Effects of climate change

Precipitation

Global warming is expected to be accompanied by a reduction in rainfall in the subtropics and an increase in precipitation in subpolar latitudes and some equatorial regions. In other words, regions which are dry at present will generally become even drier, while regions that are currently wet will generally become even wetter. This projection does not apply to every locale, and in some cases can be modified by local conditions. Drying is projected to be strongest near the poleward margins of the subtropics (for example, South Africa, southern Australia, the Mediterranean, and the south-western U.S.), a pattern that can be described as a poleward expansion of these semi-arid zones.^[43]

This large-scale pattern of change is a robust feature present in nearly all of the simulations conducted by the world's climate modeling groups for the 4th Assessment of the Intergovernmental Panel on Climate Change (IPCC), and is also evident in observed 20th century precipitation trends.^[43] Changes in regional climate are expected to include greater warming over land, with most warming at high northern latitudes, and least warming over the Southern Ocean and parts of the North Atlantic Ocean.^[44] Future changes in precipitation are expected to follow existing trends, with reduced precipitation over subtropical land areas, and increased precipitation at subpolar latitudes and some equatorial regions.^[45]

Higher temperatures lead to increased evaporation and surface drying. As the air warms, its water-holding capacity also increases, particularly over the oceans. In general the air can hold about 7% more moisture for every 1 °C of temperature rise.^[31] In the tropics, there's more than a 10% increase in precipitation for a 1 °C increase in temperature.^[46] Changes have already been observed in the amount, intensity, frequency, and type of precipitation. Widespread increases in heavy precipitation have occurred even in places where total rain amounts have decreased.^[47]

Projections of changes in precipitation show increases in the global average, with substantial shifts in location and pattern of rainfall.^[31] Although increased rainfall will not occur everywhere, models suggest most of the world will have a 16–24% increase in heavy precipitation intensity by 2100.^[48] Warming has increased contrasts in rainfall amounts between wet and dry seasons.^[49]

Heat waves and temperature extremes

The IPCC Sixth Assessment Report (2021) projects large increases in both the frequency and intensity of extreme weather events, for increasing degrees of global warming.^[50]

It was estimated in 2013 that global warming had increased the probability of local record-breaking monthly temperatures worldwide by a factor of 5.^[51] This was compared to a baseline climate in which no global warming had occurred. Using a medium global warming scenario, they project that by 2040, the number of monthly heat records globally could be more than 12 times greater than that of a scenario with no long-term warming.

Global warming boosts the probability of extreme weather events such as heat waves^[52][53] where the daily maximum temperature exceeds the average maximum temperature by 5 °C (9 °F) for more than five consecutive days.^[54] In the last 30–40 years, heat waves with high humidity have become more frequent and severe. Extremely hot nights have doubled in frequency. The area in which extremely hot summers are observed has increased 50–100 fold. These changes are not explained by natural variability, and are attributed by climate scientists to the influence of anthropogenic climate change. Heat waves with high humidity pose a big risk to human health while heat waves with low humidity lead to dry conditions that increase wildfires. The mortality from extreme heat is larger than the mortality from hurricanes, lightning, tornadoes, floods, and earthquakes together.^[55]

Future climate change will include more very hot days and fewer very cold days.^[56] The frequency, length and intensity of heat waves will very likely increase over most land areas.^[56] Higher growth in anthropogenic GHG emissions would cause more frequent and severe temperature extremes.^[57] Globally, cold waves have decreased in frequency.^[58] There is some evidence climate change leads to a weakening of the polar vortex, which would make the jet stream more wavy.^[59] This would lead to outbursts of very cold winter weather across parts of Eurasia^[60] and North America.^[61][62][63]

Frequency of occurrence (vertical axis) of local June–July–August temperature anomalies (relative to 1951–1980 mean) for Northern Hemisphere land in units of local standard deviation (horizontal axis).^[64] According to Hansen et al. (2012),^[64] the distribution of anomalies has shifted to the right as a consequence of global warming, meaning that unusually hot summers have become more common. This is analogous to the rolling of a die: cool summers now cover only half of one side of a six-sided die, white covers one side, red covers four sides, and an extremely hot (red-brown) anomaly covers half of one side.^[64]

