation. ★ The second approach is a coupled-wave theory in which the nonlinear wave equation is used to derive linear coupled partial differential equations that govern the interacting waves. This is the basis of the more advanced study of wave interactions in nonlinear media.

13 2015-5-20Fundamentals of Photonics 13 19.2 Second-order Nonlinear Optics

14 2015-5-20Fundamentals of Photonics 14 A. Second-Harmonic Generation and Rectification complex amplitude Substitute it into (9.2-l)

15 2015-5-20Fundamentals of Photonics 15 This process is illustrated graphically in Fig. 9.2-1. Figure 9.2-1 A sinusoidal electric field of angular frequency w in a second-order nonlinear optical medium creates a component at 2w (second-harmonic) and a steady (dc) component. P E 0 E(t) t t t + t P NL (t) dc second-harmonic

16 2015-5-20Fundamentals of Photonics 16 Second-Harmonic Generation SHG SFG DHG

17 2015-5-20Fundamentals of Photonics 17 Component of frequency 2w SHG complex amplitude intensity The interaction region should also be as long as possible. Guided wave structures that confine light for relatively long distances offer a clear advantage.

18 2015-5-20Fundamentals of Photonics 18 Figure 9.2-2 Optical second-harmonic generation in (a) a bulk crystal; (b) a glass fiber; (c) within the cavity of a semiconductor laser.

19 2015-5-20Fundamentals of Photonics 19 Optical Rectification The component P NL (0) corresponds to a steady (non-time-varying) polarization density that creates a dc potential difference across the plates of a capacitor within which the nonlinear material is placed. An optical pulse of several MW peak power, may generate a voltage of several hundred uV.

20 2015-5-20Fundamentals of Photonics 20 B. The Electra-Optic Effect Substitute it into (9.2-l) 9.2-8

21 2015-5-20Fundamentals of Photonics 21 If the optical field is substantially smaller in magnitude than the electric field Can be negleted

22 2015-5-20Fundamentals of Photonics 22 9.2-8 a linear relation between PNL(w) and E(w) incremental change of the refractive index 9.2-9

23 2015-5-20Fundamentals of Photonics 23 the nonlinear medium exhibits the linear electro-optic effect Pockels effect Pockels coefficient Comparing this formula with (9.2-9)

24 2015-5-20Fundamentals of Photonics 24 C. Three-Wave Mixing Frequency Conversion E(t) comprising two harmonic components at frequencies w1 and w2 Frequency up-conversion Frequency down-conversion

25 2015-5-20Fundamentals of Photonics 25 Figure 9.2-5 An example of frequency conversion in a nonlinear crystal Although the incident pair of waves at frequencies w 1 and w 2 produce polarization densities at frequencies 0, 2w l, 2w 2, w l +w 2, and w 1 -w 2, all of these waves are not necessarily generated, since certain additional conditions (phase matching) must be satisfied, as explained presently. 点击查看 flash 动画

26 2015-5-20Fundamentals of Photonics 26 Phase Matching where Frequency-Matching Condition Phase-Matching Condition Figure 9.2-6 The phase-matching condition

27 2015-5-20Fundamentals of Photonics 27 ★ same direction: nw 3 /c 0 =nw 1 /c 0 + nw 2 /c 0, w 3 =w 1 +w 2 frequency matching ensures phase matching. ★ different refractive indices, n l, n 2, and n 3 : n 3 w 3 /c 0 =n 1 w 1 /c 0 +n 2 w 2 /c 0 n 3 w 3 =n 1 w 1 +n 2 w 2 The phase-matching condition is then independent of the frequency-matching condition w 3 =w 1 +w 2 ; both conditions must be simultaneously satisfied. Precise control of the refractive indices at the three frequencies is often achieved by appropriate selection of the polarization and in some cases by control of the temperature.

