Coral bleaching

Healthy coral
Bleached coral

Coral bleaching is the process when corals become white due to loss of symbiotic algae and photosynthetic pigments. This loss of pigment can be caused by various stressors, such as changes in temperature, light, or nutrients.[1][2] Bleaching occurs when coral polyps expel the zooxanthellae (dinoflagellates that are commonly referred to as algae) that live inside their tissue, causing the coral to turn white.[1] The zooxanthellae are photosynthetic, and as the water temperature rises, they begin to produce reactive oxygen species.[2] This is toxic to the coral, so the coral expels the zooxanthellae.[2] Since the zooxanthellae produce the majority of coral colouration, the coral tissue becomes transparent, revealing the coral skeleton made of calcium carbonate.[2] Most bleached corals appear bright white, but some are blue, yellow, or pink due to pigment proteins in the coral.[2]

The leading cause of coral bleaching is rising ocean temperatures due to climate change caused by anthropogenic activities.[3] A temperature about 1 °C (or 2 °F) above average can cause bleaching.[3]The ocean takes in a large portion of the carbon dioxide (CO2) emissions produced by human activity. Although this uptake helps regulate global warming, it is also changing the chemistry of the ocean in ways never seen before. [4] Ocean acidification (OA) is the decline in seawater pH caused by absorption of anthropogenic carbon dioxide from the atmosphere. This decrease in seawater pH has a significant effect on marine ecosystems.[5]

According to the United Nations Environment Programme, between 2014 and 2016, the longest recorded global bleaching events killed coral on an unprecedented scale. In 2016, bleaching of coral on the Great Barrier Reef killed 29 to 50 percent of the reef's coral.[6][7][8][9] In 2017, the bleaching extended into the central region of the reef.[10][11] The average interval between bleaching events has halved between 1980 and 2016.[12] The world's most bleaching-tolerant corals can be found in the southern Persian/Arabian Gulf. Some of these corals bleach only when water temperatures exceed ~35 °C.[13][14]

Bleached corals continue to live, but they are more vulnerable to disease and starvation.[15][16] Zooxanthellae provide up to 90 percent of the coral's energy,[2] so corals are deprived of nutrients when zooxanthellae are expelled.[17] Some corals recover[1] if conditions return to normal,[15] and some corals can feed themselves.[15] However, the majority of coral without zooxanthellae starve.[15]

Normally, coral polyps live in an endosymbiotic relationship with zooxanthellae.[18] This relationship is crucial for the health of the coral and the reef,[18] which provide shelter for approximately 25% of all marine life.[19] In this relationship, the coral provides the zooxanthellae with shelter. In return, the zooxanthellae provide compounds that give energy to the coral through photosynthesis.[19] This relationship has allowed coral to survive for at least 210 million years in nutrient-poor environments.[19] Coral bleaching is caused by the breakdown of this relationship.[2]

Coral bleaching in ecosystems is a complex dynamic. Coral is able to slowly recover after experiencing bleaching, however, it is a slow process which typically results in re-bleaching.

Process

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Coral and microscopic algae have a symbiotic relationship. When water temperatures get too high, the algae leave the coral tissue and the coral begins to starve.[20]
Climate change will affect coral reef ecosystems, through sea level rise, changes to the frequency and intensity of tropical storms, and altered ocean circulation patterns. When combined, all of these impacts dramatically alter ecosystem function, as well as the goods and services coral reef ecosystems provide.[21]
Zooxanthellae, the microscopic algae that lives inside coral, gives it colour and provides it with food through photosynthesis

The corals that form the great reef ecosystems of tropical seas depend upon a symbiotic relationship with algae-like single-celled flagellate protozoa called zooxanthellae that live within their tissues and give the coral its coloration. The zooxanthellae provide the coral with nutrients through photosynthesis, a crucial factor in the clear and nutrient-poor tropical waters. In exchange, the coral provides the zooxanthellae with the carbon dioxide and ammonium needed for photosynthesis. Negative environmental conditions, such as abnormally warm or cool temperatures, high light, and even some microbial diseases, can lead to the breakdown of the coral/zooxanthellae symbiosis.[22] To ensure short-term survival, the coral-polyp then consumes or expels the zooxanthellae. This leads to a lighter or completely white appearance, hence the term "bleached".[23] Under mild stress conditions, some corals may appear bright blue, pink, purple, or yellow instead of white, due to the continued or increased presence of the coral cells' intrinsic pigment molecules, a phenomenon known as "colourful bleaching".[24] As the zooxanthellae provide up to 90 percent of the coral's energy needs through products of photosynthesis, after expelling, the coral may begin to starve.[2]

Coral can survive short-term disturbances, but if the conditions that lead to the expulsion of the zooxanthellae persist, the coral's chances of survival diminish. In order to recover from bleaching, the zooxanthellae have to re-enter the tissues of the coral polyps and restart photosynthesis to sustain the coral as a whole and the ecosystem that depends on it.[25] If the coral polyps die of starvation after bleaching, they will decay. The hard coral species will then leave behind their calcium carbonate skeletons, which will be taken over by algae, effectively blocking coral regrowth. Eventually, the coral skeletons will erode, causing the reef structure to collapse.[citation needed]

Triggers

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Healthy coral at left, and bleached, but still living, coral at right

Coral bleaching may be caused by a number of factors. While localized triggers lead to localized bleaching, the large-scale coral bleaching events of recent years have been triggered by global warming. Under the increased carbon dioxide concentration expected in the 21st century, corals are expected to become increasingly rare on reef systems.[26] Coral reefs located in warm, shallow water with low water flow have been more affected than reefs located in areas with higher water flow.[27]Marine heatwaves caused by the El Nino Southern Oscillation have been found to be one of the main causes of widespread coral bleaching and consequent coral mortality.[28]

List of triggers

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A colourful bleaching event photographed in Palawan, Philippines, in 2010. The colours derive from high concentrations of sun-screening pigments produced by the coral host.[29]
Bleached coral—partially overgrown with algae
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Extreme bleaching events are directly linked with climate-induced phenomena that increase ocean temperature, such as El Niño-Southern Oscillation (ENSO).[48] The warming ocean surface waters can lead to bleaching of corals which can cause serious damage and coral death. The IPCC Sixth Assessment Report in 2022 found that: "Since the early 1980s, the frequency and severity of mass coral bleaching events have increased sharply worldwide".[49]: 416  Coral reefs, as well as other shelf-sea ecosystems, such as rocky shores, kelp forests, seagrasses, and mangroves, have recently undergone mass mortalities from marine heatwaves.[49]: 381  It is expected that many coral reefs will "undergo irreversible phase shifts due to marine heatwaves with global warming levels >1.5°C".[49]: 382 

This problem was already identified in 2007 by the Intergovernmental Panel on Climate Change (IPCC) as the greatest threat to the world's reef systems.[50][51]

The Great Barrier Reef experienced its first major bleaching event in 1998. Since then, bleaching events have increased in frequency, with three events occurring in the years 2016–2020.[52] Bleaching is predicted to occur three times a decade on the Great Barrier Reef if warming is kept to 1.5 °C, increasing every other year to 2 °C.[53]

With the increase of coral bleaching events worldwide, National Geographic noted in 2017, "In the past three years, 25 reefs—which comprise three-fourths of the world's reef systems—experienced severe bleaching events in what scientists concluded was the worst-ever sequence of bleachings to date."[54]

In a study conducted on the Hawaiian mushroom coral Lobactis scutaria, researchers discovered that higher temperatures and elevated levels of photosynthetically active radiation (PAR) had a detrimental impact on its reproductive physiology. The purpose of this study was to investigate the survival of reef-building corals in their natural habitat, as coral reproduction is being hindered by the effects of climate change.[55]

Mass bleaching events

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Bleached Acropora coral with normal coral in the background

Elevated sea water temperatures are the main cause of mass bleaching events.[56] Sixty major episodes of coral bleaching have occurred between 1979 and 1990,[57][58] with the associated coral mortality affecting reefs in every part of the world. In 2016, the longest coral bleaching event was recorded.[59] The longest and most destructive coral bleaching event was because of the El Niño that occurred from 2014 to 2017.[60] During this time, over 70 percent of the coral reefs around the world have become damaged.[60]

Factors that influence the outcome of a bleaching event include stress-resistance which reduces bleaching, tolerance to the absence of zooxanthellae, and how quickly new coral grows to replace the dead. Due to the patchy nature of bleaching, local climatic conditions such as shade or a stream of cooler water can reduce bleaching incidence.[61] Coral and zooxanthellae health and genetics also influence bleaching.[61]

Large coral colonies such as Porites are able to withstand extreme temperature shocks, while fragile branching corals such Acropora are far more susceptible to stress following a temperature change.[62] Corals consistently exposed to low-stress levels may be more resistant to bleaching.[63][64]

Scientists believe that the oldest known bleaching was that of the Late Devonian (Frasnian/Famennian), also triggered by the rise of sea surface temperatures. It resulted in the demise of the largest coral reefs in the Earth's history.[65][66]

According to Clive Wilkinson of Global Coral Reef Monitoring Network of Townsville, Australia, in 1998 the mass bleaching event that occurred in the Indian Ocean region was due to the rising of sea temperatures by 2 °C coupled with the strong El Niño event in 1997–1998.[67]

In April 2024 a 4th global coral bleaching event was confirmed by NOAA[68][69][70] The share of affected coral reefs worldwide by each of the four bleaching events has been estimated to be 20%, 35%, 56% and 54%.[71][72]

Preceding this, the second major coral bleaching crisis of this decade began in February 2023, affecting reefs across 54 nations in all major ocean basins. This event has led to severe damage, with coral mortalities reaching up to 93% in areas like the Pacific coast near Mexico. The economic implications are profound, as coral reefs contribute approximately $2.7 trillion annually to the global economy, including $36 billion from tourism alone. Although a forthcoming shift to a La Niña phase may offer some relief, regions such as Florida have already experienced complete die-offs in some reefs, where temperatures have risen to 101°F (38.3°C). Moreover, the Great Barrier Reef is undergoing its fifth extensive bleaching event since 2016, underscoring the persistent and serious risks these vital ecosystems face.[73]

Impacts

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Two images of the Great Barrier Reef showing that the warmest water (top picture) coincides with the coral reefs (lower picture), setting up conditions that can cause coral bleaching.
Bleaching observed at the Great Barrier Reef resulting in the deprivation of habitat for numerous other marine species.

Coral bleaching events and the subsequent loss of coral coverage often result in the decline of fish diversity. The loss of diversity and abundance in herbivorous fish particularly affect coral reef ecosystems.[74] As mass bleaching events occur more frequently, fish populations will continue to homogenize. Smaller and more specialized fish species that fill particular ecological niches that are crucial for coral health are replaced by more generalized species. The loss of specialization likely contributes to the loss of resilience in coral reef ecosystems after bleaching events.[75]

Economic and political impact

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According to Brian Skoloff of The Christian Science Monitor, "If the reefs vanished, experts say, hunger, poverty and political instability could ensue."[76] Since countless sea life depend on the reefs for shelter and protection from predators, the extinction of the reefs would ultimately create a domino effect that would trickle down to the many human societies that depend on those fish for food and livelihood. There has been a 44% decline over the last 20 years in the Florida Keys and up to 80% in the Caribbean alone.[77]

Coral reefs provide various ecosystem services, one of which is being a natural fishery, as many frequently consumed commercial fish spawn or live out their juvenile lives in coral reefs around the tropics.[78][79][80] Thus, reefs are a popular fishing site and are an important source of income for fishers, especially small, local fisheries.[80] As coral reef habitat decreases due to bleaching, reef associated fish populations also decrease, which affects fishing opportunities.[78] A model from one study by Speers et al. calculated direct losses to fisheries from decreased coral cover to be around $49–69 billion, if human societies continue to emit high levels of greenhouse gases.[78] But, these losses could be reduced for a consumer surplus benefit of about $14–20 billion, if societies chose to emit a lower level of greenhouse gases instead.[78] These economic losses also have important political implications, as they fall disproportionately on developing countries where the reefs are located, namely in Southeast Asia and around the Indian Ocean.[78][80][81] It would cost more for countries in these areas to respond to coral reef loss as they would need to turn to different sources of income and food, in addition to losing other ecosystem services such as ecotourism.[79][81] A study completed by Chen et al. suggested that the commercial value of reefs decreases by almost 4% every time coral cover decreases by 1% because of losses in ecotourism and other potential outdoor recreational activities.[79]

Coral reefs also act as a protective barrier for coastlines by reducing wave impact, which lowers the damage from storms, erosions, and flooding. Countries that lose this natural protection will lose more money because of the increased susceptibility of storms. This indirect cost, combined with the lost revenue from tourism, will result in enormous economic effects.[23]

