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Soliton

January 01, 1970

For other uses, see Soliton (disambiguation).

In mathematics and physics, a soliton is a nonlinear, self-reinforcing, localized wave packet that is strongly stable, in that it preserves its shape while propagating freely, at constant velocity, and recovers it even after collisions with other such localized wave packets. Its remarkable stability can be traced to a balanced cancellation of nonlinear and dispersive effects in the medium. (Dispersive effects are a property of certain systems where the speed of a wave depends on its frequency.) Solitons were subsequently found to provide stable solutions of a wide class of weakly nonlinear dispersive partial differential equations describing physical systems.

Solitary wave in a laboratory wave channel

The soliton phenomenon was first described in 1834 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". The term soliton was coined by Zabusky and Kruskal to describe localized, strongly stable propagating solutions to the Korteweg–de Vries equation, which models waves of the type seen by Russell. The name was meant to characterize the solitary nature of the waves, with the 'on' suffix recalling the usage for particles such as electrons, baryons or hadrons, reflecting their observed particle-like behaviour.[1]

Definition edit

A single, consensus definition of a soliton is difficult to find. Drazin & Johnson (1989, p. 15) ascribe three properties to solitons:

  1. They are of permanent form;
  2. They are localized 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).[2]

Explanation edit

 
A hyperbolic secant (sech) envelope soliton for water waves: The blue line is the carrier signal, while the red line is the envelope soliton.

Dispersion and nonlinearity 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 travel at different speeds and the shape of the pulse therefore changes over time. However, also the nonlinear Kerr effect occurs; 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 exactly cancels the dispersion effect and the pulse's shape does not change over time. Thus, the pulse is 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 traveling 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, also called a 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 nontrivial homotopy group, preserved by the differential equations. Thus, the differential equation solutions can be classified into homotopy classes.

No continuous transformation maps 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, the magnetic skyrmion in condensed matter physics, and cosmic strings and domain walls in cosmology.

History edit

 
A plaque marking the workshop of John Scott Russell at 8 Stafford Street in Edinburgh

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.[3]

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. Additionnal observations were reported by Henry Bazin in 1862 after experiments carried out in the canal de Bourgogne in France.[4] Their contemporaries spent some time attempting to extend the theory but it would take until the 1870s before Joseph Boussinesq[5] 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.[6][nb 4]

 
An animation of the overtaking of two solitary waves according to the Benjamin–Bona–Mahony equation – or BBM equation, a model equation for (among others) long surface gravity waves. The wave heights of the solitary waves are 1.2 and 0.6, respectively, and their velocities are 1.4 and 1.2.
The upper graph is for a frame of reference moving with the average velocity of the solitary waves.
The lower graph (with a different vertical scale and in a stationary frame of reference) shows the oscillatory tail produced by the interaction.[7] Thus, the solitary wave solutions of the BBM equation are not solitons.

In 1965 Norman Zabusky of Bell Labs and Martin Kruskal of Princeton University first demonstrated soliton behavior 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, Ulam, and Tsingou.[1]

In 1967, Gardner, Greene, Kruskal and Miura discovered an inverse scattering transform enabling analytical solution of the KdV equation.[8] The work of Peter Lax on Lax pairs and the Lax equation has since extended this to solution of many related soliton-generating systems.

Solitons are, by definition, unaltered in shape and speed by a collision with other solitons.[9] So solitary waves on a water surface are near-solitons, but not exactly – after the interaction of two (colliding or overtaking) solitary waves, they have changed a bit in amplitude and an oscillatory residual is left behind.[10]

Solitons are also studied in quantum mechanics, thanks to the fact that they could provide a new foundation of it through de Broglie's unfinished program, known as "Double solution theory" or "Nonlinear wave mechanics". This theory, developed by de Broglie in 1927 and revived in the 1950s, is the natural continuation of his ideas developed between 1923 and 1926, which extended the wave–particle duality introduced by Albert Einstein for the light quanta, to all the particles of matter. The observation of accelerating surface gravity water wave soliton using an external hydrodynamic linear potential was demonstrated in 2019. This experiment also demonstrated the ability to excite and measure the phases of ballistic solitons.[11]

In fiber optics edit

See also: Soliton (optics)

Much experimentation has been done using solitons in fiber optics applications. Solitons in a fiber optic system are described by the Manakov equations. Solitons' inherent stability make long-distance transmission possible without the use of repeaters, and could potentially double transmission capacity as well.[12]

Year Discovery
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.[13] 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.
1987 Emplit et al. (1987) – from the Universities of Brussels and Limoges – made the first experimental observation of the propagation of a dark soliton, in an optical fiber.
1988 Linn F. 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.
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.
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 dense wavelength-division multiplexing (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.

