SOLITONS

1 / 39
About This Presentation
Title:

SOLITONS

Description:

SOLITONS From Canal Water Waves to Molecular Lasers Hieu D. Nguyen Rowan University IEEE Night 5-20-03 Atom Lasers Gross-Pitaevskii equation: Atom-atom interaction ... – PowerPoint PPT presentation

Number of Views:7
Avg rating:3.0/5.0
Slides: 40
Provided by: Hie62
Learn more at: https://www.rowan.edu

less

Transcript and Presenter's Notes

Title: SOLITONS


1
SOLITONS From Canal Water Waves to Molecular
Lasers
Hieu D. Nguyen Rowan University
IEEE Night 5-20-03
2
from SIAM News, Volume 31, Number 2, 1998 Making
Waves Solitons and Their Practical Applications
"A Bright Idea Economist (11/27/99) Vol. 353,
No. 8147, P. 84 Solitons, waves that move at a
constant shape and speed, can be used for
fiber-optic-based data transmissions
From the Academy Mathematical frontiers in
optical solitons Proceedings NAS, November 6, 2001
Number 588, May 9, 2002 Bright Solitons in a
Bose-Einstein Condensate
Solitons may be the wave of the future Scientists
in two labs coax very cold atoms to move in
trains 05/20/2002 The Dallas Morning News
3
Definition of Soliton
One entry found for soliton. Main Entry
soliton   Pronunciation 'sä-l-"tänFunction
nounEtymology solitary 2-onDate 1965 a
solitary wave (as in a gaseous plasma) that
propagates with little loss of energy and
retains its shape and speed after colliding with
another such wave
http//www.m-w.com/cgi-bin/dictionary
4
Solitary Waves
John Scott Russell (1808-1882)
  • Scottish engineer at Edinburgh
  • Committee on Waves BAAC

Union Canal at Hermiston, Scotland
http//www.ma.hw.ac.uk/chris/scott_russell.html
5
Great Wave of Translation
I was observing the motion of a boat which was
rapidly drawn along a narrow channel by a pair
of horses, when the boat suddenly stopped - not
so the mass of water in the channel which it had
put in motion it accumulated round the prow of
the vessel in a state of violent agitation, then
suddenly leaving it behind,rolled forward with
great velocity, assuming the form of a large
solitary elevation, a rounded, smooth and
well-defined heap of water, which continued its
course along the channel apparently without
change of form or diminution of speed -
J. Scott Russell
6
(No Transcript)
7
I followed it on horseback, and overtook it
still rolling on at a rate of some eight or nine
miles an hour, preserving its original figure
some thirty feet long and a foot to a foot and a
half in height. Its height gradually diminished,
and after a chase of one or two miles I lost it
in the windings of the channel. Such, in the
month of August 1834, was my first chance
interview with that singular and beautiful
phenomenon which I have called the Wave of
Translation.
Report on Waves - Report of the fourteenth
meeting of the British Association for the
Advancement of Science, York, September 1844
(London 1845), pp 311-390, Plates XLVII-LVII.
8
Copperplate etching by J. Scott Russell depicting
the 30-foot tank he built in his back garden in
1834
9
Controversy Over Russells Work1
George Airy
  • Unconvinced of the Great Wave of Translation
  • Consequence of linear wave theory

G. G. Stokes
- Doubted that the solitary wave could propagate
without change in form
Boussinesq (1871) and Rayleigh (1876)
- Gave a correct nonlinear approximation theory
1http//www-gap.dcs.st-and.ac.uk/history/Mathemat
icians/Russell_Scott.html
10
Model of Long Shallow Water Waves
D.J. Korteweg and G. de Vries (1895)
  • surface elevation above equilibrium
  • depth of water
  • surface tension
  • density of water
  • force due to gravity
  • small arbitrary constant

11
Korteweg-de Vries (KdV) Equation
Rescaling
KdV Equation
Nonlinear Term
Dispersion Term
(Steepen)
(Flatten)
12
Stable Solutions
Profile of solution curve
  • Unchanging in shape
  • Bounded
  • Localized

Do such solutions exist?
Steepen Flatten Stable
13
Solitary Wave Solutions
1. Assume traveling wave of the form
2. KdV reduces to an integrable equation
3. Cnoidal waves (periodic)
14
4. Solitary waves (one-solitons)
- Assume wavelength approaches infinity
15
Other Soliton Equations
Sine-Gordon Equation
  • Superconductors (Josephson tunneling effect)
  • Relativistic field theories

Nonlinear Schroedinger (NLS) Equation
  • Fiber optic transmission systems
  • Lasers

16
N-Solitons
Zabusky and Kruskal (1965)
  • Partitions of energy modes in crystal lattices
  • Solitary waves pass through each other
  • Coined the term soliton (particle-like behavior)

