Science Fair Project Encyclopedia
- For the recent disaster in the Indian Ocean region, see 2004 Indian Ocean earthquake.
A tsunami (pronounced soo-nah-mee or tsoo-nah-mee) is a natural phenomenon consisting of a series of waves generated when water in a lake or the sea is rapidly displaced on a massive scale. Earthquakes, landslides, volcanic eruptions and large meteorite impacts all have the potential to generate a tsunami. The effects of a tsunami can range from unnoticeable to devastation.
The term tsunami comes from the Japanese language meaning harbour ("tsu", 津) and wave ("nami", 波 or 浪). Although in Japanese tsunami is used for both the singular and plural, in English tsunamis is well-established as the plural. The term was created by fishermen who returned to port to find the area surrounding the harbour devastated, although they had not been aware of any wave in the open water. A tsunami is not a sub-surface event in the deep ocean; it simply has a much smaller amplitude (wave heights) offshore, and a very long wavelength (often hundreds of kilometres long), which is why they generally pass unnoticed at sea, forming only a passing "hump" in the ocean.
Tsunamis were historically referred to as tidal waves because as they approach land they take on the characteristics of a violent onrushing tide rather than the sort of cresting waves that are formed by wind action upon the ocean (with which people are more familiar). However, since they are not actually related to tides the term is considered misleading and its usage is discouraged by oceanographers.
A tsunami can be generated by any disturbance that rapidly displaces a large mass of water, such as an earthquake, volcanic eruption, landslide or meteorite impact. However, the most common cause is an undersea earthquake. An earthquake which is too small to create a tsunami by itself may trigger an undersea landslide quite capable of generating a tsunami.
Tsunamis can be generated when the sea floor abruptly deforms and vertically displaces the overlying water. Such large vertical movements of the earth's crust can occur at plate boundaries. Subduction earthquakes are particularly effective in generating tsunamis, and occur where denser oceanic plates slip under continental plates in a process known as subduction.
Sub-marine landslides; which are sometimes triggered by large earthquakes; as well as collapses of volcanic edifices, may also disturb the overlying water column as sediment and rocks slide downslope and are redistributed across the sea floor. Similarly, a violent submarine volcanic eruption can uplift the water column and generate a tsunami.
Waves are formed as the displaced water mass moves under the influence of gravity to regain its equilibrium and radiates across the ocean like ripples on a pond.
In the 1950s it was discovered that larger tsunamis than previously believed possible could be caused by landslides, explosive volcanic action and impact events that rapidly displace large volumes of water, as energy from falling debris or expansion is transferred to the water into which the debris falls. Generally speaking, tsunamis generated from these mechanisms, unlike the ocean-wide tsunamis caused by some earthquakes, dissipate quickly and rarely affect coastlines distant from the source area due to the small area of sea affected. However they can give rise to much larger shock waves (solitons) locally, such as the Lituya Bay megatsunami which produced a water wave estimated at 50 – 150 m and reached 524 m up local mountains.
Although often referred to as "tidal waves", a tsunami does not look like the popular impression of "a normal wave only much bigger". Instead it looks rather like an endlessly onrushing tide which forces its way around and through any obstacle. Most of the damage is caused by the huge mass of water behind the initial wave front, as the height of the sea keeps rising fast and floods powerfully into the coastal area. The sheer weight of water is enough to pulverise objects in its path, often reducing buildings to their foundations and scouring exposed ground to the bedrock. Large objects such as ships and boulders can be carried several miles inland before the tsunami subsides.
Tsunamis act very differently from typical surf swells; they are phenomena which move the entire depth of the ocean (often several kilometres deep) rather than just the surface, so they contain immense energy, propagate at high speeds and can travel great transoceanic distances with little overall energy loss. A tsunami can cause damage thousands of kilometres from its origin, so there may be several hours between its creation and its impact on a coast, arriving long after the seismic wave generated by the originating event arrives. Although the total or overall loss of energy is small, the total energy is spread over a larger and larger circumference as the wave travels, so the energy per linear meter in the wave decreases as the inverse power of the distance from the source. This is the two-dimensional equivalent of the inverse square law in three dimensions.