2000 Steven Cundiff predicted the existence of a vector soliton in a birefringence fiber cavity passively mode locking through a semiconductor saturable absorber mirror (SESAM). The polarization state of such a vector soliton could either be rotating or locked depending on the cavity parameters.[14]
2008 D. Y. Tang et al. observed a novel form of higher-order vector soliton from the perspectives of experiments and numerical simulations. Different types of vector solitons and the polarization state of vector solitons have been investigated by his group.[15]

In biology edit

Solitons may occur in proteins[16] and DNA.[17] Solitons are related to the low-frequency collective motion in proteins and DNA.[18]

A recently developed model in neuroscience proposes that signals, in the form of density waves, are conducted within neurons in the form of solitons.[19][20][21] Solitons can be described as almost lossless energy transfer in biomolecular chains or lattices as wave-like propagations of coupled conformational and electronic disturbances.[22]

In material physics edit

Solitons can occur in materials, such as ferroelectrics, in the form of domain walls. Ferroelectric materials exhibit spontaneous polarization, or electric dipoles, which are coupled to configurations of the material structure. Domains of oppositely poled polarizations can be present within a single material as the structural configurations corresponding to opposing polarizations are equally favorable with no presence of external forces. The domain boundaries, or “walls”, that separate these local structural configurations are regions of lattice dislocations.[23] The domain walls can propagate as the polarizations, and thus, the local structural configurations can switch within a domain with applied forces such as electric bias or mechanical stress. Consequently, the domain walls can be described as solitons, discrete regions of dislocations that are able to slip or propagate and maintain their shape in width and length.[24][25][26]  

In recent literature, ferroelectricity has been observed in twisted bilayers of van der Waal materials such as molybdenum disulfide and graphene.[23][27][28] The moiré superlattice that arises from the relative twist angle between the van der Waal monolayers generates regions of different stacking orders of the atoms within the layers. These regions exhibit inversion symmetry breaking structural configurations that enable ferroelectricity at the interface of these monolayers. The domain walls that separate these regions are composed of partial dislocations where different types of stresses, and thus, strains are experienced by the lattice. It has been observed that soliton or domain wall propagation across a moderate length of the sample (order of nanometers to micrometers) can be initiated with applied stress from an AFM tip on a fixed region. The soliton propagation carries the mechanical perturbation with little loss in energy across the material, which enables domain switching in a domino-like fashion.[25]

It has also been observed that the type of dislocations found at the walls can affect propagation parameters such as direction. For instance, STM measurements showed four types of strains of varying degrees of shear, compression, and tension at domain walls depending on the type of localized stacking order in twisted bilayer graphene. Different slip directions of the walls are achieved with different types of strains found at the domains, influencing the direction of the soliton network propagation.[25]

Nonidealities such as disruptions to the soliton network and surface impurities can influence soliton propagation as well. Domain walls can meet at nodes and get effectively pinned, forming triangular domains, which have been readily observed in various ferroelectric twisted bilayer systems.[23] In addition, closed loops of domain walls enclosing multiple polarization domains can inhibit soliton propagation and thus, switching of polarizations across it.[25] Also, domain walls can propagate and meet at wrinkles and surface inhomogeneities within the van der Waal layers, which can act as obstacles obstructing the propagation.[25]

In magnets edit

In magnets, there also exist different types of solitons and other nonlinear waves.[29] 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 Schrödinger equation and others.

In nuclear physics edit

Atomic nuclei may exhibit solitonic behavior.[30] Here the whole nuclear wave function is predicted to exist as a soliton under certain conditions of temperature and energy. Such conditions are suggested to exist in the cores of some stars in which the nuclei would not react but pass through each other unchanged, retaining their soliton waves through a collision between nuclei.

The Skyrme Model is a model of nuclei in which each nucleus is considered to be a topologically stable soliton solution of a field theory with conserved baryon number.

