Library of Congress Cataloging-in-Publication Data
Powers, Peter E.
Field guide to nonlinear optics / Peter E. Powers.
pages cm. – (The field guide series; FG29)
Includes bibliographical references and index.
ISBN 978-0-8194-9635-5—ISBN 978-0-8194-9636-2—ISBN 978-0-8194-9637-9
1. Nonlinear optics. I. Title.
QC446.2.P688 2013
621.36'94−dc23
2013014471
Published by
SPIE
P.O. Box 10
Bellingham, Washington 98227-0010 USA
Phone: +1.360.676.3290
Fax: +1.360.647.1445
Email: books@spie.org
The content of this book reflects the work and thought of the author(s). Every effort has been made to publish reliable and accurate information herein, but the publisher is not responsible for the validity of the information or for any outcomes resulting from reliance thereon.
Printed in the United States of America.
First printing
Introduction to the Series
Welcome to the SPIE Field Guides—a series of publications written directly for the practicing engineer or scientist. Many textbooks and professional reference books cover optical principles and techniques in depth. The aim of the SPIE Field Guides is to distill this information, providing readers with a handy desk or briefcase reference that provides basic, essential information about optical principles, techniques, or phenomena, including definitions and descriptions, key equations, illustrations, application examples, design considerations, and additional resources. A significant effort will be made to provide a consistent notation and style between volumes in the series.
Each SPIE Field Guide addresses a major field of optical science and technology. The concept of these Field Guides is a format-intensive presentation based on figures and equations supplemented by concise explanations. In most cases, this modular approach places a single topic on a page, and provides full coverage of that topic on that page. Highlights, insights, and rules of thumb are displayed in sidebars to the main text. The appendices at the end of each Field Guide provide additional information such as related material outside the main scope of the volume, key mathematical relationships, and alternative methods. While complete in their coverage, the concise presentation may not be appropriate for those new to the field.
The SPIE Field Guides are intended to be living documents. The modular page-based presentation format allows them to be updated and expanded. We are interested in your suggestions for new Field Guide topics as well as what material should be added to an individual volume to make these Field Guides more useful to you. Please contact us at fieldguides@SPIE.org.
John E. Greivenkamp, Series Editor
College of Optical Sciences
The University of Arizona
The Field Guide Series
Adaptive Optics, Second Edition, Robert Tyson & Benjamin Frazier
Atmospheric Optics, Larry Andrews
Binoculars and Scopes, Paul Yoder, Jr. & Daniel Vukobratovich
Diffractive Optics, Yakov Soskind
Geometrical Optics, John Greivenkamp
Illumination, Angelo Arecchi, Tahar Messadi, & John Koshel
Image Processing, Khan M. Iftekharuddin & Abdul Awwal
Infrared Systems, Detectors, and FPAs, 2nd Edition, Arnold Daniels
Interferometric Optical Testing, Eric Goodwin & Jim Wyant
Laser Pulse Generation, Rüdiger Paschotta
Lasers, Rüdiger Paschotta
Lens Design, Julie Bentley & Craig Olson
Microscopy, Tomasz Tkaczyk
Nonlinear Optics, Peter Powers
Optical Fabrication, Ray Williamson
Optical Fiber Technology, Rüdiger Paschotta
Optical Lithography, Chris Mack
Optical Thin Films, Ronald Willey
Optomechanical Design and Analysis, Katie Schwertz & James Burge
Physical Optics, Daniel Smith
Polarization, Edward Collett
Probability, Random Processes, and Random Data Analysis, Larry Andrews
Radiometry, Barbara Grant
Special Functions for Engineers, Larry Andrews
Spectroscopy, David Ball
Terahertz Sources, Detectors, and Optics, Créidhe O’Sullivan & J. Anthony Murphy
Visual and Ophthalmic Optics, Jim Schwiegerling
Field Guide to Nonlinear Optics
This Field Guide is designed for those looking for a condensed and concise source of key concepts, equations, and techniques for nonlinear optics. Topics covered include technologically important effects, recent developments in nonlinear optics, and linear optical properties central to nonlinear phenomena. The focus of each section is based on my research, my interactions with colleagues in the field, and my experiences teaching nonlinear optics.
Examples throughout this Field Guide illustrate fundamental concepts while demonstrating the application of key equations. Equations are presented without proof or derivation; however, the interested reader may refer to the bibliography for a list of resources that go into greater detail. In addition to the overview of nonlinear phenomena, this Field Guide includes an appendix of material properties for some commonly used nonlinear crystals.