In open water, tsunamis have extremely long periods (the time for the next wave top to pass a point after the previous one), from minutes to hours, and long wavelengths of up to several hundred kilometres (compare to the typical wind-generated swell one sees at a beach, which might be spawned by a faraway storm and rhythmically roll in, one wave after another, with a period of about 10 seconds and a wavelength of 150 m). The actual height of a tsunami wave in open water is often less than one metre. This is often practically unnoticeable to people on ships. The energy of a tsunami passes through the entire water column to the sea bed, unlike surface waves, which typically reach only down to a depth of 10 m or so.
The wave travels across the ocean at speeds from 500 to 1,000 km/h. As the wave approaches land, the sea shallows and the wave no longer travels as quickly, so it begins to 'pile-up'; the wave-front becomes steeper and taller, and there is less distance between crests. While a person at the surface of deep water would probably not even notice the tsunami, the wave can increase to a height of 30 m or more as it approaches the coastline and compresses. The steepening process is analogous to the cracking of a tapered whip. As a wave goes down the whip from handle to tip, the same energy is deposited in less and less material, which then moves more violently as it receives this energy.
A wave becomes a 'shallow-water wave' when the ratio between the water depth and its wavelength gets very small, and since a tsunami has an extremely large wavelength (hundreds of kilometres), tsunamis act as a shallow-water wave even in deep oceanic water. Shallow-water waves move at a speed that is equal to the square root of the product of the acceleration of gravity (9.8 m/s2) and the water depth. For example, in the Pacific Ocean, where the typical water depth is about 4000 m, a tsunami travels at about 200 m/s (720 km/h or 450 mi/h) with little energy loss, even over long distances. At a water depth of 40 m, the speed would be 20 m/s (about 72 km/h or 45 mi/h), which is much slower than the speed in the open ocean but the wave would still be difficult to outrun.
Tsunamis propagate outward from their source, so coasts in the "shadow" of affected land masses are usually fairly safe. However, tsunami waves can diffract around land masses (as shown in this Indian Ocean tsunami animation as the waves reach southern Sri Lanka and India). They also need not be symmetrical; tsunami waves may be much stronger in one direction than another, depending on the nature of the source and the surrounding geography.
Local geographic peculiarities can lead to seiche or standing waves forming, which can amplify the onshore damage. For instance, the tsunami that hit Hawaii on April 1, 1946 had a fifteen-minute interval between wave fronts. The natural resonant period of Hilo Bay is about thirty minutes. That meant that every second wave was in phase with the motion of Hilo Bay, creating a seiche in the bay. As a result, Hilo suffered worse damage than any other place in Hawaii, with the tsunami/seiche reaching a height of 14 m and killing 159 inhabitants.
Warnings and prevention
In instances where the leading edge of the tsunami wave is its trough, the sea will recede from the coast half of the wave's period before the wave's arrival. If the slope is shallow, this recession can exceed many hundreds of metres. People unaware of the danger may remain at the shore due to curiosity, or for collecting fish from the exposed sea bed.
In instances where the leading edge of the tsunami is its first peak, succeeding waves can lead to further flooding. Again, being educated about a tsunami is important, to realise that when the water level drops the first time, the danger is not yet over.
Regions with a high risk of tsunamis use tsunami warning systems to forecast tsunamis and warn the general population. On the west coast of the United States, which is prone to Pacific Ocean tsunamis, warning signs advise people where to run in the event of an incoming tsunami.
One of early warnings comes from nearby animals. Many animals sense danger and flee to higher ground before the water arrives. The Lisbon quake is the first documented case of such a phenomenon in Europe. The phenomenon was also noted in Sri Lanka in the 2004 Indian Ocean earthquake (Lambourne , [BBC News http://news.bbc.co.uk/1/hi/sci/tech/4381395.stm]). Some scientists speculate that animals may have an ability to sense subsonic Rayleigh waves from an earthquake minutes or hours before a tsunami strikes shore (Kenneally, [Slate http://www.slate.com/id/2111608/]).
