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Friday, April 28, 2023

Effects of climate change

https://en.wikipedia.org/wiki/Effects_of_climate_change

Thick orange-brown smoke blocks half a blue sky, with conifers in the foreground
A few grey fish swim over grey coral with white spikes
Desert sand half covers a village of small flat-roofed houses with scattered green trees
large areas of still water behind riverside buildings
Some climate change effects, clockwise from top left: Wildfire caused by heat and dryness, bleached coral caused by ocean acidification and heating, coastal flooding caused by storms and sea level rise, and environmental migration caused by desertification.

 
The primary causes and the wide-ranging impacts of climate change. Some effects act as feedbacks that intensify climate change.

The effects of climate change impact the physical environment, ecosystems and human societies. Changes in the climate system include an overall warming trend, more extreme weather and rising sea levels. These in turn impact nature and wildlife, as well as human settlements and societies. The effects of human-caused climate change are broad and far-reaching, especially if significant climate action is not taken. The projected and observed negative impacts of climate change are sometimes referred to as the climate crisis.

The changes in climate are not uniform across the Earth. In particular, most land areas have warmed faster than most ocean areas, and the Arctic is warming faster than most other regions. Among the effects of climate change on oceans are an increase of ocean temperatures, a rise in sea level from ocean warming and ice sheet melting, increased ocean stratification, and changes to ocean currents including a weakening of the Atlantic meridional overturning circulation. Carbon dioxide from the atmosphere is acidifiying the ocean.

Recent warming has strongly affected natural biological systems. It has degraded land by raising temperatures, drying soils and increasing wildfire risk. Species worldwide are migrating poleward to colder areas. On land, many species move to higher ground, whereas marine species seek colder water at greater depths. At 2 °C (3.6 °F) of warming, around 10% of species on land would become critically endangered.

Food security and access to fresh water are at risk due to rising temperatures. Climate change has profound impacts on human health, directly via heat stress and indirectly via the spread of infectious diseases. The vulnerability and exposure of humans to climate change varies by economic sector and by country. Wealthy industrialised countries, which have emitted the most CO2, have more resources and so are the least vulnerable to global warming. Economic sectors affected include agriculture, fisheries, forestry, energy, insurance, and tourism. Some groups may be particularly at risk from climate change, such as the poor, women, children and indigenous peoples. Climate change can lead to displacement and changes in migration flows.

Changes in temperature

Average surface air temperatures from 2011 to 2021 compared to the 1956–1976 average. Source: NASA

Global warming affects all elements of Earth's climate system. Global surface temperatures have risen by 1.1 °C (2.0 °F) and are expected to rise further in the future. The changes in climate are not uniform across the Earth. In particular, most land areas have warmed faster than most ocean areas, and the Arctic is warming faster than most other regions. In addition, night-time temperatures have increased faster than daytime temperatures. The impact on the environment, wildlife, society and humanity depends on how much more the Earth warms.

One of the methods scientists use to predict the effects of human-caused climate change is to investigate past natural changes in climate. To assess changes in Earth's past climate scientists have studied tree rings, ice cores, corals, and ocean and lake sediments. These show that recent warming has surpassed anything in the last 2,000 years. By the end of the 21st century, temperatures may increase to a level not experienced since the mid-Pliocene, around 3 million years ago. At that time, mean global temperatures were about 2–4 °C (3.6–7.2 °F) warmer than pre-industrial temperatures, and the global mean sea level was up to 25 meters higher than it is today.

Projected temperature and sea-level rise relative to the 2000–2019 mean for RCP climate change scenarios up to 2500.

How much the world warms depends on human greenhouse gas emissions and how sensitive the climate is to greenhouse gases. The more carbon dioxide (CO2) emitted in the 21st century the hotter the world will be by 2100. For a doubling of greenhouse gas concentrations, the global mean temperature would rise by about 2.5–4 °C (4.5–7.2 °F). If emissions of CO2 were to be abruptly stopped and no negative emission technologies deployed, the Earth's climate would not start moving back to its pre-industrial state. Instead, temperatures would stay elevated at the same level for several centuries. After about a thousand years, 20% to 30% of human-emitted CO2 will remain in the atmosphere, not taken up by the ocean or the land, committing the climate to a warmer state long after emissions have stopped.

Mitigation policies currently in place will result in about 2.7 °C (2.0–3.6 °C) warming above pre-industrial levels by 2100. If all unconditional pledges and targets made by governments are achieved the temperature will rise by around 2.4 °C (4.3 °F). If additionally all the countries that adopted or are considering to adopt net-zero targets will achieve them, the temperature will rise by a median of 1.8 °C (3.2 °F). There is a substantial gap between national plans and commitments and actions so far taken by governments around the world.

Weather

The lower and middle atmosphere, where nearly all of the weather occurs, are heating due to the enhanced greenhouse effect. Increased greenhouse gases cause the higher parts of the atmosphere, the stratosphere, to cool. As temperatures increase, so does evaporation and atmospheric moisture content. As water vapour is also a greenhouse gas, this process acts as a self-reinforcing feedback.

The excess water vapour also gets caught up in storms and makes them more intense, larger, and potentially longer-lasting. This in turn causes rain and snow events to become stronger and leads to increased risk of flooding. Extra drying worsens natural dry spells and droughts, and increases risk of heat waves and wildfires. With recent climate trends clearly identified as caused by human activities, extreme event attribution estimates the impact of climate change in extreme climate events. For instance, such research can demonstrate that a specific heatwave was more intense due to climate change based on historical data for that region.

Rain and snow

Warming increases global average precipitation (such as rain and snow). Higher temperatures lead to increased evaporation and surface drying. As the air warms, its water-holding capacity also increases: Air can hold 7% more water vapour for every degree Celsius it is warmed. Changes have already been observed in the amount, intensity, frequency, and type of precipitation. Overall, climate change causing longer hot dry spells, broken by more intense heavy rainfalls. Widespread increases in heavy precipitation have occurred even in places where total rain amounts have decreased.

Climate change has increased contrasts in rainfall amounts between wet and dry seasons: wet seasons are getting wetter and dry seasons are getting drier. In the northern high latitutes, warming has also caused an increase in the amount of snow and rain. 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.

Heat waves and temperature extremes

Large increases in both the frequency and intensity of extreme weather events (for increasing degrees of global warming) are expected.
Map of increasing heatwave trends (frequency and cumulative intensity) over the midlatitudes and Europe, July–August 1979–2020.[41]

Heatwaves over land have become more frequent and more intense since the 1950s due to climate change in almost all world regions. Furthermore, heat waves are more likely to occur simultaneously with droughts. Marine heatwaves have also increased in frequency, with a doubling since 1980. Climate change will lead to more very hot days and fewer very cold days. Globally, cold waves have decreased in frequency.

The intensity of individual heat waves can often be attributed to global warming. Some extreme events would have been nearly impossible without human influence on the climate system. A heatwave that would occur once every ten years before global warming started, now occurs 2.8 times as often. Under further warming, heatwaves are set to become more frequent. An event that would occur each ten year, would occur every other year if global warming reaches 2 °C (3.6 °F).