Monitoring coral bleaching and reef sea surface temperature

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The US National Oceanic and Atmospheric Administration (NOAA) monitors for bleaching "hot spots", areas where sea surface temperature rises 1 °C or more above the long-term monthly average. The "hot spots" are the locations in which thermal stress is measured, and with the development of Degree Heating Week (DHW), the coral reef's thermal stress is monitored.[82][83] Global coral bleaching is being detected earlier due to the satellite remote sensing of the rise of sea temperatures.[82][84] It is necessary to monitor the high temperatures because coral bleaching events are affecting coral reef reproduction and normal growth capacity, as well as it weakening corals, eventually leading to their mortality.[84] This system detected the worldwide 1998 bleaching event,[85][86] that corresponded to the 1997–98 El Niño event.[87] Currently, 190 reef sites around the globe are monitored by the NOAA, and send alerts to research scientists and reef managers via the NOAA Coral Reef Watch (CRW) website.[88] By monitoring the warming of sea temperatures, the early warnings of coral bleaching alert reef managers to prepare for and draw awareness to future bleaching events.[88] The first mass global bleaching events were recorded in 1998 and 2010, which was when the El Niño caused the ocean temperatures to rise and worsened the corals living conditions.[60] The 2014–2017 El Niño was recorded to be the longest and most damaging to the corals, which harmed over 70% of our coral reefs.[60] Over two-thirds of the Great Barrier Reef have been reported to be bleached or dead.[60]

To accurately monitoring the extent and evolution of bleaching events, scientist are using underwater photogrammetric techniques to create accurate orthophoto of coral reefs transects and AI-assisted image segmentation with open source tools like TagLab to identify from these photos the health status of the corals.[89]

A visual depicting the process of atmospheric carbon dioxide contributing to ocean acidification. [1]

Changes in ocean chemistry

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Increasing ocean acidification due to rises in carbon dioxide levels exacerbates the bleaching effects of thermal stress. Acidification affects the corals' ability to create calcareous skeletons, essential to their survival.[90][91] This is because ocean acidification decreases the amount of carbonate ion in the water, making it more difficult for corals to absorb the calcium carbonate they need for the skeleton. As a result, the resilience of reefs goes down, while it becomes easier for them to erode and dissolve.[92] In addition, the increase in CO2 allows herbivore overfishing and nutrification to change coral-dominated ecosystems to algal-dominated ecosystems.[93] A recent study from the Atkinson Center for a Sustainable Future found that with the combination of acidification and temperature rises, the levels of CO2 could become too high for coral to survive in as little as 50 years.[90]

Coral bleaching due to photoinhibition of zooxanthellae

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A major coral bleaching event took place on this part of the Great Barrier Reef in Australia.

Zooxanthellae are a type of dinoflagellate that live within the cytoplasm of many marine invertebrates.[94] Members of the phylum Dinoflagellata, they are round microalgae that share a symbiotic relationship with their host. They are also part of the genus Symbiodinium and Kingdom Alveolata. These organisms are phytoplankton and therefore photosynthesize. The host organism harnesses the products of photosynthesis, i.e. oxygen, sugar, etc., and in exchange, the zooxanthellae are offered housing and protection, as well as carbon dioxide, phosphates, and other essential inorganic compounds that help them to survive and thrive. Zooxanthellae share 95% of the products of photosynthesis with their host coral.[95] According to a study done by D.J. Smith et al., photoinhibition is a likely factor in coral bleaching.[96] It also suggests that the hydrogen peroxide produced in zooxanthealle plays a role in signaling themselves to flee the corals. Photo-inhibition of Zooxanthellae can be caused by exposure to UV filters found in personal care products.[97] In a study done by Zhong et al., Oxybenzone (BP-3) had the most negative effects on zooxanthellae health. The combination of temperature increase and presence of UV filters in the ocean has further decreased zooxanthellae health.[98] The combination of UV filters and higher temperatures led to an additive effect on photo-inhibition and overall stress on coral species.[98]

Infectious disease

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Following bleaching events, there has been a rise in the global disease outbreak among coral populations. This is due to the weakened state of the corals that makes them susceptible to infection caused by disease-carrying pathogens.[28] Infectious bacteria of the species Vibrio shiloi are the bleaching agent of Oculina patagonica in the Mediterranean Sea, causing this effect by attacking the zooxanthellae.[99][100][101] V. shiloi is infectious only during warm periods. Elevated temperature increases the virulence of V. shiloi, which then become able to adhere to a beta-galactoside-containing receptor in the surface mucus of the host coral.[100][102] V. shiloi then penetrates the coral's epidermis, multiplies, and produces both heat-stable and heat-sensitive toxins, which affect zooxanthellae by inhibiting photosynthesis and causing lysis.[citation needed]

During the summer of 2003, coral reefs in the Mediterranean Sea appeared to gain resistance to the pathogen, and further infection was not observed.[103] The main hypothesis for the emerged resistance is the presence of symbiotic communities of protective bacteria living in the corals. The bacterial species capable of lysing V. shiloi had not been identified as of 2011.[citation needed]

By region

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Pacific Ocean

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Great Barrier Reef

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The Great Barrier Reef along the coast of Australia experienced bleaching events in 1980, 1982, 1992, 1994, 1998, 2002, 2006, 2016, 2017 and 2022.[104][105] Some locations suffered severe damage, with up to 90% mortality.[106] The most widespread and intense events occurred in the summers of 1998 and 2002, with 42% and 54%, respectively, of reefs bleached to some extent, and 18% strongly bleached.[107][108] However, coral losses on the reef between 1995 and 2009 were largely offset by growth of new corals.[109] An overall analysis of coral loss found that coral populations on the Great Barrier Reef had declined by 50.7% from 1985 to 2012, but with only about 10% of that decline attributable to bleaching, and the remaining 90% caused about equally by tropical cyclones and by predation by crown-of-thorns starfishes.[110] A global mass coral bleaching has been occurring since 2014 because of the highest recorded temperatures plaguing oceans. These temperatures have caused the most severe and widespread coral bleaching ever recorded in the Great Barrier reef. The most severe bleaching in 2016 occurred near Port Douglas. In late November 2016, surveys of 62 reefs showed that long term heat stress from climate change caused a 29% loss of shallow water coral. The highest coral death and reef habitat loss was inshore and mid-shelf reefs around Cape Grenville and Princess Charlotte Bay.[111] The IPCC's moderate warming scenarios (B1 to A1T, 2 °C by 2100, IPCC, 2007, Table SPM.3, p. 13[112]) forecast that corals on the Great Barrier Reef are very likely to regularly experience summer temperatures high enough to induce bleaching.[107]

Hawaii

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In 1996, Hawaii's first major coral bleaching occurred in Kaneohe Bay, followed by major bleaching events in the Northwest islands in 2002 and 2004.[113] In 2014, biologists from the University of Queensland observed the first mass bleaching event, and attributed it to The Blob.[114] In 2014 and 2015, a survey in Hanauma Bay Nature Preserve on Oahu found 47% of the corals suffering from coral bleaching and close to 10% of the corals dying.[115] In 2014 and 2015, 56% of the coral reefs of the big island were affected by coral bleaching events. During the same period, 44% of the corals on west Maui were effected.[116] On 24 January 2019, scientists with The Nature Conservancy found that the reefs had begun to stabilize nearly 4 years after the last bleaching event.[117] According to the Division of Aquatic Resources (DAR), there was still a considerable amount of bleaching in 2019. On Oahu and Maui, up to 50% of the coral reefs were bleached. On the big island, roughly 40% of corals experienced bleaching in the Kona coast area. The DAR stated that the recent bleaching events have not been as bad as the 2014–2015 events.[118] In 2020, the National Oceanic and Atmospheric Administration (NOAA) released the first-ever nationwide coral reef status report. The report stated that the northwestern and main Hawaiian islands were in "fair" shape, meaning the corals have been moderately impacted.[119]

  • Hawaiian Sunscreen Policy In May 2018, Hawaii passed the bill "SB-2571", banning the vending of sunscreen containing chemicals deemed conducive of coral bleaching on the island's local reefs. The bill was signed in by David Ige, of the Democratic party.[120]  A chemical deemed toxic in SB-2571 is the 'oxybenzone' (also banned; octinoxate), a chemical that becomes toxic to coral when exposed to sunlight. Up to one-tenth of the approximated 14,000 tons of sunscreen polluting coral reef areas contains oxybenzone, putting almost half of all coral reefs in danger of being exposed. Coral reefs show increased rates of bleaching in both controlled and natural environments when exposed to high levels of oxybenzone, found in many commercial sunscreen products.[121] Another study showed that over time, the presence of oxybenzone in water will decrease a reef's strength to face other bleaching events such as increasing water temperatures.[122] SB-2571 banned all sunscreen products with the exception of prescription products. Hawaii is the first U.S. state to introduce this type of ban, which went into effect in January 2021.[120]

Jarvis Island

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Eight severe and two moderate bleaching events occurred between 1960 and 2016 in the coral community in Jarvis Island, with the 2015–16 bleaching displaying the unprecedented severity in the record.[123]

Japan

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About 94% of the corals on Japan's Iriomote Island in the Ryukyu Islands bleached during a significant coral bleaching event that occurred in 2016.[124] Prior to this event, the region typically experienced multiple typhoons during July and August. However, during this particular event, no typhoon was detected until September, suggesting a prolonged period of high seawater temperatures.[125][124]According to the 2017 Japanese government report, almost 75% of Japan's largest coral reef in Okinawa has died from bleaching.[126]

Indian Ocean

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Coral reef provinces have been permanently damaged by warm sea temperatures, most severely in the Indian Ocean. Up to 90% of coral cover has been lost in the Maldives, Sri Lanka, Kenya and Tanzania and in the Seychelles during the massive 1997–98 bleaching event. The Indian Ocean in 1998 reported 20% of its coral had died and 80% was bleached.[3] The shallow tropical areas of the Indian Ocean are already experiencing what are predicted to be worldwide ocean conditions in the future. Coral that has survived in the shallow areas of the Indian Ocean may be proper candidates for coral restoration efforts in other areas of the world because they are able to survive the extreme conditions of the ocean.[127]

Maldives

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The Maldives has over 20,000 km2 of reefs, of which more than 60% of the coral has suffered from bleaching in 2016.[128][129][130]Moreover, the Maldivian coral reef faces risks from the growing tourism industry and coastal construction,[131] as well as land reclamation projects,[132] alongside natural challenges such as diseases.[133][134]

Thailand

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Coral reef ecosystems are a notable feature of the western shoreline of the Gulf of Thailand. In 1998 and 2010, there were bleaching events in Thailand; the effects of both occurrences varied among coral species, with some exhibiting more resilience to the 2010 bleaching. In contrast to 1998, there was a more severe bleaching event in 2010.[135] Thailand experienced a severe mass bleaching in 2010 which affected 70% of the coral in the Andaman Sea. Between 30% and 95% of the bleached coral died.[136]

Indonesia

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Acropora corals were dominant coral species of Indonesian reef system however they are extremely vulnerable to external stressors. A study was conducted to study effect of mass bleaching event in 2010 on Acropora. Post bleaching recovery is influenced by severity and frequency of the bleaching event.[137] Research indicates that frequent moderate disturbances tend to affect Porites, while less frequent but stronger disturbances primarily impact Acropora. Consequently, Acropora demonstrates rapid regrowth in such instances.[138]

In 2017, there was a study done on two islands in Indonesia to see how their coral cover was. One of the places was the Melinjo Islands and the other was the Saktu Islands. On Saktu Island, the lifeform conditions were categorized as bad, with an average coral cover of 22.3%. In the Melinjo Islands, the lifeform conditions were categorized as bad, with an average coral cover of 22.2%.

