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Soliton


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Solitary wave  in a laboratory wave
channel.

In mathematics and physics , a *soliton* is a self-reinforcing solitary
wave (a wave packet or pulse) that maintains its shape while it travels at
constant speed. Solitons are caused by a cancellation of nonlinear and
dispersive effects in the medium. (The term "dispersive effects" refers to
a property of certain systems where the speed of the waves varies
according to frequency.) Solitons arise as the solutions of a widespread
class of weakly nonlinear dispersive partial differential equations
describing physical systems. The soliton phenomenon was first described by
John Scott Russell (1808–1882) who observed a solitary wave in the Union
Canal in Scotland. He reproduced the phenomenon in a wave tank and named
it the "Wave of Translation ".


Contents

[hide ]

* 1 Definition 
* 2 Explanation 
* 3 History 
* 4 Solitons in fiber optics 
* 5 Solitons in proteins and DNA 
* 6 Solitons in magnets 
* 7 Bions 
* 8 See also 
* 9 Notes 
* 10 References 
o 10.1 Inline 
o 10.2 General 
* 11 External links 


[edit ] Definition

A single, consensus definition of a soliton is difficult to find. Drazin
and Johnson (1989) ascribe 3 properties to solitons:^[1] 

1. They are of permanent form;
2. They are localised within a region;
3. They can interact with other solitons, and emerge from the
collision unchanged, except for a phase shift .

More formal definitions exist, but they require substantial mathematics.
Moreover, some scientists use the term /soliton/ for phenomena that do not
quite have these three properties (for instance, the 'light bullets ' of
nonlinear optics are often called solitons despite losing energy during
interaction).


[edit ] Explanation



A sech envelope soliton for water waves. The blue line is the carrier
waves , while the red line is the envelope soliton.

Dispersion and non-linearity can interact to produce permanent and
localized wave forms. Consider a pulse of light traveling in glass. This
pulse can be thought of as consisting of light of several different
frequencies. Since glass shows dispersion, these different frequencies
will travel at different speeds and the shape of the pulse will therefore
change over time. However, there is also the non-linear Kerr effect : the
refractive index of a material at a given frequency depends on the light's
amplitude or strength. If the pulse has just the right shape, the Kerr
effect will exactly cancel the dispersion effect, and the pulse's shape
won't change over time: a soliton. See soliton (optics)  for a more
detailed description.

Many exactly solvable models have soliton solutions, including the
Korteweg–de Vries equation , the nonlinear Schrödinger equation , the
coupled nonlinear Schrödinger equation, and the sine-Gordon equation .
The soliton solutions are typically obtained by means of the inverse
scattering transform and owe their stability to the integrability of the
field equations. The mathematical theory of these equations is a broad and
very active field of mathematical research.

Some types of tidal bore , a wave phenomenon of a few rivers including the
River Severn , are 'undular': a wavefront followed by a train of solitons.
Other solitons occur as the undersea internal waves , initiated by seabed
topography , that propagate on the oceanic pycnocline . Atmospheric
solitons also exist, such as the Morning Glory Cloud of the Gulf of
Carpentaria , where pressure solitons travelling in a temperature
inversion layer produce vast linear roll clouds . The recent and not
widely accepted soliton model in neuroscience proposes to explain the
signal conduction within neurons as pressure solitons.

A topological soliton , or topological defect , is any solution of a set
of partial differential equations that is stable against decay to the
"trivial solution." Soliton stability is due to topological constraints,
rather than integrability of the field equations. The constraints arise
almost always because the differential equations must obey a set of
boundary conditions , and the boundary has a non-trivial homotopy group ,
preserved by the differential equations. Thus, the differential equation
solutions can be classified into homotopy classes . There is no continuous
transformation that will map a solution in one homotopy class to another.
The solutions are truly distinct, and maintain their integrity, even in
the face of extremely powerful forces. Examples of topological solitons
include the screw dislocation in a crystalline lattice , the Dirac string
and the magnetic monopole in electromagnetism , the Skyrmion and the
Wess-Zumino-Witten model in quantum field theory , and cosmic strings and
domain walls in cosmology .


