Rogue wave

This article is about the deep ocean rogue waves which occur far out at sea. For tsunami and tidal wave phenomena, see those respective articles. For other uses, see Rogue wave (disambiguation).
The Draupner wave, a single giant wave measured on New Year's Day 1995, finally confirmed the existence of freak waves, which had previously been considered near-mythical.

Rogue waves (also known as freak waves, monster waves, killer waves, extreme waves, and abnormal waves) are relatively large and spontaneous ocean surface waves that occur far out at sea, and are a threat even to large ships and ocean liners.[1]

In oceanography, they are more precisely defined as waves whose height is more than twice the significant wave height (Hs or SWH), which is itself defined as the mean of the largest third of waves in a wave record. Therefore rogue waves are not necessarily the biggest waves found at sea; they are, rather, unusually large waves for a given sea state. Rogue waves seem not to have a single distinct cause, but occur where physical factors such as high winds and strong currents cause waves to merge to create a single exceptionally large wave.[1]

Background

Rogue waves, sometimes known as freak waves, are an ocean phenomenon, in which winds, currents, non-linear phenomena such as solitons, and other circumstances cause a wave to briefly form that is far larger than the "average" large occurring wave (the significant wave height or 'SWH') of that time and place. The basic underlying physics that makes phenomena such as rogue waves possible is that different gravity waves can travel at different speeds, and so they can pile up at random. In deep ocean the speed of a gravity wave is proportional to the square root of its wavelength--the distance peak-to-peak.

Once considered mythical and lacking hard evidence for their existence, rogue waves are now proven to exist and known to be a natural ocean phenomenon. Eyewitness accounts from mariners and damages inflicted on ships have long suggested they occurred; however, their scientific measurement was only positively confirmed following measurements of the "Draupner wave", a rogue wave at the Draupner platform, in the North Sea on January 1, 1995. During that event, minor damage was also inflicted on the platform, far above sea level, confirming that the reading was valid. Their existence has also since been confirmed by satellite imagery of the ocean surface.[2]

A rogue wave is distinct from a tsunami.[1] Tsunamis are caused by massive displacement of water, and often result from sudden movement of the ocean floor, which then propagate at high speed over a wide area. They are more or less unnoticeable in deep water and only become dangerous as they approach the shoreline and the ocean floor becomes shallower; therefore tsunamis do not present a threat to shipping at sea (the only ships lost in the 2004 Asian tsunami were in port). They are also distinct from mega-tsunamis, which are single massive waves caused by landslides within enclosed or limited bodies of water. A rogue wave, on the other hand, is an ocean phenomenon that is not caused by land movement, only lasts briefly, occurs in a limited location, and most often happens far out at sea.[1] Rogue waves are considered rare but potentially very dangerous, since they can involve the spontaneous formation of massive waves far beyond the usual expectations of ship designers, and can overwhelm the usual capabilities of ocean-going vessels which are not designed for such encounters.

In February 2000, a British oceanographic research vessel, the RRS Discovery, sailing in the Rockall Trough west of Scotland encountered the largest waves ever recorded by scientific instruments in the open ocean, with a SWH of 18.5 metres (61 ft) and individual waves up to 29.1 metres (95 ft).[3] "In 2004 scientists using three weeks of radar images from European Space Agency satellites found ten rogue waves, each 25 metres (82 ft) or higher."[4]

Rogue waves have been cited in the media as a likely cause of the sudden, inexplicable disappearance of many ocean-going vessels. One of the very few cases in which evidence exists that may indicate a rogue wave incident is the case of the freighter MS München, lost in 1978.

Rogue waves should not be confused with the so-called "hundred-year wave", which is a statistical prediction of the highest wave likely to occur in a hundred-year period in a particular body of water.

History of rogue wave knowledge

Merchant ship labouring in heavy seas as a huge wave looms ahead. Huge waves are common near the 100-fathom line in the Bay of Biscay.