Atlantic Ocean

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United States

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During the 2005 mass bleaching event in Florida, the bleaching patterns varied among species. Colpophyllia natans and Diploria strigosa were particularly susceptible to thermal stress, whereas Stephanocoenia intersepta exhibited greater tolerance. Moreover, it was noted that larger coral colonies experienced more bleaching compared to smaller ones. The prediction suggests that mass bleaching events are likely to affect larger coral colonies even within the same community.[139]

In South Florida, a 2016 survey of large corals from Key Biscayne to Fort Lauderdale found that about 66% of the corals were dead or reduced to less than half of their live tissue.[140]

Belize

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The first recorded mass bleaching event that took place in the Belize Barrier Reef was in 1998, where sea level temperatures reached up to 31.5 °C (88.7 °F) from 10 August to 14 October. For a few days, Hurricane Mitch brought in stormy weather on 27 October but only reduced temperatures by 1 degree or less. During this time period, mass bleaching in the fore-reef and lagoon occurred. While some fore reef colonies suffered some damage, coral mortality in the lagoon was catastrophic.[citation needed]

The most prevalent coral in the reefs Belize in 1998 was the lettuce coral, Agaricia tenuifolia. On 22 and 23 October, surveys were conducted at two sites and the findings were devastating. Virtually all the living coral was bleached white and their skeletons indicated that they had died recently. At the lagoon floor, complete bleaching was evident among A. tenuifolia. Furthermore, surveys done in 1999 and 2000 showed a near total mortality of A. tenuifolia at all depths. Similar patterns occurred in other coral species as well. Measurements on water turbidity suggest that these mortalities were attributed to rising water temperatures rather than solar radiation.[citation needed]

Caribbean

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Hard coral cover on reefs in the Caribbean have declined by an estimated 80%, from an average of 50% cover in the 1970s to only about 10% cover in the early 2000s.[141] A 2013 study to follow up on a mass bleaching event in Tobago from 2010 showed that after only one year, the majority of the dominant species declined by about 62% while coral abundance declined by about 50%. However, between 2011 and 2013, coral cover increased for 10 of the 26 dominant species but declined for 5 other populations.[142]

Other areas

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Coral in the south Red Sea does not bleach despite summer water temperatures up to 34 °C (93 °F).[63][143] Coral bleaching in the Red Sea is more common in the northern section of the reefs; the southern part of the reef has been plagued by coral-eating starfish, dynamite fishing and human impacts on the environment. In 1988, there was a massive bleaching event that affected the reefs in Saudi Arabia and Sudan, though the southern reefs were more resilient and it affected them very little. Previously, it was thought that the northern reef suffers more from coral bleaching and shows a fast turnover of coral, while the southern reef was thought to not suffer from bleaching as harshly and show more consistency. However, new research shows that where the southern reef should be bigger and healthier than the northern, it was not. This is believed to be because of major disturbances in recent history from bleaching events, and coral-eating starfish.[144] In 2010, coral bleaching occurred in Saudi Arabia and Sudan, where the temperature rose 10 to 11 degrees. Certain taxa experienced 80% to 100% of their colonies bleaching, while some showed on average 20% of that taxa bleaching.[145]

Coral adaptation

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This schematic shows how bleaching can trigger the production of sun-screening pigments that are responsible for the bright colours observed during some bleaching events. In case of a mild or short episode of stress, the protective pigments may help the algal symbionts return to the coral after the stress episode has ended, helping the coral recover and survive the bleaching event.[24]

In recent times, climate change has been linked to a notable increase in coral mortality. Moreover, mounting evidence suggests that bacteria associated with corals contribute to their ability to withstand thermal stress. Attempts have been undertaken to enhance coral resilience in the face of bleaching incidents.[146] Since corals serve as the fundamental components of coral reefs, their decline significantly affects the endurance and composition of reefs[147] directly affecting the reef-dwelling organisms.[146]

In 2010, researchers at Penn State discovered corals that were thriving while using an unusual species of symbiotic algae in the warm waters of the Andaman Sea in the Indian Ocean. Normal zooxanthellae cannot withstand temperatures as high as was there, so this finding was unexpected. This gives researchers hope that with rising temperatures due to global warming, coral reefs will develop tolerance for different species of symbiotic algae that are resistant to high temperature, and can live within the reefs.[148][149] In 2010, researchers from Stanford University also found corals around the Samoan Islands that experience a drastic temperature increase for about four hours a day during low tide. The corals do not bleach or die regardless of the high heat increase. Studies showed that the corals off the coast of Ofu Island near America Samoa have become trained to withstand the high temperatures. Researchers are now asking a new question: can we condition corals, that are not from this area, in this manner and slowly introduce them to higher temperatures for short periods of time and make them more resilient against rising ocean temperatures.[150]

Certain mild bleaching events can cause coral to produce high concentrations of sun-screening pigments in order to shield themselves from further stress.[24] Some of the pigments produced have pink, blue or purple hues, while others are strongly fluorescent. Production of these pigments by shallow-water corals is stimulated by blue light.[151] When corals bleach, blue light inside the coral tissue increases greatly because it is no longer being absorbed by the photosynthetic pigments found inside the symbiotic algae, and is instead reflected by the white coral skeleton.[152] This causes an increase in the production of the sun-screening pigments, making the bleached corals appear very colourful instead of white – a phenomenon sometimes called 'colourful coral bleaching'.[24]

Increased sea surface temperature leads to the thinning of the epidermis and apoptosis of gastrodermis cells in the host coral.[153] The reduction in apoptosis and gastrodermis is seen via epithelium, leading to up to a 50% loss in the concentration of symbionts over a short period of time.[154] Under conditions of high temperature or increased light exposure, the coral will exhibit a stress response that includes producing reactive oxygen species, the accumulation of this if not removed by antioxidant systems will lead to the death of the coral.[153] Studies testing the structures of coral under heat stressed environments show that the thickness of the coral itself greatly decreases under heat stress compared to the control.[154] With the death of the zooxanthellae in the heat stressed events, the coral must find new sources to gather fixed carbon to generate energy, species of coral that can increase their carnivorous tendencies have been found to have an increased likelihood of recovering from bleaching events.[155][153]

After the zooxanthellae leaves the coral, the coral structures are often taken over by algae due to their ability to outcompete the zooxanthella since they need less resources to survive.[156] There is little evidence of competition between zooxanthellae and algae, but in the absence of zooxanthellae the algae thrives on the coral structures.[156] Once algae takes over and the coral can no longer sustain itself, the structures often begin to decay due to ocean acidification.[157][156] Ocean acidification is the process by which carbon dioxide is absorbed into the ocean, this decreases the amounts of carbonate ions in the ocean, a necessary ion corals use to build their skeletons.[157] Corals go through processes of decalcifying and calcifying during different times of the day and year due to temperature fluctuations.[158] Under current IPCC emission pathway scenarios, corals tend to disintegrate, and the winter months with cooler temperatures will not serve ample time for the corals to reform.[158]

Artificial assistance

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In 2020, scientists reported to have evolved 10 clonal strains of a common coral microalgal endosymbionts at elevated temperatures for 4 years, increasing their thermal tolerance for climate resilience. Three of the strains increased the corals' bleaching tolerance after reintroduction into coral host larvae. Their strains and findings may potentially be relevant for the adaptation to and mitigation of climate change and further tests of algal strains in adult colonies across a range of coral species are planned.[159][160][161]

In 2021, researchers demonstrated that probiotics can help coral reefs mitigate heat stress, indicating that such could make them more resilient to climate change and mitigate coral bleaching.[162][163]

Recovery and macroalgal regime shifts

[edit]

After corals experience a bleaching event to increased temperature stress some reefs are able to return to their original, pre-bleaching state.[164][165] Reefs either recover from bleaching, where they are recolonized by zooxanthellae, or they experience a regime shift, where previously flourishing coral reefs are taken over by thick layers of macroalgae.[166] This inhibits further coral growth because the algae produces antifouling compounds to deter settlement and competes with corals for space and light. As a result, macroalgae forms stable communities that make it difficult for corals to grow again. Reefs will then be more susceptible to other issues, such as declining water quality and removal of herbivore fish, because coral growth is weaker.[26] Discovering what causes reefs to be resilient or recover from bleaching events is of primary importance because it helps inform conservation efforts and protect coral more effectively.

A primary subject of research regarding coral recovery pertains to the idea of super-corals, otherwise referred to as the corals that live and thrive in naturally warmer and more acidic regions and bodies of water. When transplanted to endangered or bleached reefs, their resilience and irradiance can equip the algae to live among the bleached corals. As Emma Camp, a National Geographic Explorer, marine bio-geochemist and an ambassador for Biodiversity for the charity IBEX Earth,[167] suggests, the super-corals could have the capability to help with the damaged reefs long-term.[citation needed] While it can take 10 to 15 years to restore damaged and bleached coral reefs,[168] the super-corals could have lasting impacts despite climate change as the oceans rise in temperature and gain more acidity. Bolstered by the research of Ruth Gates, Camp has looked into lower oxygen levels and the extreme, unexpected habitats that reefs can be found in across the globe.[citation needed]

Corals have shown to be resilient to short-term disturbances. Recovery has been shown in after storm disturbance and crown of thorns starfish invasions.[164] Fish species tend to fare better following reef disturbance than coral species as corals show limited recovery and reef fish assemblages have shown little change as a result of short-term disturbances.[164] In contrast, fish assemblages in reefs that experience bleaching exhibit potentially damaging changes. One study by Bellwood et al. notes that while species richness, diversity, and abundance did not change, fish assemblages contained more generalist species and less coral dependent species.[164] Responses to coral bleaching are diverse between reef fish species, based on what resources are affected.[169] Rising sea temperature and coral bleaching do not directly impact adult fish mortality, but there are many indirect consequences of both.[169] Coral-associated fish populations tend to be in decline due to habitat loss; however, some herbivorous fish populations have seen a drastic increase due to the increase of algae colonization on dead coral.[169] Studies note that better methods are needed to measure the effects of disturbance on the resilience of corals.[164][170]

lemon damselfish
The lemon damselfish (Pomacentrus moluccensis) is a coral-associated species that has been shown to decline dramatically following coral bleaching.[171]

Until recently, the factors mediating the recovery of coral reefs from bleaching were not well studied. Research by Graham et al. (2015) studied 21 reefs around Seychelles in the Indo-Pacific in order to document the long-term effects of coral bleaching.[165] After the loss of more than 90% of corals due to bleaching in 1998 around 50% of the reefs recovered and roughly 40% of the reefs experienced regime shifts to macroalgae dominated compositions.[165] After an assessment of factors influencing the probability of recovery, the study identified five major factors: density of juvenile corals, initial structural complexity, water depth, biomass of herbivorous fishes, and nutrient conditions on the reef.[165] Overall, resilience was seen most in coral reef systems that were structurally complex and in deeper water.[165]

The ecological roles and functional groups of species also play a role in the recovery of regime shifting potential in reef systems. Coral reefs are affected by bioeroding, scraping, and grazing fish species. Bioeroding species remove dead corals, scraping species remove algae and sediment to further future growth, grazing species remove algae.[172] The presence of each type of species can influence the ability for normal levels of coral recruitment which is an important part of coral recovery.[172] Lowered numbers of grazing species after coral bleaching in the Caribbean has been likened to sea-urchin-dominated systems which do not undergo regime shifts to fleshy macroalgae dominated conditions.[166]

There is always the possibility of unobservable changes, or cryptic losses or resilience, in a coral community's ability to perform ecological processes.[164][172] These cryptic losses can result in unforeseen regime changes or ecological flips.[164] More detailed methods for determining the health of coral reefs that take into account long-term changes to the coral ecosystems and better-informed conservation policies are necessary to protect coral reefs in the years to come.[164][165][170][172]

Rebuilding coral reefs

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Research is being done to help slow down the mortality rate of corals. Worldwide projects are being completed to help replenish and restore the coral reefs. Current coral restoration efforts include microfragmentation, coral farming, and relocation. The population of corals is rapidly declining, so scientists are doing experiments in coral growth and research tanks to help replenish their population.[60] These research tanks mimic the coral reefs natural environment in the ocean.[60] They are growing corals in these tanks to use for their experiments, so no more corals are being harmed or taken from the ocean.[60] They are also transplanting the successfully grown corals from the research tanks and putting them into the areas of the ocean where the reefs are dying out.[60] An experiment is being done in some coral growth and research tanks by Ruth Gates and Madelaine Van Oppen.[60] They are trying to make "super corals" that can withstand some of the environmental factors that the corals are currently dying from.[60] Van Oppen is also working on developing a type of algae that will have a symbiotic relationship with corals and can withstand water temperature fluctuations for long periods of time.[60] This project may be helping to replenish our reefs, but the growing process of corals in research tanks is very time-consuming.[60] It can take at least 10 years for the corals to fully grow and mature enough to where they will be able to breed.[60] Following Ruth Gates' death in October 2018, her team at the Gates Coral Lab at the Hawai'i Institute of Marine Biology continues her research on restoration efforts. Continuing research and restoration efforts at the Gates Coral Lab focuses on the effects of beneficial mutations, genetic variation, and relocation via human assistance on the resilience of coral reefs.[173][174] As of 2019, the Gates Coral Lab team determined that large-scale restoration techniques would not be effective; localized efforts to restore coral reefs on an individual basis are tested to be more realistic and effective while research is conducted to determine the best ways to combat coral destruction on a mass scale.[175]

Marine Protected Areas

[edit]
Example of a Marine Protected Area sign on Rarotonga Island in Hawaii.

