The Great Barrier Reef, the world's largest reef system, stretching along the East coast of Australia from the northern tip down to the town of Bundaberg, is composed of roughly 2,900 individual reefs and 940 islands and cays that stretch for 2,300 kilometres (1,616 mi) and cover an area of approximately 344,400 square kilometres (133,000 sq mi). The reef is located in the Coral Sea, off the coast of Queensland in northeast Australia. A large part of the reef is protected by the Great Barrier Reef Marine Park.
According to the 2014 report of the Australian Government's Great Barrier Reef Marine Park Authority (GBRMPA), says that climate change is the most significant environmental threat to the Great Barrier Reef, while the other major environmental pressures are listed as decreased water quality from land-based runoff, impacts from coastal development and some persistent impacts from fishing activities. The reef is also threatened by storms, coral bleaching and ocean acidification. The 2014 report also shows that, while numerous marine life species have recovered after previous declines, the strength of the dugong population is continuing to decline. Terry Hughes, Federation Fellow, ARC Centre of Excellence for Coral Reef Studies at James Cook University, wrote in a 14 August 2014 Conversation piece that harmful government policies and ongoing conflicts of interest over mining royalties are risks of an equivalent magnitude.
The GBRMPA consider climate change, poor water quality, coastal development, and some impacts from fishing to be the area's major threats, but reef scientists Jon Day, Bob Pressey, Jon Brodie and Hughes stated that the "cumulative effects of many combined impacts" is the real issue.
In a Conversation Article, Mathieu Mongin, a biogeochemical modeller at CSIRO and colleagues mapped parts of the Great Barrier Reef that are most exposed to ocean acidification. This map of pH on the Great Barrier Reef presents the exposure to ocean acidification on each of the 3,581 reefs, providing managers with the information they need to tailor management to individual reefs. The Great Barrier Reef is not a singular reef nor a physical barrier that prevents exchange between reefs; it is a mixture of thousands of productive reefs and shallow areas lying on a continental shelf with complex oceanic circulation.
History
In
1967, efforts began to conserve the Great Barrier Reef. It was
proposed to mine lime from Ellison Reef, but surveys showed that the
reef supported a diverse community of corals and fish.
The Australian and Queensland Governments committed to act in partnership in 2007 to protect the reef, and water quality monitoring programmes were implemented. However, the World Wildlife Fund
criticised the slow progress of the governments, raising a concern that
as many as 700 reefs continued to be at risk from sediment runoff.
The Australian government then outlined further action after the
WHC called for the completion of a strategic assessment of the Reef area
in 2011. The Committee also urged the government to use the assessment
data to develop a long-term plan for protecting the "Outstanding
Universal Value" of the reef, which is the basis for its World Heritage
listing. Again, criticisms emerged from the expert community—due to
vague quantitative targets, the absence of clear, specific strategies,
and no mention of the implications of climate change—but the significant
efforts of both state and federal governments addressed key
recommendations from the World Heritage Committee.
A 2012 UNESCO report, published by the World Heritage Committee
(WHC), then criticised the government's management of the Great Barrier
Reef, warning that the area could be downgraded to a world heritage site
"in danger" unless major changes were implemented. The report expressed
"extreme concern" at the rapid rate of coastal development,
highlighting the construction of liquefied natural gas plants at
Gladstone and Curtis Island, and recommended that thorough assessments
are made before any new developments that could affect the reef are
approved. UNESCO specifically recommended no new port development in Abbot Point, Gladstone, Hay Point, Mackay, and Townsville.
Australian Foreign Minister Julie Bishop informed the Australian media that she would use climate change talks, held in Lima, Peru, in December 2014, to avoid the WHC—consisting of experts from 20 nations—applying the "in danger" listing in 2015. Bishop believed that "no justification" existed for the downgrading:
It would send a message around the world that even if you meet all of the criteria set out by the world heritage committee, there is still a risk that they will place an area on the in-danger list ... It [downgrading] would have significant implications for Australia but it would also set a very dangerous precedent for countries who don’t have the opportunity to take the action that Australia has.
To avoid the Great Barrier Reef being listed as "in danger", the
Queensland Government introduced the Ports Bill 2014 on 25 November
2014. The Bill seeks to restrict further port development along the
coast to Brisbane and four "Priority Port Development Areas", with the
latter including four ports identified by the WHC in its 2012 report.
The Bill also restricts dredging over a decade-long period, with the
exception of priority ports. Additionally, a long-term sustainability
plan and the expansion of water-quality activities were introduced by
state and federal governments, and their partner agencies.