While it is of course not possible to prevent a tsunami, in some particularly tsunami-prone countries some measures have been taken to reduce the damage caused on shore. Japan has implemented an extensive programme of building tsunami walls of up to 4.5m (13.5 ft) high in front of populated coastal areas. Other localities have built floodgates and channels to redirect the water from incoming tsunamis. However, their effectiveness has been questioned, as tsunamis are often higher than the barriers. For instance, the tsunami which hit Hokkaido on July 12, 1993 created waves as much as 30m (100 ft) tall - as high as a 10-story building. Although the port town of Aonae was completely surrounded by a tsunami wall, the waves washed right over the wall and destroyed all the wood-framed structures in the area. The wall may have succeeded in slowing down and moderating the height of the tsunami but it did not prevent major destruction and loss of life.
See also List of historic tsunamis by death toll.
Tsunamis occur most frequently in the Pacific Ocean, but are a global phenomenon; they are possible wherever large bodies of water are found - including inland lakes.
Each of the following tsunamis is also described, sometimes at much greater length, in its own article:
6100 B.C. and before
1650 B.C. - Santorini
At some time between 1650 BC and 1600 BC (still debated), the volcanic Greek island Santorini erupted, causing a 100 m to 150 m high tsunami that devastated the north coast of Crete, 70 km (45 miles) away, and would certainly have eliminated every timber of the Minoan fleet along Crete's northern shore. Santorini is regarded as the most likely source for Plato's literary parable of Atlantis, and is believed by some scientists to have been the basis of Great Flood accounts which were eventually recorded in Jewish, Christian, and Islamic texts.
1755 - Lisbon, Portugal
Tens of thousands of Portuguese who survived the great 1755 Lisbon earthquake were killed by a tsunami which followed a half hour later. Many townspeople fled to the waterfront, believing the area safe from fires and from falling debris from aftershocks. Before the great wall of water hit the harbour, waters retreated, revealing lost cargo and forgotten shipwrecks.
The earthquake, tsunami, and subsequent fires killed more than a third of Lisbon's pre-quake population of 275,000. Historical records of explorations by Vasco da Gama and other early navigators were lost, and countless buildings were destroyed (including most examples of Portugal's Manueline architecture). Europeans of the 18th century struggled to understand the disaster within religious and rational belief systems. Philosophers of the Enlightenment, notably Voltaire, wrote about the event. The philosophical concept of the sublime, as described by philosopher Immanuel Kant in the Observations on the Feeling of the Beautiful and Sublime, took inspiration in part from attempts to comprehend the enormity of the Lisbon quake and tsunami.
1883 - Krakatoa explosive eruption
The island volcano of Krakatoa in Indonesia exploded with devastating fury in 1883, blowing its underground magma chamber partly empty so that much overlying land and seabed collapsed into it. A series of large tsunami waves was generated from the explosion, some reaching a height of over 40 metres above sea level. Tsunami waves were observed throughout the Indian Ocean, the Pacific Ocean, the American West Coast, South America, and even as far away as the English Channel. On the facing coasts of Java and Sumatra the sea flood went many miles inland and caused such vast loss of life that one area was never resettled but went back to the jungle and is now the Ujung Kulon nature reserve.
1929 - Newfoundland Tsunami
On November 18, 1929, an earthquake of magnitude 7.2 occurred beneath the Laurentian Slope on the Grand Banks. The 'quake was felt throughout the Atlantic Provinces of Canada and as far west as Ottawa, Ontario and as far south as Claymont, Delaware. The resulting tsunami measured over 7 metres in height and took about 2-1/2 hours to reach the Burin Peninsula on the south coast of Newfoundland, where 28 people lost their lives in various communities.