Heat stress is not only related to temperature, but also increases if humidity is higher. The wet-bulb temperature measures both temperature and humidity. Above a wet-bulb temperature of 35 °C (95 °F), this heat stress is beyond human adaptation, and can lead to mortality. If global warming is kept below 1.5 or 2 °C (2.7 or 3.6 °F), this survival limit can likely be avoided in most of the tropics, but there may still be negative health impacts.

There is some evidence climate change leads to a weakening of the polar vortex, which would make the jet stream more wavy. This would lead to outbursts of very cold winter weather across parts of Eurasia and North America, as well as very warm air incursions into the Arctic.

Tropical cyclones and storms

New Orleans submerged after Hurricane Katrina, September 2005
Climate change can affect tropical cyclones in a variety of ways: an intensification of rainfall and wind speed, a decrease in overall frequency, an increase in the frequency of very intense storms and a poleward extension of where the cyclones reach maximum intensity are among the possible 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.

Weather-related impacts

Floods

High tide flooding is increasing due to sea level rise, land subsidence, and the loss of natural barriers.
Long-term sea level rise occurs in addition to intermittent tidal flooding. NOAA predicts different levels of sea level rise for coastlines within a single country.

Due to an increase in heavy rainfall events, floods are expected to become more severe when they do occur. However, the interactions between rainfall and flooding are complex. There are some regions in which flooding is expected to become rarer. This depends on several factors, such as changes in rain and snowmelt, but also soil moisture.

Sea level rise further increases risks of coastal flooding: with substantial disruption projected for cities, settlements and infrastructure on coasts.

Droughts

A dry lakebed in California. In 2022, the state was experiencing its most serious drought in 1,200 years, worsened by climate change.

Climate change affects multiple factors associated with droughts, such as how much rain falls and how fast the rain evaporates again. Warming over land increases the severity and frequency of droughts around much of the world. In some tropical and subtropical regions of the world, there will likely be less rain due to global warming, making them more prone to drought. These regions where droughts are set to worsen are Central America, the Amazon and south-western South America, West and Southern Africa, as well as the Mediterranean and south-western Australia.

Higher temperatures lead to increased evaporation, thus drying the soil and increasing plant stress, which will have impacts on agriculture. For this reason, even regions where overall rainfall is expected to remain relatively stable, such as central and northern Europe, will experience these impacts. Without climate change mitigation, it is expected that around a third of land areas will experience moderate or more severe drought by 2100. Droughts are likely to be more intense than in the past.

Due to limitations on how much data is available about drought in the past, it is often impossible to confidently attribute a specific drought to human-induced climate change. Some areas however, such as the Mediterranean and California, already show the impacts of human activities. Their impacts are made worse because of increased water demand, population growth, urban expansion, and environmental protection efforts in many areas. Land restoration, especially by agroforestry, can help reduce the impact of droughts.

Wildfires

Average U.S. acreage burned annually by wildfires has almost tripled in three decades.

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. 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.

Even though weather conditions are raising the risks of wildfires, the total area burnt by wildfires has decreased. This is mostly the result of the conversion of savanna into croplands, after which 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. The carbon released from wildfires can further increase greenhouse gas concentrations. This feedback is not yet fully integrated into climate models.

Oceans

Oceans have taken up almost 90% of the excess heat accumulated on Earth due to global warming.
 
A part of the Great Barrier Reef in Australia in 2016 after a coral bleaching event

Among the effects of climate change on oceans are an increase of ocean temperatures, more frequent marine heatwaves, ocean acidification, a rise in sea levels, sea ice decline, increased ocean stratification, reductions in oxygen levels, changes to ocean currents including a weakening of the Atlantic meridional overturning circulation. All these changes have knock-on effects which disturb marine ecosystems. The primary factor causing these changes is the Earth warming due to human-caused emissions of greenhouse gases, such as carbon dioxide and methane. This leads inevitably to ocean warming, because the ocean is taking up most of the additional heat in the climate system. The ocean absorbs some of the extra carbon dioxide in the atmosphere and this causes the pH value of the ocean to drop. It is estimated that the ocean absorbs about 25% of all human-caused CO2 emissions.

Ocean temperature stratification increases as the ocean surface warms due to rising air temperatures.The decline in mixing of the ocean layers stabilises warm water near the surface while reducing cold, deep water circulation. The reduced up and down mixing reduces the ability of the ocean to absorb heat, directing a larger fraction of future warming toward the atmosphere and land. The amount of energy available for tropical cyclones and other storms is expected to increase, while nutrients for fish in the upper ocean layers are expected to decrease, as is 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 result in a reduced supply of oxygen from surface waters to deeper waters, lowering the water's oxygen content further. The ocean has already lost oxygen throughout its water column, and oxygen minimum zones are expanding worldwide.

Sea level rise

A graph showing a around 25 cm of sea level rise, based on tidal gauge data.
Global sea level rise from 1880

Between 1901 and 2018, the average global sea level rose by 15–25 cm (6–10 in), or 1–2 mm per year. This rate is increasing; sea levels are now rising at a rate of 3.7 mm (0.146 inches) per year. Human-caused climate change is predominantly the cause, as it constantly heats (and thus expands) the ocean and melts land-based ice sheets and glaciers. Between 1993 and 2018, thermal expansion of water contributed 42% to sea level rise (SLR); melting of temperate glaciers contributed 21%; Greenland contributed 15%; and Antarctica contributed 8%. Because sea level rise lags changes in Earth temperature, it will continue to accelerate between now and 2050 purely in response to already-occurring warming; whether it continues to accelerate after that depends on human greenhouse gas emissions. If global warming is limited to 1.5 °C (2.7 °F), then sea level rise does not accelerate, but it would still amount to 2–3 m (7–10 ft) over the next 2000 years, while 19–22 metres (62–72 ft) would occur if the warming peaks at 5 °C (9.0 °F).

Rising seas pose both a direct risk of flooding unprotected areas and indirect threats of higher storm surges, king tides, and tsunamis. They are also associated with second-order effects such as loss of coastal ecosystems like mangroves, losses in crop production due to freshwater salinization of irrigation water, and the disruption of sea trade due to damaged ports. Just the projected sea level rise by 2050 will expose places currently inhabited by tens of millions of people to annual flooding. This may increase to hundreds of millions in the latter decades of the century if greenhouse gas emissions are not reduced drastically. While slow increases in sea level may allow time for adaptation, such as building sea walls, the passage of time can also increase the number of people at risk, as many coastal areas have large population growth. Later in the century, millions more would be affected in cities such as Miami, Rio de Janeiro, Osaka and Shanghai under the warming of 3 °C (5.4 °F), which is close to the current trajectory.

Ice and snow

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. The rate of ice loss has risen by 57% since the 1990s−from 0.8 to 1.2 trillion tonnes per year.
 
Melting of glacial mass is approximately linearly related to temperature rise.
 
Shrinkage of snow cover duration in the Alps, starting ca. end of the 19th century, highlighting climate change adaptation needs.

