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Effects of climate change on oceans

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Overview of climatic changes and their effects on the ocean. Regional effects are displayed in italics.
This NASA animation conveys Earth's oceanic processes as a driving force among Earth's interrelated systems.

There are many effects of climate change on oceans. One of the most important is an increase in ocean temperatures. More frequent marine heatwaves are linked to this. The rising temperature contributes to a rise in sea levels due to the expansion of water as it warms and the melting of ice sheets on land. Other effects on oceans include sea ice decline, reducing pH values and oxygen levels, as well as increased ocean stratification. All this can lead to changes of ocean currents, for example a weakening of the Atlantic meridional overturning circulation (AMOC). The main cause of these changes are the emissions of greenhouse gases from human activities, mainly burning of fossil fuels and deforestation. Carbon dioxide and methane are examples of greenhouse gases. The additional greenhouse effect leads to ocean warming because the ocean takes up most of the additional heat in the climate system. The ocean also absorbs some of the extra carbon dioxide that is in the atmosphere. This causes the pH value of the seawater to drop. Scientists estimate that the ocean absorbs about 25% of all human-caused CO2 emissions.

The various layers of the oceans have different temperatures. For example, the water is colder towards the bottom of the ocean. This temperature stratification will increase as the ocean surface warms due to rising air temperatures. Connected to this is a decline in mixing of the ocean layers, so that warm water stabilises near the surface. A reduction of cold, deep water circulation follows. The reduced vertical mixing makes it harder for the ocean to absorb heat. So a larger share of future warming goes into the atmosphere and land. One result is an increase in the amount of energy available for tropical cyclones and other storms. Another result is a decrease in nutrients for fish in the upper ocean layers. These changes also reduce the ocean's capacity to store carbon. At the same time, contrasts in salinity are increasing. Salty areas are becoming saltier and fresher areas less salty.

Warmer water cannot contain the same amount of oxygen as cold water. As a result, oxygen from the oceans moves to the atmosphere. Increased thermal stratification may reduce the supply of oxygen from surface waters to deeper waters. This lowers the water's oxygen content even more. The ocean has already lost oxygen throughout its water column. Oxygen minimum zones are increasing in size worldwide.

These changes harm marine ecosystems, and this can lead to biodiversity loss or changes in species distribution. This in turn can affect fishing and coastal tourism. For example, rising water temperatures are harming tropical coral reefs. The direct effect is coral bleaching on these reefs, because they are sensitive to even minor temperature changes. So a small increase in water temperature could have a significant impact in these environments. Another example is loss of sea ice habitats due to warming. This will have severe impacts on polar bears and other animals that rely on it. The effects of climate change on oceans put additional pressures on ocean ecosystems which are already under pressure by other impacts from human activities.

Changes due to rising greenhouse gas levels

Most excess heat trapped by human-induced global warming is absorbed by the oceans, penetrating to its deeper layers.
Energy (heat) added to various parts of the climate system due to global warming (data from 2007).
Further information: Climate change and Effects of climate change

Presently (2020), atmospheric carbon dioxide (CO2) levels of more than 410 parts per million (ppm) are nearly 50% higher than preindustrial levels. These elevated levels and rapid growth rates are unprecedented in the geological record's 55 million years. The source for this excess CO2 is clearly established as human-driven, reflecting a mix of fossil fuel burning, industrial, and land-use/land-change emissions. The idea that the ocean serves as a major sink for anthropogenic CO2 has been discussed in scientific literature since at least the late 1950s. Several pieces of evidence point to the ocean absorbing roughly a quarter of total anthropogenic CO2 emissions.

The latest key findings about the observed changes and impacts from 2019 include:

It is virtually certain that the global ocean has warmed unabated since 1970 and has taken up more than 90% of the excess heat in the climate system . Since 1993, the rate of ocean warming has more than doubled . Marine heatwaves have very likely doubled in frequency since 1982 and are increasing in intensity . By absorbing more CO2, the ocean has undergone increasing surface acidification . A loss of oxygen has occurred from the surface to 1000 m .

— IPCC Special Report on the Ocean and Cryosphere in a Changing Climate (2019),

Rising ocean temperature

Land surface temperatures have increased faster than ocean temperatures as the ocean absorbs about 92% of excess heat generated by climate change. Chart with data from NASA showing how land and sea surface air temperatures have changed vs a pre-industrial baseline.
The illustration of temperature changes from 1960 to 2019 across each ocean starting at the Southern Ocean around Antarctica.
See also: Ocean temperature, Sea surface temperature, and Marine heatwave

It is clear that the ocean is warming as a result of climate change, and this rate of warming is increasing. The global ocean was the warmest it had ever been recorded by humans in 2022. This is determined by the ocean heat content, which exceeded the previous 2021 maximum in 2022. The steady rise in ocean temperatures is an unavoidable result of the Earth's energy imbalance, which is primarily caused by rising levels of greenhouse gases. Between pre-industrial times and the 2011–2020 decade, the ocean's surface has heated between 0.68 and 1.01 °C.

The majority of ocean heat gain occurs in the Southern Ocean. For example, between the 1950s and the 1980s, the temperature of the Antarctic Southern Ocean rose by 0.17 °C (0.31 °F), nearly twice the rate of the global ocean.

The warming rate varies with depth. The upper ocean (above 700 m) is warming the fastest. At an ocean depth of a thousand metres the warming occurs at a rate of nearly 0.4 °C per century (data from 1981 to 2019). In deeper zones of the ocean (globally speaking), at 2000 metres depth, the warming has been around 0.1 °C per century. The warming pattern is different for the Antarctic Ocean (at 55°S), where the highest warming (0.3 °C per century) has been observed at a depth of 4500 m.

Marine heatwaves

Marine heatwaves also take their toll on marine life: For example, due to fall-out from the 2019-2021 Pacific Northwest marine heatwave, Bering Sea snow crab populations declined 84% between 2018 and 2022, a loss of 9.8 billion crabs.

This section is an excerpt from Marine heatwave. Scientists predict that the frequency, duration, scale (or area) and intensity of marine heatwaves will continue to increase. This is because sea surface temperatures will continue to increase with global warming. The IPCC Sixth Assessment Report in 2022 has summarized research findings to date and stated that "marine heatwaves are more frequent , more intense and longer since the 1980s, and since at least 2006 very likely attributable to anthropogenic climate change". This confirms earlier findings in a report by the IPCC in 2019 which had found that "marine heatwaves have doubled in frequency and have become longer lasting, more intense and more extensive (very likely).". The extent of ocean warming depends on greenhouse gas emission scenarios, and thus humans' climate change mitigation efforts. Scientists predict that marine heatwaves will become "four times more frequent in 2081–2100 compared to 1995–2014" under the lower greenhouse gas emissions scenario, or eight times more frequent under the higher emissions scenario.

Ocean heat content

The ocean temperature varies from place to place. Temperatures are higher near the equator and lower at the poles. As a result, changes in total ocean heat content best illustrate ocean warming. When compared to 1969–1993, heat uptake has increased between 1993 and 2017.

This section is an excerpt from Ocean heat content.

Ocean heat content (OHC) or ocean heat uptake (OHU) is the energy absorbed and stored by oceans. To calculate the ocean heat content, it is necessary to measure ocean temperature at many different locations and depths. Integrating the areal density of a change in enthalpic energy over an ocean basin or entire ocean gives the total ocean heat uptake. Between 1971 and 2018, the rise in ocean heat content accounted for over 90% of Earth's excess energy from global heating. The main driver of this increase was caused by humans via their rising greenhouse gas emissions. By 2020, about one third of the added energy had propagated to depths below 700 meters.

In 2023, the world's oceans were again the hottest in the historical record and exceeded the previous 2022 record maximum. The five highest ocean heat observations to a depth of 2000 meters occurred in the period 2019–2023. The North Pacific, North Atlantic, the Mediterranean, and the Southern Ocean all recorded their highest heat observations for more than sixty years of global measurements. Ocean heat content and sea level rise are important indicators of climate change.

Ocean acidification

Ocean acidification: mean seawater pH. Mean seawater pH is shown based on in-situ measurements of pH from the Aloha station.
Change in pH since the beginning of the industrial revolution. RCP2.6 scenario is "low CO2 emissions". RCP8.5 scenario is "high CO2 emissions".
This section is an excerpt from Ocean acidification.

Ocean acidification is the ongoing decrease in the pH of the Earth's ocean. Between 1950 and 2020, the average pH of the ocean surface fell from approximately 8.15 to 8.05. Carbon dioxide emissions from human activities are the primary cause of ocean acidification, with atmospheric carbon dioxide (CO2) levels exceeding 422 ppm (as of 2024). CO2 from the atmosphere is absorbed by the oceans. This chemical reaction produces carbonic acid (H2CO3) which dissociates into a bicarbonate ion (HCO−3) and a hydrogen ion (H). The presence of free hydrogen ions (H) lowers the pH of the ocean, increasing acidity (this does not mean that seawater is acidic yet; it is still alkaline, with a pH higher than 8). Marine calcifying organisms, such as mollusks and corals, are especially vulnerable because they rely on calcium carbonate to build shells and skeletons.

A change in pH by 0.1 represents a 26% increase in hydrogen ion concentration in the world's oceans (the pH scale is logarithmic, so a change of one in pH units is equivalent to a tenfold change in hydrogen ion concentration). Sea-surface pH and carbonate saturation states vary depending on ocean depth and location. Colder and higher latitude waters are capable of absorbing more CO2. This can cause acidity to rise, lowering the pH and carbonate saturation levels in these areas. There are several other factors that influence the atmosphere-ocean CO2 exchange, and thus local ocean acidification. These include ocean currents and upwelling zones, proximity to large continental rivers, sea ice coverage, and atmospheric exchange with nitrogen and sulfur from fossil fuel burning and agriculture.

A lower ocean pH has a range of potentially harmful effects for marine organisms. Scientists have observed for example reduced calcification, lowered immune responses, and reduced energy for basic functions such as reproduction. Ocean acidification can impact marine ecosystems that provide food and livelihoods for many people. About one billion people are wholly or partially dependent on the fishing, tourism, and coastal management services provided by coral reefs. Ongoing acidification of the oceans may therefore threaten food chains linked with the oceans.

Time scales

Many ocean-related elements of the climate system respond slowly to warming. For instance, acidification of the deep ocean will continue for millennia, and the same is true for the increase in ocean heat content. Similarly, sea level rise will continue for centuries or even millennia even if greenhouse gas emissions are brought to zero, due to the slow response of ice sheets to warming and the continued uptake of heat by the oceans, which expand when warmed.

