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Effects of climate change on the water cycle

October 21, 2023

The effects of climate change on the water cycle are profound and have been described as an intensification or a strengthening of the water cycle (also called hydrologic cycle).[2]: 1079  This effect has been observed since at least 1980.[2]: 1079  One example is the intensification of heavy precipitation events. This has important negative effects on the availability of freshwater resources, as well as other water reservoirs such as oceans, ice sheets, atmosphere and land surface. The water cycle is essential to life on Earth and plays a large role in the global climate and the ocean circulation. The warming of our planet is expected to cause changes in the water cycle for various reasons.[3] For example, warmer atmosphere can contain more water vapor which has effects on evaporation and rainfall.

Extreme weather (heavy rains, droughts, heat waves) is one consequence of a changing water cycle due to global warming. These events will be progressively more common as the Earth warms more and more.[1]: Figure SPM.6 

The underlying cause of the intensifying water cycle is the increased amount of greenhouse gases, which lead to a warmer atmosphere through the greenhouse effect.[3] Physics dictates that saturation vapor pressure increases by 7% when temperature rises by 1 °C (as described in the Clausius-Clapeyron equation).[4]

The strength of the water cycle and its changes over time are of considerable interest, especially as the climate changes.[5] The essence of the overall hydrological cycle is the evaporation of moisture in one place and the precipitation in other places. In particular, evaporation exceeds precipitation over the oceans, which allows moisture to be transported by the atmosphere from the oceans onto land where precipitation exceeds evapotranspiration, and the runoff flows into streams and rivers and discharges into the ocean, completing the cycle.[5] The water cycle is a key part of Earth's energy cycle through the evaporative cooling at the surface which provides latent heat to the atmosphere, as atmospheric systems play a primary role in moving heat upward.[5]

If water is available, extra heat goes mostly into evaporation, as it always does on the oceans, otherwise it goes into raising air temperature.[6] The availability of water plus the water holding capacity of the atmosphere, which increases proportionally with temperature increase, means that water plays a major role over the oceans and tropics, but much less over continents and the polar regions. This is why temperature increases dominate in the Arctic (polar amplification) and on land.[6]

Several inherent characteristics have the potential to cause sudden (abrupt) changes in the water cycle.[7]: 1148  However, the likelihood that such changes will occur during the 21st century is currently regarded as low.[7]: 72 

Causes Edit

 
Where carbon goes when water flows[8]

Global warming leads to changes in the global water cycle.[9] These include first and foremost an increased water vapor pressure in the atmosphere. This causes changes in precipitation patterns with regards to frequency and intensity, as well as changes in groundwater and soil moisture. Taken together, these changes are often referred to as an "intensification and acceleration" of the water cycle.[9]: xvii  Key processes that will also be affected are droughts and floods, tropical cyclones, glacier retreat, snow cover, ice jam floods and extreme weather events.

The increased amount of greenhouse gases in the atmosphere leads to a warmer atmosphere.[3] The saturation vapor pressure of air increases with temperature, which means that warmer air can contain more water vapor. Because the air can contain more moisture and the land becomes warmer, evaporation is enhanced. As a consequence, the increased amount of water in the atmosphere leads to more intense rainfall.[10]

This relation between temperature and saturation vapor pressure is described in the Clausius–Clapeyron equation, which states that saturation pressure will increase by 7% when temperature rises by 1 °C.[4] This is visible in measurements of the tropospheric water vapor, which are provided by satellites,[11] radiosondes and surface stations. The IPCC AR5 concludes that tropospheric water vapor has increased by 3.5% over the last 40 years, which is consistent with the observed temperature increase of 0.5 °C.[12]

Observations and predictions Edit

 
Predicted changes in average soil moisture for a scenario of 2°C global warming. This can disrupt agriculture and ecosystems. A reduction in soil moisture by one standard deviation means that average soil moisture will approximately match the ninth driest year between 1850 and 1900 at that location.

Since the middle of the 20th century, human-caused climate change has resulted in observable changes in the global water cycle.[7]: 85  The IPCC Sixth Assessment Report in 2021 predicted that these changes will continue to grow significantly at the global and regional level.[7]: 85 

The report also found that: Precipitation over land has increased since 1950, and the rate of increase has become faster since the 1980s and in higher latitudes. Water vapour in the atmosphere (in particular the troposhere) has increased since at least the 1980s. It is expected that over the course of the 21st century, the annual global precipitation over land will increase due to a higher global surface temperature.[7]: 85 

The human influence on the water cycle can be observed by analysing the ocean's surface salinity and the "precipitation minus evaporation (P–E)" patterns over the ocean. Both are elevated.[7]: 85  Research published in 2012 based on surface ocean salinity over the period 1950 to 2000 confirm this projection of an intensified global water cycle with salty areas becoming more saline and fresher areas becoming more fresh over the period.[13] IPCC indicates there is high confidence that heavy precipitation events associated with both tropical and extratropical cyclones, and atmospheric moisture transport and heavy precipitation events will intensify.[14]