Bions edit

The bound state of two solitons is known as a bion,[31][32][33][34] or in systems where the bound state periodically oscillates, a breather. The interference-type forces between solitons could be used in making bions.[35] However, these forces are very sensitive to their relative phases. Alternatively, the bound state of solitons could be formed by dressing atoms with highly excited Rydberg levels.[34] The resulting self-generated potential profile[34] features an inner attractive soft-core supporting the 3D self-trapped soliton, an intermediate repulsive shell (barrier) preventing solitons’ fusion, and an outer attractive layer (well) used for completing the bound state resulting in giant stable soliton molecules. In this scheme, the distance and size of the individual solitons in the molecule can be controlled dynamically with the laser adjustment.

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.[36] 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.

Alcubierre drive edit

Erik Lentz, a physicist at the University of Göttingen, has theorized that solitons could allow for the generation of Alcubierre warp bubbles in spacetime without the need for exotic matter, i.e., matter with negative mass.[37]

See also edit

Notes edit

  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 lifetime 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.

References edit

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  38. ^ Powell, Devin (20 May 2011). "Rogue Waves Captured". Science News. Retrieved 24 May 2011.

Further reading edit

  • Zabusky, N. J.; Kruskal, M. D. (1965). "Interaction of 'solitons' in a collisionless plasma and the recurrence of initial states". Phys. Rev. Lett. 15 (6): 240–243. Bibcode:1965PhRvL..15..240Z. doi:10.1103/PhysRevLett.15.240.
  • Hasegawa, A.; Tappert, F. (1973). "Transmission of stationary nonlinear optical pulses in dispersive dielectric fibers. I. Anomalous dispersion". Appl. Phys. Lett. 23 (3): 142–144. Bibcode:1973ApPhL..23..142H. doi:10.1063/1.1654836.
  • Emplit, P.; Hamaide, J. P.; Reynaud, F.; Froehly, C.; Barthelemy, A. (1987). "Picosecond steps and dark pulses through nonlinear single mode fibers". Optics Comm. 62 (6): 374–379. Bibcode:1987OptCo..62..374E. doi:10.1016/0030-4018(87)90003-4.
  • Tao, Terence (2009). "Why are solitons stable?" (PDF). Bull. Am. Math. Soc. 46 (1): 1–33. arXiv:0802.2408. doi:10.1090/s0273-0979-08-01228-7. MR 2457070. S2CID 546859.
  • Drazin, P. G.; Johnson, R. S. (1989). Solitons: an introduction (2nd ed.). Cambridge University Press. ISBN 978-0-521-33655-0.
  • Dunajski, M. (2009). Solitons, Instantons and Twistors. Oxford University Press. ISBN 978-0-19-857063-9.
  • Jaffe, A.; Taubes, C. H. (1980). Vortices and monopoles. Birkhauser. ISBN 978-0-8176-3025-6.
  • Manton, N.; Sutcliffe, P. (2004). Topological solitons. Cambridge University Press. ISBN 978-0-521-83836-8.
  • Mollenauer, Linn F.; Gordon, James P. (2006). Solitons in optical fibers. Elsevier. ISBN 978-0-12-504190-4.
  • Rajaraman, R. (1982). Solitons and instantons. North-Holland. ISBN 978-0-444-86229-7.
  • Yang, Y. (2001). Solitons in field theory and nonlinear analysis. Springer. ISBN 978-0-387-95242-0.

External links edit

 
Wikimedia Commons has media related to Solitons.
 
Look up soliton in Wiktionary, the free dictionary.
 
Wikiquote has quotations related to Soliton.
Related to John Scott Russell
  • John Scott Russell and the solitary wave
  • John Scott Russell biography 2005-04-22 at the Wayback Machine
  • Photograph of soliton on the Scott Russell Aqueduct 2006-07-06 at the Wayback Machine
Other
  • Heriot–Watt University soliton page
  • Short didactic review on optical solitons
  • Filmed collision between two Solitons on YouTube