[edit ] History

In 1834, John Scott Russell describes his /wave of translation /.^[nb 1]
The discovery is described here in Scott Russell's own words:^[nb 2]


/"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. 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"/.^[2]

Scott Russell spent some time making practical and theoretical
investigations of these waves. He built wave tanks at his home and noticed
some key properties:

* The waves are stable, and can travel over very large distances (normal
waves would tend to either flatten out, or steepen and topple over) * The
speed depends on the size of the wave, and its width on the depth of
water. * Unlike normal waves they will never merge – so a small wave is
overtaken by a large one, rather than the two combining. * If a wave is
too big for the depth of water, it splits into two, one big and one small.

Scott Russell's experimental work seemed at odds with Isaac Newton 's and
Daniel Bernoulli 's theories of hydrodynamics . George Biddell Airy and
George Gabriel Stokes had difficulty accepting Scott Russell's
experimental observations because they could not be explained by the
existing water wave theories. Their contemporaries spent some time
attempting to extend the theory but it would take until the 1870s before
Joseph Boussinesq and Lord Rayleigh published a theoretical treatment and
solutions.^[nb 3] In 1895 Diederik Korteweg and Gustav de Vries provided
what is now known as the Korteweg–de Vries equation , including solitary
wave and periodic cnoidal wave solutions.^[3] ^[nb 4]

In 1965 Norman Zabusky of Bell Labs and Martin Kruskal of Princeton
University first demonstrated soliton behaviour in media subject to the
Korteweg–de Vries equation (KdV equation) in a computational
investigation using a finite difference approach. They also showed how
this behavior explained the puzzling earlier work of Fermi, Pasta and Ulam
.

In 1967, Gardner, Greene, Kruskal and Miura discovered an inverse
scattering transform enabling analytical solution of the KdV equation. The
work of Peter Lax on Lax pairs and the Lax equation has since extended
this to solution of many related soliton-generating systems.


[edit ] Solitons in fiber optics

/See also Soliton (optics) /

	*Lists of miscellaneous information should be avoided.* Please
relocate

any relevant information into appropriate sections or articles. /(August
2009)/

Much experimentation has been done using solitons in fiber optics
applications. Solitons' inherent stability make long-distance transmission
possible without the use of repeaters , and could potentially double
transmission capacity as well.^[4]

In 1973, Akira Hasegawa of AT&T Bell Labs was the first to suggest that
solitons could exist in optical fibers , due to a balance between
self-phase modulation and anomalous dispersion . Also in 1973 Robin
Bullough made the first mathematical report of the existence of optical
solitons. He also proposed the idea of a soliton-based transmission system
to increase performance of optical telecommunications .

Solitons in a fiber optic system are described by the Manakov equations .

In 1987, P. Emplit, J.P. Hamaide, F. Reynaud, C. Froehly and A.
Barthelemy, from the Universities of Brussels and Limoges, made the first
experimental observation of the propagation of a dark soliton , in an
optical fiber.

In 1988, Linn Mollenauer and his team transmitted soliton pulses over
4,000 kilometers using a phenomenon called the Raman effect , named after
Sir C. V. Raman who first described it in the 1920s, to provide optical
gain in the fiber.

In 1991, a Bell Labs research team transmitted solitons error-free at 2.5
gigabits per second over more than 14,000 kilometers, using erbium optical
fiber amplifiers (spliced-in segments of optical fiber containing the rare
earth element erbium). Pump lasers, coupled to the optical amplifiers,
activate the erbium, which energizes the light pulses.

In 1998, Thierry Georges and his team at France Telecom R&D Center,
combining optical solitons of different wavelengths (wavelength division
multiplexing ), demonstrated a /composite/ data transmission of 1 terabit
per second (1,000,000,000,000 units of information per second), not to be
confused with Terabit-Ethernet.