Marine Protected Areas (MPAs) are sectioned-off areas of the ocean designated for protection from human activities such as fishing and un-managed tourism. According to NOAA, MPAs currently occupy 26% of U.S. waters.[176] MPAs have been documented to improve and prevent the effects of coral bleaching in the United States. In 2018, research by coral scientists in the Caribbean concluded that areas of the ocean managed/protected by government had improved conditions that coral reefs were able to flourish in. MPAs defend ecosystems from overfishing, which allows multiple species of fish to thrive and deplete seaweed density, making it easier for young coral organisms to grow and increase in population/strength.[177] From this study, a 62% increase in coral populations was recorded due to the protection of an MPA. Higher populations of young coral increase the longevity of a reef, as well as its ability to recover from extreme bleaching events.[178]

Local impacts and solutions to coral bleaching

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There are a number of stressors locally impacting coral bleaching, including sedimentation, continual support of urban development, land change, increased tourism, untreated sewage, and pollution. To illustrate, increased tourism is good for a country, however, it also comes with costs. An example is the Dominican Republic which relies heavily on its coral reefs to attract tourists resulting in increased structural damage, over fishing, nutrient pollution, and an increase in diseases to the coral reefs. As a result, the Dominican Republic has implemented a sustainable management plan for its land and marine areas to regulate ecotourism.[179]

Economic value of coral reefs

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Coral reefs provide shelter to an estimated quarter of all ocean species.[180] Experts estimate that coral reef services are worth up to $1.2 million per hectare which translates to an average of $172 billion per year.[181] The benefits of coral reefs include providing physical structures such as coastal shoreline protection, biotic services within and between ecosystems, biogeochemical services such as maintaining nitrogen levels in the ocean, climate records, and recreational and commercial (tourism) services.[182] Coral reefs are one of the best marine ecosystems to use to as a food source.[46] The coral reefs are also the perfect habitat for rare and economically important species of tropical fish, as they provide the perfect area for fish to breed and create nurseries in.[46] If the populations of the fish and corals in the reef are high, then we can use the area as a place to gather food and things with medicinal properties, creating jobs for people who can collect these specimens.[46] The reefs also have cultural importance in specific regions around the world.[46]

Cost benefit analysis of reducing loss of coral reefs

[edit]

Coral restoration is a common strategy used to combat the problems brought on by global warming; however, while ecological factors are primarily taken into account, efforts need also be made to address social, economic, and governance factors.[183]The rapid growth in advocacy and implementation of intervention measures, such coral restoration, are a result of the intensifying effects of climate change and human pressure on coral reefs. The goal is to preserve the remaining reefs and the functions that they provide to the reef ecosystem.[184]

The Paris Agreement has offered reasons for hope by pledging nations worldwide to maintain the rise in global average temperatures significantly below 2°C compared to pre-industrial levels, with concerted endeavors aimed at capping the increase at 1.5°C.[185] In 2010, the Convention on Biological Diversity's (CBD) Strategic Plan for Biodiversity 2011–2020 created twenty distinct targets for sustainable development for post-2015. Target 10 indicates the goal of minimizing "anthropogenic pressures on coral reefs".[186] Two programs were looked at, one that reduces coral reef loss by 50% that has a capital cost of $684 million and a recurrent cost of $81 million. The other program reduces coral reef loss by 80 percent and has a capital cost of $1.036 billion with recurring costs of $130 million. CBD acknowledges that they may be underestimating the costs and resources needed to achieve this target due to lack of relevant data but nonetheless, the cost–benefit analysis shows that the benefits outweigh the costs by a great enough amount for both programs (benefit cost ratio of 95.3 and 98.5) that "there is ample scope to increase outlays on coral protection and still achieve a benefit to cost ratio that is well over one".[186]

See also

[edit]