The cryosphere, the area of the Earth covered by snow or ice, is extremely sensitive to changes in global climate. There has been an extensive loss in snow on land since 1981. Some of the largest declines have been observed in the spring. During the 21st century, snow cover is projected to continue its retreat in almost all regions.

Glaciers and ice sheets decline

Since the beginning of the twentieth century, there has been a widespread loss of glacier mass. This is also called retreat of glaciers. Excluding peripheral glaciers of ice sheets, the total cumulated global glacial losses over the 26 year period from 1993–2018 were likely 5500 gigatons, or 210 gigatons per yr. In locations such as the Andes and Himalayas, the demise of glaciers has the potential to affect water supplies.

The melting of the Greenland and West Antarctic ice sheets will continue to contribute to sea level rise over long time-scales. The Greenland ice sheet loss is mainly driven by melt from the top, whereas Antarctic ice loss is driven by warm ocean water melting the outlet glaciers.

Future melt of the West Antarctic ice sheet is potentially abrupt under a high emission scenario, as a consequence of a partial collapse. 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. 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.

In contrast to the West Antarctic ice sheet, melt of the Greenland ice sheet is projected to be taking place more gradually over millennia. Sustained warming between 1 °C (1.8 °F) (low confidence) and 4 °C (7.2 °F) (medium confidence) would lead to a complete loss of the ice sheet, contributing 7 m (23 ft) to sea levels globally. 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.

Sea ice decline

Sea ice reflects 50% to 70% of the incoming solar radiation back into space, while only 6% of the incoming solar energy is reflected by the ocean. As the climate warms, snow cover and sea ice extent decrease. When sea ice melts, more energy is absorbed by the ocean, with rising temperature as a consequence. This ice-albedo feedback is a self-reinforcing feedback of climate change. Large-scale measurements of sea ice have only been possible since the satellite era.

Sea ice in the Arctic 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. 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). While ice-free summers are expected to be rare at 1.5 °C (2.7 °F) degrees of warming, they are set to occur at least once every decade at a warming level of 2 °C (3.6 °F). The Arctic will likely become ice-free at the end of some summers before 2050.

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.

Permafrost thawing

Globally, permafrost warmed by about 0.3 °C between 2007 and 2016. Permafrost extent has been diminishing for decades, and more decline is expected in the future. Thawing soil may be weaker and release methane, which contributes to an increased rate of global warming as part of a feedback loop caused by microbial decomposition. In areas where there is a lot of permafrost, nearby human infrastructure may be damaged severely by the thawing of permafrost. It is believed that carbon storage in permafrost globally is approximately 1600 gigatons, equivalent to twice the atmospheric pool.

Wildlife and nature

Recent warming has strongly affected natural biological systems. Species worldwide are moving poleward to colder areas. On land, species may move to higher elevations, whereas marine species find colder water at greater depths. Of the drivers with the biggest global impact on nature, climate change ranks third over the five decades before 2020, with only change in land use and sea use, and direct exploitation of organisms having a greater impact.

The impacts of climate change in nature and nature's contributions to humans are projected to become more pronounced in the next few decades. The stresses caused by climate change, added to other stresses on ecological systems (e.g. land conversion, land degradation, harvesting, and pollution), threaten substantial damage to or complete loss of some unique ecosystems, and extinction of species. Key interactions between species within ecosystems are often disrupted because species from one location do not move to colder habitats at the same rate, giving rise to rapid changes in the functioning of the ecosystem. Impacts include changes in regional rainfall patterns, earlier leafing of trees and plants over many regions; movements of species to higher latitudes and altitudes in the Northern Hemisphere; changes in bird migrations; and shifting of the oceans' plankton and fish from cold- to warm-adapted communities.

Ecosystems on land

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. In other ecosystems, land-use change may be a stronger driver of biodiversity loss, at least in the near-term. Beyond the year 2050, climate change may be the major driver for biodiversity loss globally. 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. At 2 °C (3.6 °F) of warming, around 10% of species on land would become critically endangered. This differs by group: for instance insects and salamanders are more vulnerable.

Amazon rainforest

The rate of global tree cover loss has approximately doubled since 2001, to an annual loss approaching an area the size of Italy.

Rainfall 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.

Marine ecosystems

Marine heatwaves have seen an increased frequency and have widespread impacts on life in the oceans, such as mass dying events and coral bleaching. Harmful algae blooms have increased in response to warming waters, loss of oxygen and eutrophication. Melting sea ice destroys habitat, including for algae that grows on its underside.

Ocean acidification is the 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. Decreased ocean pH has a range of potentially harmful effects for marine organisms. Marine calcifying organisms, such as mollusks and corals, are especially vulnerable because they rely on calcium carbonate to build shells and skeletons.

Warm water coral reefs are very sensitive to global warming and ocean acidification. Coral reefs provide a habitat for thousands of species and ecosystem services such as coastal protection and food. The resilience of reefs can be improved by curbing local pollution and overfishing, but 70–90% of today's warm water coral reefs will disappear even if warming is kept to 1.5 °C (2.7 °F). Coral reefs are framework organisms: they build physical structures that form habitats for other sea creatures. Other framework organisms are also at risk from climate change. For instance, mangroves and seagrass are considered to be at moderate risk for lower levels of global warming.

Tipping points and irreversible impacts

Self-reinforcing feedbacks can amplify climate change. The climate system exhibits "threshold behaviour" or tipping points when these feedbacks lead parts of the Earth system into a new state, such as the runaway loss of ice sheets or the dieback of forests. Tipping points are studied using data from Earth's distant past and by physical modelling. There is already moderate risk of global tipping points at 1 °C (1.8 °F) above pre-industrial temperatures, and that risk becomes high at 2.5 °C (4.5 °F).

Tipping points are "perhaps the most 'dangerous' aspect of future climate changes", leading to irreversible impacts on society. Many tipping points are interlinked, so that triggering one may lead to a cascade of effects, even well below 2 °C (3.6 °F) of warming. A 2018 study states that 45% of environmental problems, including those caused by climate change, are interconnected and make the risk of a domino effect bigger.

There are a number of climate change impacts on the environment that may be irreversible, at least over the timescale of many human generations. These include the large-scale singularities such as the melting of the Greenland and West Antarctic ice sheets, and changes to the Atlantic Meridional Overturning Circulation. In biological systems, the extinction of species would be an irreversible impact. In social systems, unique cultures may be lost or the survival of endangered languages may be exacerbated due to climate change. For example, humans living on atoll islands face risks due to sea level rise, sea surface warming, and increased frequency and intensity of extreme weather events.

Health, food security and water security

Health

The effects of climate change on human health are increasingly well studied and quantified. They fall into three main categories: (i) direct effects (e.g. due to heat waves, extreme weather events), (ii) impacts from climate-related changes in ecological systems and relationships (e.g. crop yields, marine productivity), and (iii) the more indirect consequences relating to impoverishment, displacement, and mental health problems.