28 2015-5-20Fundamentals of Photonics 28 Three- Wave Mixing We assume that only the component at the sum frequency w 3 =w 1 +w 2 satisfies the phase-matching condition. Other frequencies cannot be sustained by the medium since they are assumed not to satisfy the phase-matching condition. Once wave 3 is generated, it interacts with wave 1 and generates a wave at the difference frequency w 2 =w 3 -w 1. Waves 3 and 2 similarly combine and radiate at w 1. The three waves therefore undergo mutual coupling in which each pair of waves interacts and contributes to the third wave. three-wave mixing parametric interaction

29 2015-5-20Fundamentals of Photonics 29 parametric interaction ◆ Waves 1 and 2 are mixed in an up-converter, generating a wave at a higher frequency w 3 =w 1 +w 2. A down-converter is realized by an interaction between waves 3 and 1 to generate wave 2, at the difference frequency w 2 =w 3 -w 1. ◆ Waves 1, 2, and 3 interact so that wave 1 grows. The device operates as an amplifier and is known as a parametric amplifier. Wave 3, called the pump, provides the required energy, whereas wave 2 is an auxiliary wave known as the idler wave. The amplified wave is called the signal. ◆ With proper feedback, the parametric amplifier can operate as a parametric oscillator, in which only a pump wave is supplied.

30 2015-5-20Fundamentals of Photonics 30 Figure 9.2-7 Optical parametric devices: (a) frequency up- converter; (b) parametric amplifier; (c) parametric oscillator. Crystal Pump w 3 w1w1 w1w1 w2w2 w1w1 w3w3 w3w3 w1w1 Amplified signal w2w2 Pump signal Crystal signal w 1 Pump w 2 Up-converted signal w 3 =w 1 +w 2 w 1, w 2 Filter (a) (b) (c)

31 2015-5-20Fundamentals of Photonics 31 Two-wave mixing can occur only in the degenerate case, w 2 =2w 1, in which the second-harmonic of wave 1 contributes to wave 2; and the subharmonic w 2 /2 of wave 2, which is at the frequency difference w 2 -w 1, contributes to wave 1. Parametric devices are used for coherent light amplification, for the generation of coherent light at frequencies where no lasers are available (e.g., in the UV band), and for the detection of weak light at wavelengths for which sensitive detectors do not exist.

32 2015-5-20Fundamentals of Photonics 32

33 2015-5-20Fundamentals of Photonics 33 Wave Mixing as a Photon Interaction Process conservation of energy and momentum require Figure 9.2-8 Mixing of three photons in a second-order nonlinear medium: (a) photon combining; (b) photon splitting.

34 2015-5-20Fundamentals of Photonics 34 Photon-Number Conservation Manley-Rowe Relation

35 2015-5-20Fundamentals of Photonics 35 19.3 Coupled-wave theory of three-wave mixing Coupled- Wave Equations Rewrite in the compact form

36 2015-5-20Fundamentals of Photonics 36 Frequency-Matching Condition Three-wave Mixing Coupled Equations

37 2015-5-20Fundamentals of Photonics 37 Mixing of Three Collinear Uniform Plane Waves slowly varying envelope approximation Three-wave Mixing Coupled Equations

38 2015-5-20Fundamentals of Photonics 38 A. Second-Harmonic Generation a degenerate case of three-wave mixing w 1 =w 2 =w and w 3 =2w Two forms of interaction occur: ☆ Two photons of frequency o combine to form a photon of frequency 2w (second harmonic). ☆ One photon of frequency 2w splits into two photons, each of frequency w. ☆ The interaction of the two waves is described by the Helmholtz with equations sources. k3=2k1

39 2015-5-20Fundamentals of Photonics 39 Coupled- Wave Equations for Second-Harmonic Generation. where perfect phase matching Coupled Equations (Second-Harmonic Generation)

40 2015-5-20Fundamentals of Photonics 40 the solution Consequently, the photon flux densities

41 2015-5-20Fundamentals of Photonics 41 Figure 9.4-1 Second-harmonic generation. (a) A wave of frequency w incident on a nonlinear crystal generates a wave of frequency 2w. (b) Two photons of frequency w combine to make one photon of frequency 2w. (c) As the photon flux density   (z) of the fundamental wave decreases, the photon flux density  3 (z) of the second-harmonic wave increases. Since photon numbers are conserved, the sum  1 (z)+2  3 (z)=  1 (0) is a constant.