References

[edit]
  1. ^ a b c US Department of Commerce, National Oceanic and Atmospheric Administration. "What is coral bleaching?". oceanservice.noaa.gov. Retrieved 13 September 2021.
  2. ^ a b c d e f g h "CORAL BLEACHING – A REVIEW OF THE CAUSES AND CONSEQUENCES" (PDF). Archived (PDF) from the original on 29 December 2009.
  3. ^ a b c "Corals and Coral Reefs". Smithsonian Ocean. 30 April 2018. Archived from the original on 18 October 2020. Retrieved 15 August 2019.
  4. ^ Turley, Carol (September 2011). "Ocean Acidification. A National Strategy to Meet the Challenges of a Changing Ocean: Book Reviews". Fish and Fisheries. 12 (3): 352–354. doi:10.1111/j.1467-2979.2011.00415.x.
  5. ^ Hall-Spencer, Jason M.; Thorndyke, Mike; Dupont, Sam (October 2015). "Impact of Ocean Acidification on Marine Organisms—Unifying Principles and New Paradigms". Water. 7 (10): 5592–5598. doi:10.3390/w7105592. hdl:10026.1/3897. ISSN 2073-4441.
  6. ^ "Coral bleaching on Great Barrier Reef worse than expected, surveys show". The Guardian. 29 May 2017. Archived from the original on 29 May 2017. Retrieved 29 May 2017.
  7. ^ Gilmour, J. P.; Smith, L. D.; Heyward, A. J.; Baird, A. H.; Pratchett, M. S. (2013). "Recovery of an Isolated Coral Reef System Following Severe Disturbance". Science. 340 (6128): 69–71. Bibcode:2013Sci...340...69G. doi:10.1126/science.1232310. PMID 23559247. S2CID 206546394.
  8. ^ "The United Nations just released a warning that the Great Barrier Reef is dying". The Independent. 3 June 2017. Archived from the original on 9 June 2017. Retrieved 11 June 2017.
  9. ^ Hughes TP, Kerry JT, Álvarez-Noriega M, Álvarez-Romero JG, Anderson KD, Baird AH, et al. (March 2017). "Global warming and recurrent mass bleaching of corals" (PDF). Nature. 543 (7645): 373–377. Bibcode:2017Natur.543..373H. doi:10.1038/nature21707. hdl:20.500.11937/52828. PMID 28300113. S2CID 205254779. Archived (PDF) from the original on 12 November 2020. Retrieved 12 April 2020.
  10. ^ "Mass coral bleaching hits the Great Barrier Reef for the second year in a row". USA Today. 13 March 2017. Archived from the original on 13 March 2017. Retrieved 14 March 2017.
  11. ^ Galimberti, Katy (18 April 2017). "Portion of Great Barrier Reef hit with back-to-back coral bleaching has 'zero prospect for recovery'". AccuWeather.com. Archived from the original on 18 April 2017. Retrieved 18 April 2017. When coral experiences abnormal conditions, it releases an algae called zooxanthellae. The loss of the colorful algae causes the coral to turn white.
  12. ^ Hughes TP, Anderson KD, Connolly SR, Heron SF, Kerry JT, Lough JM, et al. (January 2018). "Spatial and temporal patterns of mass bleaching of corals in the Anthropocene" (PDF). Science. 359 (6371): 80–83. Bibcode:2018Sci...359...80H. doi:10.1126/science.aan8048. PMID 29302011. S2CID 206661455. Archived (PDF) from the original on 28 April 2019. Retrieved 25 November 2018.
  13. ^ Shuail, Dawood; Wiedenmann, Jörg; D'Angelo, Cecilia; Baird, Andrew H.; Pratchett, Morgan S.; Riegl, Bernhard; Burt, John A.; Petrov, Peter; Amos, Carl (30 April 2016). "Local bleaching thresholds established by remote sensing techniques vary among reefs with deviating bleaching patterns during the 2012 event in the Arabian/Persian Gulf". Marine Pollution Bulletin. Coral Reefs of Arabia. 105 (2): 654–659. Bibcode:2016MarPB.105..654S. doi:10.1016/j.marpolbul.2016.03.001. ISSN 0025-326X. PMID 26971815. S2CID 37407032.
  14. ^ Hume, Benjamin C. C.; Voolstra, Christian R.; Arif, Chatchanit; D’Angelo, Cecilia; Burt, John A.; Eyal, Gal; Loya, Yossi; Wiedenmann, Jörg (19 April 2016). "Ancestral genetic diversity associated with the rapid spread of stress-tolerant coral symbionts in response to Holocene climate change". Proceedings of the National Academy of Sciences. 113 (16): 4416–4421. Bibcode:2016PNAS..113.4416H. doi:10.1073/pnas.1601910113. ISSN 0027-8424. PMC 4843444. PMID 27044109.
  15. ^ a b c d "What is Coral Bleaching and What Causes It – Fight For Our Reef". Australian Marine Conservation Society. Retrieved 13 September 2021.
  16. ^ "Coral Bleaching". Great Barrier Reef Foundation. Retrieved 13 September 2021.
  17. ^ Slezak, Michael (6 June 2016). "The Great Barrier Reef: a catastrophe laid bare". The Guardian. ISSN 0261-3077. Retrieved 13 September 2021.
  18. ^ a b Dove SG, Hoegh-Guldberg O (2006). "Coral bleaching can be caused by distress to the coral. The cell physiology of coral bleaching". In Ove Hoegh-Guldberg, Jonathan T. Phinney, William Skirving, Joanie Kleypas (eds.). Coral Reefs and Climate Change: Science and Management. [Washington]: American Geophysical Union. pp. 1–18. ISBN 978-0-87590-359-0.
  19. ^ a b c Zandonella, Catherine (2 November 2016). "When corals met algae: Symbiotic relationship crucial to reef survival dates to the Triassic". Princeton University. Retrieved 13 September 2021.
  20. ^ "What is coral bleaching?". NOAA National Ocean Service. Archived from the original on 20 December 2020. Retrieved 10 January 2020.
  21. ^ US Department of Commerce, National Oceanic and Atmospheric Administration. "How does climate change affect coral reefs?". oceanservice.noaa.gov. Retrieved 19 February 2024.
  22. ^ Lesser, M.P. (2010). "Coral Bleaching: Causes and Mechanisms". In Dubinzk, Z.; Stambler, N. (eds.). Coral Reefs: An Ecosystem in Transition. Dordrecht: Springer. pp. 405–419. doi:10.1007/978-94-007-0114-4_23. ISBN 978-94-007-0114-4.
  23. ^ a b Hoegh-Guldberg, Ove (1999). "Climate change, coral bleaching and the future of the world's coral reefs". Marine and Freshwater Research. 50 (8): 839–66. doi:10.1071/MF99078.
  24. ^ a b c d Bollati, Elena; D’Angelo, Cecilia; Alderdice, Rachel; Pratchett, Morgan; Ziegler, Maren; Wiedenmann, Jörg (July 2020). "Optical Feedback Loop Involving Dinoflagellate Symbiont and Scleractinian Host Drives Colorful Coral Bleaching". Current Biology. 30 (13): 2433–2445.e3. Bibcode:2020CBio...30E2433B. doi:10.1016/j.cub.2020.04.055. hdl:10453/149693. PMID 32442463.
  25. ^ Nir O, Gruber DF, Shemesh E, Glasser E, Tchernov D (15 January 2014). "Seasonal mesophotic coral bleaching of Stylophora pistillata in the Northern Red Sea". PLOS ONE. 9 (1): e84968. Bibcode:2014PLoSO...984968N. doi:10.1371/journal.pone.0084968. PMC 3893136. PMID 24454772.
  26. ^ a b Hoegh-Guldberg O, Mumby PJ, Hooten AJ, Steneck RS, Greenfield P, Gomez E, et al. (December 2007). "Coral reefs under rapid climate change and ocean acidification". Science. 318 (5857): 1737–42. Bibcode:2007Sci...318.1737H. CiteSeerX 10.1.1.702.1733. doi:10.1126/science.1152509. PMID 18079392. S2CID 12607336.
  27. ^ Baker A, Glynn P, Riegl B (2008). "Climate change and coral reef bleaching: An ecological assessment of long-term impacts, recovery trends and future outlook". Estuarine, Coastal and Shelf Science. 80 (4): 435–471. Bibcode:2008ECSS...80..435B. doi:10.1016/j.ecss.2008.09.003.
  28. ^ a b De, Kalyan; Nanajkar, Mandar; Mote, Sambhaji; Ingole, Baban (1 January 2023). "Reef on the edge: resilience failure of marginal patch coral reefs in Eastern Arabian Sea under recurrent coral bleaching, coral diseases, and local stressors". Environmental Science and Pollution Research. 30 (3): 7288–7302. Bibcode:2023ESPR...30.7288D. doi:10.1007/s11356-022-22651-3. ISSN 1614-7499. PMID 36031676.
  29. ^ Bollati, Elena; D’Angelo, Cecilia; Alderdice, Rachel; Pratchett, Morgan; Ziegler, Maren; Wiedenmann, Jörg (July 2020). "Optical Feedback Loop Involving Dinoflagellate Symbiont and Scleractinian Host Drives Colorful Coral Bleaching". Current Biology. 30 (13): 2433–2445.e3. Bibcode:2020CBio...30E2433B. doi:10.1016/j.cub.2020.04.055. hdl:10453/149693. ISSN 0960-9822. PMID 32442463. S2CID 218762967.
  30. ^ "Reef 'at risk in climate change'" (Press release). The University of Queensland. 6 April 2007. Archived from the original on 13 September 2016. Retrieved 2 August 2016.
  31. ^ Anthony, K. 2007; Berkelmans
  32. ^ Saxby T, Dennison WC, Hoegh-Guldberg O (2003). "Photosynthetic responses of the coral Montipora digitata to cold temperature stress". Marine Ecology Progress Series. 248: 85–97. Bibcode:2003MEPS..248...85S. doi:10.3354/meps248085.
  33. ^ Marimuthu N, Jerald Wilson J, Vinithkumar NV, Kirubagaran R (9 November 2012). "Coral reef recovery status in south Andaman Islands after the bleaching event 2010". Journal of Ocean University of China. 12 (1): 91–96. Bibcode:2013JOUC...12...91M. doi:10.1007/s11802-013-2014-2. S2CID 89531419.
  34. ^ Rogers CS (1990). "Responses of coral reefs and reef organisms to sedimentation". Marine Ecology Progress Series. 62: 185–202. Bibcode:1990MEPS...62..185R. doi:10.3354/meps062185.
  35. ^ Kushmaro A, Rosenberg E, Fine M, Loya Y (1997). "Bleaching of the coral Oculina patagonica by Vibrio AK-1". Marine Ecology Progress Series. 147: 159–65. Bibcode:1997MEPS..147..159K. doi:10.3354/meps147159.
  36. ^ Hoegh-Guldberg O, Smith G (1989). "The effect of sudden changes in temperature, light and salinity on the population density and export of zooxanthellae from the reef corals Stylophora pistillata Esper and Seriatopora hystrix Dana". Journal of Experimental Marine Biology and Ecology. 129 (3): 279–303. Bibcode:1989JEMBE.129..279H. doi:10.1016/0022-0981(89)90109-3.
  37. ^ Jones RJ, Muller J, Haynes D, Schreiber U (2003). "Effects of herbicides diuron and atrazine on corals of the Great Barrier Reef, Australia". Marine Ecology Progress Series. 251: 153–167. Bibcode:2003MEPS..251..153J. doi:10.3354/meps251153.
  38. ^ Anthony KR, Kerswell AP (2007). "Coral mortality following extreme low tides and high solar radiation". Marine Biology. 151 (5): 1623–31. Bibcode:2007MarBi.151.1623A. doi:10.1007/s00227-006-0573-0. S2CID 84328751.
  39. ^ Jones RJ, Hoegh-Guldberg O (1999). "Effects of cyanide on coral photosynthesis:implications for identifying the cause of coral bleaching and for assessing the environmental effects of cyanide fishing". Marine Ecology Progress Series. 177: 83–91. Bibcode:1999MEPS..177...83J. doi:10.3354/meps177083.
  40. ^ "Coral Mortality and African Dust". U. S. Geological Survey. Archived from the original on 2 May 2012. Retrieved 10 June 2007.
  41. ^ "Protect Yourself, Protect The Reef! The impacts of sunscreens on our coral reefs" (PDF). U.S. National Park Service. Archived (PDF) from the original on 13 February 2013. Retrieved 1 July 2013.
  42. ^ "Coral Reef Safe Sunscreen". badgerbalm.com. Archived from the original on 24 March 2014. Retrieved 24 March 2014.
  43. ^ Danovaro R, Bongiorni L, Corinaldesi C, Giovannelli D, Damiani E, Astolfi P, Greci L, Pusceddu A (April 2008). "Sunscreens cause coral bleaching by promoting viral infections". Environmental Health Perspectives. 116 (4): 441–7. doi:10.1289/ehp.10966. PMC 2291018. PMID 18414624.
  44. ^ Downs CA, Kramarsky-Winter E, Fauth JE, Segal R, Bronstein O, Jeger R, Lichtenfeld Y, Woodley CM, Pennington P, Kushmaro A, Loya Y (March 2014). "Toxicological effects of the sunscreen UV filter, benzophenone-2, on planulae and in vitro cells of the coral, Stylophora pistillata". Ecotoxicology. 23 (2): 175–91. Bibcode:2014Ecotx..23..175D. doi:10.1007/s10646-013-1161-y. PMID 24352829. S2CID 1505199.
  45. ^ Anthony KR, Kline DI, Diaz-Pulido G, Dove S, Hoegh-Guldberg O (November 2008). "Ocean acidification causes bleaching and productivity loss in coral reef builders". Proceedings of the National Academy of Sciences of the United States of America. 105 (45): 17442–6. Bibcode:2008PNAS..10517442A. doi:10.1073/pnas.0804478105. PMC 2580748. PMID 18988740.
  46. ^ a b c d e "How Do Oil Spills Affect Coral Reefs?". response.restoration.noaa.gov. Archived from the original on 24 April 2018. Retrieved 24 April 2018.
  47. ^ Wiedenmann, Jörg; D'Angelo, Cecilia; Smith, Edward G.; Hunt, Alan N.; Legiret, François-Eric; Postle, Anthony D.; Achterberg, Eric P. (February 2013). "Nutrient enrichment can increase the susceptibility of reef corals to bleaching". Nature Climate Change. 3 (2): 160–164. Bibcode:2013NatCC...3..160W. doi:10.1038/nclimate1661. ISSN 1758-6798.
  48. ^ Baker, Andrew C.; Glynn, Peter W.; Riegl, Bernhard (December 2008). "Climate change and coral reef bleaching: An ecological assessment of long-term impacts, recovery trends and future outlook". Estuarine, Coastal and Shelf Science. 80 (4): 435–471. Bibcode:2008ECSS...80..435B. doi:10.1016/j.ecss.2008.09.003. ISSN 0272-7714.