A warming climate makes extremely wet and very dry occurrences more severe. There can also be changes in atmospheric circulation patterns. This will affect the regions and frequency for these extremes to occur. In most parts of the world and under all emission scenarios, water cycle variability and accompanying extremes are anticipated to rise more quickly than the changes of average values.[7]: 85 

Changes to regional weather patterns Edit

Regional weather patterns across the globe are also changing due to tropical ocean warming. The Indo-Pacific warm pool has been warming rapidly and expanding during the recent decades, largely in response to increased carbon emissions from fossil fuel burning.[15] The warm pool expanded to almost double its size, from an area of 22 million km2 during 1900–1980, to an area of 40 million km2 during 1981–2018.[16] This expansion of the warm pool has altered global rainfall patterns, by changing the life cycle of the Madden Julian Oscillation (MJO), which is the most dominant mode of weather fluctuation originating in the tropics.

Potential for abrupt change Edit

Several characteristics of the water cycle have the potential to cause sudden (abrupt) changes of the water cycle.[7]: 1148  The definition for "abrupt change" is: a regional to global scale change in the climate system that happens more quickly than it has in the past, indicating that the climate response is not linear.[7]: 1148  There may be "rapid transitions between wet and dry states" as a result of non-linear interactions between the ocean, atmosphere, and land surface.

For example, a collapse of the Atlantic meridional overturning circulation (AMOC), if it did occur, could have large regional impacts on the water cycle.[7]: 1149  The initiation or termination of solar radiation modification could also result in abrupt changes in the water cycle.[7]: 1151 There could also be abrupt water cycle responses to changes in the land surface: Amazon deforestation and drying, greening of the Sahara and the Sahel, amplification of drought by dust are all processes which could contribute.

The scientific understanding of the likelihood of such abrupt changes to the water cycle is not yet clear.[7]: 1151  Sudden changes in the water cycle due to human activity are a possibility that cannot be ruled out, with current scientific knowledge. However, the likelihood that such changes will occur during the 21st century is currently regarded as low.[7]: 72 

Measurement and modelling techniques Edit

 
The water cycle

Intermittency in precipitation Edit

Climate models do not simulate the water cycle very well.[17] One reason is that precipitation is a difficult quantity to deal with because it is inherently intermittent.[6]: 50  Often, only the average amount is considered.[18] People tend to use the term "precipitation" as if it was the same as "precipitation amount". What actually matters when describing changes to Earth's precipitation patterns is more than just the total amount: it is also about the intensity (how hard it rains or snows), frequency (how often), duration (how long), and type (whether rain or snow).[6]: 50  New Zealand climatologist Kevin E. Trenberth and former NCAR scientist, has researched the characteristics of precipitation and found that it is the frequency and intensity that matter for extremes, and those are difficult to calculate in climate models.[17]

Changes in ocean salinity Edit

See also: Effects of climate change on oceans
 
The yearly average distribution of precipitation minus evaporation. The image shows how the region around the equator is dominated by precipitation, and the subtropics are mainly dominated by evaporation.

Due to global warming and increased glacier melt, thermohaline circulation patterns may be altered by increasing amounts of freshwater released into oceans and, therefore, changing ocean salinity. Thermohaline circulation is responsible for bringing up cold, nutrient-rich water from the depths of the ocean, a process known as upwelling.[19]

Seawater consists of fresh water and salt, and the concentration of salt in seawater is called salinity. Salt does not evaporate, thus the precipitation and evaporation of freshwater influences salinity strongly. Changes in the water cycle are therefore strongly visible in surface salinity measurements, which has already been known since the 1930s.[20][21]

 
The global pattern of the oceanic surface salinity. It can be seen how the by evaporation dominated subtropics are relatively saline. The tropics and higher latitudes are less saline. When comparing with the map above it can be seen how the high salinity regions match the by evaporation dominated areas, and the lower salinity regions match the by precipitation dominated areas.[22]

The advantage of using surface salinity is that it is well documented in the last 50 years, for example with in-situ measurement systems as ARGO.[23] Another advantage is that oceanic salinity is stable on very long time scales, which makes small changes due to anthropogenic forcing easier to track. The oceanic salinity is not homogeneously distributed over the globe, there are regional differences that show a clear pattern. The tropic regions are relatively fresh, since these regions are dominated by rainfall. The subtropics are more saline, since these are dominated by evaporation, these regions are also known as the 'desert latitudes'.[23] The latitudes close to the polar regions are then again less saline, with the lowest salinity values found in these regions. This is because there is a low amount of evaporation in this region,[24] and a high amount of fresh meltwater entering the Arctic Ocean.[25]

The long-term observation records show a clear trend: the global salinity patterns are amplifying in this period.[26][27] This means that the high saline regions have become more saline, and regions of low salinity have become less saline. The regions of high salinity are dominated by evaporation, and the increase in salinity shows that evaporation is increasing even more. The same goes for regions of low salinity that are become less saline, which indicates that precipitation is intensifying only more.[23][28] This spatial pattern is similar to the spatial pattern of evaporation minus precipitation. The amplification of the salinity patterns is therefore indirect evidence for an intensifying water cycle.