More specifically, the relationship between health and heat includes the following main aspects: exposure of vulnerable populations to heatwaves, heat-related mortality, reduced labour capacity for outdoor workers and impacts on mental health. There is a range of climate-sensitive infectious diseases which may increase in some regions, such as mosquito-borne diseases, cholera and some waterborne diseases. Health is also acutely impacted by extreme weather events (floods, hurricanes, droughts, wildfires) through injuries, diseases and air pollution in the case of wildfires. Other indirect health impacts from climate change can be related to rising food insecurity, undernutrition and water insecurity.

The effects of climate change on mental health and well-being can be rather negative, especially for vulnerable populations and those with pre-existing serious mental illness. There are three broad pathways by which these effects can take place: directly, indirectly or via awareness. The direct pathway includes stress related conditions being caused by exposure to extreme weather events, such as post-traumatic stress disorder (PTSD). Scientific studies have linked mental health outcomes to several climate-related exposures—heat, humidity, rainfall, drought, wildfires and floods. The indirect pathway can be via disruption to economic and social activities, such as when an area of farmland is less able to produce food. The third pathway can be of mere awareness of the climate change threat, even by individuals who are not otherwise affected by it.
Mental health outcomes have been measured in several studies through indicators such as psychiatric hospital admissions, mortality, self-harm and suicide rates. Vulnerable populations and life stages include people with pre-existing mental illness, Indigenous peoples, children and adolescents. The emotional responses to the threat of climate change can include eco-anxiety, ecological grief and eco-anger. Such emotions can be rational responses to the degradation of the natural world and lead to adaptive action.

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. Droughts result in crop failures and the loss of pasture for livestock. Loss and poor growth of livestock cause milk yield and meat production to decrease. The rate of soil erosion is 10–20 times higher than the rate of soil accumulation in agricultural areas that use no-till farming. In areas with tilling it is 100 times higher. Climate change makes this type of land degradation and desertification worse.

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. For example, climate change is already affecting the productivity of wheat and other key staples.

In many areas, fisheries have already seen their catch decrease because of global warming and changes in biochemical cycles. In combination with overfishing, warming waters decrease the maximum catch potential. Global catch potential is projected to reduce further in 2050 by less than 4% if emissions are reduced strongly, and by about 8% for very high future emissions, with growth in the Arctic Ocean.

Water security

Water resources can be affected by climate change in various ways. The total amount of freshwater available can change, for instance due to dry spells or droughts. Heavy rainfall and flooding can have an impact on water quality: pollutants can be transported into water bodies by the increased surface runoff. In coastal regions, more salt may find its way into water resources due to higher sea levels and more intense storms. Higher temperatures also directly degrade water quality: warm water contains less oxygen. Changes in the water cycle threaten existing and future water infrastructure. It will be harder to plan investments for water infrastructure as there are significant uncertainties about future variability for the water cycle.

Between 1.5 and 2.5 billion people live in areas with regular water security issues. If global warming would reach 4 °C (7.2 °F), water insecurity would affect about twice as many people. Water resources are projected to decrease in most dry subtropical regions and mid-latitudes, but increase in high latitudes. However, as streamflow becomes more variable, even regions with increased water resources can experience additional short-term shortages. The arid regions of India, China, the US and Africa are already seeing dry spells and drought impact water availability.[158]

Economic impacts

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, but are worse if there is only limited adaptation. Economic modelling may underrate the impact of potentially catastrophic climatic changes. When estimating losses, economists choose a discount rate which determines how much one prefers to have a good or cash now compared to at a future date. Choices of a high discount rate may also understate estimates of economic losses, as losses for future generation weight less heavily.

The total economic impacts also increase for higher temperature changes. For instance, total damages are estimated to be 90% less if global warming is limited to 1.5 °C (2.7 °F) compared to 3.66 °C (6.59 °F), a warming level chosen to represent no mitigation. One study found a 3.5% reduction in global GDP by the end of the century if warming is limited to 3 °C (5.4 °F), 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. In a study on a high-emission scenario, a temperature rise of 2 °C (3.6 °F) by 2050 would reduce global GDP by 2.5%–7.5%. By 2100 in this case, the temperature would rise by 4 °C (7.2 °F), which could reduce the global GDP by 30% in the worst case.

Global losses reveal rapidly rising costs due to extreme weather events since the 1970s. Socio-economic factors have contributed to the observed trend of global losses, such as population growth and increased wealth. 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. The trend does, however, suggest increasing vulnerability of social systems to climate change.

Economic inequality

Most climate damage is caused by high-income, high-emitting countries. These countries benefitted at the expense of low-income, low-emitting countries.

Climate change has contributed towards global economic inequality. Wealthy countries in colder regions have 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.

Highly affected sectors

Economic sectors directly affected by weather are more impacted by climate change than other sectors. For instance, the agriculture, fisheries and forestry sectors are all heavily affected, but also the tourism and energy sectors. Agriculture and forestry have suffered economic losses due to droughts and extreme heat, for instance in Europe. If global warming surpasses 1.5 degrees, there may be limits to adaptation for existing tourism and for outdoor work.

In the energy sector, fossil fuel plants and nuclear power plants depend on water to cool them. Climate change can increase the likelihood of drought and fresh water shortages. In addition, higher operating temperatures reduces their efficiency and hence their output. Hydropower is affected by changes in the water cycle such as river flows. The result of diminished river flow can be a power shortage in areas that depend heavily on hydroelectric power. Brazil in particular, is vulnerable due to its reliance on hydroelectricity, as rising temperatures, lower water flow, and alterations in rainfall, could reduce total energy production by 7% annually by the end of the century. Oil and natural gas infrastructure is affected by the effects of climate change and the increased risk of disasters such as storm, cyclones, flooding and rising sea levels.

The insurance and financial services sectors also experience impacts from global warming. Insurance is an important tool to manage risks, but often unavailable to poorer households. Due to climate change, premiums are going up for certain types of insurance, such as flood insurance. Poor adaptation to climate change further widens the gap between what people can afford and the costs of insurance, as risks increase. In 2019, Munich Re noted that climate change could cause home insurance to become unaffordable for households at or below average incomes.

Human settlement

The Arctic, Africa, small islands, Asian megadeltas and the Middle East are regions that are likely to be especially affected by climate change. Low-latitude, less-developed regions are at most risk of experiencing negative impacts due to climate change. The ten countries of the Association of Southeast Asian Nations (ASEAN) are among the most vulnerable in the world to the negative effects of climate change, however, ASEAN's climate mitigation efforts are not in proportion to the climate change threats the region faces.

Impacts from heat

Overlap between future population distribution and extreme heat in a high emission scenario

Regions inhabited by a third of the human population could become as hot as the hottest parts of the Sahara within 50 years without a change in patterns of population growth and without migration, if greenhouse gas emissions grow unabated. The projected average temperature of above 29 °C (84 °F) for these regions would be outside the "human temperature niche" – a suggested range for climate biologically suitable for humans based on historical data of mean annual temperatures – and the most affected regions have little adaptive capacity.

Increased extreme heat exposure from both climate change and the urban heat island effect threatens urban settlements. This is made worse by the loss of shade from urban trees that cannot withstand the heat stress.