Effects on the physical environment

Sea level rise

Main article: Sea level rise
The global average sea level has risen about 250 millimetres (9.8 in) since 1880, increasing the elevation on top of which other types of flooding (high-tide flooding, storm surge) occur.

Many coastal cities will experience coastal flooding in the coming decades and beyond. Local subsidence, which may be natural but can be increased by human activity, can exacerbate coastal flooding. Coastal flooding will threaten hundreds of millions of people by 2050, particularly in Southeast Asia.

This section is an excerpt from Sea level rise. Between 1901 and 2018, the average sea level rose by 15–25 cm (6–10 in), with an increase of 2.3 mm (0.091 in) per year since the 1970s. This was faster than the sea level had ever risen over at least the past 3,000 years. The rate accelerated to 4.62 mm (0.182 in)/yr for the decade 2013–2022. Climate change due to human activities is the main cause. Between 1993 and 2018, melting ice sheets and glaciers accounted for 44% of sea level rise, with another 42% resulting from thermal expansion of water.

Changing ocean currents

Main articles: Ocean § Ocean currents and global climate, and Atlantic meridional overturning circulation
Waves on an ocean coast

Ocean currents are caused by temperature variations caused by sunlight and air temperatures at various latitudes, as well as prevailing winds and the different densities of salt and fresh water. Warm air rises near the equator. Later, as it moves toward the poles, it cools again. Cool air sinks near the poles, but warms and rises again as it moves toward the equator. This produces Hadley cells, which are large-scale wind patterns, with similar effects driving a mid-latitude cell in each hemisphere. Wind patterns associated with these circulation cells drive surface currents which push the surface water to higher latitudes where the air is colder. This cools the water, causing it to become very dense in comparison to lower latitude waters, causing it to sink to the ocean floor, forming North Atlantic Deep Water (NADW) in the north and Antarctic Bottom Water (AABW) in the south.

Driven by this sinking and the upwelling that occurs in lower latitudes, as well as the driving force of the winds on surface water, the ocean currents act to circulate water throughout the sea. When global warming is factored in, changes occur, particularly in areas where deep water is formed. As the oceans warm and glaciers and polar ice caps melt, more and more fresh water is released into the high latitude regions where deep water forms, lowering the density of the surface water. As a result, the water sinks more slowly than it would normally.

The Atlantic Meridional Overturning Circulation (AMOC) may have weakened since the preindustrial era, according to modern observations and paleoclimate reconstructions (the AMOC is part of a global thermohaline circulation), but there is too much uncertainty in the data to know for certain. Climate change projections assessed in 2021 indicate that the AMOC is very likely to weaken over the course of the 21st century. A weakening of this magnitude could have a significant impact on global climate, with the North Atlantic being particularly vulnerable.

Any changes in ocean currents affect the ocean's ability to absorb carbon dioxide (which is affected by water temperature) as well as ocean productivity because the currents transport nutrients (see Impacts on phytoplankton and net primary production). Because the AMOC deep ocean circulation is slow (it takes hundreds to thousands of years to circulate the entire ocean), it is slow to respond to climate change.

Increasing stratification

Main articles: Ocean stratification and Ocean § Physical properties
Drivers of hypoxia and ocean acidification intensification in upwelling shelf systems. Equatorward winds drive the upwelling of low dissolved oxygen (DO), high nutrient, and high dissolved inorganic carbon (DIC) water from above the oxygen minimum zone. Cross-shelf gradients in productivity and bottom water residence times drive the strength of DO (DIC) decrease (increase) as water transits across a productive continental shelf.

Changes in ocean stratification are significant because they can influence productivity and oxygen levels. The separation of water into layers based on density is known as stratification. Stratification by layers occurs in all ocean basins. The stratified layers limit how much vertical water mixing takes place, reducing the exchange of heat, carbon, oxygen and particles between the upper ocean and the interior. Since 1970, there has been an increase in stratification in the upper ocean due to global warming and, in some areas, salinity changes. The salinity changes are caused by evaporation in tropical waters, which results in higher salinity and density levels. Meanwhile, melting ice can cause a decrease in salinity at higher latitudes.

Temperature, salinity and pressure all influence water density. As surface waters are often warmer than deep waters, they are less dense, resulting in stratification. This stratification is crucial not just in the production of the Atlantic Meridional Overturning Circulation, which has worldwide weather and climate ramifications, but it is also significant because stratification controls the movement of nutrients from deep water to the surface. This increases ocean productivity and is associated with the compensatory downward flow of water that carries oxygen from the atmosphere and surface waters into the deep sea.

Reduced oxygen levels

Main article: Ocean deoxygenation
Global map of low and declining oxygen levels in the open ocean and coastal waters. The map indicates coastal sites where anthropogenic nutrients have resulted in oxygen declines to less than 2 mg L (red dots), as well as ocean oxygen minimum zones at 300 metres (blue shaded regions).

Climate change has an impact on ocean oxygen, both in coastal areas and in the open ocean.

The open ocean naturally has some areas of low oxygen, known as oxygen minimum zones. These areas are isolated from the atmospheric oxygen by sluggish ocean circulation. At the same time, oxygen is consumed when sinking organic matter from surface waters is broken down. These low oxygen ocean areas are expanding as a result of ocean warming which both reduces water circulation and also reduces the oxygen content of that water, while the solubility of oxygen declines as the temperature rises.

Overall ocean oxygen concentrations are estimated to have declined 2% over 50 years from the 1960s. The nature of the ocean circulation means that in general these low oxygen regions are more pronounced in the Pacific Ocean. Low oxygen represents a stress for almost all marine animals. Very low oxygen levels create regions with much reduced fauna. It is predicted that these low oxygen zones will expand in future due to climate change, and this represents a serious threat to marine life in these oxygen minimum zones.  

The second area of concern relates to coastal waters where increasing nutrient supply from rivers to coastal areas leads to increasing production and sinking organic matter which in some coastal regions leads to extreme oxygen depletion, sometimes referred to as dead zones. These dead zones are expanding driven particularly by increasing nutrient inputs, but also compounded by increasing ocean stratification driven by climate change.

Oceans turning green

Satellite image analysis reveals that the oceans have been gradually turning green from blue as climate breakdown continues. The color change has been detected for a majority of the word's ocean surfaces and may be due to changing plankton populations caused by climate change.

Changes to Earth's weather system and wind patterns

Further information: Effects of climate change on the water cycle

Climate change and the associated warming of the ocean will lead to widespread changes to the Earth's climate and weather system including increased tropical cyclone and monsoon intensities and weather extremes with some areas becoming wetter and others drier. Changing wind patterns are predicted to increase wave heights in some areas.

Intensifying tropical cyclones

Human-induced climate change "continues to warm the oceans which provide the memory of past accumulated effects". The result is a higher ocean heat content and higher sea surface temperatures. In turn, this "invigorates tropical cyclones to make them more intense, bigger, longer lasting and greatly increases their flooding rains". One example is Hurricane Harvey in 2017.

This section is an excerpt from Tropical cyclones and climate change.

Climate change affects tropical cyclones in a variety of ways: an intensification of rainfall and wind speed, an increase in the frequency of very intense storms and a poleward extension of where the cyclones reach maximum intensity are among the consequences of human-induced climate change. Tropical cyclones use warm, moist air as their source of energy or fuel. As climate change is warming ocean temperatures, there is potentially more of this fuel available.

Between 1979 and 2017, there was a global increase in the proportion of tropical cyclones of Category 3 and higher on the Saffir–Simpson scale. The trend was most clear in the north Indian Ocean, North Atlantic and in the Southern Indian Ocean. In the north Indian Ocean, particularly the Arabian Sea, the frequency, duration, and intensity of cyclones have increased significantly. There has been a 52% increase in the number of cyclones in the Arabian Sea, while the number of very severe cyclones have increased by 150%, during 1982–2019. Meanwhile, the total duration of cyclones in the Arabian Sea has increased by 80% while that of very severe cyclones has increased by 260%. In the North Pacific, tropical cyclones have been moving poleward into colder waters and there was no increase in intensity over this period. With 2 °C (3.6 °F) warming, a greater percentage (+13%) of tropical cyclones are expected to reach Category 4 and 5 strength. A 2019 study indicates that climate change has been driving the observed trend of rapid intensification of tropical cyclones in the Atlantic basin. Rapidly intensifying cyclones are hard to forecast and therefore pose additional risk to coastal communities.

Salinity changes

Further information: Ocean § Salinity, and Effects of climate change on the water cycle

Due to global warming and increased glacier melt, thermohaline circulation patterns may be altered by increasing amounts of freshwater released into oceans and, therefore, changing ocean salinity. Thermohaline circulation is responsible for bringing up cold, nutrient-rich water from the depths of the ocean, a process known as upwelling.

Seawater consists of fresh water and salt, and the concentration of salt in seawater is called salinity. Salt does not evaporate, thus the precipitation and evaporation of freshwater influences salinity strongly. Changes in the water cycle are therefore strongly visible in surface salinity measurements, which has been known since the 1930s.

The long term observation records show a clear trend: the global salinity patterns are amplifying in this period. This means that the high saline regions have become more saline, and regions of low salinity have become less saline. The regions of high salinity are dominated by evaporation, and the increase in salinity shows that evaporation is increasing even more. The same goes for regions of low salinity that are becoming less saline, which indicates that precipitation is becoming more intensified.

Sea ice decline and changes

Decline in arctic sea ice extent (area) from 1979 to 2022

Sea ice decline occurs more in the Arctic than in Antarctica, where it is more a matter of changing sea ice conditions.

This section is an excerpt from Arctic sea ice decline. Sea ice in the Arctic region has declined in recent decades in area and volume due to climate change. It has been melting more in summer than it refreezes in winter. Global warming, caused by greenhouse gas forcing is responsible for the decline in Arctic sea ice. The decline of sea ice in the Arctic has been accelerating during the early twenty-first century, with a decline rate of 4.7% per decade (it has declined over 50% since the first satellite records). Summertime sea ice will likely cease to exist sometime during the 21st century. This section is an excerpt from Antarctic sea ice § Recent trends and climate change. Sea ice extent in Antarctica varies a lot year by year. This makes it difficult determine a trend, and record highs and record lows have been observed between 2013 and 2023. The general trend since 1979, the start of the satellite measurements, has been roughly flat. Between 2015 and 2023, there has been a decline in sea ice, but due to the high variability, this does not correspond to a significant trend. The flat trend is in contrast with Arctic sea ice, which has seen a declining trend.