It is common for mid-ocean storm waves to reach 7 metres (23 ft) in height, and in extreme conditions such waves can reach heights of 15 metres (49 ft). However, for centuries maritime folklore told of the existence of much larger waves — up to 30 metres (98 ft) in height (approximately the height of a 10-story building) — that could appear without warning in mid-ocean, against the prevailing current and wave direction, and often in perfectly clear weather. Such waves were said to consist of an almost vertical wall of water preceded by a trough so deep that it was referred to as a "hole in the sea"; a ship encountering a wave of such magnitude would be unlikely to survive the tremendous pressures exerted by the weight of the breaking water, and would almost certainly be sunk in a matter of seconds or minutes.

Some research confirms that observed wave height distribution in general follows well the Rayleigh distribution, but in shallow waters during high energy events, extremely high waves are more rare than this particular model predicts.[4]

Rogue waves seem to occur in all of the world's oceans many times every year. This has caused reconsideration of the ocean-going ship design.

Rogue waves may also occur in lakes. A phenomenon known as the "Three Sisters" is said to occur in Lake Superior when a series of three large waves forms. The second wave hits the ship's deck before the first wave clears. The third incoming wave adds to the two accumulated backwashes and suddenly overloads the ship deck with tons of water. The phenomenon was implicated in the sinking of the SS Edmund Fitzgerald on Lake Superior in November 1975.[5]

Occurrence

In the course of Project MaxWave, researchers from the GKSS Research Centre, using data collected by ESA satellites, identified a large number of radar signatures that have been portrayed as evidence for rogue waves. Further research is under way to develop better methods of translating the radar echoes into sea surface elevation, but at present this technique is not proven.[6][7]

Causes

Experimental demonstration of rogue wave generation through nonlinear processes (on a small scale) in a wave tank.
Experimental demonstration of rogue wave generation through nonlinear processes (on a small scale) in a wave tank.
The linear part solution of the Nonlinear Schrodinger Equation describing the evolution of a complex wave envelop in deep water.

Because the phenomenon of rogue waves is still a matter of active research, it is premature to state clearly what the most common causes are or whether they vary from place to place. The areas of highest predictable risk appear to be where a strong current runs counter to the primary direction of travel of the waves; the area near Cape Agulhas off the southern tip of Africa is one such area; the warm Agulhas current runs to the southwest, while the dominant winds are westerlies. However, since this thesis does not explain the existence of all waves that have been detected, several different mechanisms are likely, with localised variation. Suggested mechanisms for freak waves include the following:

Diffractive focusing 
According to this hypothesis, coast shape or seabed shape directs several small waves to meet in phase. Their crest heights combine to create a freak wave.[8]
Focusing by currents 
Waves from one current are driven into an opposing current. This results in shortening of wavelength, causing shoaling (i.e., increase in wave height), and oncoming wave trains to compress together into a rogue wave.[8] This happens off the South African coast, where the Agulhas current is countered by westerlies.
Nonlinear effects (modulational instability) 
It seems possible to have a rogue wave occur by natural, nonlinear processes from a random background of smaller waves.[9] In such a case, it is hypothesised, an unusual, unstable wave type may form which 'sucks' energy from other waves, growing to a near-vertical monster itself, before becoming too unstable and collapsing shortly after. One simple model for this is a wave equation known as the nonlinear Schrödinger equation (NLS), in which a normal and perfectly accountable (by the standard linear model) wave begins to 'soak' energy from the waves immediately fore and aft, reducing them to minor ripples compared to other waves. The NLS can be used in deep water conditions. In shallow water, waves are described by the Korteweg–de Vries equation or the Boussinesq equation. These equations also have non-linear contributions and show solitary-wave solutions. A small-scale rogue wave consistent with the nonlinear Schrödinger equation was produced in a laboratory water tank in 2011.[10] In particular, the study of solitons, and especially Peregrine solitons, have supported the idea that non-linear effects could arise in bodies of water.
Normal part of the wave spectrum 
Rogue waves are not freaks at all but are part of normal wave generation process, albeit a rare extremity.[8]
Wind waves 
While it is unlikely that wind alone can generate a rogue wave, its effect combined with other mechanisms may provide a fuller explanation of freak wave phenomena. As wind blows over the ocean, energy is transferred to the sea surface. When strong winds from a storm happen to blow in the opposing direction of the ocean current the forces might be strong enough to randomly generate rogue waves. Theories of instability mechanisms for the generation and growth of wind waves—although not on the causes of rogue waves—are provided by Phillips[11] and Miles.[12]
Thermal expansion 
When a stable wave group in a warm water column moves into a cold water column the size of the waves must change because energy must be conserved in the system. So each wave in the wave group become smaller because cold water holds more wave energy based on density. The waves are now spaced further apart and because of gravity they will propagate into more waves to fill up the space and become a stable wave group. If a stable wave group exists in cold water and moves into a warm water column the waves will get larger and the wavelength will be shorter. The waves will seek equilibrium by attempting to displace the waves amplitude because of gravity. However by starting with a stable wave group the wave energy can displace towards the center of the group. If both the front and back of the wave group are displacing energy towards the center it can become a rogue wave. This would happen only if the wave group is very large.