In 2019, the Crowther Lab from ETH Zürich paired the climatic conditions of 520 major cities worldwide with the predicted climatic conditions of cities in 2050. 22% of the major cities are predicted to have climatic conditions that do not exist in any city today. For instance, 2050 London will have a climate similar to 2019 Melbourne in Australia, Athens and Madrid like Fez, Morocco, Nairobi in Kenya like Maputo in Mozambique. The Indian city Pune will be like Bamako in Mali, Bamako will be like Niamey in Niger. Brasilia will be like Goiania, both in Brazil.

Low-lying coastal regions

Socioeconomic impacts of climate change in coastal and low-lying areas will be overwhelmingly adverse. Coastal and low-lying areas are exposed to increasing risks including coastal erosion due to sea level rise. For instance, sea level rise is expected to threaten vital infrastructure and human settlements. This could lead to issues of statelessness for populations in countries such as the Maldives and Tuvalu and homelessness in countries with low-lying areas such as Bangladesh. In 1991, 140,000 people died and 10 million became homeless when floods hit Bangladesh. In Myanmar, which was hit in 2007, a storm killed 146,000 people.

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

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, to 300 million or even 640 million in a worst-case scenario related to the instability of the Antarctic ice sheet. The most people affected are in the densely-populated and low-lying megadeltas of Asia and Africa.

Small islands developing states are especially vulnerable. They are expected to experience more intense storm surges, salt water intrusion, and coastal destruction. Low-lying small islands in the Pacific, Indian, and Caribbean regions are at risk of permanent inundation and population displacement. On the islands of Fiji, Tonga and western Samoa, concentrations of migrants from outer islands inhabit low and unsafe areas along the coasts. Atoll nations, which include countries that are composed entirely of the smallest form of islands are at risk of entire population displacement. These nations include Kiribati, Maldives, the Marshall Islands, and Tuvalu. Vulnerability is increased by small size, isolation from other land, low financial resources, and lack of protective infrastructure.

Impacts on societies

Climate change impacts health, the availability of drinking water and food, inequality and economic growth. The effects of climate change are often interlinked and can exacerbate each other as well as existing vulnerabilities. Some areas may become too hot for humans to live in. People in some areas may experience internal or long-distance displacement due to climate-related changes or disasters.

The effects of climate change, in combination with the sustained increases in greenhouse gas emissions, have led scientists to characterize it as a "climate emergency" or "climate crisis". Some climate researchers and activists have called it an "existential threat to civilization". The consequences of climate change, and the failure to address it, can draw focus and resources from tackling its root causes, leading to what researchers have termed a "climate doom loop".

Displacement and migration

Climate change affects displacement of people in several ways. Firstly, involuntary displacement may increase through the increased number and severity of weather-related disasters which destroy homes and habitats. 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. Other forms of migration are adaptive and voluntary, based on individual or household decisions. On the other hand, some households may fall (further) into poverty due to climate change, limiting their ability to move to areas less affected.

Migration due to climate and weather is usually domestic, but long-distance. Slow-onset disasters such as droughts and heat are more likely to induce long-term migration compared to weather disasters like floods. Migration related to desertification and reduced soil fertility is likely to be predominantly from rural areas in developing countries to towns and cities.

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. In 2018, the World Bank estimated that climate change will cause internal migration of between 31 and 143 million people by 2050, as they escape crop failures, water scarcity, and sea level rise. The study only included Sub-Saharan Africa, South Asia, and Latin America.

Sea level rise at the Marshall Islands, reaching the edge of a village (from the documentary One Word)

Conflict

Overlap between state fragility, extreme heat, and nuclear and biological catastrophic hazards

Climate change can worsen conflicts by exacerbating tensions over limited resources like drinking water (in the case of water conflicts). Climate change also has the potential to cause large population dislocations and migration, which can also lead to increased tensions. However, factors other than climate change were judged to be substantially more important in affecting conflict over the last century. These factors include intergroup inequality and low socio-economic development. In some cases, climate change can even lead to more peaceful relationships between groups, as environmental problems requires common policy to be developed.

Global warming has been described as a "threat multiplier". Conditions in certain places make it more likely that climate change impacts conflict: ethnic exclusion, an economy dependent on agriculture, insufficient infrastructure, poor local governance, and low levels of development. A spike in wheat prices following crop losses from a period of drought may have contributed to the onset of the "Arab Spring" protests and revolutions in 2010.

Social impacts on vulnerable groups

Climate change does not impact people within communities in the same way. Vulnerable groups such as women, the elderly, religious minorities and refugees may be more impacted by climate change than others.

  • People living in poverty: Climate change disproportionally affects poor people in low-income communities and developing countries around the world. Those in poverty have a higher chance of experiencing the ill-effects of climate change due to the increased exposure and vulnerability. A 2020 World Bank paper estimated that between 32 million to 132 million additional people will be pushed into extreme poverty by 2030 due to climate change.
  • Women: Climate change increases gender inequality, reduces women's ability to be financially independent, and has an overall negative impact on the social and political rights of women, especially in economies that are heavily based on agriculture.
  • Indigenous peoples: Indigenous communities tend to rely more on the environment for food and other necessities, which makes them more vulnerable to disturbances in ecosystems. Indigenous communities across the globe generally have economic disadvantages that are not as prevalent in non-indigenous communities due to the oppression they have experienced. These disadvantages include lower education levels and higher rates of poverty and unemployment, which add to their vulnerability to climate change.
  • Children: The Lancet review on health and climate change lists children among the worst-affected by global warming. Children are 14–44 percent more likely to die from environmental factors.

Possibility of societal collapse

Climate change has long been described as a severe risk to humans. Climate change as an existential threat has emerged as a key theme in the climate movement discourse; the theme is also used by people from Small Island Nations. The topic has not been researched extensively. The research community on existential risks typically defines existential risks as threats that could cause the extinction of humanity or destroy the potential of intelligent life on Earth. Key risks of climate change do not fit that definition. However, some key climate risks do impact survivability. For instance, areas may become too hot to survive, or sea level rise makes it impossible to live at a specific location.

Severe impacts of climate change can combine, including with climate-unrelated, concurrent risks such as worldwide pollution, fragility, resource depletion, political disenchantment, poverty or wealth inequality, and biotechnology risk, to result in a confluence of developments that cause a drastically aggravated impact on societies or humanity – such or multiple concurrent crises are sometimes referred to as a "perfect storm". Climate change may also be considered as a threat multiplier "which exacerbates existing trends, tensions, and instability". Climate-related factors of a potential collapse may include famine (crop loss, drought), extreme weather (hurricanes, floods), war ([co-]caused by scarce resources) and conflict, systemic risk (relating to migration, famine, or conflict), and disease.

Drought

https://en.wikipedia.org/wiki/Drought

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Droughts cause a range of impacts and are often worsened due to climate change. From top to bottom: a dry lakebed in California, which is in 2022 experiencing its most serious megadrought in 1,200 years; Sandstorm in Somaliland due to drought; drought and high temperatures worsened the 2020 bushfires in Australia.; Droughts negatively impact agriculture in Texas.