Impacts on biological processes

Examples of projected impacts and vulnerabilities for fisheries associated with climate change

Ocean productivity

Further information: Ocean § Oxygen, photosynthesis and carbon cycle

The process of photosynthesis in the surface ocean releases oxygen and consumes carbon dioxide. This photosynthesis in the ocean is dominated by phytoplankton – microscopic free-floating algae. After the plants grow, bacterial decomposition of the organic matter formed by photosynthesis in the ocean consumes oxygen and releases carbon dioxide. The sinking and bacterial decomposition of some organic matter in deep ocean water, at depths where the waters are out of contact with the atmosphere, leads to a reduction in oxygen concentrations and increase in carbon dioxide, carbonate and bicarbonate. This cycling of carbon dioxide in oceans is an important part of the global carbon cycle.

The photosynthesis in surface waters consumes nutrients (e.g. nitrogen and phosphorus) and transfers these nutrients to deep water as the organic matter produced by photosynthesis sinks upon the death of the organisms. Productivity in surface waters therefore depends in part on the transfer of nutrients from deep water back to the surface by ocean mixing and currents. The increasing stratification of the oceans due to climate change therefore acts generally to reduce ocean productivity. However, in some areas, such as previously ice covered regions, productivity may increase. This trend is already observable and is projected to continue under current projected climate change. In the Indian Ocean for example, productivity is estimated to have declined over the past sixty years due to climate warming and is projected to continue.

Ocean productivity under a very high emission scenario (RCP8.5) is very likely to drop by 4-11% by 2100. The decline will show regional variations. For example, the tropical ocean NPP will decline more: by 7–16% for the same emissions scenario. Less organic matter will likely sink from the upper oceans into deeper ocean layers due to increased ocean stratification and a reduction in nutrient supply. The reduction in ocean productivity is due to the "combined effects of warming, stratification, light, nutrients and predation".

Calcifying organisms and ocean acidification

This section is an excerpt from Ocean acidification § Complexity of research findings.

The full ecological consequences of the changes in calcification due to ocean acidification are complex but it appears likely that many calcifying species will be adversely affected by ocean acidification. Increasing ocean acidification makes it more difficult for shell-accreting organisms to access carbonate ions, essential for the production of their hard exoskeletal shell. Oceanic calcifying organism span the food chain from autotrophs to heterotrophs and include organisms such as coccolithophores, corals, foraminifera, echinoderms, crustaceans and molluscs.

Overall, all marine ecosystems on Earth will be exposed to changes in acidification and several other ocean biogeochemical changes. Ocean acidification may force some organisms to reallocate resources away from productive endpoints in order to maintain calcification. For example, the oyster Magallana gigas is recognized to experience metabolic changes alongside altered calcification rates due to energetic tradeoffs resulting from pH imbalances.

Harmful algal blooms

Further information: Harmful algal bloom

Although the drivers of harmful algal blooms (HABs) are poorly understood, they appear to have increased in range and frequency in coastal areas since the 1980s. This is the result of human induced factors such as increased nutrient inputs (nutrient pollution) and climate change (in particular the warming of water temperatures). The parameters that affect the formation of HABs are ocean warming, marine heatwaves, oxygen loss, eutrophication and water pollution. These increases in HABs are of concern because of the impact of their occurrence on local food security, tourism and the economy.

It is however also possible that the perceived increase in HABs globally is simply due to more severe bloom impacts and better monitoring and not due to climate change.

Impacts on coral reefs and fisheries

Coral reefs

Further information: Coral bleaching, Coral reef, and Coral
Bleached Staghorn coral in the Great Barrier Reef.

While some mobile marine species can migrate in response to climate change, others such as corals find this much more difficult. A coral reef is an underwater ecosystem characterised by reef-building corals. Reefs are formed by colonies of coral polyps held together by calcium carbonate. Coral reefs are important centres of biodiversity and vital to millions of people who rely on them for coastal protection, food and for sustaining tourism in many regions.

Warm water corals are clearly in decline, with losses of 50% over the last 30–50 years due to multiple threats from ocean warming, ocean acidification, pollution and physical damage from activities such as fishing. These pressures are expected to intensify.

The warming ocean surface waters can lead to bleaching of the corals which can cause serious damage and/or 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". Marine heatwaves have caused coral reef mass mortality. It is expected that many coral reefs will suffer irreversible changes and loss due to marine heatwaves with global temperatures increasing by more than 1.5 °C.

Coral bleaching occurs when thermal stress from a warming ocean results in the expulsion of the symbiotic algae that resides within coral tissues. These symbiotic algae are the reason for the bright, vibrant colors of coral reefs. A 1-2°C sustained increase in seawater temperatures is sufficient for bleaching to occur, which turns corals white. If a coral is bleached for a prolonged period of time, death may result. In the Great Barrier Reef, before 1998 there were no such events. The first event happened in 1998 and after that, they began to occur more frequently. Between 2016 and 2020 there were three of them.

Apart from coral bleaching, the reducing pH value in oceans is also a problem for coral reefs because ocean acidification reduces coralline algal biodiversity. The physiology of coralline algal calcification determines how the algae will respond to ocean acidification.

This section is an excerpt from Ocean acidification § Corals.

Warm water corals are clearly in decline, with losses of 50% over the last 30–50 years due to multiple threats from ocean warming, ocean acidification, pollution and physical damage from activities such as fishing, and these pressures are expected to intensify.

The fluid in the internal compartments (the coelenteron) where corals grow their exoskeleton is also extremely important for calcification growth. When the saturation state of aragonite in the external seawater is at ambient levels, the corals will grow their aragonite crystals rapidly in their internal compartments, hence their exoskeleton grows rapidly. If the saturation state of aragonite in the external seawater is lower than the ambient level, the corals have to work harder to maintain the right balance in the internal compartment. When that happens, the process of growing the crystals slows down, and this slows down the rate of how much their exoskeleton is growing. Depending on the aragonite saturation state in the surrounding water, the corals may halt growth because pumping aragonite into the internal compartment will not be energetically favorable. Under the current progression of carbon emissions, around 70% of North Atlantic cold-water corals will be living in corrosive waters by 2050–60.

Effects on fisheries

This section is an excerpt from Climate change and fisheries.

Fisheries are affected by climate change in many ways: marine aquatic ecosystems are being affected by rising ocean temperatures, ocean acidification and ocean deoxygenation, while freshwater ecosystems are being impacted by changes in water temperature, water flow, and fish habitat loss. These effects vary in the context of each fishery. Climate change is modifying fish distributions and the productivity of marine and freshwater species. Climate change is expected to lead to significant changes in the availability and trade of fish products. The geopolitical and economic consequences will be significant, especially for the countries most dependent on the sector. The biggest decreases in maximum catch potential can be expected in the tropics, mostly in the South Pacific regions.

The impacts of climate change on ocean systems has impacts on the sustainability of fisheries and aquaculture, on the livelihoods of the communities that depend on fisheries, and on the ability of the oceans to capture and store carbon (biological pump). The effect of sea level rise means that coastal fishing communities are significantly impacted by climate change, while changing rainfall patterns and water use impact on inland freshwater fisheries and aquaculture. Increased risks of floods, diseases, parasites and harmful algal blooms are climate change impacts on aquaculture which can lead to losses of production and infrastructure.

It is projected that "climate change decreases the modelled global fish community biomass by as much as 30% by 2100".

Impacts on marine mammals

Regions and habitats particularly affected

Some effects on marine mammals, especially those in the Arctic, are very direct such as loss of habitat, temperature stress, and exposure to severe weather. Other effects are more indirect, such as changes in host pathogen associations, changes in body condition because of predator–prey interaction, changes in exposure to toxins and CO2 emissions, and increased human interactions. Despite the large potential impacts of ocean warming on marine mammals, the global vulnerability of marine mammals to global warming is still poorly understood.

Marine mammals have evolved to live in oceans, but climate change is affecting their natural habitat. Some species may not adapt fast enough, which might lead to their extinction.

It has been generally assumed that the Arctic marine mammals were the most vulnerable in the face of climate change given the substantial observed and projected decline in Arctic sea ice. However, research has shown that the North Pacific Ocean, the Greenland Sea and the Barents Sea host the species that are most vulnerable to global warming. The North Pacific has already been identified as a hotspot for human threats for marine mammals and is now also a hotspot for vulnerability to global warming. Marine mammals in this region will face double jeopardy from both human activities (e.g., marine traffic, pollution and offshore oil and gas development) and global warming, with potential additive or synergetic effects. As a result, these ecosystems face irreversible consequences for marine ecosystem functioning.

Marine organisms usually tend to encounter relatively stable temperatures compared to terrestrial species and thus are likely to be more sensitive to temperature change than terrestrial organisms. Therefore, the ocean warming will lead to the migration of increased species, as endangered species look for a more suitable habitat. If sea temperatures continue to rise, then some fauna may move to cooler water and some range-edge species may disappear from regional waters or experience a reduced global range. Change in the abundance of some species will alter the food resources available to marine mammals, which then results in marine mammals' biogeographic shifts. Furthermore, if a species is unable to successfully migrate to a suitable environment, it will be at risk of extinction if it cannot adapt to rising temperatures of the ocean.

Arctic sea ice decline leads to loss of the sea ice habitat, elevations of water and air temperature, and increased occurrence of severe weather. The loss of sea ice habitat will reduce the abundance of seal prey for marine mammals, particularly polar bears. Sea ice changes may also have indirect effects on animal heath due to changes in the transmission of pathogens, impacts on animals' body condition due to shifts in the prey-based food web, and increased exposure to toxicants as a result of increased human habitation in the Arctic habitat.

Sea level rise is also important when assessing the impacts of global warming on marine mammals, since it affects coastal environments that marine mammal species rely on.

Polar bears

A polar bear waiting in the Fall for the sea ice to form.
This section is an excerpt from Polar bear conservation § Climate change. The key danger for polar bears posed by the effects of climate change is malnutrition or starvation due to habitat loss. Polar bears hunt seals from a platform of sea ice. Rising temperatures cause the sea ice to melt earlier in the year, driving the bears to shore before they have built sufficient fat reserves to survive the period of scarce food in the late summer and early fall. Reduction in sea-ice cover also forces bears to swim longer distances, which further depletes their energy stores and occasionally leads to drowning. Thinner sea ice tends to deform more easily, which appears to make it more difficult for polar bears to access seals. Insufficient nourishment leads to lower reproductive rates in adult females and lower survival rates in cubs and juvenile bears, in addition to poorer body condition in bears of all ages.

