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Need Emergency Advice? In the event of a tsunami warning for Australia for which you urgently need extra advice, please listen to your local radio and TV announcements for emergency services messages.
The name Tsunami, from the Japanese words tsu meaning harbour and nami meaning wave, is now used internationally to describe a series of waves travelling across the ocean. These waves have extremely long wavelengths, up to hundreds of kilometres between wave crests in the deep ocean.
In the past, tsunami have been referred to as 'tidal waves' or 'seismic sea waves'. The term 'tidal wave' is misleading. Even though a tsunami's impact upon a coastline is dependent on the tidal level at the time a tsunami strikes, tsunami are unrelated to the tides. Tides result from the gravitational influences of the moon, sun and planets. The term 'seismic sea wave' is also misleading. Seismic implies an earthquake-related generation mechanism. Earthquakes are only one of several ways that a tsunami can be generated. Tsunami can also be caused by events such as underwater landslides, volcanic eruptions, land slumping into the ocean, meteorite impacts, or even the weather when the atmospheric pressure changes very rapidly.
The most common cause of tsunami is an undersea earthquake that results in a sudden rise or fall of a section of the earth's crust under or near the ocean. This earthquake creates an explosive vertical motion that can displace the overlying water column, creating a rise or fall in the level of the ocean above. This rise or fall in sea level is the initial impulse that generates a tsunami wave.
Tsunami are typically generated by earthquakes that occur along subduction zones. A subduction zone is an area on the earth where two tectonic plates meet and move towards one another, with one sliding underneath the other and moving down into the earth at rates typically measured in centimetres per year.
Tsunami are different from normal waves
Tsunami waves involve the movement of water all the way to the sea floor. The effects of wind-driven ocean waves are seen only near the surface of the ocean.
Tsunami have long wavelengths
In the deep ocean tsunami waves have extremely long wavelengths. In comparison to wind-driven waves, tsunami waves may have wavelengths up to hundreds of kilometres between wave crests. Tsunami are therefore much more destructive than normal waves because the huge flooding body of water can continue to rush onto land for an extended period of time. This may be anything from a few minutes up to an hour, compared to seconds for wind-driven waves.
As a tsunami approaches land, the size increases
The speed and size of a tsunami is controlled by water depth. In the deep ocean tsunami waves may be unnoticed by ships or from the air. As the wave approaches land it reaches shallow water and slows down. Compared to the front of the wave, the rear is still in slightly deeper water (so it is going slightly faster) and catches up. The result is that the wave quickly 'bunches up', the wavelength becomes shorter and the body of water becomes much higher. This is called shoaling.
Tsunami are fast
In the deep ocean, a tsunami can travel at more than 900 kilometres per hour, close to the speed of a jumbo jet, and in shallow water, it can be described as roughly the speed of a fast cyclist.
Tsunami retain their energy
As well as travelling at high speeds, tsunami can also travel large distances with limited energy losses. Tsunami can therefore have sufficient energy to travel across entire oceans.
Tsunami waves move outwards, away from their source
The path of a tsunami is never symmetrical and is determined by a number of factors including the bathymetry of the sea floor. Bathymetry is the measurement of the depth of the ocean floor from the water surface and is the oceanic equivalent of topography. Tsunami move outwards at right angles to the subduction trench where the earthquake has occurred. A tsunami travels faster through deep water and slower through shallow water. This directs the wave along undersea valleys. The size of the earthquake, the shape of the earthquake and the direction of the subduction zone that ruptures are also influencing factors.
A tsunami is a 'series' of waves
A tsunami generally consists of a series of waves. The amount of time between successive waves is known as the wave period. Waves can be a few minutes or over two hours apart. In most cases, the first tsunami wave is not the largest. Subsequent waves, sometimes the fifth or sixth, can be many times larger.
Tsunami can vary in size and severity
The impact of a tsunami can vary widely. A small tsunami may result in unusual tides or currents that can be dangerous to swimmers or cause damage to berthed boats. A large tsunami can cause widespread flooding and destruction such as that seen off the west coast of Northern Sumatra on 26 December 2004. The south Java tsunami (17 July 2006) was caused by a relatively small earthquake (magnitude 7.7) that generated a 0.5 metre tsunami. This tsunami inundated the coast by up to four meters in some places, killing over 600 people. Large tsunami cause strong rips and currents in oceans around the world for up to a few days after the initiating earthquake.
Most tsunami occur in the Pacific and Indian Oceans. The boundary of the Pacific Ocean, known as the Ring of Fire, experiences frequent earthquakes. There are two major subduction zones in the Indian Ocean that can also generate tsunami. The frequency of tsunami is variable across the globe and over time. In the two years after the event of 26 December 2004 the Pacific Tsunami Warning Centre issued 52 tsunami alerts for six tsunami, two of which resulted in significant loss of life.
Australia is surrounded to the northwest and east by some 8,000 kilometres of active tectonic plate boundaries capable of generating tsunami, which could reach our coastline within two to four hours. One-third of earthquakes worldwide occur along these boundaries. The impact of a tsunami hitting vulnerable, low-lying areas on the Australian coast could be significant.
Typically, earthquakes that may generate a tsunami are detected through a network of seismic monitoring stations. Any resulting tsunami are then verified by sea-level monitoring stations and deep ocean tsunami detection buoys. The seismic monitoring stations can determine the location and depth of earthquakes that have the potential to cause tsunami. The sea-level gauges and deep ocean tsunami detection buoys then measure any abnormal changes in sea level to verify if a tsunami has been generated.
With the introduction of the Joint Australian Tsunami Warning Centre (JATWC) in July 2007, Australia now has the capacity to detect and verify potential tsunami in our region.
The JATWC combines the operational roles of Geoscience Australia (GA) and the Bureau of Meteorology (the Bureau). GA notifies the Bureau of any earthquakes that may cause a tsunami. The Bureau then uses its network of sea-level monitoring equipment to determine the existence of a tsunami and issues a tsunami warning if required.
Emergency Management Australia (EMA) supports the system through its community awareness and preparedness campaigns. EMA also have a role in coordinating a national response to a tsunami disaster if requested by the States or Territories.
The establishment of the fully functional Australian Tsunami Warning System is a four-year project funded by the Federal Government that is due to be completed in June 2009. At the completion of the project Australia will have considerably improved tsunami detection equipment in Australia and around the region, enhanced scientific modelling of tsunami, a responsive warning system, and increased public awareness and community preparedness.
The Pacific Tsunami Warning Centre (PTWC) in Hawaii currently provides tsunami advice for the Pacific Ocean. PTWC and the Japan Meteorological Agency (JMA) jointly provide an interim tsunami warning service for the Indian Ocean.
Australia is participating in the development of a tsunami warning system for the Indian Ocean through the Intergovernmental Oceanographic Commission, an agency of UNESCO. Australia is also enhancing seismic and sea-level monitoring networks in the Pacific Ocean, with observations being provided to PTWC in support of its warning service for the Pacific Ocean.
The number one warning sign of a tsunami in Australia is the advice you may receive from the media (on radio or television) or from police and other emergency services. Follow their instructions immediately.
The following are natural signs of a tsunami that you may, but not always, experience when you are near the coast in Australia or overseas. If you notice any of these three warning signs take action.
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