January 01, 1970
soliton, other, uses, disambiguation, mathematics, physics, soliton, nonlinear, self, reinforcing, localized, wave, packet, that, strongly, stable, that, preserves, shape, while, propagating, freely, constant, velocity, recovers, even, after, collisions, with,. For other uses see Soliton disambiguation In mathematics and physics a soliton is a nonlinear self reinforcing localized wave packet that is strongly stable in that it preserves its shape while propagating freely at constant velocity and recovers it even after collisions with other such localized wave packets Its remarkable stability can be traced to a balanced cancellation of nonlinear and dispersive effects in the medium Dispersive effects are a property of certain systems where the speed of a wave depends on its frequency Solitons were subsequently found to provide stable solutions of a wide class of weakly nonlinear dispersive partial differential equations describing physical systems Solitary wave in a laboratory wave channel The soliton phenomenon was first described in 1834 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 The term soliton was coined by Zabusky and Kruskal to describe localized strongly stable propagating solutions to the Korteweg de Vries equation which models waves of the type seen by Russell The name was meant to characterize the solitary nature of the waves with the on suffix recalling the usage for particles such as electrons baryons or hadrons reflecting their observed particle like behaviour 1 Contents 1 Definition 2 Explanation 3 History 4 In fiber optics 5 In biology 6 In material physics 7 In magnets 8 In nuclear physics 9 Bions 10 Alcubierre drive 11 See also 12 Notes 13 References 14 Further reading 15 External linksDefinition editA single consensus definition of a soliton is difficult to find Drazin amp Johnson 1989 p 15 ascribe three properties to solitons They are of permanent form They are localized within a region 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 2 Explanation edit nbsp A hyperbolic secant sech envelope soliton for water waves The blue line is the carrier signal while the red line is the envelope soliton Dispersion and nonlinearity 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 travel at different speeds and the shape of the pulse therefore changes over time However also the nonlinear Kerr effect occurs 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 exactly cancels the dispersion effect and the pulse s shape does not change over time Thus the pulse is 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 Schrodinger equation the coupled nonlinear Schrodinger 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 traveling 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 also called a 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 nontrivial homotopy group preserved by the differential equations Thus the differential equation solutions can be classified into homotopy classes No continuous transformation maps 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 the magnetic skyrmion in condensed matter physics and cosmic strings and domain walls in cosmology History edit nbsp A plaque marking the workshop of John Scott Russell at 8 Stafford Street in Edinburgh 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 3 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 Additionnal observations were reported by Henry Bazin in 1862 after experiments carried out in the canal de Bourgogne in France 4 Their contemporaries spent some time attempting to extend the theory but it would take until the 1870s before Joseph Boussinesq 5 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 6 nb 4 nbsp An animation of the overtaking of two solitary waves according to the Benjamin Bona Mahony equation or BBM equation a model equation for among others long surface gravity waves The wave heights of the solitary waves are 1 2 and 0 6 respectively and their velocities are 1 4 and 1 2 The upper graph is for a frame of reference moving with the average velocity of the solitary waves The lower graph with a different vertical scale and in a stationary frame of reference shows the oscillatory tail produced by the interaction 7 Thus the solitary wave solutions of the BBM equation are not solitons In 1965 Norman Zabusky of Bell Labs and Martin Kruskal of Princeton University first demonstrated soliton behavior 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 Ulam and Tsingou 1 In 1967 Gardner Greene Kruskal and Miura discovered an inverse scattering transform enabling analytical solution of the KdV equation 8 The work of Peter Lax on Lax pairs and the Lax equation has since extended this to solution of many related soliton