1946 - Pacific Tsunami
1960 - Chilean tsunami
The Great Chilean Earthquake, at magnitude 9.5 the strongest earthquake ever recorded, off the coast of South Central Chile, generated one of the most destructive tsunamis of the 20th century. It spread across the entire Pacific Ocean, with waves measuring up to 25 metres high. When the tsunami hit Onagawa , Japan, almost 22 hours after the quake, the wave height was 3 m above high tide. The number of people killed by the earthquake and subsequent tsunami is estimated to be between 490 to 2,290.
1964 - Good Friday tsunami
After the magnitude 9.2 Good Friday Earthquake, tsunamis struck Alaska, British Columbia, California and coastal Pacific Northwest towns, killing 122 people. The tsunamis were up to 6 m tall, and killed 11 people as far away as Crescent City, California.
2004 - Indian Ocean tsunami
The magnitude 9.0 (now 9.2 on the Richter Scale) 2004 Indian Ocean Earthquake triggered a series of lethal tsunamis on December 26, 2004 that killed over 310,000 people (more than 220,000 in Indonesia alone), making it the deadliest tsunami in recorded history. The tsunami killed people over an area ranging from the immediate vicinity of the quake in Indonesia, Thailand and the north-western coast of Malaysia to thousands of kilometres away in Bangladesh, India, Sri Lanka, the Maldives, and even as far as Somalia, Kenya and Tanzania in eastern Africa. Over 300 million pounds was raised worldwide to help victims of the tragedy.
Unlike in the Pacific Ocean, there is no organised alert service covering the Indian Ocean. This is in part due to the absence of major tsunami events between 1883 (the Krakatoa eruption, which killed 36,000 people) and 2004. In light of the 2004 Indian Ocean tsunami, UNESCO and other world bodies have called for a global tsunami monitoring system.
Other tsunamis in South Asia
| Tsunamis in South Asia |
(Source: Amateur Seismic Centre, India)
|1524||Near Dabhol, Maharashtra|
|02 April 1762||Arakan Coast, Myanmar|
|16 June 1819||Rann of Kachchh, Gujarat|
|31 October 1847||Great Nicobar Island|
|31 December 1881||Car Nicobar Island|
|26 August 1883||Krakatoa volcanic eruption|
|28 November 1945||Mekran coast, Balochistan|
|26 December 2004||Banda Aceh, Indonesia; Tamil Nadu, Kerala, Andhra Pradesh, Andaman and Nicobar Islands, India; Sri Lanka; Thailand; Malaysia; Somalia; Kenya; Tanzania|
Other historical tsunamis
Other tsunamis that have occurred include the following:
- 1500 years ago : Sea that wiped off Poompuhar
- January 20, 1606/1607: along the coast of the Bristol Channel (main article) thousands of people were drowned, houses and villages swept away, farmland was inundated and flocks were destroyed by a flood that might have been a tsunami. The cause of the flood remains disputed, it is quite possible that it was caused by a combination of meteorological extremes and tidal peaks (discussion).
- January 26, 1700: the Cascadia Earthquake (estimated 9.0 magnitude) caused massive tsunamis across the Pacific Northwest and in Awa, Japan
- One of the worst tsunami disasters engulfed whole villages along Sanriku , Japan, in 1896. A wave more than seven stories tall (about 20 m) drowned some 26,000 people.
- 1929: An undersea landslide off the Grand Banks of Newfoundland, Canada triggered a giant wave that killed 28 people in Newfoundland.
- 1946: An earthquake in the Aleutian Islands sent a tsunami to Hawaii, killing 159 people (five died in Alaska).
- July 9, 1958: A huge landslip caused the highest ever reported tsunami which was 524 metres high. This happened in the fjord shaped Lituya Bay, Alaska, USA. It travelled at over 100mph.
- 1976: On 16 August (midnight) a tsunami killed more than 5000 people in the Moro Gulf region (Cotabato city ) of the Philippines.