Two-soliton collision
17
Inverse Scattering
Nonlinear Fourier Transform
Space-time domain
Frequency domain
Fourier Series
http//mathworld.wolfram.com/FourierSeriesSquareWa
ve.html
18
Solving Linear PDEs by Fourier Series
1. Heat equation
2. Separate variables
3. Determine modes
4. Solution
19
Solving Nonlinear PDEs by Inverse Scattering
1. KdV equation
2. Linearize KdV
3. Determine spectrum
(discrete)
4. Solution by inverse scattering
20
2. Linearize KdV
21
Schroedingers Equation (time-independent)
Potential (t0)
Eigenvalue (mode)
Eigenfunction
Scattering Problem
Inverse Scattering Problem
22
3. Determine Spectrum
(a) Solve the scattering problem at t 0 to
obtain reflection-less spectrum
(eigenvalues)
(eigenfunctions)
(normalizing constants)
(b) Use the fact that the KdV equation is
isospectral to obtain spectrum for all t
- Lax pair L, A
23
4. Solution by Inverse Scattering
(a) Solve GLM integral equation (1955)
(b) N-Solitons (GGKM, WT, 1970)
24
Soliton matrix
One-soliton (N1)
Two-solitons (N2)
25
Unique Properties of Solitons
Signature phase-shift due to collision
Infinitely many conservation laws
(conservation of mass)
26
Other Methods of Solution
Hirota bilinear method Backlund
transformations Wronskian technique Zakharov-Sha
bat dressing method
27
Decay of Solitons
Solitons as particles
- Do solitons pass through or bounce off each
other?
Linear collision
Nonlinear collision
  • Each particle decays upon collision
  • Exchange of particle identities
  • Creation of ghost particle pair

28
Applications of Solitons
Optical Communications
- Temporal solitons (optical pulses)
Lasers
  • Spatial solitons (coherent beams of light)
  • BEC solitons (coherent beams of atoms)

29
Hieu Nguyen Temporal solitons involve weak
nonlinearity whereas spatial solitons involve
strong nonlinearity
Optical Phenomena
Refraction
Diffraction
Coherent Light
30
NLS Equation
Nonlinear term
Dispersion/diffraction term
One-solitons
Envelope
Oscillation
31
Temporal Solitons (1980)
Chromatic dispersion
- Pulse broadening effect
Before
After
Self-phase modulation
- Pulse narrowing effect
Before
After
32
Spatial Solitons
Diffraction
- Beam broadening effect

Self-focusing intensive refraction (Kerr effect)
- Beam narrowing effect
33
BEC (1995)
Cold atoms
  • Coherent matter waves
  • Dilute alkali gases

http//cua.mit.edu/ketterle_group/
34
Atom Lasers
Atom beam
Gross-Pitaevskii equation
- Quantum field theory
Atom-atom interaction
External potential
35
Molecular Lasers
Cold molecules
- Bound states between two atoms (Feshbach
resonance)
Molecular laser equations
(atoms)
(molecules)
Joint work with Hong Y. Ling (Rowan University)
36
Many Faces of Solitons
Quantum Field Theory
  • Quantum solitons
  • Monopoles
  • Instantons

General Relativity
  • Bartnik-McKinnon solitons (black holes)

Biochemistry
- Davydov solitons (protein energy transport)
37
Future of Solitons
"Anywhere you find waves you find
solitons." -Randall Hulet, Rice University, on
creating solitons in Bose-Einstein condensates,
Dallas Morning News, May 20, 2002
38
Recreation of the Wave of Translation (1995)
Scott Russell Aqueduct on the Union Canal near
Heriot-Watt University, 12 July 1995
39
References
C. Gardner, J. Greene, M. Kruskal, R. Miura,
Korteweg-de Vries equation and generalizations.
VI. Methods for exact solution, Comm. Pure and
Appl. Math. 27 (1974), pp. 97-133 R. Miura, The
Korteweg-de Vries equation a survey of results,
SIAM Review 18 (1976), No. 3, 412-459. A. Snyder
and F.Ladouceur, Light Guiding Light, Optics and
Photonics News, February, 1999, p. 35 P. D.
Drummond, K. V. Kheruntsyan and H. He, Coherent
Molecular Solitons in Bose-Einstein Condensates,
Physical Review Letters 81 (1998), No. 15,
3055-3058 B. Seaman and H. Y. Ling, Feshbach
Resonance and Coherent Molecular Beam Generation
in a Matter Waveguide, preprint (2003). H. D.
Nguyen, Decay of KdV Solitons, SIAM J. Applied
Math. 63 (2003), No. 3, 874-888. M. Wadati and
M. Toda, The exact N-soliton solution of the
Korteweg-de Vries equation, J. Phys. Soc. Japan
32 (1972), no. 5, 1403-1411. Solitons Home Page
http//www.ma.hw.ac.uk/solitons/ Light Bullet
Home Page http//people.deas.harvard.edu/jones/s
olitons/solitons.html Alkali Gases _at_ Mit Home
page http//cua.mit.edu/ketterle_group/
www.rowan.edu/math/nguyen/soliton/
Write a Comment
User Comments (0)