The above impressive experiments have not translated to actual commercial
soliton system deployments however, in either terrestrial or submarine
systems, chiefly due to the Gordon-Haus (GH) jitter. The GH jitter
requires sophisticated, expensive compensatory solutions that ultimately
makes DWDM soliton transmission in the field unattractive, compared to the
conventional non-return-to-zero/return-to-zero paradigm. Further, the
likely future adoption of the more spectrally efficient
phase-shift-keyed/QAM formats makes soliton transmission even less viable,
due to the Gordon-Mollenauer effect. Consequently, the long-haul
fiberoptic transmission soliton has remained a laboratory curiosity.

In 2000, Cundiff predicted the existence of a vector soliton in a
birefringence fiber cavity passively mode locking through SESAM . The
polarization state of such a vector soliton could either be rotating or
locked depending on the cavity parameters.^[5]

In 2008, D.Y.Tang /et al./ observed a novel form of higher-order vector
soliton from the perspect of experiments and numerical simulations.
Different types of vector solitons and the polarization state of vector
solitons have been investigated by his group.^[6]


[edit ] Solitons in proteins and DNA

Solitons may occur in proteins ^[7] and DNA.^[8] Solitons are related to
the low-frequency collective motion in proteins and DNA .^[9]



[edit ] Solitons in magnets

In magnets, there also exist different types of solitons and other
nonlinear waves.^[10] These magnetic solitons are an exact solution of
classical nonlinear differential equations — magnetic equations, e.g.
the Landau-Lifshitz equation , continuum Heisenberg model , Ishimori
equation , nonlinear Schrodinger equation and so on.


[edit ] Bions

Wiki letter w.svg This section requires expansion .

The bound state of two solitons is known as a /bion/.

In field theory Bion usually refers to the solution of the Born–Infeld
model . The name appears to have been coined by G.W. Gibbons in order to
distinguish this solution from the conventional soliton, understood as a
/regular/, finite-energy (and usually stable) solution of a differential
equation describing some physical system.^[11] The word /regular/ means a
smooth solution carrying no sources at all. However, the solution of the
Born-Infeld model still carries a source in the form of a Dirac-delta
function at the origin. As a consequence it displays a singularity in this
point (although the electric field is everywhere regular). In some
physical contexts (for instance string theory) this feature can be
important, which motivated the introduction of a special name for this
class of solitons.

On the other hand, when gravity is added (i.e. when considering the
coupling of the Born–Infeld model to General Relativity) the
corresponding solution is called /EBIon/, where "E" stands for "Einstein".


[edit ] See also

* compacton , a soliton with compact support * freak waves may be a
related phenomenon. * oscillons * peakon , a soliton with a
non-differentiable peak * soliton (topological)  * non-topological soliton
,in Quantum Field Theory * Q-ball a non-topological soliton * soliton
(optics)  * soliton model of nerve impulse propagation * topological
quantum number * sine-Gordon equation * nonlinear Schrödinger equation

* vector soliton * soliton distribution


[edit ] Notes

1. *^ * "Translation" here means that there is real mass
transport, although it is not the same water which is transported
from one end of the canal to the other end by this "Wave of
Translation". Rather, a fluid parcel  acquires
momentum  during the passage of the solitary wave,
and comes to rest again after the passage of the wave. But the
fluid parcel has been displaced substantially forward during the
process – by Stokes drift  in the wave
propagation direction. And a net mass transport is the result.
Usually there is little mass transport from one side to another
side for ordinary waves.
2. *^ * This passage has been repeated in many papers
and books on soliton theory.
3. *^ * Lord Rayleigh  published a
paper in Philosophical Magazine in 1876 to support John Scott
Russell's experimental observation with his mathematical theory.
In his 1876 paper, Lord Rayleigh mentioned Scott Russell's name
and also admitted that the first theoretical treatment was by
Joseph Valentin Boussinesq in 1871. Joseph Boussinesq
mentioned Russell's name in his 1871
paper. Thus Scott Russell's observations on solitons were accepted
as true by some prominent scientists within his own life time of
1808–1882.
4. *^ * Korteweg and de Vries did not mention John Scott
Russell's name at all in their 1895 paper but they did quote
Boussinesq's paper of 1871 and Lord Rayleigh's paper of 1876. The
paper by Korteweg and de Vries in 1895 was not the first
theoretical treatment of this subject but it was a very important
milestone in the history of the development of soliton theory.