  49. ^ a b c Cooley, S., D. Schoeman, L. Bopp, P. Boyd, S. Donner, D.Y. Ghebrehiwet, S.-I. Ito, W. Kiessling, P. Martinetto, E. Ojea, M.-F. Racault, B. Rost, and M. Skern-Mauritzen, 2022: Chapter 3: Oceans and Coastal Ecosystems and Their Services. In: Climate Change 2022: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [H.-O. Pörtner, D.C. Roberts, M. Tignor, E.S. Poloczanska, K. Mintenbeck, A. Alegría, M. Craig, S. Langsdorf, S. Löschke, V. Möller, A. Okem, B. Rama (eds.)]. Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 379–550, doi:10.1017/9781009325844.005.
  50. ^ IPCC (2007). "Summary for policymakers" (PDF). In Parry ML, Canziani OF, Palutikof JP, van der Linden PJ, Hanson CE (eds.). Climate Change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge, UK: Cambridge University Press. pp. 7–22. ISBN 978-0-521-70597-4. Archived (PDF) from the original on 13 January 2018. Retrieved 8 July 2009.
  51. ^ Fischlin A, Midgley GF, Price JT, Leemans R, Gopal B, Turley C, Rounsevell MD, Dube OP, Tarazona J, Velichko AA (2007). "Ch 4. Ecosystems, their properties, goods and services" (PDF). In Parry ML, Canziani OF, Palutikof JP, van der Linden PJ, Hanson CE (eds.). Climate Change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge, UK: Cambridge University Press. pp. 211–72. ISBN 978-0-521-70597-4. Archived (PDF) from the original on 11 October 2017. Retrieved 8 July 2009.
  52. ^ Davidson, Jordan (25 March 2020). "Great Barrier Reef Has Third Major Bleaching Event in Five Years". Ecowatch. Retrieved 27 March 2020.
  53. ^ McWhorter, Jennifer K.; Halloran, Paul R.; Roff, George; Skirving, William J.; Perry, Chris T.; Mumby, Peter J. (February 2022). "The importance of 1.5°C warming for the Great Barrier Reef". Global Change Biology. 28 (4): 1332–1341. doi:10.1111/gcb.15994. hdl:10871/127948. PMID 34783126. S2CID 244131267.
  54. ^ "Coral Reefs Could Be Gone in 30 Years". National Geographic News. 23 June 2017. Archived from the original on 7 May 2019. Retrieved 7 May 2019.
  55. ^ Bouwmeester, Jessica; Daly, Jonathan; Zuchowicz, Nikolas; Lager, Claire; Henley, E. Michael; Quinn, Mariko; Hagedorn, Mary (5 January 2023). "Solar radiation, temperature and the reproductive biology of the coral Lobactis scutaria in a changing climate". Scientific Reports. 13 (1): 246. Bibcode:2023NatSR..13..246B. doi:10.1038/s41598-022-27207-6. ISSN 2045-2322. PMC 9816315. PMID 36604569.
  56. ^ Baker AC, Glynn PW, Riegl B (2008). "Climate change and coral reef bleaching: An ecological assessment of long-term impacts, recovery trends and future outlook". Estuarine, Coastal and Shelf Science. 80 (4): 435–71. Bibcode:2008ECSS...80..435B. doi:10.1016/j.ecss.2008.09.003.
  57. ^ Chumkiew S, Jaroensutasinee M, Jaroensutasinee K (2011). "Impact of Global Warming on Coral Reefs". Walailak Journal of Science and Technology. 8 (2): 111–29. Archived from the original on 6 August 2016. Retrieved 2 August 2016.
  58. ^ Huppert A, Stone L (September 1998). "Chaos in the Pacific's coral reef bleaching cycle". The American Naturalist. 152 (3): 447–59. doi:10.1086/286181. PMID 18811451. S2CID 29245066.
  59. ^ McDermott, Amy (22 June 2016). "Coral bleaching event is longest on record". Science News. Archived from the original on 16 August 2016. Retrieved 25 July 2016.
  60. ^ a b c d e f g h i j k l m n Albright R (December 2017). "Can We Save the Corals?". Scientific American. 318 (1): 42–49. Bibcode:2017SciAm.318a..42A. doi:10.1038/scientificamerican0118-42. PMID 29257818.
  61. ^ a b Marshall P, Schuttenberg H (2006). A Reef Manager's Guide to Coral Bleaching (PDF). Townsville, Australia: Great Barrier Reef Marine Park Authority. pp. 78–79. ISBN 978-1-876945-40-4. Archived (PDF) from the original on 13 February 2014. Retrieved 23 May 2014.
  62. ^ Baird, Ah; Marshall, Pa (2002). "Mortality, growth and reproduction in scleractinian corals following bleaching on the Great Barrier Reef". Marine Ecology Progress Series. 237: 133–141. Bibcode:2002MEPS..237..133B. doi:10.3354/meps237133. ISSN 0171-8630.
  63. ^ a b Gabriel D. Grinmsditch and Rodney V. Salm, Coral Reef Resilience and Resistance to Bleaching Archived 28 October 2012 at the Wayback Machine, "IUCN: The World Conservation Union", 2006[page needed]
  64. ^ Iguchi A, Ozaki S, Nakamura T, Inoue M, Tanaka Y, Suzuki A, Kawahata H, Sakai K (February 2012). "Effects of acidified seawater on coral calcification and symbiotic algae on the massive coral Porites australiensis". Marine Environmental Research. 73: 32–6. Bibcode:2012MarER..73...32I. doi:10.1016/j.marenvres.2011.10.008. PMID 22115919.
  65. ^ Bridge, Tom C. L.; Baird, Andrew H.; Pandolfi, John M.; McWilliam, Michael J.; Zapalski, Mikołaj K. (26 January 2022). "Functional consequences of Palaeozoic reef collapse". Scientific Reports. 12 (1): 1386. Bibcode:2022NatSR..12.1386B. doi:10.1038/s41598-022-05154-6. ISSN 2045-2322. PMC 8792005. PMID 35082318.
  66. ^ Zapalski MK, Nowicki J, Jakubowicz M, Berkowski B (2017). "Tabulate corals across the Frasnian/Famennian boundary: architectural turnover and its possible relation to ancient photosymbiosis". Palaeogeography, Palaeoclimatology, Palaeoecology. 487: 416–429. Bibcode:2017PPP...487..416Z. doi:10.1016/j.palaeo.2017.09.028.
  67. ^ Wilkinson, C. P. (1998). "The 1997–1998 Mass Bleaching Event Around the World". AquaDocs.
  68. ^ McWhorter, Jennifer K.; Halloran, Paul R.; Roff, George; Mumby, Peter J. (16 April 2024). "Climate change impacts on mesophotic regions of the Great Barrier Reef". Proceedings of the National Academy of Sciences. 121 (16): e2303336121. Bibcode:2024PNAS..12103336M. doi:10.1073/pnas.2303336121. hdl:10871/135524. ISSN 0027-8424. PMC 11032494. PMID 38588432.
  69. ^ "NOAA confirms 4th global coral bleaching event | National Oceanic and Atmospheric Administration". www.noaa.gov. 15 April 2024. Retrieved 16 April 2024.
  70. ^ "Coral bleaching: Fourth global mass stress episode underway - US scientists". 15 April 2024. Retrieved 16 April 2024.
  71. ^ "State of the Oceans 2024 report". German Ocean Foundation (Deutsche meeresstiftung) & Statista. Retrieved 3 August 2024.
  72. ^ "Infographic: The Extent of Global Coral Bleaching Events". Statista Daily Data. 7 June 2024. Retrieved 3 August 2024.
  73. ^ "Heat Stress Is Plunging the World's Coral Reefs Into Crisis". Bloomberg.com. 16 April 2024. Retrieved 16 April 2024.
  74. ^ Pratchett, Morgan S.; Hoey, Andrew S.; Wilson, Shaun K.; Messmer, Vanessa; Graham, Nicholas A. J. (1 September 2011). "Changes in Biodiversity and Functioning of Reef Fish Assemblages following Coral Bleaching and Coral Loss". Diversity. 3 (3): 424–452. doi:10.3390/d3030424. hdl:10754/334624. ISSN 1424-2818.
  75. ^ "The Hidden Coral Crisis: Loss of Fish Diversity After Bleaching Strikes". Oceans. 10 April 2018. Archived from the original on 26 June 2020. Retrieved 2 July 2020.
  76. ^ Skoloff, Brian (26 March 2010) Death of coral reefs could devastate nations Archived 13 November 2012 at the Wayback Machine, The Christian Science Monitor
  77. ^ "Endangered Coral Reefs Die as Ocean Temperatures Rise and Water Turns Acidic". PBS Newshour. 5 December 2012. Archived from the original on 12 October 2017.
  78. ^ a b c d e Speers AE, Besedin EY, Palardy JE, Moore C (1 August 2016). "Impacts of climate change and ocean acidification on coral reef fisheries: An integrated ecological–economic model". Ecological Economics. 128: 33–43. Bibcode:2016EcoEc.128...33S. doi:10.1016/j.ecolecon.2016.04.012.
  79. ^ a b c Chen PY, Chen CC, Chu L, McCarl B (1 January 2015). "Evaluating the economic damage of climate change on global coral reefs". Global Environmental Change. 30: 12–20. Bibcode:2015GEC....30...12C. doi:10.1016/j.gloenvcha.2014.10.011.
  80. ^ a b c Teh LS, Teh LC, Sumaila UR (19 June 2013). "A Global Estimate of the Number of Coral Reef Fishers". PLOS ONE. 8 (6): e65397. Bibcode:2013PLoSO...865397T. doi:10.1371/journal.pone.0065397. PMC 3686796. PMID 23840327.
  81. ^ a b Wolff NH, Donner SD, Cao L, Iglesias-Prieto R, Sale PF, Mumby PJ (November 2015). "Global inequities between polluters and the polluted: climate change impacts on coral reefs". Global Change Biology. 21 (11): 3982–94. Bibcode:2015GCBio..21.3982W. doi:10.1111/gcb.13015. PMID 26234736. S2CID 23157593.
  82. ^ a b Liu G, Strong AE, Skirving W (15 April 2003). "Remote sensing of sea surface temperatures during 2002 Barrier Reef coral bleaching". Eos, Transactions American Geophysical Union. 84 (15): 137–141. Bibcode:2003EOSTr..84..137L. doi:10.1029/2003EO150001. S2CID 128559504.
  83. ^ McClanahan TR, Ateweberhan M, Sebastián CR, Graham NJ, Wilson SK, Bruggemann JH, Guillaume MM (1 September 2007). "Predictability of coral bleaching from synoptic satellite and in situ temperature observations". Coral Reefs. 26 (3): 695–701. doi:10.1007/s00338-006-0193-7. S2CID 7435285.
  84. ^ a b Liu, Gang & Strong, Alan & Skirving, William & Arzayus, Felipe. (2005). Overview of NOAA coral reef watch program's near-real time satellite global coral bleaching monitoring activities Archived 30 September 2018 at the Wayback Machine. Proc 10th Int Coral Reef Symp. 1. pp. 1783–1793.
  85. ^ "NOAA Hotspots". coral.aoml.noaa.gov. 19 October 2006. Archived from the original on 16 July 2011. Retrieved 1 November 2007.
  86. ^ "Pro-opinion of NOAA Hotspots". Archived from the original on 12 May 2015. Retrieved 23 July 2021.
  87. ^ NOAA Coral Reef Watch. "Methodology, Product Description, and Data Availability of Coral Reef Watch Operational and Experimental Satellite Coral Bleaching Monitoring Products". NOAA. Archived from the original on 7 March 2014. Retrieved 27 February 2014.
  88. ^ a b Maynard JA, Johnson JE, Marshall PA, Eakin CM, Goby G, Schuttenberg H, Spillman CM (July 2009). "A strategic framework for responding to coral bleaching events in a changing climate". Environmental Management. 44 (1): 1–11. Bibcode:2009EnMan..44....1M. doi:10.1007/s00267-009-9295-7. PMID 19434447. S2CID 30321497.
  89. ^ Kopecky, Kai L.; Pavoni, Gaia; Nocerino, Erica; Brooks, Andrew J.; Corsini, Massimiliano; Menna, Fabio; Gallagher, Jordan P.; Capra, Alessandro; Castagnetti, Cristina; Rossi, Paolo; Gruen, Armin; Neyer, Fabian; Muntoni, Alessandro; Ponchio, Federico; Cignoni, Paolo (August 2023). "Quantifying the Loss of Coral from a Bleaching Event Using Underwater Photogrammetry and AI-Assisted Image Segmentation". Remote Sensing. 15 (16): 4077. Bibcode:2023RemS...15.4077K. doi:10.3390/rs15164077. hdl:11380/1316375. ISSN 2072-4292.
  90. ^ a b Lang, Susan (13 December 2007). "Major international study warns global warming is destroying coral reefs and calls for 'drastic actions'". Cornell Chronicle. Archived from the original on 6 August 2011. Retrieved 8 August 2011.
  91. ^ Kleypas, J. A. (2 April 1999). "Geochemical Consequences of Increased Atmospheric Carbon Dioxide on Coral Reefs". Science. 284 (5411): 118–120. Bibcode:1999Sci...284..118K. doi:10.1126/science.284.5411.118. PMID 10102806. Archived from the original on 23 July 2021. Retrieved 10 June 2021.
  92. ^ Manzello DP, Eakin CM, Glynn PW (2017). "Effects of Global Warming and Ocean Acidification on Carbonate Budgets of Eastern Pacific Coral Reefs". Coral Reefs of the Eastern Tropical Pacific. Coral Reefs of the World. Vol. 8. Springer, Dordrecht. pp. 517–533. doi:10.1007/978-94-017-7499-4_18. ISBN 9789401774987.
  93. ^ Anthony KR, Maynard JA, Diaz-Pulido G, Mumby PJ, Marshall PA, Cao L, Hoegh-Guldberg O (1 May 2011). "Ocean acidification and warming will lower coral reef resilience". Global Change Biology. 17 (5): 1798–1808. Bibcode:2011GCBio..17.1798A. doi:10.1111/j.1365-2486.2010.02364.x. PMC 3597261.
  94. ^ "Zooxanthella | Definition of Zooxanthella by Oxford Dictionary on Lexico.com also meaning of Zooxanthella". Lexico Dictionaries | English. Archived from the original on 16 November 2020. Retrieved 10 November 2020.
  95. ^ Smith, D.J (2005). "Is photoinhibition of zooxanthellae photosynthesis the primary cause of thermal bleaching in corals?". Global Change Biology. 11 (1): 1–11. Bibcode:2005GCBio..11....1S. doi:10.1111/j.1529-8817.2003.00895.x. S2CID 42629591. Archived from the original on 20 November 2020. Retrieved 9 November 2020.
  96. ^ Smith, D.J (2005). "Is photoinhibition of zooxanthellae photosynthesis the primary cause of thermal bleaching in corals?". Global Change Biology. 11 (1): 1. Bibcode:2005GCBio..11....1S. doi:10.1111/j.1529-8817.2003.00895.x. S2CID 42629591. Archived from the original on 28 November 2020. Retrieved 23 July 2021 – via Online Library.
  97. ^ Zhong, Xin; Downs, Craig A.; Che, Xingkai; Zhang, Zishan; Li, Yiman; Liu, Binbin; Li, Qingming; Li, Yuting; Gao, Huiyuan (1 November 2019). "The toxicological effects of oxybenzone, an active ingredient in suncream personal care products, on prokaryotic alga Arthrospira sp. and eukaryotic alga Chlorella sp". Aquatic Toxicology. 216: 105295. Bibcode:2019AqTox.21605295Z. doi:10.1016/j.aquatox.2019.105295. ISSN 0166-445X. PMID 31561136. S2CID 202862335. Archived from the original on 23 July 2021. Retrieved 20 November 2020.