This Field Guide features notations commonly encountered in nonlinear optics literature. All equations are written in SI units for convenience when comparing calculations to laboratory measurements. The formalism of writing equations using complex variable notation introduces ambiguity in defining the electric field’s complex amplitude. Though one convention is used throughout this text, conventions and conversions are presented as part of the first topic. Equations in terms of experimentally measured quantities such as power, intensity, and energy, have no ambiguity.
Peter E. Powers
University of Dayton
March 2013
Table of Contents
Glossary of Terms and Acronyms x
Electromagnetic Waves and Crystal Optics 1
Conventions and Conversions 1
Maxwell’s Equations and the Wave Equation 2
Uniaxial Crystals 3
Biaxial Crystals 4
Nonlinear Susceptibility 5
Nonlinear Polarization for Parametric Interactions 5
Classical Expressions for Nonlinear Susceptibility 6
Nonlinear Susceptibilities 7
d Matrices 8
Working with d Matrices and SHG 9
Effective Nonlinearities 10
Tabulation of d Matrices 11
Electro-optic Effect 13
Electro-optic Effect 13
r Matrices 14
Electro-optic Waveplates 16
Q Switches 17
Amplitude and Phase Modulators 18
Electro-optic Sampling for Terahertz Detection 19
Photorefraction 20
χ(2) Parametric Processes 21
χ(2) Coupled Amplitude Equations 21
χ(2) Processes with Focused Gaussian Beams 22
DFG and OPA 23
Sum-Frequency Generation 24
Second-Harmonic Generation 25
Three-Wave Mixing Processes with Depletion 26
Optical Parametric Generation 27
Optical Parametric Oscillator 28
Singly Resonant Optical Parametric Oscillator 29
Phase Matching 30
Birefringent Phase Matching 30
e- and o-Wave Phase Matching 31
DFG and SFG Phase Matching for Uniaxial Crystals 32
SHG Phase Matching for Uniaxial Crystals 33
Biaxial Crystals in the XY Plane 34
Biaxial Crystals in the YZ Plane 35
Biaxial Crystals in the XZ Plane 36
Quasi-phase-matching 37
Birefringent versus Quasi-phase-matching 38
Noncollinear Phase Matching 39
Tuning Curves 40
Phase Matching Bandwidth 41
Bandwidths for DFG and SFG 41
Bandwidth Calculation Aids 42
SFG and DFG Bandwidth Formulae 43
SHG Bandwidth Formulae 46
Graphical Approach for Bandwidths 48
Noncollinear Bandwidth 49
χ(2) Waveguides 50
χ(2) Waveguide Interactions 50
χ(2) Waveguide Devices 51
Waveguide Phase Matching 52
χ(3) Parametric Processes 53
Four-Wave Mixing 53
Degenerate Four-Wave Mixing 54
Third-Harmonic Generation 55
χ(3) Parametric Amplifier 56
Noncollinear Phase Matching for χ(3) Processes 57
Nonlinear Refractive Index 58
Nonlinear Refractive Index 58
Nonlinear Absorption 59
Calculations of Nonlinear Index 60
Self-Phase Modulation 61
z Scan 62
Optical Bistability 63
Raman and Brillouin Processes 64
Spontaneous Raman Scattering 64
Stimulated Raman Scattering 65
Anti-Stokes Raman Scattering 66
Raman Microscopy 67
Photo-acoustic Interactions 68
Stimulated Brillouin Scattering 69
Ultrafast Nonlinear Effects 70
Saturable Absorption 70
Temporal Solitons 71
Spatial Solitons 72
High Harmonic Generation 73
Ultrashort-Pulse Measurement 74
Appendices 75
Gaussian Beams 75
Sellmeier Equations for Selected χ(2) Crystals 76
Properties of Selected χ(2) Crystals 78
References for Selected χ(2) Crystals Tables 79
Equation Summary 81
Bibliography 90
Index 93
Glossary of Terms and Acronyms
Constants
c
Speed of light in vacuum (299,792,458 m/sec)
e
Elementary charge (1.6022 × 10−19 C)
h
Planck’s constant (6.6261 × 10−34 J · sec)
ℏ
h/2π (1.0546 × 10−34 J · sec)
kB
Boltzmann constant (1.3807 × 10−23 J/K)
me
Electron mass (9.1094 × 10−31 kg)
Vacuum permittivity (8.8542 × 10−2 F/m)
Vacuum permeability (4π × 10−7 N/A2)
General
3PA
Three-photon absorption
A
Electric field’s complex amplitude scalar
A
Electric field’s complex amplitude vector
AC
Autocorrelation
AO
Acousto-optic
b
Confocal distance (2zR)
B
Magnetic induction scalar
Magnetic induction vector
BBO
b-BaB2O4, b-barium borate
BIBO
BiB3O6, bismuth triborate
BPM
Birefringent phase matching
CARS
Coherent anti-Stokes Raman spectroscopy
c.c.