However, in response to the Ports Bill, University of Queensland
(UQ) academics said on 19 December 2014 that, although the issues are
"not insurmountable", "the health of the reef is still declining and
consequently more needs to be done." Australian Marine Conservation Society (AMCS) Great Barrier Reef campaign director Felicity Wishart was more damning and stated in a press release:
The new Ports Bill fails to rule out any currently proposed new dredging, the dumping of dredge spoil in the Reef's waters and is silent on maintenance dredging across the region. The millions of tonnes of dredging and dumping for mega port developments that are in the pipeline will be able to go ahead under the Bill. Despite the establishment of four Priority Port Development Areas along the Reef (Townsville, Abbot Point, Mackay/Hay Point and Gladstone), the Bill will still allow port expansion in Cairns. This fails to meet the recommendation by the World Heritage Committee that no new port developments be permitted outside of the existing port areas. The Bill contains no protections for the most northern section of the Reef or the Fitzroy Delta, and it does nothing to improve water quality in Reef waters, all matters which the World Heritage Committee wants action on.
UNESCO considers that the Reef 2050 Long-Term Sustainability Plan has
been effective, noting that progress had been made to reduce
agricultural runoff sediments.
Water quality
Water quality was first identified as a threat to the Great Barrier Reef in 1989.
Thirty "major rivers" and hundreds of small streams comprise the Great Barrier Reef catchment area, which covers 423,000 square kilometres (163,000 sq mi) of land. Queensland has several major urban centers on the coast including Cairns, Townsville, Mackay, Rockhampton and the industrial city of Gladstone. Dredging in the Port of Gladstone
is raising concern after dead and diseased fish where found in the
harbor. Cairns and Townsville are the largest of the coastal cities,
with populations of approximately 150,000 each.
There are many major water quality variables affecting coral reef health including water temperature, salinity, nutrients, suspended sediment concentrations, and pesticides.
The species in the Great Barrier Reef area are adapted to tolerable
variations in water quality however when critical thresholds are
exceeded they may be adversely impacted. River discharges are the single
biggest source of nutrients,
providing significant pollution of the Reef during tropical flood
events with over 90% of this pollution being sourced from farms. When the 2019 Townsville flood waters reached the Great Barrier Reef, the flood plumes covered a large area of corals, even reaching 60 km out to sea.
As of 1995, water visibility had decreased to 10 metres.
Due to the range of human uses made of the water catchment area adjacent to the Great Barrier Reef, some 700 of the 3000 reefs are within a risk zone where water quality has declined due to the naturally acidic sediment and chemical runoff from farming. Coastal development and the loss of coastal wetlands—the latter acts as natural filter—are also major factors. From mid 2012 to mid 2016, 596,000 hectares of forest in the catchment zone was cleared.
Industries in the water catchment area are cotton growing, comprising
approximately 262 km²; 340 dairy farms with an average area of 2 km²
each, 158 km² cattle grazing, 288 km² horticulture including banana
growing, sugarcane farming, and cropping of approximately 8,000 km²
wheat, 1,200 km² barley, and 6,000 to 7000 km² sorghum and maize.
Fertiliser use in the cotton, dairy, beef, horticulture and sugar
industries is essential to ensure productivity and profitability.
However, fertiliser and byproducts from sugar cane harvesting methods
form a component of surface runoff into the Great Barrier Reef lagoon.
The principal agricultural activity in the wet tropics is sugar cane
farming, while cattle grazing is the primary industry in the dry
tropics regions. Both are considered significant threats to high water
quality. Copper,
a common industrial pollutant in the waters of the Great Barrier Reef,
has been shown to interfere with the development of coral polyps.
Flood plumes are flooding events associated with higher levels of nitrogen and phosphorus. In February 2007, due to a monsoonal climate system, plumes of sediment runoff have been observed reaching to the out most regions of the reef.
Runoff is especially concerning in the region south of Cairns, as
it receives over 3000 mm of rain per year and the reefs are less than
30 kilometres (19 mi) away from the coastline.
Farm run off is polluted as a result of overgrazing and excessive
fertilizer and pesticide use. Mud pollution has increased by 800% and
inorganic nitrogen pollution
by 3,000% since the introduction of European farming practices on the
Australian landscape. This pollution has been linked to a range of very
significant risks to the reef system, including intensified outbreaks of
the coral-eating Crown of Thorns Starfish which contributed to a loss
of 66% of live coral cover on sampled reefs in 2000.