42 2015-5-20Fundamentals of Photonics 42 The efficiency of second-harmonic generation for an interaction region of length L is For large  L (long cell, large input intensity, or large nonlinear parameter), the efficiency approaches one. This signifies that all the input power (at frequency w) has been transformed into power at frequency 2w; all input photons of frequency w are converted into half as many photons of frequency 2w. For small  L (small device length L, small nonlinear parameter d, or small input photon flux density   (0)), the argument of the tanh function is small and therefore the approximation tanhx=x may be used. The efficiency of second- harmonic generation is then

43 2015-5-20Fundamentals of Photonics 43 Effect of Phase Mismatch Efficiency Solution

44 2015-5-20Fundamentals of Photonics 44 Figure 9.4-2 The factor by which the efficiency of second- harmonic generation is reduced as a result of a phase mismatch △ kL between waves interacting within a distance L.

45 2015-5-20Fundamentals of Photonics 45 B. Frequency Conversion A frequency up-converter converts a wave of frequency w 1 into a wave of higher frequency w 3 by use of an auxiliary wave at frequency w 2, called the “pump.” A photon from the pump is added to a photon from the input signal to form a photon of the output signal at an up-converted frequency w 3 =w 1 +w 2. The conversion process is governed by the three coupled equations. For simplicity, assume that the three waves are phase matched ( △ k = 0) and that the pump is sufficiently strong so that its amplitude does not change appreciably within the interaction distance of interest.

46 2015-5-20Fundamentals of Photonics 46 Figure 9.4-3 The frequency up-converter: (a) wave mixing; (b) photon interactions; (c) evolution of the photon flux densities of the input w 1 -wave and the up-converted w 3 - wave. The pump w2-wave is assumed constant Efficiency

47 2015-5-20Fundamentals of Photonics 47 C. Parametric Amplification and Oscillation Parametric Amplifiers The parametric amplifier uses three-wave mixing in a nonlinear crystal to provide optical gain. The process is governed by the same three coupled equations with the waves identified as follows: ★ Wave 1 is the “signal” to be amplified. It is incident on the crystal with a small intensity I(0). ★ Wave 3, called the “pump,” is an intense wave that provides power to the amplifier. ★ Wave 2, called the “idler,” is an auxiliary wave created by the interaction process

48 2015-5-20Fundamentals of Photonics 48 Figure 9.4-4 The parametric amplifier: (a) wave mixing; (b) photon mixing; (c) photon flux densities of the signal and the idler; the pump photon flux density is assumed constant. Parametric Amplifier Gain Coefficient

49 2015-5-20Fundamentals of Photonics 49 Parametric Oscillators A parametric oscillator is constructed by providing feedback at both the signal and the idler frequencies of a parametric amplifier. Energy is supplied by the pump. Figure 9.4-5 The parametric oscillator generates light at frequencies w 1 and w 2. A pump of frequency w 3 =w 1 +w 2 serves as the source of energy.

50 Frequency Upconversion 返回

Download ppt "2015-5-20Fundamentals of Photonics 1 NONLINEAR OPTICS- III."

Similar presentations

Key CLARITY technologies II – Four-Wave Mixing wavelength conversion National and Kapodistrian University of Athens Department of Informatics and Telecommunications.