Complex conjugate
cgs
Centimeter-gram-second
D
Electric displacement vector
deff
Effective second-order nonlinearity
DFG
Difference-frequency generation
DFWM
Degenerate four-wave mixing
dijk
d tensor
DKDP
KD2PO4, deuterated potassium dihydrogen phosphate
DR-OPO
Doubly-resonant optical parametric oscillator
e
Extraordinary wave (e-wave)
E
Electric field scalar
E
Electric field vector
EO
Electro-optic
ESC
Space-charge electric field
f
Focal length of a lens
FROG
Frequency-resolved optical gating
fsec
Femtosecond (10–15 sec)
FWHM
Full-width at half-maximum
FWM
Four-wave mixing
GaAs
Gallium arsenide
GaP
Gallium phosphide
gB
Brillouin intensity gain factor
gR
Raman intensity gain factor
GVD
Group velocity dispersion
Magnetic field
HHG
High harmonic generation
i
I
Light intensity
Io
On-axis intensity
j f
Free current density
k
Wavevector magnitude
k
Wavevector
K
Acoustic wavevector
KDP
KH2PO4, potassium dihydrogen phosphate
KTP
KTiOPO4, potassium titanyl phosphate
L
Interaction length
LBO
LiB3O5, lithium triborate
Lc
Coherence length
LiNbO3
Lithium niobate
LiTaO3
Lithium tantalite
LN
Lithium niobate
Magnetization
MPA
Multi-photon absorption
n
Refractive index/index of refraction
ne(θ)
Extraordinary refractive index
Nonlinear index intensity coefficient
NL
Nonlinear
NLA
Nonlinear absorption
NLSE
Nonlinear Schrödinger equation
no
Ordinary refractive index
nsec
Nanosecond (10−9 sec)
Principal indices (or eigenindices)
o
Ordinary wave (o-wave)
Ordinary wave unit vector
OPA
Optical parametric amplification
OPG
Optical parametric generation
OPO
Optical parametric oscillator
P
Optical power
P (1)
Linear material polarization
P (2)
Second-order nonlinear polarization
P (3)
Third-order nonlinear polarization
PCM
Phase-conjugate mirror
pm
Picometer
P (NL)
Nonlinear polarization
PPLN
Periodically poled lithium niobate
psec
Picosecond (10−12 sec)
Threshold power
q
Gaussian beam parameter
QPM
Quasi-phase-matching
QWP
Quarter-wave plate
r
Electro-optic coefficient
R
Power reflectivity
Poynting vector
SBS
Spontaneous Brillouin scattering
SESAM
Semiconductor saturable absorber mirror
SFG
Sum-frequency generation
SHG
Second-harmonic generation
sinc(x)
sin(x)/x
SPM
Self-phase modulation
SPS
Spontaneous parametric scattering
SR-OPO
Singly-resonant optical parametric oscillator
SVEA
Slowly varying envelope approximation
T
Temperature
THG
Third-harmonic generation
TPA
Two-photon absorption
Up
Ponderomotive energy
vg
Group velocity
wo
Radius at the beam waist
w(z)
Beam radius
Z
Optic axis
ZGP
ZnGeP2, zinc germanium phosphide
ZnTe
Zinc telluride
zR
Rayleigh range
α
Linear absorption coefficient
β
Waveguide propagation coefficient
β (TPA)
Two-photon absorption coefficient
Δ
Miller’s delta
Δk
k-vector mismatch
Permittivity tensor
θPM
Phase matching angle (polar angle)
Λ
Quasi-phase-matching periodicity
λ
Vacuum wavelength
λI (λ3)
Idler wavelength
λP (λ1)
Pump wavelength
λS (λ2)
Signal wavelength
ξ
Focusing parameter
ρ
Poynting vector walk-off angle
Free charge density
σR
Raman scattering cross-section
Pulse duration
φ
Azimuthal angle
Linear susceptibility tensor
Effective nonlinear susceptibility
Second-order nonlinear susceptibility tensor
Third-order nonlinear susceptibility tensor
Brillouin susceptibility
Raman susceptibility
ψ
Noncollinear angle
ω
Angular frequency
ωAS
Anti-Stokes angular frequency
ωS
Signal (parametric process) or Stokes frequency (Raman process)
ΩB
Brillouin frequency