Seals

Further information: Ringed seal § Climate change
Harp seal mother nursing pup on sea ice

Seals are another marine mammal that are susceptible to climate change. Much like polar bears, some seal species have evolved to rely on sea ice. They use the ice platforms for breeding and raising young seal pups. In 2010 and 2011, sea ice in the Northwest Atlantic was at or near an all-time low and harp seals as well as ringed seals that bred on thin ice saw increased death rates. Antarctic fur seals in South Georgia in the South Atlantic Ocean saw extreme reductions over a 20-year study, during which scientists measured increased sea surface temperature anomalies.

Dolphins

Climate change has had a significant impact on various dolphin species. For example: In the Mediterranean, increased sea surface temperatures, salinity, upwelling intensity, and sea levels have led to a reduction in prey resources, causing a steep decline in the short-beaked common dolphin subpopulation in the Mediterranean, which was classified as endangered in 2003. At the Shark Bay World Heritage Area in Western Australia, the local population of the Indo-Pacific bottlenose dolphin had a significant decline following a marine heatwave in 2011. River dolphins are highly affected by climate change as high evaporation rates, increased water temperatures, decreased precipitation, and increased acidification occur.

This section is an excerpt from Dolphin § Impacts of climate change. Dolphins are marine mammals with broad geographic extent, making them susceptible to climate change in various ways. The most common effect of climate change on dolphins is the increasing water temperatures across the globe. This has caused a large variety of dolphin species to experience range shifts, in which the species move from their typical geographic region to cooler waters. Another side effect of increasing water temperatures is the increase in harmful algae blooms, which has caused a mass die-off of bottlenose dolphins.

North Atlantic right whales

This section is an excerpt from North Atlantic right whale § Climate change.

Anthropogenic climate change poses a clear and growing threat to right whales. Documented effects in the scientific literature include impacts on reproduction, range, prey access, interactions with human activities, and individual health condition.

Climate-driven changes to ocean circulation and water temperatures have affected the species' foraging and habitat use patterns, with numerous harmful consequences. Warming waters lead to decreased abundance of an important prey species, the zooplankton Calanus finmarchicus. This reduction in prey availability affects the health of the right whale population in numerous ways. The most direct impacts are on the survival and reproductive success of individual whales, as lower C. finmarchicus densities have been associated with malnutrition-related health issues and difficulties successfully giving birth to and rearing calves.

Potential feedback effects

Methane release from methane clathrate

Rising ocean temperatures also have the potential to impact methane clathrate reservoirs located under the ocean floor sediments. These trap large amounts of the greenhouse gas methane, which ocean warming has the potential to release. However, it is currently considered unlikely that gas clathrates (mostly methane) in subsea clathrates will lead to a "detectable departure from the emissions trajectory during this century".

In 2004 the global inventory of ocean methane clathrates was estimated to occupy between one and five million cubic kilometres.