A drought is a period of drier-than-normal conditions. A drought can last for days, months or years. Drought often has large impacts on the ecosystems and agriculture of affected regions, and causes harm to the local economy. Annual dry seasons in the tropics significantly increase the chances of a drought developing and subsequent wildfires. Periods of heat can significantly worsen drought conditions by hastening evaporation of water vapour.

Drought is a recurring feature of the climate in most parts of the world, becoming more extreme and less predictable due to climate change, which dendrochronological studies date back to 1900. There are three kinds of drought effects, environmental, economic and social. Environmental effects include the drying of wetlands, more and larger wildfires, loss of biodiversity. Economic consequences include disruption of water supplies for municipal economies; lower agricultural, forest, game, and fishing outputs; higher food-production costs; and problems with water supply for the energy sector. Social and health costs include the negative effect on the health of people directly exposed to this phenomenon (excessive heat waves), high food costs, stress caused by failed harvests, water scarcity, etc. Prolonged droughts have caused mass migrations and humanitarian crisis.

Many plant species, such as those in the family Cactaceae (or cacti), have drought tolerance adaptations like reduced leaf area and waxy cuticles to enhance their ability to tolerate drought. Some others survive dry periods as buried seeds. Semi-permanent drought produces arid biomes such as deserts and grasslands. Most arid ecosystems have inherently low productivity.

The most prolonged drought ever in the world in recorded history continues in the Atacama Desert in Chile (400 years). Throughout history, humans have usually viewed droughts as "disasters" due to the impact on food availability and the rest of society. Humans have often tried to explain droughts as either a natural disaster, caused by humans, or the result of supernatural forces.

Definition

Fields outside Benambra, Australia suffering from drought conditions in 2006.

The IPCC Sixth Assessment Report defines a drought simply as "drier than normal conditions". This means that a drought is "a moisture deficit relative to the average water availability at a given location and season".

According to National Integrated Drought Information System, a multi-agency partnership, drought is generally defined as “a deficiency of precipitation over an extended period of time (usually a season or more), resulting in a water shortage”. The National Weather Service office of the NOAA defines drought as "a deficiency of moisture that results in adverse impacts on people, animals, or vegetation over a sizeable area".

Drought is a complex phenomenon − relating to the absence of water − which is difficult to monitor and define. By the early 1980's, over 150 definitions of "drought" had already been published. The range of definitions reflects differences in regions, needs, and disciplinary approaches.

Categories

There are three major categories of drought based on where in the water cycle the moisture deficit occurs: meteorological drought, hydrological drought, and agricultural or ecological drought. A meteorological drought occurs due to lack of precipitation. A hydrological drought is related to low runoff, streamflow, and reservoir storage. An agricultural or ecological drought is causing plant stress from a combination of evaporation and low soil moisture. Some organizations add another category: socioeconomic drought occurs when the demand for an economic good exceeds supply as a result of a weather-related shortfall in water supply. The socioeconomic drought is a similar concept to water scarcity.

The different categories of droughts have different causes but similar effects:

  1. Meteorological drought occurs when there is a prolonged time with less than average precipitation. Meteorological drought usually precedes the other kinds of drought. As a drought persists, the conditions surrounding it gradually worsen and its impact on the local population gradually increases.
  2. Hydrological drought is brought about when the water reserves available in sources such as aquifers, lakes and reservoirs fall below a locally significant threshold. Hydrological drought tends to show up more slowly because it involves stored water that is used but not replenished. Like an agricultural drought, this can be triggered by more than just a loss of rainfall. For instance, around 2007 Kazakhstan was awarded a large amount of money by the World Bank to restore water that had been diverted to other nations from the Aral Sea under Soviet rule. Similar circumstances also place their largest lake, Balkhash, at risk of completely drying out.
  3. Agricultural or ecological droughts affect crop production or ecosystems in general. This condition can also arise independently from any change in precipitation levels when either increased irrigation or soil conditions and erosion triggered by poorly planned agricultural endeavors cause a shortfall in water available to the crops.

Causes

Contraction/Desiccation cracks in the dry earth of the Sonoran desert, northwestern Mexico, near the U.S. state borders of California and Arizona

General precipitation deficiency

Mechanisms of producing precipitation include convective, stratiform, and orographic rainfall. Convective processes involve strong vertical motions that can cause the overturning of the atmosphere in that location within an hour and cause heavy precipitation, while stratiform processes involve weaker upward motions and less intense precipitation over a longer duration. Precipitation can be divided into three categories, based on whether it falls as liquid water, liquid water that freezes on contact with the surface, or ice. Droughts occur mainly in areas where normal levels of rainfall are, in themselves, low. If these factors do not support precipitation volumes sufficiently to reach the surface over a sufficient time, the result is a drought. Drought can be triggered by a high level of reflected sunlight and above average prevalence of high pressure systems, winds carrying continental, rather than oceanic air masses, and ridges of high pressure areas aloft can prevent or restrict the developing of thunderstorm activity or rainfall over one certain region. Once a region is within drought, feedback mechanisms such as local arid air, hot conditions which can promote warm core ridging, and minimal evapotranspiration can worsen drought conditions.

Dry season

Within the tropics, distinct, wet and dry seasons emerge due to the movement of the Intertropical Convergence Zone or Monsoon trough. The dry season greatly increases drought occurrence, and is characterized by its low humidity, with watering holes and rivers drying up. Because of the lack of these watering holes, many grazing animals are forced to migrate due to the lack of water in search of more fertile lands. Examples of such animals are zebras, elephants, and wildebeest. Because of the lack of water in the plants, bushfires are common. Since water vapor becomes more energetic with increasing temperature, more water vapor is required to increase relative humidity values to 100% at higher temperatures (or to get the temperature to fall to the dew point). Periods of warmth quicken the pace of fruit and vegetable production, increase evaporation and transpiration from plants, and worsen drought conditions.

El Niño–Southern Oscillation (ENSO)

Regional impacts of warm ENSO episodes (El Niño)

The El Niño–Southern Oscillation (ENSO) phenomenon can sometimes play a significant role in drought. ENSO comprises two patterns of temperature anomalies in the central Pacific Ocean, known as La Niña and El Niño. La Niña events are generally associated with drier and hotter conditions and further exacerbation of drought in California and the Southwestern United States, and to some extent the U.S. Southeast. Meteorological scientists have observed that La Niñas have become more frequent over time.

Conversely, during El Niño events, drier and hotter weather occurs in parts of the Amazon River Basin, Colombia, and Central America. Winters during the El Niño are warmer and drier than average conditions in the Northwest, northern Midwest, and northern Mideast United States, so those regions experience reduced snowfalls. Conditions are also drier than normal from December to February in south-central Africa, mainly in Zambia, Zimbabwe, Mozambique, and Botswana. Direct effects of El Niño resulting in drier conditions occur in parts of Southeast Asia and Northern Australia, increasing bush fires, worsening haze, and decreasing air quality dramatically. Drier-than-normal conditions are also in general observed in Queensland, inland Victoria, inland New South Wales, and eastern Tasmania from June to August. As warm water spreads from the west Pacific and the Indian Ocean to the east Pacific, it causes extensive drought in the western Pacific. Singapore experienced the driest February in 2014 since records began in 1869, with only 6.3 mm of rain falling in the month and temperatures hitting as high as 35 °C on 26 February. The years 1968 and 2005 had the next driest Februaries, when 8.4 mm of rain fell.