  98. ^ a b Wijgerde, Tim; van Ballegooijen, Mike; Nijland, Reindert; van der Loos, Luna; Kwadijk, Christiaan; Osinga, Ronald; Murk, Albertinka; Slijkerman, Diana (20 December 2019). "Adding insult to injury: Effects of chronic oxybenzone exposure and elevated temperature on two reef-building corals". bioRxiv. doi:10.1101/2019.12.19.882332. S2CID 214573850. Archived from the original on 23 July 2021. Retrieved 20 November 2020.
  99. ^ Kushmaro A, Loya Y, Fine M, Rosenberg E (1996). "Bacterial infection and coral bleaching". Nature. 380 (6573): 396. Bibcode:1996Natur.380..396K. doi:10.1038/380396a0. S2CID 31033320.
  100. ^ a b Rosenberg E, Ben-Haim Y (June 2002). "Microbial diseases of corals and global warming". Environmental Microbiology. 4 (6): 318–26. Bibcode:2002EnvMi...4..318R. doi:10.1046/j.1462-2920.2002.00302.x. PMID 12071977.
  101. ^ Sheridan C, Kramarsky-Winter E, Sweet M, Kushmaro A, Leal MC (2013). "Diseases in coral aquaculture: causes, implications and preventions". Aquaculture. 396: 124–135. Bibcode:2013Aquac.396..124S. doi:10.1016/j.aquaculture.2013.02.037. S2CID 55637399.
  102. ^ Sutherland KP, Porter J, Torres C (2004). "Disease and Immunity in Caribbean and Indo-pacific Zooxanthellate Corals". Marine Ecology Progress Series. 266: 273–302. Bibcode:2004MEPS..266..273S. doi:10.3354/meps266273.
  103. ^ Reshef L, Koren O, Loya Y, Zilber-Rosenberg I, Rosenberg E (December 2006). "The coral probiotic hypothesis". Environmental Microbiology. 8 (12): 2068–73. Bibcode:2006EnvMi...8.2068R. CiteSeerX 10.1.1.627.6120. doi:10.1111/j.1462-2920.2006.01148.x. PMID 17107548.
  104. ^ Hennessy K, Fitzharris B, Bates BC, Harvey N, Howden M, Hughes L, Salinger J, Warrick R (2007). "Ch 11. Australia and New Zealand" (PDF). In Parry ML, Canziani OF, Palutikof JP, van der Linden PJ, Hanson CE (eds.). Climate Change 2007: impacts, adaptation and vulnerability: contribution of Working Group II to the fourth assessment report of the Intergovernmental Panel on Climate Change. Cambridge, UK: Cambridge University Press. pp. 507–40. ISBN 978-0-521-70597-4. Archived from the original (PDF) on 10 March 2009. Retrieved 8 July 2009.
  105. ^ Plumer, Brad (31 March 2016). "The unprecedented coral bleaching disaster at the Great Barrier Reef, explained". Vox Energy & Environment. Archived from the original on 30 April 2017. Retrieved 13 June 2017.
  106. ^ Johnson JE, Marshall PA (2007). Climate change and the Great Barrier Reef: a vulnerability assessment. Townsville, Qld.: Great Barrier Reef Marine Park Authority. ISBN 978-1-876945-61-9. Archived from the original on 25 January 2014.
  107. ^ a b Done T, Whetton P, Jones R, Berkelmans R, Lough J, Skirving W, Wooldridge S (2003). Global Climate Change and Coral Bleaching on the Great Barrier Reef (PDF). Queensland Government Department of Natural Resources and Mines. ISBN 978-0-642-32220-3. Archived from the original (PDF) on 27 September 2011.
  108. ^ Berkelmans R, De'ath G, Kininmonth S, Skirving WJ (2004). "A comparison of the 1998 and 2002 coral bleaching events on the Great Barrier Reef: spatial correlation, patterns, and predictions". Coral Reefs. 23 (1): 74–83. doi:10.1007/s00338-003-0353-y. S2CID 26415495.
  109. ^ Osborne K, Dolman AM, Burgess SC, Johns KA (March 2011). "Disturbance and the dynamics of coral cover on the Great Barrier Reef (1995–2009)". PLOS ONE. 6 (3): e17516. Bibcode:2011PLoSO...617516O. doi:10.1371/journal.pone.0017516. PMC 3053361. PMID 21423742.
  110. ^ De'ath G, Fabricius KE, Sweatman H, Puotinen M (October 2012). "The 27-year decline of coral cover on the Great Barrier Reef and its causes". Proceedings of the National Academy of Sciences of the United States of America. 109 (44): 17995–9. Bibcode:2012PNAS..10917995D. doi:10.1073/pnas.1208909109. PMC 3497744. PMID 23027961.
  111. ^ Final Report: 2016 Coral Bleaching Event on Great Barrier Reef . Great Barrier Reef Marine Park Authority Townsville, 2017, pp. 24–24, Final Report: 2016 Coral Bleaching Event on Great Barrier Reef .
  112. ^ IPCC (2007). "Summary for policymakers" (PDF). In Solomon S, Qin D, Manning M, Chen Z, Marquis M, Averyt KB, Tignor M, Miller HL (eds.). Climate change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, UK: Cambridge University Press. pp. 1–18. Archived (PDF) from the original on 7 May 2017. Retrieved 8 July 2009.
  113. ^ "Climate Change and Marine Disease". dlnr.hawaii.gov. Archived from the original on 8 June 2020. Retrieved 15 August 2019.
  114. ^ "Rapidly warming ocean a threat to Hawaiian coral reefs". The University of Queensland. 2015. Archived from the original on 7 September 2015. Retrieved 3 September 2015.
  115. ^ "Corals in peril at a popular Hawaiian tourist destination due to global climate change". Archived from the original on 30 May 2017. Retrieved 30 May 2017.
  116. ^ Kahn, Brian (8 November 2017). "Coral Bleaching Has Ravaged Half of Hawaii's Coral Reefs". Gizmodo. Archived from the original on 15 December 2018. Retrieved 12 December 2018.
  117. ^ "Hawaii coral reefs stabilizing following bleaching event". Associated Press. 24 January 2019. Archived from the original on 24 January 2019. Retrieved 25 January 2019.
  118. ^ "11/5/19 – CORAL BLEACHING NOT AS SEVERE AS PREDICTED BUT STILL WIDESPREAD; Extensive Surveys Show Bleaching Event Now Abating". dlnr.hawaii.gov. Archived from the original on 29 November 2020. Retrieved 6 December 2020.
  119. ^ Donovan, Caroline; Towle, Erica K.; Kelsey, Heath; Allen, Mary; Barkley, Hannah; Besemer, Nicole; Blondeau, Jeremiah; Eakin, Mark; Edwards, Kimberly; Enochs, Ian; Fleming, Chloe (2020). Coral reef condition: A status report for U.S. coral reefs (Report). Coral Reef Conservation Program, University of Maryland Center for Environmental Science. doi:10.25923/wbbj-t585. Archived from the original on 28 November 2020. Retrieved 10 December 2020.
  120. ^ a b "Hawaii SB2571 | 2018 | Regular Session". LegiScan. Retrieved 29 May 2022.
  121. ^ Downs, C. A.; Kramarsky-Winter, Esti; Segal, Roee; Fauth, John; Knutson, Sean; Bronstein, Omri; Ciner, Frederic R.; Jeger, Rina; Lichtenfeld, Yona; Woodley, Cheryl M.; Pennington, Paul (1 February 2016). "Toxicopathological Effects of the Sunscreen UV Filter, Oxybenzone (Benzophenone-3), on Coral Planulae and Cultured Primary Cells and Its Environmental Contamination in Hawaii and the U.S. Virgin Islands". Archives of Environmental Contamination and Toxicology. 70 (2): 265–288. Bibcode:2016ArECT..70..265D. doi:10.1007/s00244-015-0227-7. ISSN 1432-0703. PMID 26487337. S2CID 4243494.
  122. ^ Wijgerde, Tim; van Ballegooijen, Mike; Nijland, Reindert; van der Loos, Luna; Kwadijk, Christiaan; Osinga, Ronald; Murk, Albertinka; Slijkerman, Diana (1 September 2020). "Adding insult to injury: Effects of chronic oxybenzone exposure and elevated temperature on two reef-building corals". Science of the Total Environment. 733: 139030. Bibcode:2020ScTEn.73339030W. doi:10.1016/j.scitotenv.2020.139030. ISSN 0048-9697. PMID 32446051. S2CID 218864094.
  123. ^ Barkley, Hannah C.; Cohen, Anne L.; Mollica, Nathaniel R.; Brainard, Russell E.; Rivera, Hanny E.; DeCarlo, Thomas M.; Lohmann, George P.; Drenkard, Elizabeth J.; Alpert, Alice E. (8 November 2018). "Repeat bleaching of a central Pacific coral reef over the past six decades (1960–2016)". Communications Biology. 1 (1): 177. doi:10.1038/s42003-018-0183-7. hdl:1912/10707. ISSN 2399-3642. PMC 6224388. PMID 30417118.
  124. ^ a b Nakamura, Masako; Murakami, Tomokazu; Kohno, Hiroyoshi; Mizutani, Akira; Shimokawa, Shinya (28 July 2022). "Rapid recovery of coral communities from a mass bleaching event in the summer of 2016, observed in Amitori Bay, Iriomote Island, Japan". Marine Biology. 169 (8): 104. Bibcode:2022MarBi.169..104N. doi:10.1007/s00227-022-04091-2. ISSN 0025-3162. PMC 9331011. PMID 35915766.
  125. ^ MURAKAMI, Tomokazu; KOHNO, Hiroyoshi; NAKAMURA, Masako; TAMAMURA, Naoya; MIZUTANI, Akira; SHIMOKAWA, Shinya (2017). "Bleaching in Vertically Distributed Corals in Amitori Bay of Iriomote Island". Journal of Japan Society of Civil Engineers, Ser. B3 (Ocean Engineering). 73 (2): I_881–I_886. doi:10.2208/jscejoe.73.i_881. ISSN 2185-4688.
  126. ^ McCurry, Justin (11 January 2017). "Almost 75% of Japan's biggest coral reef has died from bleaching, says report". The Guardian. Archived from the original on 21 August 2017. Retrieved 30 May 2017.
  127. ^ Freeman, Lauren A.; Kleypas, Joan A.; Miller, Arthur J. (5 December 2013). "Coral Reef Habitat Response to Climate Change Scenarios". PLOS ONE. 8 (12): e82404. Bibcode:2013PLoSO...882404F. doi:10.1371/journal.pone.0082404. ISSN 1932-6203. PMC 3855618. PMID 24340025.
  128. ^ Gischler, Eberhard; Storz, David; Schmitt, Dominik (April 2014). "Sizes, shapes, and patterns of coral reefs in the Maldives, Indian Ocean: the influence of wind, storms, and precipitation on a major tropical carbonate platform". Carbonates and Evaporites. 29 (1): 73–87. Bibcode:2014CarEv..29...73G. doi:10.1007/s13146-013-0176-z. ISSN 0891-2556. S2CID 128905096.
  129. ^ "More than 60% of Maldives' coral reefs hit by bleaching". The Guardian. 8 August 2016. Archived from the original on 29 September 2018. Retrieved 31 May 2017.
  130. ^ "Maldives coral reefs under stress from climate change: research survey reveals over 60% of corals bleached | IUCN". www.iucn.org. 8 August 2016. Retrieved 28 January 2024.
  131. ^ Brown, Kristen T.; Bender-Champ, Dorothea; Bryant, Dominic E.P.; Dove, Sophie; Hoegh-Guldberg, Ove (December 2017). "Human activities influence benthic community structure and the composition of the coral-algal interactions in the central Maldives". Journal of Experimental Marine Biology and Ecology. 497: 33–40. Bibcode:2017JEMBE.497...33B. doi:10.1016/j.jembe.2017.09.006. ISSN 0022-0981.
  132. ^ Fallati, Luca; Savini, Alessandra; Sterlacchini, Simone; Galli, Paolo (26 July 2017). "Land use and land cover (LULC) of the Republic of the Maldives: first national map and LULC change analysis using remote-sensing data". Environmental Monitoring and Assessment. 189 (8): 417. Bibcode:2017EMnAs.189..417F. doi:10.1007/s10661-017-6120-2. ISSN 0167-6369. PMID 28748428.
  133. ^ Montano, Simone; Giorgi, Aurora; Monti, Matteo; Seveso, Davide; Galli, Paolo (26 May 2016). "Spatial variability in distribution and prevalence of skeletal eroding band and brown band disease in Faafu Atoll, Maldives". Biodiversity and Conservation. 25 (9): 1625–1636. Bibcode:2016BiCon..25.1625M. doi:10.1007/s10531-016-1145-3. ISSN 0960-3115.
  134. ^ Saponari, L.; Dehnert, I.; Galli, P.; Montano, S. (4 March 2021). "Assessing population collapse of Drupella spp. (Mollusca: Gastropoda) 2 years after a coral bleaching event in the Republic of Maldives". Hydrobiologia. 848 (11): 2653–2666. Bibcode:2021HyBio.848.2653S. doi:10.1007/s10750-021-04546-5. hdl:10281/355144. ISSN 0018-8158.
  135. ^ Sutthacheep, Makamas; Yucharoen, Mathinee; Klinthong, Wanlaya; Pengsakun, Sittiporn; Sangmanee, Kanwara; Yeemin, Thamasak (November 2013). "Impacts of the 1998 and 2010 mass coral bleaching events on the Western Gulf of Thailand". Deep Sea Research Part II: Topical Studies in Oceanography. 96: 25–31. Bibcode:2013DSRII..96...25S. doi:10.1016/j.dsr2.2013.04.018. ISSN 0967-0645.
  136. ^ "As sea temperatures rise, Thailand sees coral bleeching". Bangkok Post. 25 December 2016. Archived from the original on 29 September 2018. Retrieved 31 May 2017.
  137. ^ Watt-Pringle, Rowan; Smith, David J.; Ambo-Rappe, Rohani; Lamont, Timothy A. C.; Jompa, Jamaluddin (9 June 2022). "Suppressed recovery of functionally important branching Acropora drives coral community composition changes following mass bleaching in Indonesia". Coral Reefs. 41 (5): 1337–1350. doi:10.1007/s00338-022-02275-2. ISSN 0722-4028.
  138. ^ Pratchett, Morgan S.; McWilliam, Michael J.; Riegl, Bernhard (20 April 2020). "Contrasting shifts in coral assemblages with increasing disturbances". Coral Reefs. 39 (3): 783–793. doi:10.1007/s00338-020-01936-4. ISSN 0722-4028.
  139. ^ Brandt, M. E. (26 September 2009). "The effect of species and colony size on the bleaching response of reef-building corals in the Florida Keys during the 2005 mass bleaching event". Coral Reefs. 28 (4): 911–924. Bibcode:2009CorRe..28..911B. doi:10.1007/s00338-009-0548-y. ISSN 0722-4028.
  140. ^ Fleshler, David (24 April 2016). "South Florida corals dying in "unprecedented" bleaching and disease". Sun-Sentinel. Archived from the original on 7 June 2017. Retrieved 30 May 2017.