generating systems Solitons are by definition unaltered in shape and speed by a collision with other solitons 9 So solitary waves on a water surface are near solitons but not exactly after the interaction of two colliding or overtaking solitary waves they have changed a bit in amplitude and an oscillatory residual is left behind 10 Solitons are also studied in quantum mechanics thanks to the fact that they could provide a new foundation of it through de Broglie s unfinished program known as Double solution theory or Nonlinear wave mechanics This theory developed by de Broglie in 1927 and revived in the 1950s is the natural continuation of his ideas developed between 1923 and 1926 which extended the wave particle duality introduced by Albert Einstein for the light quanta to all the particles of matter The observation of accelerating surface gravity water wave soliton using an external hydrodynamic linear potential was demonstrated in 2019 This experiment also demonstrated the ability to excite and measure the phases of ballistic solitons 11 In fiber optics editSee also Soliton optics Much experimentation has been done using solitons in fiber optics applications Solitons in a fiber optic system are described by the Manakov equations Solitons inherent stability make long distance transmission possible without the use of repeaters and could potentially double transmission capacity as well 12 Year Discovery 1973 Akira Hasegawa of AT amp 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 13 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 1987 Emplit et al 1987 from the Universities of Brussels and Limoges made the first experimental observation of the propagation of a dark soliton in an optical fiber 1988 Linn F 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 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 1998 Thierry Georges and his team at France Telecom R amp 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 dense wavelength division multiplexing 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 2000 Steven Cundiff predicted the existence of a vector soliton in a birefringence fiber cavity passively mode locking through a semiconductor saturable absorber mirror SESAM The polarization state of such a vector soliton could either be rotating or locked depending on the cavity parameters 14 2008 D Y Tang et al observed a novel form of higher order vector soliton from the perspectives of experiments and numerical simulations Different types of vector solitons and the polarization state of vector solitons have been investigated by his group 15 In biology editSolitons may occur in proteins 16 and DNA 17 Solitons are related to the low frequency collective motion in proteins and DNA 18 A recently developed model in neuroscience proposes that signals in the form of density waves are conducted within neurons in the form of solitons 19 20 21 Solitons can be described as almost lossless energy transfer in biomolecular chains or lattices as wave like propagations of coupled conformational and electronic disturbances 22 In material physics editSolitons can occur in materials such as ferroelectrics in the form of domain walls Ferroelectric materials exhibit spontaneous polarization or electric dipoles which are coupled to configurations of the material structure Domains of oppositely poled polarizations can be present within a single material as the structural configurations corresponding to opposing polarizations are equally favorable with no presence of external forces The domain boundaries or walls that separate these local structural configurations are regions of lattice dislocations 23 The domain walls can propagate as the polarizations and thus the local structural configurations can switch within a domain with applied forces such as electric bias or mechanical stress Consequently the domain walls can be described as solitons discrete regions of dislocations that are able to slip or propagate and maintain their shape in width and length 24 25 26 In recent literature ferroelectricity has been observed in twisted bilayers of van der Waal materials such as molybdenum disulfide and graphene 23 27 28 The moire superlattice that arises from the relative twist angle between the van der Waal monolayers generates regions of different stacking orders of the atoms within the layers These regions exhibit inversion symmetry breaking structural configurations that enable ferroelectricity at the interface of these monolayers The domain walls that separate these regions are composed of partial dislocations where different types of stresses and thus strains are experienced by the lattice It has been observed that soliton or domain wall propagation across a