See also

References

  1. Käse, Laura; Geuer, Jana K. (2018). "Phytoplankton Responses to Marine Climate Change – an Introduction". YOUMARES 8 – Oceans Across Boundaries: Learning from each other. pp. 55–71. doi:10.1007/978-3-319-93284-2_5. ISBN 978-3-319-93283-5. S2CID 134263396.
  2. ^ "Summary for Policymakers". The Ocean and Cryosphere in a Changing Climate (PDF). 2019. pp. 3–36. doi:10.1017/9781009157964.001. ISBN 978-1-00-915796-4. Archived (PDF) from the original on 2023-03-29. Retrieved 2023-03-26.
  3. Cheng, Lijing; Abraham, John; Hausfather, Zeke; Trenberth, Kevin E. (11 January 2019). "How fast are the oceans warming?". Science. 363 (6423): 128–129. Bibcode:2019Sci...363..128C. doi:10.1126/science.aav7619. PMID 30630919. S2CID 57825894.
  4. ^ Doney, Scott C.; Busch, D. Shallin; Cooley, Sarah R.; Kroeker, Kristy J. (2020-10-17). "The Impacts of Ocean Acidification on Marine Ecosystems and Reliant Human Communities". Annual Review of Environment and Resources. 45 (1): 83–112. doi:10.1146/annurev-environ-012320-083019. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License Archived 2017-10-16 at the Wayback Machine
  5. ^ Bindoff, N.L., W.W.L. Cheung, J.G. Kairo, J. Arístegui, V.A. Guinder, R. Hallberg, N. Hilmi, N. Jiao, M.S. Karim, L. Levin, S. O'Donoghue, S.R. Purca Cuicapusa, B. Rinkevich, T. Suga, A. Tagliabue, and P. Williamson, 2019: Chapter 5: Changing Ocean, Marine Ecosystems, and Dependent Communities Archived 2019-12-20 at the Wayback Machine. In: IPCC Special Report on the Ocean and Cryosphere in a Changing Climate Archived 2021-07-12 at the Wayback Machine . In press.
  6. Freedman, Andrew (29 September 2020). "Mixing of the planet's ocean waters is slowing down, speeding up global warming, study finds". The Washington Post. Archived from the original on 15 October 2020. Retrieved 12 October 2020.
  7. ^ Cheng, Lijing; Trenberth, Kevin E.; Gruber, Nicolas; Abraham, John P.; Fasullo, John T.; Li, Guancheng; Mann, Michael E.; Zhao, Xuanming; Zhu, Jiang (2020). "Improved Estimates of Changes in Upper Ocean Salinity and the Hydrological Cycle". Journal of Climate. 33 (23): 10357–10381. Bibcode:2020JCli...3310357C. doi:10.1175/jcli-d-20-0366.1 (inactive 2 December 2024).{{cite journal}}: CS1 maint: DOI inactive as of December 2024 (link)
  8. Chester, R.; Jickells, Tim (2012). "Chapter 9: Nutrients oxygen organic carbon and the carbon cycle in seawater". Marine geochemistry (3rd ed.). Chichester, West Sussex, UK: Wiley/Blackwell. pp. 182–183. ISBN 978-1-118-34909-0. OCLC 781078031. Archived from the original on 2022-02-18. Retrieved 2022-10-20.
  9. Top 700 meters: Lindsey, Rebecca; Dahlman, Luann (6 September 2023). "Climate Change: Ocean Heat Content". climate.gov. National Oceanic and Atmospheric Administration (NOAA). Archived from the original on 29 October 2023.Top 2000 meters: "Ocean Warming / Latest Measurement: December 2022 / 345 (± 2) zettajoules since 1955". NASA.gov. National Aeronautics and Space Administration. Archived from the original on 20 October 2023.
  10. "The Oceans Are Heating Up Faster Than Expected". scientific american. Archived from the original on 3 March 2020. Retrieved 3 March 2020.
  11. "Global Annual Mean Surface Air Temperature Change". NASA. Archived from the original on 16 April 2020. Retrieved 23 February 2020.
  12. Cheng, Lijing; Abraham, John; Zhu, Jiang; Trenberth, Kevin E.; Fasullo, John; Boyer, Tim; Locarnini, Ricardo; Zhang, Bin; Yu, Fujiang; Wan, Liying; Chen, Xingrong (February 2020). "Record-Setting Ocean Warmth Continued in 2019". Advances in Atmospheric Sciences. 37 (2): 137–142. Bibcode:2020AdAtS..37..137C. doi:10.1007/s00376-020-9283-7. S2CID 210157933.
  13. ^ Cheng, Lijing; Abraham, John; Trenberth, Kevin E.; Fasullo, John; Boyer, Tim; Mann, Michael E.; Zhu, Jiang; Wang, Fan; Locarnini, Ricardo; Li, Yuanlong; Zhang, Bin; Yu, Fujiang; Wan, Liying; Chen, Xingrong; Feng, Licheng (2023). "Another Year of Record Heat for the Oceans". Advances in Atmospheric Sciences. 40 (6): 963–974. Bibcode:2023AdAtS..40..963C. doi:10.1007/s00376-023-2385-2. ISSN 0256-1530. PMC 9832248. PMID 36643611. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  14. ^ Fox-Kemper, B., H.T. Hewitt, C. Xiao, G. Aðalgeirsdóttir, S.S. Drijfhout, T.L. Edwards, N.R. Golledge, M. Hemer, R.E. Kopp, G. Krinner, A. Mix, D. Notz, S. Nowicki, I.S. Nurhati, L. Ruiz, J.-B. Sallée, A.B.A. Slangen, and Y. Yu, 2021: Chapter 9: Ocean, Cryosphere and Sea Level Change Archived 2022-10-24 at the Wayback Machine. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change Archived 2021-08-09 at the Wayback Machine . Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 1211–1362
  15. Gille, Sarah T. (2002-02-15). "Warming of the Southern Ocean Since the 1950s". Science. 295 (5558): 1275–1277. Bibcode:2002Sci...295.1275G. doi:10.1126/science.1065863. PMID 11847337. S2CID 31434936.
  16. Barkhordarian, Armineh; Nielsen, David Marcolino; Baehr, Johanna (2022-06-21). "Recent marine heatwaves in the North Pacific warming pool can be attributed to rising atmospheric levels of greenhouse gases". Communications Earth & Environment. 3 (1): 131. Bibcode:2022ComEE...3..131B. doi:10.1038/s43247-022-00461-2. ISSN 2662-4435.
  17. Bryce, Emma (2022-10-20). "Billions gone: what's behind the disappearance of Alaska snow crabs?". The Guardian. ISSN 0261-3077. Archived from the original on 2023-07-25. Retrieved 2023-10-30.
  18. ^ Fox-Kemper, B., H.T. Hewitt, C. Xiao, G. Aðalgeirsdóttir, S.S. Drijfhout, T.L. Edwards, N.R. Golledge, M. Hemer, R.E. Kopp, G.  Krinner, A. Mix, D. Notz, S. Nowicki, I.S. Nurhati, L. Ruiz, J.-B. Sallée, A.B.A. Slangen, and Y. Yu, 2021: Chapter 9: Ocean, Cryosphere and Sea Level Change. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change . Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 1211–1362, doi:10.1017/9781009157896.011.
  19. 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 . Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 379–550, doi:10.1017/9781009325844.005.
  20. IPCC, 2019: Technical Summary . In: IPCC Special Report on the Ocean and Cryosphere in a Changing Climate . Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 39–69. https://doi.org/10.1017/9781009157964.002
  21. Dijkstra, Henk A. (2008). Dynamical oceanography ( ed.). Berlin: Springer Verlag. p. 276. ISBN 9783540763758.
  22. von Schuckmann, K.; Cheng, L.; Palmer, M. D.; Hansen, J.; et al. (7 September 2020). "Heat stored in the Earth system: where does the energy go?". Earth System Science Data. 12 (3): 2013–2041. Bibcode:2020ESSD...12.2013V. doi:10.5194/essd-12-2013-2020. hdl:20.500.11850/443809. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  23. Cheng, Lijing; Abraham, John; Trenberth, Kevin; Fasullo, John; Boyer, Tim; Locarnini, Ricardo; et al. (2021). "Upper Ocean Temperatures Hit Record High in 2020". Advances in Atmospheric Sciences. 38 (4): 523–530. Bibcode:2021AdAtS..38..523C. doi:10.1007/s00376-021-0447-x. S2CID 231672261.
  24. Fox-Kemper, B., H.T. Hewitt, C. Xiao, G. Aðalgeirsdóttir, S.S. Drijfhout, T.L. Edwards, N.R. Golledge, M. Hemer, R.E. Kopp, G. Krinner, A. Mix, D. Notz, S. Nowicki, I.S. Nurhati, L. Ruiz, J.-B. Sallée, A.B.A. Slangen, and Y. Yu, 2021: Chapter 9: Ocean, Cryosphere and Sea Level Change Archived 2022-10-24 at the Wayback Machine. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change Archived 2021-08-09 at the Wayback Machine . Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 1211–1362.
  25. LuAnn Dahlman and Rebecca Lindsey (2020-08-17). "Climate Change: Ocean Heat Content". National Oceanic and Atmospheric Administration.
  26. "Study: Deep Ocean Waters Trapping Vast Store of Heat". Climate Central. 2016.
  27. Cheng, Lijing; Abraham, John; Trenberth, Kevin E.; Boyer, Tim; Mann, Michael E.; Zhu, Jiang; Wang, Fan; Yu, Fujiang; Locarnini, Ricardo; Fasullo, John; Zheng, Fei; Li, Yuanlong; et al. (2024). "New record ocean temperatures and related climate indicators in 2023". Advances in Atmospheric Sciences. 41 (6): 1068–1082. Bibcode:2024AdAtS..41.1068C. doi:10.1007/s00376-024-3378-5. ISSN 0256-1530.
  28. NOAA National Centers for Environmental Information, Monthly Global Climate Report for Annual 2023, published online January 2024, Retrieved on February 4, 2024 from https://www.ncei.noaa.gov/access/monitoring/monthly-report/global/202313.
  29. Cheng, Lijing; Foster, Grant; Hausfather, Zeke; Trenberth, Kevin E.; Abraham, John (2022). "Improved Quantification of the Rate of Ocean Warming". Journal of Climate. 35 (14): 4827–4840. Bibcode:2022JCli...35.4827C. doi:10.1175/JCLI-D-21-0895.1.
  30. Ritchie, Roser, Mispy, Ortiz-Ospina. "SDG 14 - Measuring progress towards the Sustainable Development Goals Archived 2022-01-22 at the Wayback Machine." SDG-Tracker.org, website (2018).
  31. Gattuso, J.-P.; Magnan, A.; Billé, R.; Cheung, W. W. L.; Howes, E. L.; Joos, F.; Allemand, D.; Bopp, L.; Cooley, S. R.; Eakin, C. M.; Hoegh-Guldberg, O.; Kelly, R. P.; Pörtner, H.-O.; Rogers, A. D.; Baxter, J. M.; Laffoley, D.; Osborn, D.; Rankovic, A.; Rochette, J.; Sumaila, U. R.; Treyer, S.; Turley, C. (3 July 2015). "Contrasting futures for ocean and society from different anthropogenic CO 2 emissions scenarios" (PDF). Science. 349 (6243): aac4722. doi:10.1126/science.aac4722. PMID 26138982. S2CID 206639157. Archived (PDF) from the original on 9 December 2022. Retrieved 21 November 2022.
  32. Terhaar, Jens; Frölicher, Thomas L.; Joos, Fortunat (2023). "Ocean acidification in emission-driven temperature stabilization scenarios: the role of TCRE and non-CO2 greenhouse gases". Environmental Research Letters. 18 (2): 024033. Bibcode:2023ERL....18b4033T. doi:10.1088/1748-9326/acaf91. ISSN 1748-9326. S2CID 255431338. Figure 1f
  33. Oxygen, Pro (2024-09-21). "Earth's CO2 Home Page". Retrieved 2024-09-21.
  34. Ocean acidification due to increasing atmospheric carbon dioxide (PDF). Royal Society. 2005. ISBN 0-85403-617-2.