The spatio-temporal focusing seen in the NLS equation can also occur when the nonlinearity is removed. In this case, focusing is primarily due to different waves coming into phase, rather than any energy transfer processes. Further analysis of rogue waves using a fully nonlinear model by R.H. Gibbs (2005) brings this mode into question, as it is shown that a typical wavegroup focuses in such a way as to produce a significant wall of water, at the cost of a reduced height.

A rogue wave, and the deep trough commonly seen before and after it, may last only for some minutes before either breaking, or reducing in size again. Apart from one single rogue wave, the rogue wave may be part of a wave packet consisting of a few rogue waves. Such rogue wave groups have been observed in nature.[13]

There are three categories of freak waves:

A research group at the Umeå University, Sweden in August 2006 showed that normal stochastic wind driven waves can suddenly give rise to monster waves. The nonlinear evolution of the instabilities was investigated by means of direct simulations of the time-dependent system of nonlinear equations.[16]

Scientific applications

The possibility of the artificial stimulation of rogue wave phenomena has attracted research funding from DARPA, an agency of the United States Department of Defense. Bahram Jalali and other researchers at UCLA studied microstructured optical fibers near the threshold of soliton supercontinuum generation and observed rogue wave phenomena. After modelling the effect, the researchers announced that they had successfully characterized the proper initial conditions for generating rogue waves in any medium.[17] Additional works carried out in optics have pointed out the role played by a nonlinear structure called Peregrine soliton that may explain those waves that appear and disappear without leaving a trace.[18][19]

Reported encounters

Main article: List of rogue waves

It should be noted that many of these encounters are only reported in the media, and are not examples of open ocean rogue waves. Often, in popular culture, an endangering huge wave is loosely denoted as a rogue wave, while it has not been (and most often cannot be) established that the reported event is a rogue wave in the scientific sense — i.e. of a very different nature in characteristics as the surrounding waves in that sea state and with very low probability of occurrence (according to a Gaussian process description as valid for linear wave theory).

This section lists a limited selection of notable incidents.