moderate length of the sample order of nanometers to micrometers can be initiated with applied stress from an AFM tip on a fixed region The soliton propagation carries the mechanical perturbation with little loss in energy across the material which enables domain switching in a domino like fashion 25 It has also been observed that the type of dislocations found at the walls can affect propagation parameters such as direction For instance STM measurements showed four types of strains of varying degrees of shear compression and tension at domain walls depending on the type of localized stacking order in twisted bilayer graphene Different slip directions of the walls are achieved with different types of strains found at the domains influencing the direction of the soliton network propagation 25 Nonidealities such as disruptions to the soliton network and surface impurities can influence soliton propagation as well Domain walls can meet at nodes and get effectively pinned forming triangular domains which have been readily observed in various ferroelectric twisted bilayer systems 23 In addition closed loops of domain walls enclosing multiple polarization domains can inhibit soliton propagation and thus switching of polarizations across it 25 Also domain walls can propagate and meet at wrinkles and surface inhomogeneities within the van der Waal layers which can act as obstacles obstructing the propagation 25 In magnets editIn magnets there also exist different types of solitons and other nonlinear waves 29 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 others In nuclear physics editAtomic nuclei may exhibit solitonic behavior 30 Here the whole nuclear wave function is predicted to exist as a soliton under certain conditions of temperature and energy Such conditions are suggested to exist in the cores of some stars in which the nuclei would not react but pass through each other unchanged retaining their soliton waves through a collision between nuclei The Skyrme Model is a model of nuclei in which each nucleus is considered to be a topologically stable soliton solution of a field theory with conserved baryon number Bions editThe bound state of two solitons is known as a bion 31 32 33 34 or in systems where the bound state periodically oscillates a breather The interference type forces between solitons could be used in making bions 35 However these forces are very sensitive to their relative phases Alternatively the bound state of solitons could be formed by dressing atoms with highly excited Rydberg levels 34 The resulting self generated potential profile 34 features an inner attractive soft core supporting the 3D self trapped soliton an intermediate repulsive shell barrier preventing solitons fusion and an outer attractive layer well used for completing the bound state resulting in giant stable soliton molecules In this scheme the distance and size of the individual solitons in the molecule can be controlled dynamically with the laser adjustment 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 36 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 Alcubierre drive editErik Lentz a physicist at the University of Gottingen has theorized that solitons could allow for the generation of Alcubierre warp bubbles in spacetime without the need for exotic matter i e matter with negative mass 37 See also editCompacton a soliton with compact support Dissipative soliton Freak waves may be a Peregrine soliton related phenomenon involving breather waves which exhibit concentrated localized energy with non linear properties 38 Instantons Nematicons Non topological soliton in quantum field theory Nonlinear Schrodinger equation Oscillons Pattern formation Peakon a soliton with a non differentiable peak Q ball a non topological soliton Sine Gordon equation Soliton optics Soliton topological Soliton distribution Soliton hypothesis for ball lightning by David Finkelstein Soliton model of nerve impulse propagation Topological quantum number Vector solitonNotes edit 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 This passage has been repeated in many papers and books on soliton theory 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 lifetime of 1808 1882 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 References edit a b Zabusky amp Kruskal 1965 Light bullets Scott Russell J 1845 Report on Waves Made to the Meetings of the British Association in 1842 43 Bazin Henry 1862 Experiences sur les ondes et la propagation des remous Comptes Rendus des Seances de l Academie des Sciences in French 55 353 357 Boussinesq J 1871 Theorie de l intumescence liquide appelee onde solitaire ou de translation se propageant dans un canal rectangulaire C R Acad Sci Paris 72 