It is thought that the mechanism behind excess nutrients affecting the reefs is due to increased light and oxygen competition from algae,
but unless herbivory is unusually low, this will not create a phase
shift from the Great Barrier Reef being primarily made up of coral to
being primarily made up of algae.
It has been suggested that poor water quality due to excess nutrients encourages the spread of infectious diseases among corals. In general, the Great Barrier Reef is considered to have low incidences of coral diseases. Skeletal Eroding Band, a disease of bony corals caused by the protozoan Halofolliculina corallasia, affects 31 species of corals from six families on the reef.
The long-term monitoring program has found an increase in incidences of
coral disease in the period 1999–2002, although they dispute the claim
that on the Great Barrier Reef, coral diseases are caused by anthropogenic pollution.
Elevated nutrient concentrations result in a range of impacts on
coral communities and under extreme conditions can result in a collapse.
It also affects coral by promoting phytoplankton growth which increases
the number of filter-feeding
organisms that compete for space. Excessive inputs of sediment from
land to coral can lead to reef destruction through burial, disruption of
recruitment success, or deleterious community shifts. Sediments affect
coral by smothering them when particles settle out, reducing light
availability and potentially reducing photosynthesis and growth. Coral
reefs exist in seawater salinities from 25 to 42%. Salinity impacts to
corals are increased by other flood-related stresses.
Pollution from mining
A freedom of information request by the Northern Queensland Conservation Council in 2014 showed that Queensland Nickel, owned by Australian politician Clive Palmer,
discharged nitrate-laden water into the Great Barrier Reef in 2009 and
2011—releasing 516 tonnes (508 long tons; 569 short tons) of toxic waste
water on the latter occasion. In June 2012, Queensland Nickel stated it
intended to release waste water, continuously for three months, "at
least 100 times the allowed maximum level as well as heavy metals and
other contaminants". A GBRMPA briefing stated the company had
"threatened a compensation claim of $6.4bn should the GBRMPA intend to
exert authority over the company's operations". In response to the
publicisation of the dumping incidents, the GBRMPA stated:
We have strongly encouraged the company to investigate options that do not entail releasing the material to the environment and to develop a management plan to eliminate this potential hazard; however, GBRMPA does not have legislative control over how the Yabulu tailings dam is managed.
Dumping
Following
a tour of the Great Barrier Reef area by WHC members, a 2012 UNESCO
report, which criticised management of the Great Barrier Reef,
specifically recommended no new port development outside the established
areas of Abbot Point, Gladstone, Hay Point/Mackay, and Townsville. However, in December 2013, Greg Hunt, the Australian environment minister,
approved a plan for dredging to create three shipping terminals as part
of the construction of a coalport. According to corresponding approval
documents, the process will create around 3 million cubic metres of
dredged seabed that will be dumped within the Great Barrier Reef marine
park area.
On 31 January 2014, the GBRMPA issued a dumping permit that will allow three million cubic metres of sea bed from Abbot Point, north of Bowen,
to be transported and unloaded in the waters of the Great Barrier Reef
Marine Park. Potential significant harms have been identified in
relation to dredge spoil and the process of churning up the sea floor in
the area and exposing it to air: firstly, new research shows the finer
particles of dredge spoil can cloud the water and block sunlight,
thereby starving sea grass and coral up to distances of 80 km away from
the point of origin due to the actions of wind and currents.
Furthermore, dredge spoil can literally smother reef or sea grass to
death, while storms can repeatedly resuspend these particles so that the
harm caused is ongoing; secondly, disturbed sea floor can release toxic
substances into the surrounding environment.
The dredge spoil from the Abbot Point port project is to be
dumped 24 kilometres (15 mi) away, near Bowen in north Queensland, and
the approval from the Authority will result in the production of an
extra 70 million tonnes of coal annually, worth between A$1.4 billion
and $2.8 billion. Authority chairman, Dr Russell Reichelt, stated after the confirmation of the approval:
This approval is in line with the agency's view that port development along the Great Barrier Reef coastline should be limited to existing ports. As a deepwater port that has been in operation for nearly 30 years, Abbot Point is better placed than other ports along the Great Barrier Reef coastline to undertake expansion as the capital and maintenance dredging required will be significantly less than what would be required in other areas. It's important to note the seafloor of the approved disposal area consists of sand, silt and clay and does not contain coral reefs or seagrass beds.
The approval was provided with a corresponding set of 47 new environmental conditions that include the following:
- A long-term water quality monitoring plan extending five years after the disposal activity is completed.