Tropical cyclones and storms

Global warming not only causes changes in tropical cyclones, it may also make some impacts from them worse via sea level rise. The intensity of tropical cyclones (hurricanes, typhoons, etc.) is projected to increase globally, with the proportion of Category 4 and 5 tropical cyclones increasing. Furthermore, the rate of rainfall is projected to increase, but trends in the future frequency on a global scale are not yet clear.^[65][66] Changes in tropical cyclones vary by region.^[65]

Increases in temperature are expected to produce more intense convection over land and a higher frequency of the most severe storms.^[67]

Atmosphere

The lower and middle atmosphere are heating due to the enhanced greenhouse effect. Increased greenhouse gases cause the higher parts of the atmosphere, the stratosphere to cool. This has been observed by a set of satellites since 1979 (the Microwave sounding unit) and radiosonde data. Satellites can not measure each height of the atmosphere separately, but instead measure a set of bands that slightly overlap. The overlap between the cooling stratosphere in the measurements of tropospheric warming may cause the latter to be underestimated slightly.^[87] The heated atmosphere contains more water vapour, which is itselfs also a greenhouse gas and acts as an self-reinforcing feedback.^[88]

A contraction of the thermosphere has been observed as a possible result in part due to increased carbon dioxide concentrations, the strongest cooling and contraction occurring in that layer during solar minimum. The most recent contraction in 2008–2009 was the largest such since at least 1967.^[89][90][91]

Dust from the Sahara Desert typically blows across the Atlantic Ocean. In June 2020, the Saharan dust plume was the most dense it had been in 25 years. It is uncertain whether climate change affects this.^[92]

Biogeochemical cycles

Climate change can have an effect on the carbon cycle in an interactive "feedback" process . A feedback exists where an initial process triggers changes in a second process that in turn influences the initial process. A positive feedback intensifies the original process, and a negative feedback reduces it (IPCC, 2007d:78).^[93] Models suggest that the interaction of the climate system and the carbon cycle is one where the feedback effect is positive (Schneider et al., 2007:792).^[94]

Ice and snow (cryosphere)

Earth lost 28 trillion tonnes of ice between 1994 and 2017, with melting grounded ice (ice sheets and glaciers) raising the global sea level by 34.6 ±3.1 mm.^[95] The rate of ice loss has risen by 57% since the 1990s−from 0.8 to 1.2 trillion tonnes per year.^[95]

The cryosphere is made up of those parts of the planet which are so cold, they are frozen and covered by snow or ice. This includes ice and snow on land such as the continental ice sheets in Greenland and Antarctica, as well as glaciers and areas of snow and permafrost; and ice found on water including frozen parts of the ocean, such as the waters surrounding Antarctica and the Arctic.^[96] The cryosphere, especially the polar regions, is extremely sensitive to changes in global climate.^[97]

The Intergovernmental Panel on Climate Change issued a Special Report on the Ocean and Cryosphere in a Changing Climate. According to the report climate change caused a massive melting of glaciers, ice sheets, snow and permafrost with generally negative effects on ecosystems and humans. Indigenous knowledge helped to adapt to those effects.^[70]

Since the beginning of the twentieth century, there has also been a widespread retreat of alpine glaciers,^[98] and snow cover in the Northern Hemisphere.^[99] The sensitivity to warming of the "1981–2010 Northern hemisphere snow cover extent" is about minus 1.9 million km² per degrees Celsius throughout the snow season.^[100] During the 21st century, glaciers and snow cover are projected to continue their retreat in almost all regions.^[101] The melting of the Greenland and West Antarctic ice sheets will continue to contribute to sea level rise over long time-scales.^[102]

Northern Hemisphere average annual snow cover has declined in recent decades. This pattern is consistent with warmer global temperatures. Some of the largest declines have been observed in the spring and summer months.^[69]

Glacier retreat and disappearance

This section is an excerpt from Retreat of glaciers since 1850.[edit]

Retreat of White Chuck Glacier, Washington

White Chuck Glacier in 1973

Same vantage point in 2006. The glacier retreated 1.9 kilometres (1.2 mi) in 33 years.