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 39 240 422 443 doi 10 1080 14786449508620739 Bona J L Pritchard W G Scott L R 1980 Solitary wave interaction Physics of Fluids 23 3 438 441 Bibcode 1980PhFl 23 438B doi 10 1063 1 863011 Gardner Clifford S Greene John M Kruskal Martin D Miura Robert M 1967 Method for Solving the Korteweg deVries Equation Physical Review Letters 19 19 1095 1097 Bibcode 1967PhRvL 19 1095G doi 10 1103 PhysRevLett 19 1095 Remoissenet M 1999 Waves called solitons Concepts and experiments Springer p 11 ISBN 9783540659198 See e g Maxworthy T 1976 Experiments on collisions between solitary waves Journal of Fluid Mechanics 76 1 177 186 Bibcode 1976JFM 76 177M doi 10 1017 S0022112076003194 S2CID 122969046 Fenton J D Rienecker M M 1982 A Fourier method for solving nonlinear water wave problems application to solitary wave interactions Journal of Fluid Mechanics 118 411 443 Bibcode 1982JFM 118 411F doi 10 1017 S0022112082001141 S2CID 120467035 Craig W Guyenne P Hammack J Henderson D Sulem C 2006 Solitary water wave interactions Physics of Fluids 18 57106 057106 057106 25 Bibcode 2006PhFl 18e7106C doi 10 1063 1 2205916 G G Rozenman A Arie L Shemer 2019 Observation of accelerating solitary wavepackets Phys Rev E 101 5 050201 doi 10 1103 PhysRevE 101 050201 PMID 32575227 S2CID 219506298 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Photons advance on two fronts EETimes com October 24 2005 Archived from the original on July 28 2012 Retrieved 2011 02 15 Fred Tappert January 29 1998 Reminiscences on Optical Soliton Research with Akira Hasegawa PDF 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 Bibcode 1999PhRvL 82 3988C doi 10 1103 PhysRevLett 82 3988 hdl 10261 54313 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 arXiv 0903 2392 Bibcode 2008PhRvL 101o3904T doi 10 1103 PhysRevLett 101 153904 PMID 18999601 S2CID 35230072 Davydov Aleksandr S 1991 Solitons in molecular systems Mathematics and its applications Soviet Series Vol 61 2nd ed Kluwer Academic Publishers ISBN 978 0 7923 1029 7 Yakushevich Ludmila V 2004 Nonlinear physics of DNA 2nd revised ed Wiley VCH ISBN 978 3 527 40417 9 Sinkala Z August 2006 Soliton exciton transport in proteins J Theor Biol 241 4 919 27 Bibcode 2006JThBi 241 919S CiteSeerX 10 1 1 44 52 doi 10 1016 j jtbi 2006 01 028 PMID 16516929 Heimburg T Jackson A D 12 July 2005 On soliton propagation in biomembranes and nerves Proc Natl Acad Sci U S A 102 2 9790 5 Bibcode 2005PNAS 102 9790H doi 10 1073 pnas 0503823102 PMC 1175000 PMID 15994235 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Heimburg T Jackson A D 2007 On the action potential as a propagating density pulse and the role of anesthetics Biophys Rev Lett 2 57 78 arXiv physics 0610117 Bibcode 2006physics 10117H doi 10 1142 S179304800700043X S2CID 1295386 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Andersen S S L Jackson A D Heimburg T 2009 Towards a thermodynamic theory of nerve pulse propagation Prog Neurobiol 88 2 104 113 doi 10 1016 j pneurobio 2009 03 002 PMID 19482227 S2CID 2218193 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link dead link Hameroff Stuart 1987 Ultimate Computing Biomolecular Consciousness and Nanotechnology Netherlands Elsevier Science Publishers B V p 18 ISBN 0 444 70283 0 a b c Weston Astrid Castanon Eli G Enaldiev Vladimir Ferreira Fabio Bhattacharjee Shubhadeep Xu Shuigang Corte Leon Hector Wu Zefei Clark Nicholas Summerfield Alex Hashimoto Teruo April 2022 Interfacial ferroelectricity in marginally twisted 2D semiconductors Nature Nanotechnology 17 4 390 395 arXiv 2108 06489 Bibcode 2022NatNa 17 390W doi 10 1038 s41565 022 01072 w ISSN 1748 3395 PMC 9018412 PMID 35210566 Alden Jonathan S Tsen Adam W Huang Pinshane Y Hovden Robert Brown Lola Park Jiwoong Muller David A McEuen Paul L 2013 07 09 Strain solitons and topological defects in bilayer graphene Proceedings of the National Academy of Sciences 110 28 11256 11260 arXiv 1304 7549 Bibcode 2013PNAS 11011256A doi 10 1073 pnas 1309394110 ISSN 0027 8424 PMC 3710814 PMID 23798395 a b c d e Zhang Shuai Xu Qiang Hou Yuan Song Aisheng Ma Yuan Gao Lei Zhu Mengzhen Ma Tianbao Liu Luqi Feng Xi Qiao Li Qunyang 2022 04 21 Domino like stacking order switching in twisted monolayer multilayer graphene Nature Materials 21 6 621 626 Bibcode 2022NatMa 21 621Z doi 10 1038 s41563 022 01232 2 ISSN 1476 4660 PMID 35449221 S2CID 248303403 Jiang Lili Wang Sheng Shi Zhiwen Jin Chenhao Utama M Iqbal Bakti Zhao Sihan Shen Yuen Ron Gao Hong Jun Zhang Guangyu Wang Feng 2018 01 22 Manipulation of domain wall solitons in bi and trilayer graphene Nature Nanotechnology 13 3 204 208 Bibcode 2018NatNa 13 204J doi 10 1038 s41565 017 0042 6 ISSN 1748 3387 PMID 29358639 S2CID 205567456 Nam Nguyen