- A heritage management plan to protect the Catalina second world war aircraft wreck in Abbot Bay.
- The establishment of an independent dredging and disposal technical advice panel and a management response group, to include community representatives.
Numerous responses, including online petitions, were published in opposition to the proposal: Greenpeace
launched the "Save the Reef" campaign in opposition to the dumping,
which remained active with over 170,000 signatures on 3 March 2014; in addition to an online petition that registered more than 250,000 signatures on 3 March 2014, political activist group GetUp!
are also funding a legal case in conjunction with non-profit
Environmental Defenders Office of Queensland (EDO), which represents the
North Queensland Conservation Council; and "Fight for the Reef", a partnership between World Wide Fund for Nature (WWF)-Australia and the Australian Marine Conservation Society
(AMCS), maintains a campaign that collects online donations to fund a
"legal fighting team", and displayed nearly 60,000 supporters on its
website on 11 May 2014.
The legal fighting team of the WWF-Australia and the AMCS
received further support in April 2014 following the release of the
"Sounds For The Reef" musical fundraising project. Produced by
Straightup, the digital album features artists such as John Butler, The Herd, Sietta, Missy Higgins, The Cat Empire,
Fat Freddys Drop, The Bamboos (featuring Kylie Auldist) and Resin Dogs.
Released on 7 April, the album's 21 songs were sold on the Bandcamp website.
Further support for the WWF-Australia and AMCS partnership occurred in late April 2014, when the Ben & Jerry's
ice cream company signed onto the "Fight for the Reef" campaign. In
early April 2014, the company withdrew the popular "Phish Food" flavour
in Australia due to the aquatic association and the potential for
awareness-raising. The product withdrawal decision followed tours around
select parts of the nation that involved Ben & Jerry's
representatives distributing free ice cream to highlight the reef damage
issue.
In response, Minister for the Environment and Heritage Protection of Queensland Andrew Powell said that he would be contacting parent corporation Unilever,
explaining, "The only people taking a scoop out of the reef is Ben and
Jerry's and Unilever. If you understand the facts, you'd want to be
boycotting Ben and Jerry's". The Australian public was also informed by
Australian Ben & Jerry's brand manager Kalli Swaik, who stated to
the Brisbane Times newspaper: "Ben & Jerry's believes that
dredging and dumping in world heritage waters surrounding the marine
park area will be detrimental to the reef ecology. It threatens the
health of one of Australia's most iconic treasures."
A Queensland state senator, Matthew Canavan, confirmed that he raised the issue in writing with the Australian Competition and Consumer Commission (ACCC) and said to The Courier-Mail:
Ben & Jerry's can campaign on whatever issue they like but as a company they have an obligation to tell Australians the whole truth and nothing but the truth. Australia has strict laws to protect consumers against misleading and deceptive behavior. These mistruths could cost jobs and development in regional Queensland. It's irresponsible behavior from a company that should know better.
After Cyclone Debbie in 2017, the Adani mine released water with eight times the permitted sediment into the Abbot Point lagoon.
Climate change
According to the GBRMPA in 2014, the most significant threat to the status of the Great Barrier Reef is climate change,
due to the consequential rise of sea temperatures, gradual ocean
acidification and an increase in the number of "intense weather events".
Hughes writes of "the demonstrable failure of the state and
Commonwealth" to address the issue of climate change in his August 2014
article. Furthermore, a temperature rise of between two and three degrees Celsius would result in 97% of the Great Barrier Reef being bleached every year.
Reef scientist Terry Done has predicted that a one-degree rise in global temperature
would result in 82% of the reef bleached—two degrees would result in
97%, while three degrees would result in "total devastation".
A predictive model based on the 1998 and 2002 bleaching events has
concurred that a temperature rise of three degrees would result in total
coral mortality.
However, a few scientists hold that coral bleaching may in some
cases be less of a problem than the mainstream believes. Professor Peter Ridd,
from James Cook University in Townsville was quoted in The Australian
(a conservative newspaper) as saying; "They are saying bleaching is the
end of the world, but when you look into it, that is a highly dubious
proposition". Research by scientist Ray Berkelmans "... has documented
astonishing levels of recovery on the Keppel outcrops devastated by
bleaching in 2006."
A related article in The Australian newspaper goes on to explain that;
"Those that expel their zooxanthellae have a narrow opening to
recolonise with new, temperature-resistant algae before succumbing. In
the Keppels in 2006, Berkelmans and his team noticed that the dominant
strain of zooxanthellae changed from light and heat-sensitive type C2,
to more robust types D and C1."