Impacts of climate change on soil moisture at 2 °C of global warming. A reduction of one standard deviation means that average soil moisture will approximate the ninth driest year between 1850 and 1900.

Precipitation deficiency due to climate change

The IPCC Sixth Assessment Report (2021) projected multiplicative increases in the frequency of extreme events compared to the pre-industrial era for heat waves, droughts and heavy precipitation events, for various climate change scenarios.

Global climate change is expected to trigger droughts with a substantial impact on agriculture throughout the world, and especially in developing nations. Along with drought in some areas, flooding and erosion could increase in others. Some proposed climate change mitigation actions that focus on more active techniques, solar radiation management through the use of a space sunshade for one, may also carry with them increased chances of drought.

There is a rise of compound warm-season droughts in Europe that are concurrent with an increase in potential evapotranspiration.

A dry lakebed in California. In 2022, the state was experiencing its most serious drought in 1,200 years, worsened by climate change.
 
Climate change affects multiple factors associated with droughts, such as how much rain falls and how fast the rain evaporates again. Warming over land increases the severity and frequency of droughts around much of the world. In some tropical and subtropical regions of the world, there will likely be less rain due to global warming, making them more prone to drought. These regions where droughts are set to worsen are Central America, the Amazon and south-western South America, West and Southern Africa, as well as the Mediterranean and south-western Australia.

Higher temperatures lead to increased evaporation, thus drying the soil and increasing plant stress, which will have impacts on agriculture. For this reason, even regions where overall rainfall is expected to remain relatively stable, such as central and northern Europe, will experience these impacts. Without climate change mitigation, it is expected that around a third of land areas will experience moderate or more severe drought by 2100. Droughts are likely to be more intense than in the past.

Due to limitations on how much data is available about drought in the past, it is often impossible to confidently attribute a specific drought to human-induced climate change. Some areas however, such as the Mediterranean and California, already show the impacts of human activities. Their impacts are made worse because of increased water demand, population growth, urban expansion, and environmental protection efforts in many areas. Land restoration, especially by agroforestry, can help reduce the impact of droughts.

Erosion and human activities

Human activity can directly trigger exacerbating factors such as over farming, excessive irrigation, deforestation, and erosion adversely impact the ability of the land to capture and hold water. In arid climates, the main source of erosion is wind. Erosion can be the result of material movement by the wind. The wind can cause small particles to be lifted and therefore moved to another region (deflation). Suspended particles within the wind may impact on solid objects causing erosion by abrasion (ecological succession). Wind erosion generally occurs in areas with little or no vegetation, often in areas where there is insufficient rainfall to support vegetation.

Loess is a homogeneous, typically nonstratified, porous, friable, slightly coherent, often calcareous, fine-grained, silty, pale yellow or buff, windblown (Aeolian) sediment. It generally occurs as a widespread blanket deposit that covers areas of hundreds of square kilometers and tens of meters thick. Loess often stands in either steep or vertical faces. Loess tends to develop into highly rich soils. Under appropriate climatic conditions, areas with loess are among the most agriculturally productive in the world. Loess deposits are geologically unstable by nature, and will erode very readily. Therefore, windbreaks (such as big trees and bushes) are often planted by farmers to reduce the wind erosion of loess. Wind erosion is much more severe in arid areas and during times of drought. For example, in the Great Plains, it is estimated that soil loss due to wind erosion can be as much as 6100 times greater in drought years than in wet years.

Consequences

Global drought total economic loss risk
 
Pair of dead oryx in Namibia during the 2018–19 Southern Africa drought.
 
After years of drought and dust storms the town of Farina in South Australia was abandoned.

One can divide the effects of droughts and water shortages into three groups: environmental, economic and social (including health).

  • In the case of environmental effects: lower surface and subterranean water-levels, lower flow-levels (with a decrease below the minimum leading to direct danger for amphibian life), increased pollution of surface water, the drying out of wetlands, more and larger wildfires, higher deflation intensity, loss of biodiversity, worse health of trees and the appearance of pests and dendroid diseases.
  • Economic losses include lower agricultural, forests, game and fishing output, higher food-production costs, lower energy-production levels in hydro plants, losses caused by depleted water tourism and transport revenue, problems with water supply for the energy sector and for technological processes in metallurgy, mining, the chemical, paper, wood, foodstuff industries etc., disruption of water supplies for municipal economies. The Global Commission of Economics of Water produced "The What, Why and How of the World Water Crisis" report for the UN Conference of Water 2023 to provide a ground work for understanding the economics of water and action on the water crisis.
  • Social and health costs include the negative effect on the health of people directly exposed to this phenomenon (excessive heat waves), possible limitation of water supplies, increased pollution levels, high food-costs, stress caused by failed harvests, water scarcity, etc. This explains why droughts and water scarcity operate as a factor which increases the gap between developed and developing countries.

Effects vary according to vulnerability. For example, subsistence farmers are more likely to migrate during drought because they do not have alternative food-sources. Areas with populations that depend on water sources as a major food-source are more vulnerable to famine.

Environmental and economic consequences

Common environmental and economic consequences of drought include:

Social and health consequences

Impacts on crops

Water stress affects plant development and quality in a variety of ways: firstly drought can cause poor germination and impaired seedling development. At the same time plant growth relies on cellular division, cell enlargement, and differentiation. Drought stress impairs mitosis and cell elongation via loss of turgor pressure which results in poor growth. Development of leaves is also dependent upon turgor pressure, concentration of nutrients, and carbon assimilates all of which are reduced by drought conditions, thus drought stress lead to a decrease in leaf size and number. Plant height, biomass, leaf size and stem girth has been shown to decrease in maize under water limiting conditions. Crop yield is also negatively effected by drought stress, the reduction in crop yield results from a decrease in photosynthetic rate, changes in leaf development, and altered allocation of resources all due to drought stress. Crop plants exposed to drought stress suffer from reductions in leaf water potential and transpiration rate. Water-use efficiency increases in crops such as wheat while decreasing in others, such as potatoes.

Plants need water for the uptake of nutrients from the soil, and for the transport of nutrients throughout the plant: drought conditions limit these functions leading to stunted growth. Drought stress also causes a decrease in photosynthetic activity in plants due to the reduction of photosynthetic tissues, stomatal closure, and reduced performance of photosynthetic machinery. This reduction in photosynthetic activity contributes to the reduction in plant growth and yields. Another factor influencing reduced plant growth and yields include the allocation of resources; following drought stress plants will allocate more resources to roots to aid in water uptake increasing root growth and reducing the growth of other plant parts while decreasing yields.

Protection, mitigation and relief

Succulent plants are well-adapted to survive long periods of drought.
 
Water distribution on Marshall Islands during El Niño.