In all, about 25 percent of the ice that melted between 2003 and 2010 occurred in the Americas (excluding Greenland).

The retreat of glaciers since 1850—affects the availability of fresh water for irrigation and domestic use, mountain recreation, animals and plants that depend on glacier-melt, and, in the longer term, the level of the oceans. Deglaciation occurs naturally at the end of ice ages, but glaciologists find the current glacier retreat is accelerated by the measured increase of atmospheric greenhouse gases—an effect of climate change. Mid-latitude mountain ranges such as the Himalayas, Rockies, Alps, Cascades, and the southern Andes, as well as isolated tropical summits such as Mount Kilimanjaro in Africa, are showing some of the largest proportionate glacial losses. Excluding peripheral glaciers of ice sheets, total global glacial losses were likely 5500 gigatons over 1993–2018.^[111]

The retreat of mountain glaciers, notably in western North America, Asia, the Alps and tropical and subtropical regions of South America, Africa and Indonesia, provide evidence for the rise in global temperatures since the late 19th century. The acceleration of the rate of retreat since 1995 of key outlet glaciers of the Greenland and West Antarctic ice sheets may foreshadow a rise in sea level, which would affect coastal regions.

Permafrost thawing

Terrestrial and wetland systems

Climate change has been estimated to be a major driver of biodiversity loss in cool conifer forests, savannas, mediterranean-climate systems, tropical forests, and the Arctic tundra.^[123] In other ecosystems, land-use change may be a stronger driver of biodiversity loss, at least in the near-term.^[123] Beyond the year 2050, climate change may be the major driver for biodiversity loss globally.^[123] Climate change interacts with other pressures such as habitat modification, pollution and invasive species. Interacting with these pressures, climate change increases extinction risk for a large fraction of terrestrial and freshwater species.^[124] Between 1% and 50% of species in different groups were assessed to be at substantially higher risk of extinction due to climate change.^[125]

Floods

High tides flooding is increasing due to sea level rise, land subsidence, and the loss of natural barriers.^[126]

Air holds 7% more water vapour for every degree Celsius it is warmed.^[127] More highly water-saturated air tends to produce heavier rains, potentially worsening flooding.^[127]

A 2017 study found that peak precipitation is increasing between 5 and 10% for every one degree Celsius increase.^[128] In the United States and many other parts of the world there has been a marked increase in intense rainfall events which have resulted in more severe flooding.^[129]

Between 1994 and 2006, satellite observations shows an 18% increase in the flow of freshwater into the world's oceans, partly from melting ice and partly from increased precipitation driven by an increase in global ocean evaporation. Much of the increase is in areas which already experience high rainfall. One effect, as perhaps experienced in the 2010 Pakistan floods, is to overwhelm flood control infrastructure.^[130]

Droughts

Climate change affects multiple factors associated with droughts, such as how much rain falls and how fast the rain evaporates again. Warming over land drives an increase in atmospheric evaporative demand which will increase the severity and frequency of droughts around much of the world.^[131][132] Due to limitations on how much data is available about drought in the past, it is often impossible to confidently attribute droughts to human-induced climate change. Some areas however, such as the Mediterranean and California, already show a clear human signature.^[133] Their impacts are aggravated because of increased water demand, population growth, urban expansion, and environmental protection efforts in many areas.^[134]

In 2019 the Intergovernmental Panel on Climate Change issued a Special Report on Climate Change and Land. The main statements of the report include:^[135][136] In the years 1960 – 2013 the area of drylands in drought, increased by 1% per year. In the year 2015 around 500 million people lived in areas that was impacted by desertification in the years 1980s – 2000s. People who live in the areas affected by land degradation and desertification are "increasingly negatively affected by climate change".