Nevertheless, most coral reef researchers anticipate severely
negative effects from climate change already occurring, and potentially
disastrous effects as climate change worsens.
The future of the Reef may well depend on how much the planet's climate
changes, and thus, on how high atmospheric greenhouse gas concentration
levels are allowed to rise. On 2 September 2009, a report by the
Australian Great Barrier Reef Marine Park Authority revealed that if carbon dioxide levels reached 450 parts per million
corals and reef habitats will be highly vulnerable. If carbon dioxide
levels are managed at or below 380 parts per million they will be only
moderately vulnerable and the reefs will remain coral-dominated.
Global warming may have triggered the collapse of reef ecosystems
throughout the tropics. Increased global temperatures are thought by
some to bring more violent tropical storms,
but reef systems are naturally resilient and recover from storm
battering. Most people agree that an upward trend in temperature will
cause much more coral bleaching;
others suggest that while reefs may die in certain areas, other areas
will become habitable for corals, and new reefs will form.
However, the rate at which the mass bleaching events occur is estimated
to be much faster than reefs can recover from, or adjust to.
However, Kleypas et al. in their 2006 report suggest that the trend towards ocean acidification indicates that as the sea's pH decreases, corals will become less able to secrete calcium carbonate. In 2009, a study showed that Porites
corals, the most robust on the Great Barrier Reef, have slowed down
their growth by 14.2% since 1990. It suggested that the cause was heat
stress and a lower availability of dissolved calcium to the corals.
Climate change has implications for other forms of life on the Great Barrier Reef as well – some fish's preferred temperature range
lead them to seek new areas to live, thus causing chick mortality in
seabirds that prey on the fish. Also, in sea turtles, higher
temperatures mean that the sex ratio of their populations will change,
as the sex of sea turtles is determined by temperature. The habitat of
sea turtles will also shrink.
A 2018 study which compared the sex ratio of green sea turtles in the
northern and southern populations found that the northern population was
almost all female.
On April 22, 2018 Scientist concerned alarm that coral massive damage could impact ecosystem due to climate change.
Crown of Thorns Starfish
The Crown-of-Thorns Starfish is a coral reef predator which preys on coral polyps by climbing onto them, extruding its stomach over them, and releasing digestive enzymes
to absorb the liquefied tissue. An individual adult of this species can
eat up to six square meters of living reef in a single year.
Geological evidence suggests that the Crown-of-Thorns Starfish has
been part of the Great Barrier Reef's ecology for "at least several
thousand years", but there is no geological evidence for Crown of Thorns
outbreaks. The first known outbreak occurred during the 1960s.
Large outbreaks of these starfish can devastate reefs. In 2000, an
outbreak contributed to a loss of 66% of live coral cover on sampled
reefs in a study by the CRC Reefs Research Centre.
Although large outbreaks of these starfish are believed to occur in
natural cycles, human activity in and around the Great Barrier Reef can
worsen the effects. Reduction of water quality associated with
agriculture can cause the crown-of-thorns starfish larvae
to thrive. Fertilizer runoff from farming increases the amount of
phytoplankton available for the Crown of Thorns Starfish larvae to
consume. A study by the Australian Institute of Marine Science
showed that a doubling of the chlorophyll in the water leads to a
tenfold increase in the crown-of-thorns starfish larvae's survival rate. Overfishing of its natural predators, such as the Giant Triton, is also considered to contribute to an increase in the number of Crown of Thorns Starfish. The CRC Reef Research Centre defines an outbreak as when there are more than 30 adult starfish in an area of one hectare.
There have been three large outbreaks of COTS on the reef since
observation began, between 1962 and 1976; 1978 and 1991; 1993 and 2005,
and a fourth began in 2009.
Investigation is being undertaken into mimicking a chemical scent
released by the COTS' natural predator, the giant triton snail.
Overfishing
The unsustainable overfishing of keystone species, such as the Giant Triton and sharks, can cause disruption to food chains vital to life on the reef. Fishing also impacts the reef through increased pollution from boats, by-catch of unwanted species (such as dolphins and turtles) and reef habitat destruction from trawling, anchors and nets. Overfishing of herbivore populations can cause algal growths on reefs. The Batfish Platax pinnatus has been observed to significantly reduce algal growths in studies simulating overfishing.