  141. ^ Smith JE, Brainard R, Carter A, Grillo S, Edwards C, Harris J, Lewis L, Obura D, Rohwer F, Sala E, Vroom PS, Sandin S (January 2016). "Re-evaluating the health of coral reef communities: baselines and evidence for human impacts across the central Pacific". Proceedings. Biological Sciences. 283 (1822): 20151985. doi:10.1098/rspb.2015.1985. PMC 4721084. PMID 26740615.
  142. ^ Buglass S, Donner SD, Alemu I JB (March 2016). "A study on the recovery of Tobago's coral reefs following the 2010 mass bleaching event". Marine Pollution Bulletin. 104 (1–2): 198–206. Bibcode:2016MarPB.104..198B. doi:10.1016/j.marpolbul.2016.01.038. hdl:2429/51752. PMID 26856646.
  143. ^ Alevizon, William. "Red Sea Coral Reefs". Coral Reef Facts. Archived from the original on 6 December 2016. Retrieved 27 February 2014.
  144. ^ Riegl BM, Bruckner AW, Rowlands GP, Purkis SJ, Renaud P (31 May 2012). "Red Sea coral reef trajectories over 2 decades suggest increasing community homogenization and decline in coral size". PLOS ONE. 7 (5): e38396. Bibcode:2012PLoSO...738396R. doi:10.1371/journal.pone.0038396. PMC 3365012. PMID 22693620.
  145. ^ Furby KA, Bouwmeester J, Berumen ML (4 January 2013). "Susceptibility of central Red Sea corals during a major bleaching event". Coral Reefs. 32 (2): 505–513. Bibcode:2013CorRe..32..505F. doi:10.1007/s00338-012-0998-5. S2CID 17189231. Archived from the original on 29 September 2018. Retrieved 29 November 2017.
  146. ^ a b Maire, Justin; van Oppen, Madeleine J.H. (March 2022). "A role for bacterial experimental evolution in coral bleaching mitigation?". Trends in Microbiology. 30 (3): 217–228. doi:10.1016/j.tim.2021.07.006. ISSN 0966-842X. PMID 34429226.
  147. ^ Leggat, William P.; Camp, Emma F.; Suggett, David J.; Heron, Scott F.; Fordyce, Alexander J.; Gardner, Stephanie; Deakin, Lachlan; Turner, Michael; Beeching, Levi J.; Kuzhiumparambil, Unnikrishnan; Eakin, C. Mark; Ainsworth, Tracy D. (August 2019). "Rapid Coral Decay Is Associated with Marine Heatwave Mortality Events on Reefs". Current Biology. 29 (16): 2723–2730.e4. Bibcode:2019CBio...29E2723L. doi:10.1016/j.cub.2019.06.077. hdl:10453/135453. ISSN 0960-9822. PMID 31402301.
  148. ^ LaJeunesse, Todd. "Diversity of Corals, Algae in Warm Indian Ocean Suggests Resilience to Future Global Warming". Penn State Science. Archived from the original on 7 March 2014. Retrieved 27 February 2014.
  149. ^ LaJeunesse TC, Smith R, Walther M, Pinzón J, Pettay DT, McGinley M, Aschaffenburg M, Medina-Rosas P, Cupul-Magaña AL, Pérez AL, Reyes-Bonilla H, Warner ME (October 2010). "Host-symbiont recombination versus natural selection in the response of coral-dinoflagellate symbioses to environmental disturbance". Proceedings. Biological Sciences. 277 (1696): 2925–34. Bibcode:2010RSPSB.277.2925L. doi:10.1098/rspb.2010.0385. PMC 2982020. PMID 20444713.
  150. ^ Climatewire, Lauren Morello. "Can Corals Adapt to Climate Change and Ocean Acidification?". Scientific American. Archived from the original on 1 December 2017. Retrieved 29 November 2017.
  151. ^ D’Angelo, Cecilia; Denzel, Andrea; Vogt, Alexander; Matz, Mikhail V.; Oswald, Franz; Salih, Anya; Nienhaus, G. Ulrich; Wiedenmann, Jörg (29 July 2008). "Blue light regulation of host pigment in reef-building corals". Marine Ecology Progress Series. 364: 97–106. Bibcode:2008MEPS..364...97D. doi:10.3354/meps07588. ISSN 0171-8630.
  152. ^ Enríquez, Susana; Méndez, Eugenio R.; Iglesias -Prieto, Roberto (2005). "Multiple scattering on coral skeletons enhances light absorption by symbiotic algae". Limnology and Oceanography. 50 (4): 1025–1032. Bibcode:2005LimOc..50.1025E. doi:10.4319/lo.2005.50.4.1025. ISSN 1939-5590. S2CID 27756367.
  153. ^ a b c Baird, Andrew H.; Bhagooli, Ranjeet; Ralph, Peter J.; Takahashi, Shunichi (1 January 2009). "Coral bleaching: the role of the host". Trends in Ecology & Evolution. 24 (1): 16–20. Bibcode:2009TEcoE..24...16B. doi:10.1016/j.tree.2008.09.005. ISSN 0169-5347. PMID 19022522.
  154. ^ a b Ainsworth, T. D.; Hoegh-Guldberg, O.; Heron, S. F.; Skirving, W. J.; Leggat, W. (3 October 2008). "Early cellular changes are indicators of pre-bleaching thermal stress in the coral host". Journal of Experimental Marine Biology and Ecology. 364 (2): 63–71. Bibcode:2008JEMBE.364...63A. doi:10.1016/j.jembe.2008.06.032. ISSN 0022-0981.
  155. ^ Grottoli, Andréa G.; Rodrigues, Lisa J.; Palardy, James E. (April 2006). "Heterotrophic plasticity and resilience in bleached corals". Nature. 440 (7088): 1186–1189. Bibcode:2006Natur.440.1186G. doi:10.1038/nature04565. ISSN 1476-4687. PMID 16641995. S2CID 4422247.
  156. ^ a b c McCook, L.; Jompa, J.; Diaz-Pulido, G. (1 May 2001). "Competition between corals and algae on coral reefs: a review of evidence and mechanisms". Coral Reefs. 19 (4): 400–417. Bibcode:2001CorRe..19..400M. doi:10.1007/s003380000129. ISSN 1432-0975. S2CID 19522125.
  157. ^ a b Mollica, Nathaniel R.; Guo, Weifu; Cohen, Anne L.; Huang, Kuo-Fang; Foster, Gavin L.; Donald, Hannah K.; Solow, Andrew R. (20 February 2018). "Ocean acidification affects coral growth by reducing skeletal density". Proceedings of the National Academy of Sciences. 115 (8): 1754–1759. Bibcode:2018PNAS..115.1754M. doi:10.1073/pnas.1712806115. ISSN 0027-8424. PMC 5828584. PMID 29378969.
  158. ^ a b Dove, Sophie G.; Kline, David I.; Pantos, Olga; Angly, Florent E.; Tyson, Gene W.; Hoegh-Guldberg, Ove (17 September 2013). "Future reef decalcification under a business-as-usual CO 2 emission scenario". Proceedings of the National Academy of Sciences. 110 (38): 15342–15347. Bibcode:2013PNAS..11015342D. doi:10.1073/pnas.1302701110. ISSN 0027-8424. PMC 3780867. PMID 24003127.
  159. ^ "Scientists successfully develop 'heat resistant' coral to fight bleaching". phys.org. Retrieved 12 June 2020.
  160. ^ Cornwall, Warren (13 May 2020). "Lab-evolved algae could protect coral reefs". Science. doi:10.1126/science.abc7842. S2CID 219408415.
  161. ^ Buerger, P.; Alvarez-Roa, C.; Coppin, C. W.; Pearce, S. L.; Chakravarti, L. J.; Oakeshott, J. G.; Edwards, O. R.; Oppen, M. J. H. van (1 May 2020). "Heat-evolved microalgal symbionts increase coral bleaching tolerance". Science Advances. 6 (20): eaba2498. Bibcode:2020SciA....6.2498B. doi:10.1126/sciadv.aba2498. PMC 7220355. PMID 32426508.
  162. ^ "Probiotics help lab corals survive deadly heat stress". Science News. 13 August 2021. Retrieved 22 September 2021.
  163. ^ Santoro, Erika P.; Borges, Ricardo M.; Espinoza, Josh L.; Freire, Marcelo; Messias, Camila S. M. A.; Villela, Helena D. M.; Pereira, Leandro M.; Vilela, Caren L. S.; Rosado, João G.; Cardoso, Pedro M.; Rosado, Phillipe M.; Assis, Juliana M.; Duarte, Gustavo A. S.; Perna, Gabriela; Rosado, Alexandre S.; Macrae, Andrew; Dupont, Christopher L.; Nelson, Karen E.; Sweet, Michael J.; Voolstra, Christian R.; Peixoto, Raquel S. (August 2021). "Coral microbiome manipulation elicits metabolic and genetic restructuring to mitigate heat stress and evade mortality". Science Advances. 7 (33). Bibcode:2021SciA....7.3088S. doi:10.1126/sciadv.abg3088. PMC 8363143. PMID 34389536.
  164. ^ a b c d e f g h Ateweberhan M, Feary DA, Keshavmurthy S, Chen A, Schleyer MH, Sheppard CR (September 2013). "Climate change impacts on coral reefs: synergies with local effects, possibilities for acclimation, and management implications". Marine Pollution Bulletin. 74 (2): 526–39. Bibcode:2013MarPB..74..526A. doi:10.1016/j.marpolbul.2013.06.011. PMID 23816307.
  165. ^ a b c d e f Graham NA, Jennings S, MacNeil MA, Mouillot D, Wilson SK (February 2015). "Predicting climate-driven regime shifts versus rebound potential in coral reefs". Nature. 518 (7537): 94–7. Bibcode:2015Natur.518...94G. doi:10.1038/nature14140. PMID 25607371. S2CID 4453338.
  166. ^ a b Folke C, Carpenter S, Walker B, Scheffer M, Elmqvist T, Gunderson L, Holling C (2004). "Regime Shifts, Resilience, and Biodiversity in Ecosystem Management". Annual Review of Ecology, Evolution, and Systematics. 35 (1): 557–81. CiteSeerX 10.1.1.489.8717. doi:10.1146/annurev.ecolsys.35.021103.105711. JSTOR 30034127.
  167. ^ Camp, Emma. "Scientist description". National Geographic. Archived from the original on 10 June 2020. Retrieved 9 June 2020.
  168. ^ Coffey, Donavyn (31 January 2019). "What Is Coral Bleaching?". livescience.com. Archived from the original on 3 June 2020. Retrieved 10 June 2020.
  169. ^ a b c Baker AC, Glynn PW, Riegl B (10 December 2008). "Climate change and coral reef bleaching: An ecological assessment of long-term impacts, recovery trends and future outlook". Estuarine, Coastal and Shelf Science. 80 (4): 435–471. Bibcode:2008ECSS...80..435B. doi:10.1016/j.ecss.2008.09.003.
  170. ^ a b Hughes TP, Graham NA, Jackson JB, Mumby PJ, Steneck RS (November 2010). "Rising to the challenge of sustaining coral reef resilience". Trends in Ecology & Evolution. 25 (11): 633–42. Bibcode:2010TEcoE..25..633H. doi:10.1016/j.tree.2010.07.011. PMID 20800316.
  171. ^ Bellwood DR, Hoey AS, Ackerman JL, Depczynski M (2006). "Coral bleaching, reef fish community phase shifts and the resilience of coral reefs". Global Change Biology. 12 (9): 1587–94. Bibcode:2006GCBio..12.1587B. doi:10.1111/j.1365-2486.2006.01204.x. S2CID 86006489.
  172. ^ a b c d Bellwood DR, Hughes TP, Folke C, Nyström M (June 2004). "Confronting the coral reef crisis". Nature. 429 (6994): 827–33. Bibcode:2004Natur.429..827B. doi:10.1038/nature02691. PMID 15215854. S2CID 404163.
  173. ^ Van Oppen, M. J., & Gates, R. D. (2006). Conservation genetics and the resilience of reef‐building corals. Molecular Ecology, 15(13), 3863-3883.
  174. ^ Drury C. (2020) Resilience in Reef-Building Corals: The ecological and evolutionary importance of the host response to thermal stress. Molecular Ecology
  175. ^ Ainsworth TD, CL Hurd, RD Gates, PW Boyd (2019) How do we overcome abrupt degradation of marine ecosystems and meet the challenge of heatwaves and climate extremes? Global Change Biology 26: 343-354 https://doi.org/10.1111/gcb.14901 Archived 23 July 2021 at the Wayback Machine
  176. ^ US Department of Commerce, National Oceanic and Atmospheric Administration. "Where are marine protected areas located?". oceanservice.noaa.gov. Retrieved 29 May 2022.
  177. ^ Steneck, Robert S.; Mumby, Peter J.; MacDonald, Chancey; Rasher, Douglas B.; Stoyle, George (4 May 2018). "Attenuating effects of ecosystem management on coral reefs". Science Advances. 4 (5): eaao5493. Bibcode:2018SciA....4.5493S. doi:10.1126/sciadv.aao5493. ISSN 2375-2548. PMC 5942913. PMID 29750192.
  178. ^ U. of Queensland (14 June 2018). "Study finds marine protected areas can help coral reefs". biological-sciences.uq.edu.au. Archived from the original on 26 March 2023. Retrieved 29 May 2022.
  179. ^ Good, Alexandra M.; Bahr, Keisha D. (12 February 2021). "The coral conservation crisis: interacting local and global stressors reduce reef resiliency and create challenges for conservation solutions". SN Applied Sciences. 3 (3): 312. doi:10.1007/s42452-021-04319-8. ISSN 2523-3971. S2CID 233919638.
  180. ^ "New DNA study suggests coral reef biodiversity is seriously underestimated". Smithsonian Insider. 2 November 2011. Archived from the original on 7 March 2018. Retrieved 7 March 2018.
  181. ^ "What are coral reef services worth? $130,000 to $1.2 million per hectare, per year: experts". EurekAlert!. American Association for the Advancement of Science (AAAS). 16 October 2009. Archived from the original on 7 March 2018. Retrieved 7 March 2018.
  182. ^ Economic valuation and policy priorities for sustainable management of coral reefs. Sweden: World Fish Center. c. 2004. OCLC 56538155.
  183. ^ Hein, Margaux Y.; Birtles, Alastair; Willis, Bette L.; Gardiner, Naomi; Beeden, Roger; Marshall, Nadine A. (January 2019). "Coral restoration: Socio-ecological perspectives of benefits and limitations". Biological Conservation. 229: 14–25. Bibcode:2019BCons.229...14H. doi:10.1016/j.biocon.2018.11.014. ISSN 0006-3207.
  184. ^ Darling, Emily S.; Côté, Isabelle M. (2 March 2018). "Seeking resilience in marine ecosystems". Science. 359 (6379): 986–987. Bibcode:2018Sci...359..986D. doi:10.1126/science.aas9852. ISSN 0036-8075. PMID 29496864.
  185. ^ "Paris Agreement" (PDF). unfccc.int. Retrieved 22 March 2024.
  186. ^ a b Markandya A (21 October 2014). "Benefits and Costs of the Biodiversity Targets for the Post-2015 Development Agenda" (PDF). Copenhagen Consensus Center. Archived (PDF) from the original on 21 September 2015. Retrieved 3 March 2018.

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