Wildfires

Average U.S. acreage burned annually by wildfires has almost tripled in three decades.^[137]

Globally, climate change promotes the type of weather that makes wildfires more likely. In some areas, an increase of wildfires has been attributed directly to climate change. That warmer climate conditions pose more risks of wildfire is consistent with evidence from Earth's past: there was more fire in warmer periods, and less in colder climatic periods.^[138] Climate change increases evaporation, which can cause vegetation to dry out. When a fire starts in an area with very dry vegetation, it can spread rapidly. Higher temperatures can also make the fire season longer, the time period in which severe wildfires are most likely. In regions where snow is disappearing, the fire season may get particularly more extended.^[139]

Even thought weather conditions are raising the risks of wildfires, the total area burnt by wildfires has decreased globally. This is mostly the result of the conversion of savanna into croplands, so that there is less forest area that can burn. Prescribed burning, an indigenous practice in the US and Australia, can reduce the area burnt too, and may form an adaptation to increased risk.^[139] The carbon released from wildfires can further increase greenhouse gas concentrations. This feedback is not yet fully integrated into climate models.^[140]

Key vulnerabilities

Most of the key vulnerabilities to climate change are related to climate phenomena that exceed thresholds for adaptation; such as extreme weather events or abrupt climate change, as well as limited access to resources (financial, technical, human, institutional) to cope. Humans generally live in areas where the average temperature is between 6 °C and 28 °C, with the majority of life in regions with a temperature of 11 °C – 15 °C. A temperature of 29 degrees or higher is considered as too hot for normal life and currently found only in 0.8% of the land surface (mainly in Sahara desert). However, according to the study by the year 2070 in the RCP8.5 (very high emission) scenario, 30% of human population will live in this area.^[173][174] In the supplementary materials of the study, it is said that according to this scenario the global average temperature will be 3.2-degree higher in the year 2070 relatively to the pre – industrial baseline.^[175] According to the United Nations Environmental Program report, the temperature will rise by 3.2 degrees by the end of the century. Even if all the pledges in Paris Agreement (as they were in 2019) will be accomplished.^[176]

Agriculture and food security

Climate change will impact agriculture and food production around the world due to the effects of elevated CO₂ in the atmosphere; higher temperatures; altered precipitation and transpiration regimes; increased frequency of extreme events; and modified weed, pest, and pathogen pressure.^[177] Climate change is projected to negatively affect all four pillars of food security: not only how much food is available, but also how easy food is to access (prices), food quality and how stable the food system is.^[178]

Water security

A number of climate-related trends have been observed that affect water resources. These include changes in precipitation, the cryosphere and surface waters (e.g., changes in river flows).^[188] Observed and projected impacts of climate change on freshwater systems and their management are mainly due to changes in temperature, sea level and precipitation variability.^[189] Changes in temperature are correlated with variability in precipitation because the water cycle is reactive to temperature.^[190] Temperature increases change precipitation patterns. Excessive precipitation leads to excessive sediment deposition, nutrient pollution, and concentration of minerals in aquifers.

The rising global temperature will cause sea level rise and will extend areas of salinization of groundwater and estuaries, resulting in a decrease in freshwater availability for humans and ecosystems in coastal areas. The rising sea level will push the salt gradient into freshwater deposits and will eventually pollute freshwater sources. The 2014 fifth IPCC assessment report concluded that:

• Water resources are projected to decrease in most dry subtropical regions and mid-latitudes, but increase in high latitudes. As streamflow becomes more variable, even regions with increased water resources can experience additional short-term shortages.^[191]
• Climate change is projected to reduce water quality before treatment. Even after conventional treatments, risks remain. The quality reduction is a consequence of higher temperatures, more intense rainfall, droughts and disruption of treatment facilities during floods.^[192]
• Droughts that stress water supply are expected to increase in southern Europe and the Mediterranean region, central Europe, central and southern North America, Central America, northeast Brazil, and southern Africa.^[193]

Health

Climate Crisis = Health Crisis

This section is an excerpt from Effects of climate change on human health.[edit]

Air pollution from a surface fire in the western desert of Utah (wildfires become more frequent and intense due to climate change).