  35. Jiang, Li-Qing; Carter, Brendan R.; Feely, Richard A.; Lauvset, Siv K.; Olsen, Are (2019). "Surface ocean pH and buffer capacity: past, present and future". Scientific Reports. 9 (1): 18624. Bibcode:2019NatSR...918624J. doi:10.1038/s41598-019-55039-4. PMC 6901524. PMID 31819102. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License Archived 16 October 2017 at the Wayback Machine
  36. Zhang, Y.; Yamamoto-Kawai, M.; Williams, W.J. (2020-02-16). "Two Decades of Ocean Acidification in the Surface Waters of the Beaufort Gyre, Arctic Ocean: Effects of Sea Ice Melt and Retreat From 1997–2016". Geophysical Research Letters. 47 (3). doi:10.1029/2019GL086421. S2CID 214271838.
  37. Beaupré-Laperrière, Alexis; Mucci, Alfonso; Thomas, Helmuth (2020-07-31). "The recent state and variability of the carbonate system of the Canadian Arctic Archipelago and adjacent basins in the context of ocean acidification". Biogeosciences. 17 (14): 3923–3942. Bibcode:2020BGeo...17.3923B. doi:10.5194/bg-17-3923-2020. S2CID 221369828.
  38. Anthony, K. R. N.; Kline, D. I.; Diaz-Pulido, G.; Dove, S.; Hoegh-Guldberg, O. (11 November 2008). "Ocean acidification causes bleaching and productivity loss in coral reef builders". Proceedings of the National Academy of Sciences. 105 (45): 17442–17446. Bibcode:2008PNAS..10517442A. doi:10.1073/pnas.0804478105. PMC 2580748. PMID 18988740.
  39. Dean, Cornelia (30 January 2009). "Rising Acidity Is Threatening Food Web of Oceans, Science Panel Says". New York Times.
  40. Service, Robert E. (13 July 2012). "Rising Acidity Brings an Ocean of Trouble". Science. 337 (6091): 146–148. Bibcode:2012Sci...337..146S. doi:10.1126/science.337.6091.146. PMID 22798578.
  41. ^ Arias, P.A., N. Bellouin, E. Coppola, R.G. Jones, G. Krinner, J. Marotzke, V. Naik, M.D. Palmer, G.-K. Plattner, J. Rogelj, M. Rojas, J. Sillmann, T. Storelvmo, P.W. Thorne, B. Trewin, K. Achuta Rao, B. Adhikary, R.P. Allan, K. Armour, G. Bala, R. Barimalala, S. Berger, J.G. Canadell, C. Cassou, A. Cherchi, W. Collins, W.D. Collins, S.L. Connors, S. Corti, F. Cruz, F.J. Dentener, C. Dereczynski, A. Di Luca, A. Diongue Niang, F.J. Doblas-Reyes, A. Dosio, H. Douville, F. Engelbrecht, V. Eyring, E. Fischer, P. Forster, B. Fox-Kemper, J.S. Fuglestvedt, J.C. Fyfe, N.P. Gillett, L. Goldfarb, I. Gorodetskaya, J.M. Gutierrez, R. Hamdi, E. Hawkins, H.T. Hewitt, P. Hope, A.S. Islam, C. Jones, D.S. Kaufman, R.E. Kopp, Y. Kosaka, J. Kossin, S. Krakovska, J.-Y. Lee, et al., 2021: Technical Summary Archived 2022-07-21 at the Wayback Machine. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change Archived 2021-08-09 at the Wayback Machine . Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 33−144.
  42. "Climate Change Indicators: Sea Level / Figure 1. Absolute Sea Level Change". EPA.gov. U.S. Environmental Protection Agency (EPA). July 2022. Archived from the original on 4 September 2023. Data sources: CSIRO, 2017. NOAA, 2022.
  43. ^ Nicholls, Robert J.; Lincke, Daniel; Hinkel, Jochen; Brown, Sally; Vafeidis, Athanasios T.; Meyssignac, Benoit; Hanson, Susan E.; Merkens, Jan-Ludolf; Fang, Jiayi (2021). "A global analysis of subsidence, relative sea-level change and coastal flood exposure". Nature Climate Change. 11 (4): 338–342. Bibcode:2021NatCC..11..338N. doi:10.1038/s41558-021-00993-z. S2CID 232145685. Archived from the original on 2022-08-10. Retrieved 2022-11-21.
  44. ^ Fox-Kemper, B.; Hewitt, Helene T.; Xiao, C.; Aðalgeirsdóttir, G.; Drijfhout, S. S.; Edwards, T. L.; Golledge, N. R.; Hemer, M.; Kopp, R. E.; Krinner, G.; Mix, A. (2021). Masson-Delmotte, V.; Zhai, P.; Pirani, A.; Connors, S. L.; Péan, C.; Berger, S.; Caud, N.; Chen, Y.; Goldfarb, L. (eds.). "Chapter 9: Ocean, Cryosphere and Sea Level Change" (PDF). Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, UK and New York, US. Archived (PDF) from the original on 2022-10-24. Retrieved 2022-10-18.
  45. "WMO annual report highlights continuous advance of climate change". World Meteorological Organization. 21 April 2023. Archived from the original on 17 December 2023. Retrieved 18 December 2023. Press Release Number: 21042023.
  46. IPCC, 2021: Summary for Policymakers Archived 2021-08-11 at the Wayback Machine. In: Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change Archived 2023-05-26 at the Wayback Machine Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M. I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J. B. R. Matthews, T. K. Maycock, T. Waterfield, O. Yelekçi, R. Yu, and B. Zhou (eds.). Cambridge University Press, Cambridge, UK and New York, US, pp. 3−32, doi:10.1017/9781009157896.001.
  47. WCRP Global Sea Level Budget Group (2018). "Global sea-level budget 1993–present". Earth System Science Data. 10 (3): 1551–1590. Bibcode:2018ESSD...10.1551W. doi:10.5194/essd-10-1551-2018. hdl:20.500.11850/287786. This corresponds to a mean sea-level rise of about 7.5 cm over the whole altimetry period. More importantly, the GMSL curve shows a net acceleration, estimated to be at 0.08mm/yr.
  48. ^ Trujillo, Alan P. (2014). Essentials of oceanography. Harold V. Thurman (11th ed.). Boston: Pearson. ISBN 978-0-321-81405-0. OCLC 815043823.
  49. Talley, L. (2000). Sio 210 talley topic 5: North Atlantic circulation and water masses. thermohaline forcing Archived 2015-01-15 at the Wayback Machine.
  50. ^ Trenberth, K; Caron, J (2001). "Estimates of Meridional Atmosphere and Ocean Heat Transports". Journal of Climate. 14 (16): 3433–43. Bibcode:2001JCli...14.3433T. doi:10.1175/1520-0442(2001)014<3433:EOMAAO>2.0.CO;2. Archived from the original on 2022-10-28. Retrieved 2022-10-28.
  51. ^ Chester, R.; Jickells, Tim (2012). "Chapter 9: Nutrients oxygen organic carbon and the carbon cycle in seawater". Marine geochemistry (3rd ed.). Chichester, West Sussex, UK: Wiley/Blackwell. ISBN 978-1-118-34909-0. OCLC 781078031. Archived from the original on 2022-02-18. Retrieved 2022-10-20.
  52. Chan, Francis; Barth, John; Kroeker, Kristy; Lubchenco, Jane; Menge, Bruce (1 September 2019). "The Dynamics and Impact of Ocean Acidification and Hypoxia: Insights from Sustained Investigations in the Northern California Current Large Marine Ecosystem". Oceanography. 32 (3): 62–71. doi:10.5670/oceanog.2019.312. S2CID 202922296. Material was copied from this source, which is available under a Creative Commons Attribution 4.0 International License Archived 2017-10-16 at the Wayback Machine.
  53. Gewin, Virginia (August 2010). "Oceanography: Dead in the water". Nature. 466 (7308): 812–814. doi:10.1038/466812a. PMID 20703282. S2CID 4358903.
  54. ^ Li, Guancheng; Cheng, Lijing; Zhu, Jiang; Trenberth, Kevin E.; Mann, Michael E.; Abraham, John P. (December 2020). "Increasing ocean stratification over the past half-century". Nature Climate Change. 10 (12): 1116–1123. Bibcode:2020NatCC..10.1116L. doi:10.1038/s41558-020-00918-2. S2CID 221985871. Archived from the original on 2023-01-10. Retrieved 2022-10-21.
  55. ^ Breitburg, Denise; Levin, Lisa A.; Oschlies, Andreas; Grégoire, Marilaure; Chavez, Francisco P.; Conley, Daniel J.; Garçon, Véronique; Gilbert, Denis; Gutiérrez, Dimitri; Isensee, Kirsten; Jacinto, Gil S.; Limburg, Karin E.; Montes, Ivonne; Naqvi, S. W. A.; Pitcher, Grant C.; Rabalais, Nancy N.; Roman, Michael R.; Rose, Kenneth A.; Seibel, Brad A.; Telszewski, Maciej; Yasuhara, Moriaki; Zhang, Jing (5 January 2018). "Declining oxygen in the global ocean and coastal waters". Science. 359 (6371): eaam7240. Bibcode:2018Sci...359M7240B. doi:10.1126/science.aam7240. PMID 29301986. S2CID 206657115.
  56. ^ Oschlies, Andreas; Brandt, Peter; Stramma, Lothar; Schmidtko, Sunke (2018). "Drivers and mechanisms of ocean deoxygenation". Nature Geoscience. 11 (7): 467–473. Bibcode:2018NatGe..11..467O. doi:10.1038/s41561-018-0152-2. S2CID 135112478.
  57. Breitburg, Denise; Levin, Lisa A.; Oschlies, Andreas; Grégoire, Marilaure; Chavez, Francisco P.; Conley, Daniel J.; Garçon, Véronique; Gilbert, Denis; Gutiérrez, Dimitri; Isensee, Kirsten; Jacinto, Gil S.; Limburg, Karin E.; Montes, Ivonne; Naqvi, S. W. A.; Pitcher, Grant C. (2018). "Declining oxygen in the global ocean and coastal waters". Science. 359 (6371): eaam7240. Bibcode:2018Sci...359M7240B. doi:10.1126/science.aam7240. PMID 29301986. S2CID 206657115.
  58. The Guardian, 2023 July 12 "World's Oceans Changing Colour Due to Climate Breakdown"
  59. Cael, B.B., Bisson, K., Boss, E. et al. "Global climate-change trends detected in indicators of ocean ecology" Nature (2023)
  60. Odériz, I.; Silva, R.; Mortlock, T.R.; Mori, N.; Shimura, T.; Webb, A.; Padilla-Hernández, R.; Villers, S. (2021-06-16). "Natural Variability and Warming Signals in Global Ocean Wave Climates". Geophysical Research Letters. 48 (11). Bibcode:2021GeoRL..4893622O. doi:10.1029/2021GL093622. hdl:2433/263318. S2CID 236280747.
  61. ^ Trenberth, Kevin E.; Cheng, Lijing; Jacobs, Peter; Zhang, Yongxin; Fasullo, John (2018). "Hurricane Harvey Links to Ocean Heat Content and Climate Change Adaptation". Earth's Future. 6 (5): 730–744. Bibcode:2018EaFut...6..730T. doi:10.1029/2018EF000825.
  62. ^ Knutson, Thomas; Camargo, Suzana J.; Chan, Johnny C. L.; Emanuel, Kerry; Ho, Chang-Hoi; Kossin, James; Mohapatra, Mrutyunjay; Satoh, Masaki; Sugi, Masato; Walsh, Kevin; Wu, Liguang (August 6, 2019). "Tropical Cyclones and Climate Change Assessment: Part II. Projected Response to Anthropogenic Warming". Bulletin of the American Meteorological Society. 101 (3): BAMS–D–18–0194.1. Bibcode:2020BAMS..101E.303K. doi:10.1175/BAMS-D-18-0194.1. hdl:1721.1/124705.
  63. IPCC, 2021: Summary for Policymakers. In: Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change . Cambridge University Press, Cambridge, United Kingdom and New York City, US, pp. 8–9; 15–16, doi:10.1017/9781009157896.001.
  64. "Major tropical cyclones have become '15% more likely' over past 40 years". Carbon Brief. May 18, 2020. Archived from the original on August 8, 2020. Retrieved August 31, 2020.
  65. ^ Deshpande, Medha; Singh, Vineet Kumar; Ganadhi, Mano Kranthi; Roxy, M. K.; Emmanuel, R.; Kumar, Umesh (2021-12-01). "Changing status of tropical cyclones over the north Indian Ocean". Climate Dynamics. 57 (11): 3545–3567. Bibcode:2021ClDy...57.3545D. doi:10.1007/s00382-021-05880-z. ISSN 1432-0894.