Agriculturally, people can effectively mitigate much of the impact of drought through irrigation and crop rotation. Failure to develop adequate drought mitigation strategies carries a grave human cost in the modern era, exacerbated by ever-increasing population densities. President Roosevelt on April 27, 1935, signed documents creating the Soil Conservation Service (SCS)—now the Natural Resources Conservation Service (NRCS). Models of the law were sent to each state where they were enacted. These were the first enduring practical programs to curtail future susceptibility to drought, creating agencies that first began to stress soil conservation measures to protect farm lands today. It was not until the 1950s that there was an importance placed on water conservation was put into the existing laws (NRCS 2014).

Strategies for drought protection, mitigation or relief include:

  • Dams – many dams and their associated reservoirs supply additional water in times of drought.
  • Cloud seeding – a form of intentional weather modification to induce rainfall. This remains a hotly debated topic, as the United States National Research Council released a report in 2004 stating that to date, there is still no convincing scientific proof of the efficacy of intentional weather modification.
  • Desalination – use of sea water for irrigation or consumption.
  • Drought monitoring – Continuous observation of rainfall levels and comparisons with current usage levels can help prevent man-made drought. For instance, analysis of water usage in Yemen has revealed that their water table (underground water level) is put at grave risk by over-use to fertilize their Khat crop. Careful monitoring of moisture levels can also help predict increased risk for wildfires, using such metrics as the Keetch-Byram Drought Index or Palmer Drought Index.
  • Land use – Carefully planned crop rotation can help to minimize erosion and allow farmers to plant less water-dependent crops in drier years.
  • Outdoor water-use restriction – Regulating the use of sprinklers, hoses or buckets on outdoor plants, filling pools, and other water-intensive home maintenance tasks. Xeriscaping yards can significantly reduce unnecessary water use by residents of towns and cities.
  • Rainwater harvesting – Collection and storage of rainwater from roofs or other suitable catchments.
  • Recycled water – Former wastewater (sewage) that has been treated and purified for reuse.
  • Transvasement – Building canals or redirecting rivers as massive attempts at irrigation in drought-prone areas.

Scale and examples

Some large scale droughts in the 21st century included:

  • The 1997–2009 Millennium Drought in Australia led to a water supply crisis across much of the country. As a result, many desalination plants were built for the first time (see list).
  • In 2006, Sichuan Province China experienced its worst drought in modern times with nearly 8 million people and over 7 million cattle facing water shortages.
  • 12-year drought that was devastating southwest Western Australia, southeast South Australia, Victoria and northern Tasmania was "very severe and without historical precedent".
  • 2015–2018 Cape Town water crisis. This likelihood was tripled by climate change.
Affected areas in the western Sahel belt during the 2012 drought.

The Darfur conflict in Sudan, also affecting Chad, was fueled by decades of drought; combination of drought, desertification and overpopulation are among the causes of the Darfur conflict, because the Arab Baggara nomads searching for water have to take their livestock further south, to land mainly occupied by non-Arab farming people.

Drought-affected area in Karnataka, India in 2012.

Approximately 2.4 billion people live in the drainage basin of the Himalayan rivers. India, China, Pakistan, Bangladesh, Nepal and Myanmar could experience floods followed by droughts in coming decades. Drought in India affecting the Ganges is of particular concern, as it provides drinking water and agricultural irrigation for more than 500 million people. The west coast of North America, which gets much of its water from glaciers in mountain ranges such as the Rocky Mountains and Sierra Nevada, also would be affected.

In 2005, parts of the Amazon basin experienced the worst drought in 100 years. A 23 July 2006 article reported Woods Hole Research Center results showing that the forest in its present form could survive only three years of drought. Scientists at the Brazilian National Institute of Amazonian Research argue in the article that this drought response, coupled with the effects of deforestation on regional climate, are pushing the rainforest towards a "tipping point" where it would irreversibly start to die. It concludes that the rainforest is on the brink of being turned into savanna or desert, with catastrophic consequences for the world's climate. According to the WWF, the combination of climate change and deforestation increases the drying effect of dead trees that fuels forest fires.

Lake Chad in a 2001 satellite image. The lake has shrunk by 95% since the 1960s.

By far the largest part of Australia is desert or semi-arid lands commonly known as the outback. A 2005 study by Australian and American researchers investigated the desertification of the interior, and suggested that one explanation was related to human settlers who arrived about 50,000 years ago. Regular burning by these settlers could have prevented monsoons from reaching interior Australia. In June 2008 it became known that an expert panel had warned of long term, maybe irreversible, severe ecological damage for the whole Murray-Darling basin if it did not receive sufficient water by October 2008. Australia could experience more severe droughts and they could become more frequent in the future, a government-commissioned report said on July 6, 2008. Australian environmentalist Tim Flannery, predicted that unless it made drastic changes, Perth in Western Australia could become the world's first ghost metropolis, an abandoned city with no more water to sustain its population. The long Australian Millennial drought broke in 2010.

Recurring droughts leading to desertification in East Africa have created grave ecological catastrophes, prompting food shortages in 1984–85, 2006 and 2011. During the 2011 drought, an estimated 50,000 to 150,000 people were reported to have died, though these figures and the extent of the crisis are disputed. In February 2012, the UN announced that the crisis was over due to a scaling up of relief efforts and a bumper harvest. Aid agencies subsequently shifted their emphasis to recovery efforts, including digging irrigation canals and distributing plant seeds. The 2020-2022 Horn of Africa drought has surpassed the horrific drought in 2010-2011 in both duration and severity.

In 2012, a severe drought struck the western Sahel. The Methodist Relief & Development Fund (MRDF) reported that more than 10 million people in the region were at risk of famine due to a month-long heat wave that was hovering over Niger, Mali, Mauritania and Burkina Faso. A fund of about £20,000 was distributed to the drought-hit countries.

History

A South Dakota farm during the Dust Bowl, 1936
 

Throughout history, humans have usually viewed droughts as "disasters" due to the impact on food availability and the rest of society. Humans have often tried to explain droughts as either a natural disaster, caused by humans, or the result of supernatural forces. It is among the earliest documented climatic events, present in the Epic of Gilgamesh and tied to the Biblical story of Joseph's arrival in and the later Exodus from ancient Egypt. Hunter-gatherer migrations in 9,500 BC Chile have been linked to the phenomenon, as has the exodus of early humans out of Africa and into the rest of the world around 135,000 years ago. Rituals exist to prevent or avert drought, rainmaking could go from dances to scapegoating to human sacrifices. Nowadays, those ancient practices are for the most part relegated to folklore and replaced by more rational water management.

Historical droughts include:

  • 1540 Central Europe, said to be the “worst drought of the millennium” with eleven months without rain and temperatures of 5–7 °C above the average of the 20th century
  • 1900 India killing between 250,000 and 3.25 million.
  • 1921–22 Soviet Union in which over 5 million perished from starvation due to drought.
  • 1928–30 Northwest China resulting in over 3 million deaths by famine.
  • 1936 and 1941 Sichuan Province China resulting in 5 million and 2.5 million deaths respectively.

Bayesian inference

From Wikipedia, the free encyclopedia https://en.wikipedia.org/wiki/Bayesian_inference Bayesian inference ( / ...