The effects of climate change on human health include direct effects of extreme weather, leading to injury and loss of life,^[194] as well as indirect effects, such as undernutrition brought on by crop failures or lack of access safe drinking water.^[195] For instance, having to emigrate due to an extreme weather event can lead to increased rates of physical illnesses and psychological distress.^[196] Various infectious diseases are more easily transmitted in a warmer climate, such as dengue fever, which affects children most severely, and malaria. Young children are the most vulnerable to food shortages, and together with older people, to extreme heat.^[197] Other health related effects arise from environmental degradation, diseases carried by vectors, food and waterborne infections, changes to food security, and impacts on mental health.

Climate change poses a wide range of risks to population health. If global climate change continues on its current trajectory, these risks will increase in future decades to potentially critical levels.^[198] The three main categories of health risks include: (i) direct-acting effects (e.g. due to heat waves, amplified air pollution, and physical weather disasters), (ii) impacts mediated via climate-related changes in ecological systems and relationships (e.g. crop yields, mosquito ecology, marine productivity), and (iii) the more diffuse (indirect) consequences relating to impoverishment, displacement, resource conflicts (e.g. water), and post-disaster mental health problems.

Flooding in the Midwestern United States, June 2008

Conflict

Climate change can worsen conflicts by exacerbating tensions over limited resources like drinking water. Climate change has the potential to cause large population dislocations and migration, which can also lead to increased tensions and conflict.^[199][200]

However, a 2018 study in the journal Nature Climate Change found that previous studies on the relationship between climate change and conflict suffered from sampling bias and other methodological problems.^[201] Factors other than climate change are judged to be substantially more important in affecting conflict (based on expert elicitation). These factors include intergroup inequality and low socio-economic development.^[202]

Despite these issues, military planners are concerned that global warming is a "threat multiplier". "Whether it is poverty, food and water scarcity, diseases, economic instability, or threat of natural disasters, the broad range of changing climatic conditions may be far reaching. These challenges may threaten stability in much of the world".^[203] For example, the onset of the Arab Spring in 2010 was partly the result of a spike in wheat prices following crop losses from the 2010 Russian heat wave.^[204][205] The United Nations said several times that climate change is already increasing conflicts in different regions of the world.^[206][207]

Economic impact

Overall economy and inequality

Business activities affected by climate changed as found in the European Investment Bank Investment Survey 2020

Economic forecasts of the impact of global warming vary considerably. Researchers have warned that current economic modelling may seriously underestimate the impact of potentially catastrophic climate change, and point to the need for new models that give a more accurate picture of potential damages. Nevertheless, one 2018 study found that potential global economic gains if countries implement mitigation strategies to comply with the 2 °C target set at the Paris Agreement are in the vicinity of US$17 trillion per year up to 2100 compared to a very high emission scenario.^[208]

Global losses reveal rapidly rising costs due to extreme weather events since the 1970s.^[40] Socio-economic factors have contributed to the observed trend of global losses, such as population growth and increased wealth.^[209] Part of the growth is also related to regional climatic factors, e.g., changes in precipitation and flooding events. It is difficult to quantify the relative impact of socio-economic factors and climate change on the observed trend.^[210] The trend does, however, suggest increasing vulnerability of social systems to climate change.^[210]

A 2019 modelling study found that climate change had contributed towards global economic inequality. Wealthy countries in colder regions had either felt little overall economic impact from climate change, or possibly benefited, whereas poor hotter countries very likely grew less than if global warming had not occurred.^[211]

The total economic impacts from climate change are difficult to estimate, but increase for higher temperature changes.^[212] For instance, total damages are estimated to be 90% less if global warming is limited to 1.5 °C compared to 3.66 °C, a warming level chosen to represent no mitigation.^[213] One study found a 3.5% reduction in global GDP by the end of the century if warming is limited to 3 °C, excluding the potential effect of tipping points. Another study noted that global economic impact is underestimated by a factor of two to eight when tipping points are excluded from consideration.^[213] In the Oxford Economics high emission scenario, a temperature rise of 2 degrees by the year 2050 would reduce global GDP by 2.5% – 7.5%. By the year 2100 in this case, the temperature would rise by 4 degrees, which could reduce the global GDP by 30% in the worst case.^[214]