  66. Singh, Vineet Kumar; Roxy, M.K. (March 2022). "A review of ocean-atmosphere interactions during tropical cyclones in the north Indian Ocean". Earth-Science Reviews. 226: 103967. arXiv:2012.04384. Bibcode:2022ESRv..22603967S. doi:10.1016/j.earscirev.2022.103967.
  67. Kossin, James P.; Knapp, Kenneth R.; Olander, Timothy L.; Velden, Christopher S. (May 18, 2020). "Global increase in major tropical cyclone exceedance probability over the past four decades". Proceedings of the National Academy of Sciences. 117 (22): 11975–11980. Bibcode:2020PNAS..11711975K. doi:10.1073/pnas.1920849117. PMC 7275711. PMID 32424081.
  68. Collins, M.; Sutherland, M.; Bouwer, L.; Cheong, S.-M.; et al. (2019). "Chapter 6: Extremes, Abrupt Changes and Managing Risks" (PDF). IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. p. 602. Archived (PDF) from the original on December 20, 2019. Retrieved October 6, 2020.
  69. Haldar, Ishita (30 April 2018). Global Warming: The Causes and Consequences. Readworthy. ISBN 978-81-935345-7-1. Archived from the original on 2023-04-16. Retrieved 2022-04-01.
  70. Wüst, Georg (1936), Louis, Herbert; Panzer, Wolfgang (eds.), "Oberflächensalzgehalt, Verdunstung und Niederschlag auf dem Weltmeere", Länderkundliche Forschung : Festschrift zur Vollendung des sechzigsten Lebensjahres Norbert Krebs, Stuttgart, Germany: Engelhorn, pp. 347–359, archived from the original on 2021-06-07, retrieved 2021-06-07
  71. Euzen, Agathe (2017). The ocean revealed. Paris: CNRS Éditions. ISBN 978-2-271-11907-0.
  72. Durack, Paul J.; Wijffels, Susan E. (2010-08-15). "Fifty-Year Trends in Global Ocean Salinities and Their Relationship to Broad-Scale Warming". Journal of Climate. 23 (16): 4342–4362. Bibcode:2010JCli...23.4342D. doi:10.1175/2010JCLI3377.1.
  73. "Marine pollution, explained". National Geographic. 2019-08-02. Archived from the original on 2020-06-14. Retrieved 2020-04-07.
  74. Huang, Yiyi; Dong, Xiquan; Bailey, David A.; Holland, Marika M.; Xi, Baike; DuVivier, Alice K.; Kay, Jennifer E.; Landrum, Laura L.; Deng, Yi (2019-06-19). "Thicker Clouds and Accelerated Arctic Sea Ice Decline: The Atmosphere-Sea Ice Interactions in Spring". Geophysical Research Letters. 46 (12): 6980–6989. Bibcode:2019GeoRL..46.6980H. doi:10.1029/2019gl082791. hdl:10150/634665. ISSN 0094-8276. S2CID 189968828.
  75. Senftleben, Daniel; Lauer, Axel; Karpechko, Alexey (2020-02-15). "Constraining Uncertainties in CMIP5 Projections of September Arctic Sea Ice Extent with Observations". Journal of Climate. 33 (4): 1487–1503. Bibcode:2020JCli...33.1487S. doi:10.1175/jcli-d-19-0075.1. ISSN 0894-8755. S2CID 210273007.
  76. Yadav, Juhi; Kumar, Avinash; Mohan, Rahul (2020-05-21). "Dramatic decline of Arctic sea ice linked to global warming". Natural Hazards. 103 (2): 2617–2621. Bibcode:2020NatHa.103.2617Y. doi:10.1007/s11069-020-04064-y. ISSN 0921-030X. S2CID 218762126.
  77. "Ice in the Arctic is melting even faster than scientists expected, study finds". NPR.org. Retrieved 2022-07-10.
  78. ^ "Understanding climate: Antarctic sea ice extent". NOAA Climate.gov. 14 March 2023. Retrieved 2023-03-26.
  79. "Arctic Sea Ice News and Analysis". National Snow & Ice Data Centre. 15 March 2023. Retrieved 26 March 2023.
  80. Roxy, Mathew Koll; Modi, Aditi; Murtugudde, Raghu; Valsala, Vinu; Panickal, Swapna; Prasanna Kumar, S.; Ravichandran, M.; Vichi, Marcello; Lévy, Marina (2016). "A reduction in marine primary productivity driven by rapid warming over the tropical Indian Ocean". Geophysical Research Letters. 43 (2): 826–833. Bibcode:2016GeoRL..43..826R. doi:10.1002/2015GL066979. S2CID 96439754.
  81. Doney, Scott C.; Busch, D. Shallin; Cooley, Sarah R.; Kroeker, Kristy J. (2020-10-17). "The Impacts of Ocean Acidification on Marine Ecosystems and Reliant Human Communities". Annual Review of Environment and Resources. 45 (1): 83–112. doi:10.1146/annurev-environ-012320-083019. S2CID 225741986. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  82. ^ 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 Archived 21 October 2022 at the Wayback Machine. 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 Archived 28 February 2022 at the Wayback Machine . Cambridge University Press, Cambridge, UK and New York, NY, US, pp. 379–550.
  83. "PMEL CO2 – Carbon Dioxide Program". NOAA Pacific Marine Environmental Laboratory. Retrieved 2021-09-06.
  84. Mora, Camilo; Wei, Chih-Lin; Rollo, Audrey; Amaro, Teresa; Baco, Amy R.; Billett, David; Bopp, Laurent; Chen, Qi; Collier, Mark; Danovaro, Roberto; Gooday, Andrew J.; Grupe, Benjamin M.; Halloran, Paul R.; Ingels, Jeroen; Jones, Daniel O. B. (2013-10-15). Mace, Georgina M. (ed.). "Biotic and Human Vulnerability to Projected Changes in Ocean Biogeochemistry over the 21st Century". PLOS Biology. 11 (10): e1001682. doi:10.1371/journal.pbio.1001682. PMC 3797030. PMID 24143135.
  85. National Research Council. Overview of Climate Changes and Illustrative Impacts. Climate Stabilization Targets: Emissions, Concentrations, and Impacts over Decades to Millennia Archived 6 September 2015 at the Wayback Machine. Washington, DC: The National Academies Press, 2011. 1. Print.
  86. Fairchild, William; Hales, Burke (14 January 2021). "High-Resolution Carbonate System Dynamics of Netarts Bay, OR From 2014 to 2019". Frontiers in Marine Science. 7: 590236. doi:10.3389/fmars.2020.590236.
  87. Wood, Hannah L.; Spicer, John I.; Widdicombe, Stephen (2008). "Ocean acidification may increase calcification rates, but at a cost". Proceedings of the Royal Society B. 275 (1644): 1767–1773. doi:10.1098/rspb.2008.0343. PMC 2587798. PMID 18460426.
  88. Ducker, James; Falkenberg, Laura J. (12 November 2020). "How the Pacific Oyster Responds to Ocean Acidification: Development and Application of a Meta-Analysis Based Adverse Outcome Pathway". Frontiers in Marine Science. 7: 597441. doi:10.3389/fmars.2020.597441.
  89. Caretta, M.A., A. Mukherji, M. Arfanuzzaman, R.A. Betts, A. Gelfan, Y. Hirabayashi, T.K. Lissner, J. Liu, E. Lopez Gunn, R. Morgan, S. Mwanga, and S. Supratid, 2022: Chapter 4: Water Archived 2023-03-29 at the Wayback Machine. 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 Archived 2022-02-28 at the Wayback Machine . Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 551–712
  90. ^ 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 Archived 2022-10-21 at the Wayback Machine. 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 Archived 2022-02-28 at the Wayback Machine . Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 379–550
  91. "How Reefs Are Made". Coral Reef Alliance. 2021. Archived from the original on 30 October 2021. Retrieved 19 April 2022.
  92. ^ Hoegh-Guldberg, Ove; Poloczanska, Elvira S.; Skirving, William; Dove, Sophie (2017). "Coral Reef Ecosystems under Climate Change and Ocean Acidification". Frontiers in Marine Science. 4: 158. doi:10.3389/fmars.2017.00158.
  93. Hoegh-Guldberg, O.; Mumby, P. J.; Hooten, A. J.; Steneck, R. S.; Greenfield, P.; Gomez, E.; Harvell, C. D.; Sale, P. F.; Edwards, A. J.; Caldeira, K.; Knowlton, N.; Eakin, C. M.; Iglesias-Prieto, R.; Muthiga, N.; Bradbury, R. H.; Dubi, A.; Hatziolos, M. E. (14 December 2007). "Coral Reefs Under Rapid Climate Change and Ocean Acidification". Science. 318 (5857): 1737–1742. Bibcode:2007Sci...318.1737H. doi:10.1126/science.1152509. hdl:1885/28834. PMID 18079392. S2CID 12607336.
  94. "Coral reefs as world heritage". International Environmental Law and the Conservation of Coral Reefs. 2011. pp. 187–223. doi:10.4324/9780203816882-16 (inactive 1 November 2024). ISBN 978-0-203-81688-2.{{cite book}}: CS1 maint: DOI inactive as of November 2024 (link)
  95. Davidson, Jordan (25 March 2020). "Great Barrier Reef Has Third Major Bleaching Event in Five Years". Ecowatch. Archived from the original on 26 March 2020. Retrieved 27 March 2020.
  96. ^ Cornwall, Christopher E.; Harvey, Ben P.; Comeau, Steeve; Cornwall, Daniel L.; Hall-Spencer, Jason M.; Peña, Viviana; Wada, Shigeki; Porzio, Lucia (January 2022). "Understanding coralline algal responses to ocean acidification: Meta-analysis and synthesis". Global Change Biology. 28 (2): 362–374. doi:10.1111/gcb.15899. hdl:10026.1/18263. PMID 34689395. S2CID 239767511.
  97. Hoegh-Guldberg, Ove; Poloczanska, Elvira S.; Skirving, William; Dove, Sophie (2017). "Coral Reef Ecosystems under Climate Change and Ocean Acidification". Frontiers in Marine Science. 4: 158. doi:10.3389/fmars.2017.00158.
  98. Cohen, A.; Holcomb, M. (2009). "Why Corals Care About Ocean Acidification: Uncovering the Mechanism". Oceanography. 24 (4): 118–127. doi:10.5670/oceanog.2009.102.
  99. Pérez, F.; Fontela, M.; García-Ibañez, M.; Mercier, H.; Velo, A.; Lherminier, P.; Zunino, P.; de la Paz, M.; Alonso, F.; Guallart, E.; Padín, T. (22 February 2018). "Meridional overturning circulation conveys fast acidification to the deep Atlantic Ocean". Nature. 554 (7693): 515–518. Bibcode:2018Natur.554..515P. doi:10.1038/nature25493. hdl:10261/162241. PMID 29433125. S2CID 3497477.
  100. Observations: Oceanic Climate Change and Sea Level Archived 2017-05-13 at the Wayback Machine In: Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. (15 MB).
  101. Doney, S. C. (March 2006). "The Dangers of Ocean Acidification" (PDF). Scientific American. 294 (3): 58–65. Bibcode:2006SciAm.294c..58D. doi:10.1038/scientificamerican0306-58. PMID 16502612.
  102. US EPA, OAR (2015-04-07). "Climate Action Benefits: Freshwater Fish". US EPA. Retrieved 2020-04-06.
  103. Weatherdon, Lauren V.; Magnan, Alexandre K.; Rogers, Alex D.; Sumaila, U. Rashid; Cheung, William W. L. (2016). "Observed and Projected Impacts of Climate Change on Marine Fisheries, Aquaculture, Coastal Tourism, and Human Health: An Update". Frontiers in Marine Science. 3. doi:10.3389/fmars.2016.00048. ISSN 2296-7745.
  104. Cheung, W.W.L.; et al. (October 2009). Redistribution of Fish Catch by Climate Change. A Summary of a New Scientific Analysis (PDF). Sea Around Us (Report). Archived from the original (PDF) on 2011-07-26.