[edit ] References


[edit ] Inline

1. *^ * Drazin & Johnson (1989) p. 15.
2. *^ * J. Scott Russell. Report on waves, /Fourteenth
meeting of the British Association for the Advancement of
Science/, 1844.
3. *^ * Korteweg, D.J. ; de
Vries, G.  (1895), "On the Change of Form
of Long Waves advancing in a Rectangular Canal and on a New Type
of Long Stationary Waves", /Philosophical Magazine
/ *39*: 422–443 
4. *^ * "Photons advance on two fronts
",
/EETimes.com/, October 24, 2005.
5. *^ * Cundiff, S.T.; Collings, B.C.; Akhmediev, N.N.;
Soto-Crespo, J.M.; Bergman, K.; Knox, W.H. (1999), "Observation of
Polarization-Locked Vector Solitons in an Optical Fiber",
/Physical Review Letters/ *82* (20): 3988, doi
:10.1103/PhysRevLett.82.3988

6. *^ * Tang, D.Y.; Zhang, H.; Zhao, L.M.; Wu, X.
(2008), "Observation of high-order polarization-locked vector
solitons in a fiber laser", /Physical Review Letters/ *101* (15):
153904, doi
:10.1103/PhysRevLett.101.153904

7. *^ * Chou KC, Zhang CT, Maggiora GM
(January 1994). "Solitary wave dynamics as a mechanism for
explaining the internal motion during microtubule growth".
/Biopolymers/ *34* (1): 143–53. doi
:10.1002/bip.360340114
. PMID
8110966
. 
8. *^ * Guo-Ping Zhou (1989). "Biological
functions of soliton and extra electron motion in DNA structure".
/Physica Scripta/ *40*: 698. doi
:10.1088/0031-8949/40/5/021
. 
9. *^ * Sinkala Z (August 2006).
"Soliton/exciton transport in proteins". /J. Theor. Biol./ *241*
(4): 919–27. doi
:10.1016/j.jtbi.2006.01.028
. PMID
16516929
. 
10. *^ * A.M., Kosevich; Gann, V.V.; Zhukov, A.I.;
Voronov, V.P. (1998), "Magnetic soliton motion in a nonuniform
magnetic field", /Journal of Experimental and Theoretical Physics/
*87* (2): 401–407, doi
:10.1134/1.558674

11. *^ * Gibbons, G.W. (1998), /Born-Infeld particles
and Dirichlet/ p/-branes/, *514*, pp. 603–639, doi
:10.1016/S0550-3213(97)00795-5



[edit ] General

* N. J. Zabusky and M. D. Kruskal (1965). /Interaction of 'Solitons'
in a Collisionless Plasma and the Recurrence of Initial States./
Phys Rev Lett 15, 240
* A. Hasegawa and F. Tappert (1973). /Transmission of stationary
nonlinear optical pulses in dispersive dielectric fibers. I.
Anomalous dispersion./ Appl. Phys. Lett. Volume 23, Issue 3,
pp. 142–144.
* P. Emplit, J.P. Hamaide, F. Reynaud, C. Froehly and A. Barthelemy
(1987) /Picosecond steps and dark pulses through nonlinear single
mode fibers./ Optics. Comm. 62, 374
* P. G. Drazin and R. S. Johnson (1989). /Solitons: an
introduction./ Cambridge University Press, 2nd ed., ISBN
0521336554 
* A. Jaffe and C. H. Taubes (1980). /Vortices and monopoles./
Birkhauser.
* N. Manton and P. Sutcliffe (2004). /Topological solitons./
Cambridge University Press.
* Linn F. Mollenauer and James P. Gordon (2006). /Solitons in
optical fibers./ Elsevier Academic Press.
* R. Rajaraman (1982). /Solitons and instantons./ North-Holland.
* Y. Yang (2001). /Solitons in field theory and nonlinear analysis./
Springer-Verlag.