Insurance

New Orleans submerged after Hurricane Katrina

The insurance industry is predicated on managing the risks associated with damages to property and since climate change has direct consequences on the safety of society; insurers must adapt to these changes.^[231]

In March 2019, Munich Re noted that climate change could cause home insurance to become unaffordable for households at or below average incomes.^[232]

Displacement and migration

A refugee camp north of Goma near the Rwandan border

Climate change causes displacement of people in several ways, the most obvious—and dramatic—being through the increased number and severity of weather-related disasters which destroy homes and habitats causing people to seek shelter or livelihoods elsewhere. Effects of climate change such as desertification and rising sea levels gradually erode livelihood and force communities to abandon traditional homelands for more accommodating environments. This is currently happening in areas of Africa's Sahel, the semi-arid belt that spans the continent just below its northern deserts. Deteriorating environments triggered by climate change can also lead to increased conflict over resources which in turn can displace people.^[234]

According to the Internal Displacement Monitoring Centre in 2020 approximately 30 million people were displaced by extreme weather events while approximately 10 million by violence and wars and climate change significantly contributed to this.^[235][236]

Asia and the Pacific is the global area most prone to natural disasters, both in terms of the absolute number of disasters and of populations affected. It is highly exposed to climate impacts, and is home to highly vulnerable population groups, who are disproportionately poor and marginalized. A recent Asian Development Bank report highlights "environmental hot spots" that are particular risk of flooding, cyclones, typhoons, and water stress.^[237]

Some Pacific Ocean island nations, such as Tuvalu, Kiribati, and the Maldives,^[238] are considering the eventual possibility of evacuation, as flood defense may become economically unrealistic. Tuvalu already has an ad hoc agreement with New Zealand to allow phased relocation.^[239] However, for some islanders relocation is not an option. They are not willing to leave their homes, land and families. Some simply don't know the threat that climate change has on their island and this is mainly down to the lack of awareness that climate change even exists. As of 2020 many Pacific islands are growing in size, contradicting earlier claims.^[240]

Governments have considered various approaches to reduce migration compelled by environmental conditions in at-risk communities, including programs of social protection, livelihoods development, basic urban infrastructure development, and disaster risk management. Some experts even support migration as an appropriate way for people to cope with environmental changes. However, this is controversial because migrants – particularly low-skilled ones – are among the most vulnerable people in society and are often denied basic protections and access to services.^[237]

Climate change is only one factor that may contribute to a household's decision to migrate; other factors may include poverty, population growth or employment options.^[241] For this reason, it is difficult to classify environmental migrants as actual "refugees" as legally defined by the UNHCR.^[242]

In small islands and megadeltas, inundation as a result of sea level rise is expected to threaten vital infrastructure and human settlements.^[243][244] This could lead to issues of statelessness for populations in countries such as the Maldives and Tuvalu^[245] and homelessness in countries with low-lying areas such as Bangladesh.

The World Bank predicts that a "severe hit" will spur conflict and migration across the Middle East, Central Asia, and Africa.^[246]

Visible effects of climate change: sea level rise at the Marshall Islands, reaching the edge of a village (from the documentary One Word)

Gradual but pervasive environmental change and sudden natural disasters both influence the nature and extent of human migration but in different ways. United Nations High Commissioner for Refugees stated that climate change increases mass displacement, in many regions, including Sahel, East Africa, South Asia, the "drought corridor" in Latin America. 90% of refugees comes from "climate vulnerable hotspots".^[207]

Security

Social impacts

The consequences of climate change and poverty are not distributed uniformly within communities. Individual and social factors such as gender, age, education, ethnicity, geography and language lead to differential vulnerability and capacity to adapt to the effects of climate change.