N T Koshino Mikito 2020 03 16 Erratum Lattice relaxation and energy band modulation in twisted bilayer graphene Phys Rev B 96 075311 2017 Physical Review B 101 9 099901 Bibcode 2020PhRvB 101i9901N doi 10 1103 physrevb 101 099901 ISSN 2469 9950 S2CID 216407866 Dai Shuyang Xiang Yang Srolovitz David J 2016 08 22 Twisted Bilayer Graphene Moire with a Twist Nano Letters 16 9 5923 5927 Bibcode 2016NanoL 16 5923D doi 10 1021 acs nanolett 6b02870 ISSN 1530 6984 PMID 27533089 Kosevich A M 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 Bibcode 1998JETP 87 401K doi 10 1134 1 558674 S2CID 121609608 Archived from the original on 2018 05 04 Retrieved 2019 01 18 Iwata Yoritaka Stevenson Paul 2019 Conditional recovery of time reversal symmetry in many nucleus systems New Journal of Physics 21 4 043010 arXiv 1809 10461 Bibcode 2019NJPh 21d3010I doi 10 1088 1367 2630 ab0e58 S2CID 55223766 Belova T I Kudryavtsev A E 1997 Solitons and their interactions in classical field theory Physics Uspekhi 40 4 359 386 Bibcode 1997PhyU 40 359B doi 10 1070 pu1997v040n04abeh000227 S2CID 250768449 Gani V A Kudryavtsev A E Lizunova M A 2014 Kink interactions in the 1 1 dimensional f 6 model Physical Review D 89 12 125009 arXiv 1402 5903 Bibcode 2014PhRvD 89l5009G doi 10 1103 PhysRevD 89 125009 S2CID 119333950 Gani V A Lensky V Lizunova M A 2015 Kink excitation spectra in the 1 1 dimensional f 8 model Journal of High Energy Physics 2015 8 147 arXiv 1506 02313 doi 10 1007 JHEP08 2015 147 ISSN 1029 8479 S2CID 54184500 a b c Khazali Mohammadsadegh 2021 08 05 Rydberg noisy dressing and applications in making soliton molecules and droplet quasicrystals Physical Review Research 3 3 L032033 arXiv 2007 01039 Bibcode 2021PhRvR 3c2033K doi 10 1103 PhysRevResearch 3 L032033 S2CID 220301701 Nguyen Jason H V Dyke Paul Luo De Malomed Boris A Hulet Randall G 2014 11 02 Collisions of matter wave solitons Nature Physics 10 12 918 922 arXiv 1407 5087 Bibcode 2014NatPh 10 918N doi 10 1038 nphys3135 ISSN 1745 2473 S2CID 85461409 Gibbons G W 1998 Born Infeld particles and Dirichlet p branes Nuclear Physics B 514 3 603 639 arXiv hep th 9709027 Bibcode 1998NuPhB 514 603G doi 10 1016 S0550 3213 97 00795 5 S2CID 119331128 Physics World Astronomy and Space Spacecraft in a warp bubble could travel faster than light claims physicist March 19 2021 https physicsworld com a spacecraft in a warp bubble could travel faster than light claims physicist lt accessed on June 29 2021 gt Powell Devin 20 May 2011 Rogue Waves Captured Science News Retrieved 24 May 2011 Further reading editZabusky N J Kruskal M D 1965 Interaction of solitons in a collisionless plasma and the recurrence of initial states Phys Rev Lett 15 6 240 243 Bibcode 1965PhRvL 15 240Z doi 10 1103 PhysRevLett 15 240 Hasegawa A Tappert F 1973 Transmission of stationary nonlinear optical pulses in dispersive dielectric fibers I Anomalous dispersion Appl Phys Lett 23 3 142 144 Bibcode 1973ApPhL 23 142H doi 10 1063 1 1654836 Emplit P Hamaide J P Reynaud F Froehly C Barthelemy A 1987 Picosecond steps and dark pulses through nonlinear single mode fibers Optics Comm 62 6 374 379 Bibcode 1987OptCo 62 374E doi 10 1016 0030 4018 87 90003 4 Tao Terence 2009 Why are solitons stable PDF Bull Am Math Soc 46 1 1 33 arXiv 0802 2408 doi 10 1090 s0273 0979 08 01228 7 MR 2457070 S2CID 546859 Drazin P G Johnson R S 1989 Solitons an introduction 2nd ed Cambridge University Press ISBN 978 0 521 33655 0 Dunajski M 2009 Solitons Instantons and Twistors Oxford University Press ISBN 978 0 19 857063 9 Jaffe A Taubes C H 1980 Vortices and monopoles Birkhauser ISBN 978 0 8176 3025 6 Manton N Sutcliffe P 2004 Topological solitons Cambridge University Press ISBN 978 0 521 83836 8 Mollenauer Linn F Gordon James P 2006 Solitons in optical fibers Elsevier ISBN 978 0 12 504190 4 Rajaraman R 1982 Solitons and instantons North Holland ISBN 978 0 444 86229 7 Yang Y 2001 Solitons in field theory and nonlinear analysis Springer ISBN 978 0 387 95242 0 External links edit nbsp Wikimedia Commons has media related to Solitons nbsp Look up soliton in Wiktionary the free dictionary nbsp Wikiquote has quotations related to Soliton Related to John Scott Russell John Scott Russell and the solitary wave John Scott Russell biography Archived 2005 04 22 at the Wayback Machine Photograph of soliton on the Scott Russell Aqueduct Archived 2006 07 06 at the Wayback Machine Other Heriot Watt University soliton page Helmholtz solitons Salford University Short didactic review on optical solitons Filmed collision between two Solitons on YouTube Retrieved from https en wikipedia org w index php title Soliton amp oldid 1220984877, wikipedia, wiki, book, books, library,

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