- 1983: 104 people in western Japan were killed by a tsunami spawned from a nearby earthquake.
- 17 July, 1998: A Papua New Guinea tsunami killed approximately 2200 people. A 7.1 magnitude earthquake 24 km offshore was followed within 11 minutes by a tsunami about 12 m tall. While the magnitude of the quake was not large enough to create these waves directly, it is believed the earthquake generated an undersea landslide, which in turn caused the tsunami. The villages of Arop and Warapu were destroyed.
North American and Caribbean tsunamis
- 14 November 1840 - Great Swell on the Delaware River
- 18 November 1867 - Virgin Islands
- 17 November 1872 - Maine
- 11 October 1918 - Puerto Rico
- 18 November 1929 - Newfoundland
- 9 January 1926 - Maine
- 4 August 1946 - Dominican Republic
- 18 August 1946 - Dominican Republic
- 19 May 1964 - Northeast USA
- 9 June 1913 - Longport, NJ
- 6 August 1923 - Rockaway Park, Queens, NY . An article on triplicate waves.
- 8 August 1924 - Coney Island, NY .
- 19 August 1931 - Atlantic City, NJ
- 21 September 1938 - Hurricane, NJ coast.
- 3-4 July 1992 - Daytona Beach, FL
- 35 Million years ago - Chesapeake Bay impact crater, Chesapeake Bay
- Kenneally, Christine (December 30, 2004). "Surviving the Tsunami". Slate. link
- Macey, Richard (January 1, 2005). "The Big Bang that Triggered A Tragedy", The Sydney Morning Herald, p 11 - quoting Dr Mark Leonard, seismologist at Geoscience Australia.
- Lambourne, Helen (March 27, 2005). "Tsunami: Anatomy of a disaster". BBC News. link
- abelard.org . tsunamis: tsunamis travel fast but not at infinite speed. Website, retrieved March 29, 2005. link
Images and video
- Large Collection of Amateur Tsunami Videos with Thunbnail Images and Detailed Descriptions
- 5 Amateur Camcorder Video Streams of the December 26, 2004 tsunami that hit Sri Lanka, Thailand and Indonesia. They show the deceptive nature of these waves which seem harmless at first and then unstoppable.
- 2004 Asian Tsunami Satellite Images (Before and After)
- Satellite Images of Tsunami Affected Areas High resolution satellite images showing the effects of the 2004 tsunami on the affected areas in Indonesia, Thailand and Nicobar island of India.
- 2004 Asian Tsunami Aerial Pictures 150 aerial images from throughout the region showing the aftermath, devastation and recovery operations.
- Computer-generated animation of a tsunami
- Animation of 1960 tsunami originating outside coast of Chile
- Can HF Radar detect Tsunamis? University of Hamburg HF-Radar
- Development Gateway Tsunami Special
- The International Centre for Geohazards (ICG)
- ITIC tsunami FAQ
- NOAA PMEL Tsunami Research Program
- USGS: Surviving a tsunami
- ITSU Coordination Group for Pacific Tsunami Warning System
- Pacific Tsunami Museum
- Tsunami Hazard Mitigation Program
- Tsunamis and Earthquakes
- Tsunami.gov (US NOAA)
- Science of Tsunami Hazards journal
- The International Centre for Geohazards (ICG)
- The Power of Humanity... essay by Thrishana Pothupitiya of Sri Lanka
- "Life Of A Guy From Asia..." A Personal Tsunami Blog from Sri Lanka
- Tsunami Sri Lanka Information
- The Indian Ocean tsunami and what it tells us about tsunamis in general
- 2004 Indian Ocean Earthquake and Tsunami Forum
- Maps, animations, info, photographs - a New York Times feature on Indo-Asian tsunami, December 2004
- Kalkudah, Sri Lanka Before the Tsunami
- Rehabilitation of tsunami affected mangroves needed
- Mangrove forests can reduce impact of tsunamis
- Indian mangroves 'absorbed' tsunami
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