Disproportionate effects on children

This section is an excerpt from Climate change and children.[edit]

Children are more vulnerable to the effects of climate change than adults. The World Health Organization estimated that 88% of the existing global burden of disease is linked to climate change affecting children under 5 years of age.^[270] The Lancet review on health and climate change lists children as the worst-affected category by climate change.^[271] Children are also 14–44 percent more likely to die from environmental factors,^[272] again leaving them the most vulnerable. Those in urban areas will be affected by lower air quality and overcrowding, and will struggle the most to better their situation.^[273]

Climate Emergency -

Children are physically more vulnerable to climate change in all its forms.^[274] Climate change affects the physical health of a child and their well-being. Prevailing inequalities, between and within countries, determines how climate change impacts children.^[275] Children have no voice or attention in terms of global responses to climate change.^[274]

Human settlement

A major challenge for human settlements is sea level rise, indicated by ongoing observation and research of rapid declines in ice-mass balance from both Greenland and Antarctica. Estimates for 2100 are at least twice as large as previously estimated by IPCC AR4, with an upper limit of about two meters.^[277] Depending on regional changes, increased precipitation patterns can cause more flooding or extended drought stresses water resources.

Coasts and low-lying areas

Floodplains and low-lying coastal areas will flood more frequently due to climate change, like this area of Myanmar which was submerged by Cyclone Nargis

For historical reasons to do with trade, many of the world's largest and most prosperous cities are on the coast. In developing countries, the poorest often live on floodplains, because it is the only available space, or fertile agricultural land. These settlements often lack infrastructure such as dykes and early warning systems. Poorer communities also tend to lack the insurance, savings, or access to credit needed to recover from disasters.

The IPCC reported that socioeconomic impacts of climate change in coastal and low-lying areas would be overwhelmingly adverse. The following impacts were projected with very high confidence:^[278]

• Coastal and low-lying areas would be exposed to increasing risks including coastal erosion due to climate change and sea level rise.
• By the 2080s, millions of people would experience floods every year due to sea level rise. The numbers affected were projected to be largest in the densely populated and low-lying mega-deltas of Asia and Africa; and smaller islands were judged to be especially vulnerable.

Amazon rainforest

Rainfall that falls on the Amazon rainforest is recycled when it evaporates back into the atmosphere instead of running off away from the rainforest. This water is essential for sustaining the rainforest. Due to deforestation the rainforest is losing this ability, exacerbated by climate change which brings more frequent droughts to the area. The higher frequency of droughts seen in the first two decades of the 21st century, as well as other data, signal that a tipping point from rainforest to savanna might be close. One study concluded that this ecosystem could enter a mode of a 50-years-long collapse to a savanna around 2021, after which it would become increasingly and disproportionally more difficult to prevent or reverse this shift.^{[292][293][294]}

Greenland and West Antarctic Ice sheets

Future melt of the West Antarctic ice sheet is potentially abrupt under a high emission scenario, as a consequence of a partial collapse.^[295] Part of the ice sheet is grounded on bedrock below sea level, making it possibly vulnerable to the self-enhancing process of marine ice sheet instability. A further hypothesis is that marine ice cliff instability would also contribute to a partial collapse, but limited evidence is available for its importance.^[296] A partial collapse of the ice sheet would lead to rapid sea level rise and a local decrease in ocean salinity. It would be irreversible on a timescale between decades and millennia.^[295]

In contrast to the West Antarctic ice sheet, melt of the Greenland ice sheet is projected to be taking place more gradually over millennia.^[295] Sustained warming between 1 °C (low confidence) and 4 °C (medium confidence) would lead to a complete loss of the ice sheet, contributing 7 m to sea levels globally.^[297] The ice loss could become irreversible due to a further self-enhancing feedback: the elevation-surface mass balance feedback. When ice melts on top of the ice sheet, the elevation drops. As air temperature is higher at lower altitude, this promotes further melt.^[298]

Atlantic Meridional Overturning Circulation

This map shows the general location and direction of the warm surface (red) and cold deep water (blue) currents of the thermohaline circulation. Salinity is represented by color in units of the Practical Salinity Scale. Low values (blue) are less saline, while high values (orange) are more saline.^[299]