19th century

20th century

21st century

See also

Oceanography, currents and regions
Waves

References

  1. 1.0 1.1 1.2 1.3 1.4 "Monsters of the deep -- Huge, freak waves may not be as rare as once thought". Economist Magazine. September 17, 2009. Retrieved 2009-10-04.
  2. "Freak waves spotted from space". BBC News. July 22, 2004. Retrieved May 22, 2010.
  3. Holliday, NP, MJ Yelland, RW Pascal, VR Swail, PK Taylor, CR Griffiths, and EC Kent (2006). Were extreme waves in the Rockall Trough the largest ever recorded? Geophysical Research Letters, Vol. 33, L05613
  4. 4.0 4.1 Laird, Anne Marie (December 2006). "Observed Statistics of Extreme Waves". Doctoral dissertation, Monterey, California Naval Postgraduate School: 2.
  5. 5.0 5.1 Wolff, Julius F. (1979). "Lake Superior Shipwrecks", p. 28. Lake Superior Marine Museum Association, Inc., Duluth, Minnesota, USA. ISBN 0-932212-18-8.
  6. "Critical review on potential use of satellite date to find rogue waves" (PDF). European Space Agency SEASAR 2006 proceedings. April 2006. Retrieved February 23, 2008.
  7. "Freak waves spotted from space". BBC News Online. 22 July 2004. Retrieved May 8, 2006.
  8. 8.0 8.1 8.2 "Rogue Waves". Ocean Prediction Center. National Weather Service. April 22, 2005. Retrieved May 8, 2006.
  9. 9.0 9.1 Freak Wave, BBC.co.uk programme summary for Horizon episode aired on 14 November 2002
  10. Adrian Cho (13 May 2011). "Ship in Bottle, Meet Rogue Wave in Tub". Science Now 332: 774. Retrieved 2011-06-27.
  11. Phillips 1957, Journal of Fluid Mechanics
  12. Miles, 1957, Journal of Fluid Mechanics
  13. Frederic-Moreau. The Glorious Three, translated by M. Olagnon and G.A. Chase / Rogue Waves-2004, Brest, France
  14. Endeavour or Caledonian Star report, March 2, 2001, 53°03′S 63°35′W / 53.050°S 63.583°W
  15. MS Bremen report, February 22, 2001, 45°54′S 38°58′W / 45.900°S 38.967°W
  16. P. K. Shukla, I. Kourakis, B. Eliasson, M. Marklund and L. Stenflo: "Instability and Evolution of Nonlinearly Interacting Water Waves" nlin.CD/0608012, Physical Review Letters (2006)
  17. R. Colin Johnson (December 24, 2007). "EEs Working With Optical Fibers Demystify 'Rogue Wave' Phenomenon". Electronic Engineering Times (1507): 14, 16.
  18. Kibler, B.; Fatome, J.; Finot, C.; Millot, G.; Dias, F.; Genty, G.; Akhmediev, N.; Dudley, J.M. (2010). "The Peregrine soliton in nonlinear fibre optics". Nature Physics 6 (10). Bibcode:2010NatPh...6..790K. doi:10.1038/nphys1740.
  19. "Peregrine's 'Soliton' observed at last". bris.ac.uk. Retrieved 2010-08-24.
  20. "Eagle Island Lighthouse". Commissioners of Irish Lights. Retrieved 28 October 2010.
  21. Haswell-Smith, Hamish (2004). The Scottish Islands. Edinburgh: Canongate. pp. 32931. ISBN 978-1-84195-454-7.
  22. Munro, R.W. (1979) Scottish Lighthouses. Stornoway. Thule Press. ISBN 0-906191-32-7. Munro (1979) pages 170-1
  23. The New York Times, September 26, 1901, p. 16
  24. , Müller, et al., "Rogue Waves," 2005
  25. 25.0 25.1 Rogue Giants at Sea, Broad, William J, New York Times, July 11, 2006
  26. "Ship-sinking monster waves revealed by ESA satellites", ESA News, July 21, 2004, accessed June 18, 2010
  27. "The Story of the Fastnet - The Economist Magazine December 18th 2008"
  28. Douglas Faulkner, "An Analytical Assessment of the Sinking of the M.V. Derbyshire," RINA Transactions 2001, Royal Institution of Naval Architects.
  29. http://www.esa.int/esaCP/SEMOKQL26WD_index_0.html
  30. 30.0 30.1 Freak waves PDF (1.07 MiB), Beacon #185, Skuld, June 2005
  31. Hurricane Ivan prompts rogue wave rethink, The Register, 5 August 2005
  32. Reuters (April 18, 2005). Freak wave pummels cruise ship.
  33. "NTSB – Brief MAB-05/03". Archived from the original on 2009-03-08. Retrieved 2009-03-08.
  34. Deadliest Catch Season 2, Episode 4 "Finish Line" Original airdate: April 28, 2006; approx time into episode: 0:40:00–0:42:00. Edited footage viewable online at Discovery.com
  35. Monster waves threaten rescue helicopters PDF (35.7 KiB), U.S. Naval Institute, December 15, 2006
  36. "Dos muertos y 16 heridos por una ola gigante en un crucero con destino a Cartagena". La Vanguardia. 3 March 2010.
  37. "Giant rogue wave slams into ship off French coast, killing 2". FoxNews. 3 March 2010.
  38. Jivanda, Tomas (15 February 2014). "UK weather: Man killed after huge wave breaks window of cruise ship Marco Polo in English Channel as storms set to continue". The Independent. Retrieved 17 February 2014.

External links

MaxWave report and WaveAtlas

Wikimedia Commons has media related to Rogue waves.

Other

Further reading