Sharks are fished for their meat, and when they are part of bycatch, it
is common to kill the shark and throw it overboard, as there is a
belief that they interfere with fishing. As of 1 July 2004, approximately one-third of the Great Barrier Reef Marine Park is protected from species removal of any kind, including fishing, without written permission. However, illegal poaching is not unknown in these no-take zones. A 2015 study into coral trout
on the Great Barrier Reef found that the no-take zones had more coral
trout and more coral trout larvae after tropical cyclone events, which
helped replenish those areas sooner. The GBRMPA has a hotline to report suspected poachers.
Shipping
Shipping accidents continue to be perceived as a threat, as several
commercial shipping routes pass through the Great Barrier Reef. The
GBRMPA estimates that about 6000 vessels greater than 50 metres (164 ft)
in length use the Great Barrier Reef as a route. From 1985 to 2001, 11 collisions and 20 groundings occurred along the Great Barrier Reef shipping route, with human error identified as the leading cause of shipping accidents.
Reef pilots have stated that they consider the reef route safer
than outside the reef in the event of mechanical failure, since a ship
can sit safely while being repaired. The inner route is used by 75% of all ships that travel over the Great Barrier Reef. As of 2007, over 1,600 known shipwrecks have occurred in the Great Barrier Reef region.
Waste and foreign species discharged from ships in ballast water (when purging procedures are not followed) are a biological hazard to the Great Barrier Reef. Tributyltin (TBT) compounds found in some antifouling paint
on ship hulls leaches into seawater and is toxic to marine organisms
and humans; as of 2002, efforts are underway to restrict its use.
In April 2010, the bulk coal carrier Shen Neng 1 ran aground on the Great Barrier Reef,
causing the largest grounding scar to date. The spill caused damage to a
400,000sqm section of the Great Barrier Reef and the use of oil
dispersant resulted in oil spreading to reef islands 25 km away.
In 2012 and 2013, there were 9619 ship voyages through the Great
Barrier Reef region, and this is forecast to increase 250% over the next
20 years.
Over 9,600 ship voyages occurred in the GBRMPA between 2012 and 2013.
Oil
It was suspected that the Great Barrier Reef is the cap to an oil trap, after a 1923 paper suggested that it had the right rock formation to support "oilfields of great magnitude". After the Commonwealth Petroleum Search Subsidies Act of 1957, exploration activities increased in Queensland, including a well drilled at Wreck Island in the southern Great Barrier Reef in 1959. In the 1960s, drilling for oil and gas was investigated throughout the Great Barrier Reef, by seismic and magnetic methods in the Torres Strait, along "the eastern seaboard of Cape York to Princess Charlotte Bay" and along the coast from Cooktown to Fraser Island. In the late 1960s, more exploratory wells were drilled near Wreck Island in the Capricorn Channel, and near Darnley Island in the Torres Strait, but "all results were dry".
In 1970, responding to concern about oil spills such as the Torrey Canyon, two Royal Commissions
were ordered "into exploratory and production drilling for petroleum in
the area of the Great Barrier Reef". After the Royal Commissions, the
federal and state governments ceased allowing petroleum drilling on the
Great Barrier Reef. A study in 1990 concluded that the reef is too young to contain oil reserves.
Oil drilling remains prohibited on the Great Barrier Reef, yet oil
spills due to shipping routes are still a threat to the reef system,
with a total of 282 oil spills between 1987–2002.
Tropical cyclones
Tropical cyclones are a cause of ecological disturbance
to the Great Barrier Reef. The types of damage caused by tropical
cyclones to the Great Barrier Reef is varied, including fragmentation,
sediment plumes, and decreasing salinity following heavy rains (Cyclone Joy).
The patterns of reef damage are similarly 'patchy'. From 1910–1999,
170 cyclones' paths came near or through the Great Barrier Reef. Most
cyclones pass through the Great Barrier Reef within a day. In general, compact corals such as Porites fare better than branching corals under cyclone conditions. The major damage caused by Tropical Cyclone Larry
was to underlying reef structures, and breakage and displacement of
corals, which is overall consistent with previous tropical cyclone
events.
Severe tropical cyclones hit the Queensland coast every 200 to 300 years; however, during the period 1969–1999 most cyclones in the region were very weak – category one or two on the Australian Bureau of Meteorology scale.
On 2 February 2011, Severe Tropical Cyclone Yasi
struck northern Queensland and caused severe damage to a stretch of
hundreds of kilometres within the Great Barrier Reef. The corals could
take a decade to recover fully. Cyclone Yasi had wind speeds of 290
kilometers per hour.