Key CLARITY technologies II – Four-Wave Mixing wavelength conversion National and Kapodistrian University of Athens Department of Informatics and Telecommunications.
Classical behaviour of CW Optical Parametric Oscillators T. Coudreau Laboratoire Kastler Brossel, UMR CNRS 8552 et Université Pierre et Marie Curie, PARIS,

Classical behaviour of CW Optical Parametric Oscillators T. Coudreau Laboratoire Kastler Brossel, UMR CNRS 8552 et Université Pierre et Marie Curie, PARIS,
Outline Index of Refraction Introduction Classical Model

Outline Index of Refraction Introduction Classical Model
Multi-wave Mixing In this lecture a selection of phenomena based on the mixing of two or more waves to produce a new wave with a different frequency, direction.

Multi-wave Mixing In this lecture a selection of phenomena based on the mixing of two or more waves to produce a new wave with a different frequency, direction.
Simultaneously Stokes and anti-Stokes Raman amplification in silica fiber Victor G. Bespalov Russian Research Center S. I. Vavilov State Optical Institute

Simultaneously Stokes and anti-Stokes Raman amplification in silica fiber Victor G. Bespalov Russian Research Center "S. I. Vavilov State Optical Institute"
Frequency modulation and circuits

Frequency modulation and circuits
Light Waves and Polarization Xavier Fernando Ryerson Communications Lab

Light Waves and Polarization Xavier Fernando Ryerson Communications Lab
Fundamentals of Photonics

Fundamentals of Photonics
Optical sources Lecture 5.

Optical sources Lecture 5.
Stimulated scattering is a fascinating process which requires a strong coupling between light and vibrational and rotational modes, concentrations of different.

Stimulated scattering is a fascinating process which requires a strong coupling between light and vibrational and rotational modes, concentrations of different.
EEE 498/598 Overview of Electrical Engineering

EEE 498/598 Overview of Electrical Engineering
Maxwell’s Equations and Electromagnetic Waves

Maxwell’s Equations and Electromagnetic Waves
Quasi-phase matching SRS generation. Nikolai S. Makarov, State Institute of Fine Mechanics and Optics, Victor G. Bespalov, Russian Research Center S.

Quasi-phase matching SRS generation. Nikolai S. Makarov, State Institute of Fine Mechanics and Optics, Victor G. Bespalov, Russian Research Center "S.
Light and Matter Tim Freegarde School of Physics & Astronomy University of Southampton The tensor nature of susceptibility.

Light and Matter Tim Freegarde School of Physics & Astronomy University of Southampton The tensor nature of susceptibility.
Ruby Laser Crystal structure of sapphire: -Al2O3 (aluminum oxide). The shaded atoms make up a unit cell of the structure. The aluminum atom inside the.

Ruby Laser Crystal structure of sapphire: -Al2O3 (aluminum oxide). The shaded atoms make up a unit cell of the structure. The aluminum atom inside the.
COMPUTER MODELING OF LASER SYSTEMS

COMPUTER MODELING OF LASER SYSTEMS
Optical Field Mixing. Oscillating Polarisation Optical polarisation Fundamental polarisation SH Polarisation Constant (dc) polarisation.

Optical Field Mixing. Oscillating Polarisation Optical polarisation Fundamental polarisation SH Polarisation Constant (dc) polarisation.
Janez Žabkar Advisers: dr. Marko Zgonik dr. Marko Marinček

Janez Žabkar Advisers: dr. Marko Zgonik dr. Marko Marinček
EE 230: Optical Fiber Communication Lecture 7 From the movie Warriors of the Net Optical Amplifiers-the Basics.

EE 230: Optical Fiber Communication Lecture 7 From the movie Warriors of the Net Optical Amplifiers-the Basics.
EE 230: Optical Fiber Communication Lecture 6 From the movie Warriors of the Net Nonlinear Processes in Optical Fibers.

EE 230: Optical Fiber Communication Lecture 6 From the movie Warriors of the Net Nonlinear Processes in Optical Fibers.

Similar presentations

Ads by Google