The Atlantic Meridional Overturning Circulation (AMOC), an important component of the Earth's climate system, is a northward flow of warm, salty water in the upper layers of the Atlantic and a southward flow of colder water in the deep Atlantic.^[300]: 5 Potential impacts associated with AMOC changes include reduced warming or (in the case of abrupt change) absolute cooling of northern high-latitude areas near Greenland and north-western Europe, an increased warming of Southern Hemisphere high-latitudes, tropical drying, as well as changes to marine ecosystems, terrestrial vegetation, oceanic CO
₂ uptake, oceanic oxygen concentrations, and shifts in fisheries.^[301]

According to a 2019 assessment in the IPCC's Special Report on the Ocean and Cryosphere in a Changing Climate it is very likely (greater than 90% probability, based on expert judgement) that the strength of the AMOC will decrease further over the course of the 21st century.^[302] Warming is still expected to occur over most of the European region downstream of the North Atlantic Current in response to increasing GHGs, as well as over North America. With medium confidence, the IPCC report stated that it is very unlikely (less than 10% probability) that the AMOC will collapse in the 21st century.^[302] The potential consequences of such a collapse could be severe.^[300]: 5

Irreversible change

Low-lying coastal regions

Given high coastal population density, estimates of the number of people at risk of coastal flooding from climate-driven sea-level rise varies from 190 million,^[317] to 300 million or even 640 million in a worst-case scenario related to the instability of the Antarctic ice sheet.^[318][319] The most people affected are in the densely-populated and low-lying megadeltas of Asia and Africa.^[320]

The Greenland ice sheet is estimated to have reached a point of no return, continuing to melt even if warming stopped. Over time that would submerge many of the world's coastal cities including low-lying islands, especially combined with storm surges and high tides.^[321]

The Arctic

The southern part of the Arctic region (home to 4,000,000 people) has experienced a temperature rise of 1 °C to 3 °C (1.8 °F to 5.4 °F) over the last 50 years.^[326] Canada, Alaska and Russia are experiencing initial melting of permafrost. This may disrupt ecosystems and by increasing bacterial activity in the soil lead to these areas becoming carbon sources instead of carbon sinks.^[327] A study (published in Science) of changes to eastern Siberia's permafrost suggests that it is gradually disappearing in the southern regions, leading to the loss of nearly 11% of Siberia's nearly 11,000 lakes since 1971.^[328] At the same time, western Siberia is at the initial stage where melting permafrost is creating new lakes, which will eventually start disappearing as in the east. Furthermore, permafrost melting will eventually cause methane release from melting permafrost peat bogs.

Africa

Small islands

Small islands developing states are especially vulnerable to the effects of climate change, especially sea level rise. They are expected to experience more intense storm surges, salt water intrusion, and coastal destruction.^[335] Low-lying small islands in the Pacific, Indian, and Caribbean regions are at risk of permanent inundation and population displacement.^{[336][337][338]} On the islands of Fiji, Tonga and western Samoa, concentrations of migrants from outer islands inhabit low and unsafe areas along the coasts.^[338]

Atoll nations, which include countries that are composed entirely of the smallest form of islands, called motus, are at risk of entire population displacement.^[339][336] These nations include Kiribati, Maldives, the Marshall Islands, Tokelau, and Tuvalu.^[336][337] Vulnerability is increased by small size, isolation from other land, low financial resources, and lack of protective infrastructure.^[336]

A study that engaged the experiences of residents in atoll communities found that the cultural identities of these populations are strongly tied to these lands.^[340] Human rights activists argue that the potential loss of entire atoll countries, and consequently the loss of national sovereignty, self-determination, cultures, and indigenous lifestyles cannot be compensated for financially.^[339][336] Some researchers suggest that the focus of international dialogues on these issues should shift from ways to relocate entire communities to strategies that instead allow for these communities to remain on their lands.^[339][340]

Middle East

The region of Middle East is one of the most vulnerable to climate change. The impacts include increase in drought conditions, aridity, heatwaves, sea level rise. If greenhouse gas emissions are not reduced, the region can become uninhabitable before the year 2100.^[341][342]