  105. ^ Manuel Barange; Tarûb Bahri; Malcolm C. M. Beveridge; K. L. Cochrane; S. Funge Smith; Florence Poulain, eds. (2018). Impacts of climate change on fisheries and aquaculture: synthesis of current knowledge, adaptation and mitigation options. Rome: Food and Agriculture Organization of the United Nations. ISBN 978-92-5-130607-9. OCLC 1078885208.
  106. Intergovernmental Panel on Climate Change (IPCC), ed. (2022), "Sea Level Rise and Implications for Low-Lying Islands, Coasts and Communities", The Ocean and Cryosphere in a Changing Climate: Special Report of the Intergovernmental Panel on Climate Change, Cambridge: Cambridge University Press, pp. 321–446, doi:10.1017/9781009157964.006, ISBN 978-1-00-915796-4, S2CID 246522316, retrieved 2022-04-06
  107. Carozza, David A.; Bianchi, Daniele; Galbraith, Eric D. (2019). Bates, Amanda (ed.). "Metabolic impacts of climate change on marine ecosystems: Implications for fish communities and fisheries". Global Ecology and Biogeography. 28 (2): 158–169. Bibcode:2019GloEB..28..158C. doi:10.1111/geb.12832. ISSN 1466-822X. S2CID 91507418.
  108. Burek, Kathy A.; Gulland, Frances M. D.; O'Hara, Todd M. (2008). "Effects of Climate Change on Arctic Marine Mammal Health". Ecological Applications. 18 (2): S126–S134. Bibcode:2008EcoAp..18S.126B. doi:10.1890/06-0553.1. JSTOR 40062160. PMID 18494366.
  109. ^ Albouy, Camille; Delattre, Valentine; Donati, Giulia; Frölicher, Thomas L.; Albouy-Boyer, Severine; Rufino, Marta; Pellissier, Loïc; Mouillot, David; Leprieur, Fabien (December 2020). "Global vulnerability of marine mammals to global warming". Scientific Reports. 10 (1): 548. Bibcode:2020NatSR..10..548A. doi:10.1038/s41598-019-57280-3. PMC 6969058. PMID 31953496.
  110. Harwood, John (1 August 2001). "Marine mammals and their environment in the twenty-first century". Journal of Mammalogy. 82 (3): 630–640. doi:10.1644/1545-1542(2001)082<0630:MMATEI>2.0.CO;2.
  111. Simmonds, Mark P.; Isaac, Stephen J. (5 March 2007). "The impacts of climate change on marine mammals: early signs of significant problems". Oryx. 41 (1): 19–26. doi:10.1017/s0030605307001524.
  112. Tynan, Cynthia T.; DeMaster, Douglas P. (1997). "Observations and Predictions of Arctic Climatic Change: Potential Effects on Marine Mammals" (PDF). Arctic. 50 (4): 308–322. doi:10.14430/arctic1113. Archived (PDF) from the original on 2022-01-20. Retrieved 2022-04-01. Animals have a high risk of mortality.
  113. Learmonth, JA; Macleod, CD; Santos, MB; Pierce, GJ; Crick, HQP; Robinson, RA (2006). "Potential effects of climate change on marine mammals". In Gibson, RN; Atkinson, RJA; Gordon, JDM (eds.). Oceanography and marine biology an annual review. Volume 44. Boca Raton: Taylor & Francis. pp. 431–464. ISBN 978-1-4200-0639-1.
  114. ^ Laidre, Kristin L.; Stirling, Ian; Lowry, Lloyd F.; Wiig, Øystein; Heide-Jørgensen, Mads Peter; Ferguson, Steven H. (January 1, 2008). "Quantifying the Sensitivity of Arctic Marine Mammals to Climate-Induced Habitat Change". Ecological Applications. 18 (2): S97–S125. Bibcode:2008EcoAp..18S..97L. doi:10.1890/06-0546.1. JSTOR 40062159. PMID 18494365.
  115. Avila, Isabel C.; Kaschner, Kristin; Dormann, Carsten F. (May 2018). "Current global risks to marine mammals: Taking stock of the threats". Biological Conservation. 221: 44–58. Bibcode:2018BCons.221...44A. doi:10.1016/j.biocon.2018.02.021.
  116. ^ Yao, Cui-Luan; Somero, George N. (February 2014). "The impact of ocean warming on marine organisms". Chinese Science Bulletin. 59 (5–6): 468–479. Bibcode:2014ChSBu..59..468Y. doi:10.1007/s11434-014-0113-0. S2CID 98449170.
  117. Derocher, A. E. (2004-04-01). "Polar Bears in a Warming Climate". Integrative and Comparative Biology. 44 (2): 163–176. doi:10.1093/icb/44.2.163. PMID 21680496. S2CID 13716867.
  118. Burek, Kathy A.; Gulland, Frances M. D.; O'Hara, Todd M. (March 2008). "Effects of Climate Change on Arctic Marine Mammal Health". Ecological Applications. 18 (sp2): S126–S134. Bibcode:2008EcoAp..18S.126B. doi:10.1890/06-0553.1. PMID 18494366.
  119. Glick, Patrick; Clough, Jonathan; Nunley, Brad. "Sea-Level Rise and Coastal Habitats in the Chesapeake Bay Region" (PDF). National Wildlife Federation. Archived from the original (PDF) on March 4, 2016. Retrieved November 8, 2014.
  120. Stirling, Ian; Lunn, N. J.; Iacozza, J. (September 1999). "Long-term trends in the population ecology of polar bears in Western Hudson Bay in relation to climatic change" (PDF). Arctic. 52 (3): 294–306. doi:10.14430/arctic935. Retrieved 11 November 2007.
  121. Monnett, Charles; Gleason, Jeffrey S. (July 2006). "Observations of mortality associated with extended open-water swimming by polar bears in the Alaskan Beaufort Sea" (PDF). Polar Biology. 29 (8): 681–687. Bibcode:2006PoBio..29..681M. doi:10.1007/s00300-005-0105-2. S2CID 24270374. Archived (PDF) from the original on 10 August 2017.
  122. Amstrup, Steven C.; Marcot, Bruce G.; Douglas, David C. (2007). Forecasting the range-wide status of polar bears at selected times in the 21st Century (PDF). Reston, Virginia: U.S. Geological Survey. Archived from the original (PDF) on 25 October 2007. Retrieved 29 September 2007.
  123. Derocher, Andrew E.; Lunn, Nicholas J.; Stirling, Ian (2004). "Polar bears in a Warming Climate". Integrative and Comparative Biology. 44 (2): 163–176. doi:10.1093/icb/44.2.163. PMID 21680496.
  124. Stenson, G. B.; Hammill, M. O. (2014). "Can ice breeding seals adapt to habitat loss in a time of climate change?". ICES Journal of Marine Science. 71 (7): 1977–1986. doi:10.1093/icesjms/fsu074.
  125. Ferguson, Steven H.; Young, Brent G.; Yurkowski, David J.; Anderson, Randi; Willing, Cornelia; Nielsen, Ole (2017). "Demographic, ecological, and physiological responses of ringed seals to an abrupt decline in sea ice availability". PeerJ. 5: e2957. doi:10.7717/peerj.2957. PMC 5292026. PMID 28168119.
  126. Forcada, Jaume; Trathan, P. N.; Reid, K.; Murphy, E. J. (2005). "The Effects of Global Climate Variability in Pup Production of Antarctic Fur Seals". Ecology. 86 (9): 2408–2417. Bibcode:2005Ecol...86.2408F. doi:10.1890/04-1153. JSTOR 3451030.
  127. Cañadas, A.; Vázquez, J.A. (2017-07-01). "Common dolphins in the Alboran Sea: Facing a reduction in their suitable habitat due to an increase in Sea surface temperature". Deep Sea Research Part II: Topical Studies in Oceanography. 141: 306–318. Bibcode:2017DSRII.141..306C. doi:10.1016/j.dsr2.2017.03.006.
  128. Wild, Sonja; Krützen, Michael; Rankin, Robert W.; Hoppitt, William J.E.; Gerber, Livia; Allen, Simon J. (2019-04-01). "Long-term decline in survival and reproduction of dolphins following a marine heatwave". Current Biology. 29 (7): R239–R240. Bibcode:2019CBio...29.R239W. doi:10.1016/j.cub.2019.02.047. hdl:1983/1a397eb9-1713-49b5-a2fb-f0d7c747e724. PMID 30939303.
  129. Würsig, Bernd; Reeves, Randall R.; Ortega-Ortiz, J. G. (2002). "Global Climate Change and Marine Mammals". Marine Mammals. pp. 589–608. doi:10.1007/978-1-4615-0529-7_17. ISBN 978-0-306-46573-4.
  130. Gomez-Salazar, Catalina; Coll, Marta; Whitehead, Hal (December 2012). "River dolphins as indicators of ecosystem degradation in large tropical rivers". Ecological Indicators. 23: 19–26. Bibcode:2012EcInd..23...19G. doi:10.1016/j.ecolind.2012.02.034.
  131. ^ Evans, Peter G.H.; Bjørge, Arne (November 28, 2013). "Impacts of climate change on marine mammals" (PDF). MCCIP Science Review 2013.
  132. Würsig, Bernd; Reeves, Randall R.; Ortega-Ortiz, J. G. (2001), Evans, Peter G. H.; Raga, Juan Antonio (eds.), "Global Climate Change and Marine Mammals", Marine Mammals: Biology and Conservation, Boston, MA: Springer US, pp. 589–608, doi:10.1007/978-1-4615-0529-7_17, ISBN 978-1-4615-0529-7, retrieved 2021-05-01
  133. Salvadeo, CJ; Lluch-Belda, D; Gómez-Gallardo, A; Urbán-Ramírez, J; MacLeod, CD (2010-03-10). "Climate change and a poleward shift in the distribution of the Pacific white-sided dolphin in the northeastern Pacific". Endangered Species Research. 11 (1): 13–19. doi:10.3354/esr00252. ISSN 1863-5407.
  134. Meszaros, Jessica (2020-02-14). "Climate Change Is Contributing To Right Whale Deaths". WLRN. Retrieved 2023-11-07.
  135. ^ Gulland, Frances M. D.; Baker, Jason D.; Howe, Marian; LaBrecque, Erin; Leach, Lauri; Moore, Sue E.; Reeves, Randall R.; Thomas, Peter O. (2022-12-01). "A review of climate change effects on marine mammals in United States waters: Past predictions, observed impacts, current research and conservation imperatives". Climate Change Ecology. 3: 100054. Bibcode:2022CCEco...300054G. doi:10.1016/j.ecochg.2022.100054. ISSN 2666-9005.
  136. ^ Meyer-Gutbrod, Erin; Greene, Charles; Davies, Kimberley; Johns, David (September 2021). "Ocean Regime Shift is Driving Collapse of the North Atlantic Right Whale Population" (PDF). Oceanography. 34 (3): 22–31. doi:10.5670/oceanog.2021.308. ISSN 1042-8275.
  137. Brennan, Catherine E.; Maps, Frédéric; Gentleman, Wendy C.; Lavoie, Diane; Chassé, Joël; Plourde, Stéphane; Johnson, Catherine L. (September–October 2021). "Ocean circulation changes drive shifts in Calanus abundance in North Atlantic right whale foraging habitat: A model comparison of cool and warm year scenarios". Progress in Oceanography. 197: 102629. Bibcode:2021PrOce.19702629B. doi:10.1016/j.pocean.2021.102629. ISSN 0079-6611.
  138. Ganley, Laura C.; Byrnes, Jarrett; Pendleton, Daniel E.; Mayo, Charles A.; Friedland, Kevin D.; Redfern, Jessica V.; Turner, Jefferson T.; Brault, Solange (2022-10-01). "Effects of changing temperature phenology on the abundance of a critically endangered baleen whale". Global Ecology and Conservation. 38: e02193. doi:10.1016/j.gecco.2022.e02193. ISSN 2351-9894.
  139. Gavrilchuk, Katherine; Lesage, Véronique; Fortune, Sarah M. E.; Trites, Andrew W.; Plourde, Stéphane (2021-02-25). "Foraging habitat of North Atlantic right whales has declined in the Gulf of St. Lawrence, Canada, and may be insufficient for successful reproduction". Endangered Species Research. 44: 113–136. doi:10.3354/esr01097. ISSN 1863-5407.
  140. Milkov, A. V. (2004). "Global estimates of hydrate-bound gas in marine sediments: How much is really out there?". Earth-Science Reviews. 66 (3–4): 183–197. Bibcode:2004ESRv...66..183M. doi:10.1016/j.earscirev.2003.11.002.

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