To further investigate the relation between ocean salinity and the water cycle, models play a large role in current research. General Circulation Models (GCMs) and more recently Atmosphere-Ocean General Circulation Models (AOGCMs) simulate the global circulations and the effects of changes such as an intensifying water cycle.[23] The outcome of multiple studies based on such models support the relationship between surface salinity changes and the amplifying precipitation minus evaporation patterns.[23][29]

A metric to capture the difference in salinity between high and low salinity regions in the top 2000 meters of the ocean is captured in the SC2000 metric.[20] The observed increase of this metric is 5.2% (±0.6%) from 1960 to 2017.[20] But this trend is accelerating, as it increased 1.9% (±0.6%) from 1960 to 1990, and 3.3% (±0.4%) from 1991 to 2017.[20] Amplification of the pattern is weaker below the surface. This is because ocean warming increases near-surface stratification, subsurface layer is still in equilibrium with the colder climate. This causes the surface amplification to be stronger than older models predicted.[30]

An instrument carried by the SAC-D satellite Aquarius, launched in June 2011, measured global sea surface salinity.[31][32]

Between 1994 and 2006, satellite observations showed an 18% increase in the flow of freshwater into the world's oceans, partly from melting ice sheets, especially Greenland[33] and partly from increased precipitation driven by an increase in global ocean evaporation.[34]

Salinity evidence for changes in the water cycle Edit

Essential processes of the water cycle are precipitation and evaporation. The local amount of precipitation minus evaporation (often noted as P-E) shows the local influence of the water cycle. Changes in the magnitude of P-E are often used to show changes in the water cycle.[20][35] But robust conclusions about changes in the amount of precipitation and evaporation are complex.[36] About 85% of the earth's evaporation and 78% of the precipitation happens over the ocean surface, where measurements are difficult.[37][38] Precipitation on the one hand, only has long term accurate observation records over land surfaces where the amount of rainfall can be measured locally (called in-situ). Evaporation on the other hand, has no long time accurate observation records at all.[37] This prohibits confident conclusions about changes since the industrial revolution. The AR5 (Fifth Assessment Report) of the IPCC creates an overview of the available literature on a topic, and labels the topic then on scientific understanding. They assign only low confidence to precipitation changes before 1951, and medium confidence after 1951, because of the scarcity of data. These changes are attributed to human influence, but only with medium confidence as well.[39] There have been limited changes in regional monsoon precipitation observed over the 20th century because increases caused by global warming have been neutralized by cooling effects of anthropogenic aerosols.  Different regional climate models project changes in monsoon precipitation whereby more regions are projected with increases than those with decreases.[2]

Convection-permitting models to predict weather extremes Edit

The representation of convection in climate models has so far restricted the ability of scientists to accurately simulate African weather extremes, limiting climate change predictions.[40] Convection-permitting models (CPMs) are able to better simulate the diurnal cycle of tropical convection, the vertical cloud structure and the coupling between moist convection and convergence and soil moisture-convection feedbacks in the Sahel. The benefits of CPMs have also been demonstrated in other regions, including a more realistic representation of the precipitation structure and extremes. A convection-permitting (4.5 km grid-spacing) model over an Africa-wide domain shows future increases in dry spell length during the wet season over western and central Africa. The scientists concludes that, with the more accurate representation of convection, projected changes in both wet and dry extremes over Africa may be more severe.[41] In other words: "both ends of Africa's weather extremes will get more severe".[42]

Impacts on water management aspects Edit

See also: Effects of climate change

The human-caused changes to the water cycle will increase hydrologic variability and therefore have a profound impact on the water sector and investment decisions.[9] They will affect water availability (water resources), water supply, water demand, water security and water allocation at regional, basin, and local levels.[9]

Water security Edit

This section is an excerpt from Water security § Climate change.[edit]

Impacts of climate change that are tied to water, affect people's water security on a daily basis. They include more frequent and intense heavy precipitation which affects the frequency, size and timing of floods.[43] Also droughts can alter the total amount of freshwater and cause a decline in groundwater storage, and reduction in groundwater recharge.[44] Reduction in water quality due to extreme events can also occur.[45]: 558  Faster melting of glaciers can also occur.[46]

Global climate change will probably make it more complex and expensive to ensure water security.[47] It creates new threats and adaptation challenges.[48] This is because climate change leads to increased hydrological variability and extremes. Climate change has many impacts on the water cycle. These result in higher climatic and hydrological variability, which can threaten water security.[49]: vII  Changes in the water cycle threaten existing and future water infrastructure. It will be harder to plan investments for future water infrastructure as there are so many uncertainties about future variability for the water cycle.[48] This makes societies more exposed to risks of extreme events linked to water and therefore reduces water security.[49]: vII 

Water scarcity Edit

This section is an excerpt from Water scarcity § Climate change.[edit]

Climate change could have significant impacts on water resources around the world because of the close connections between the climate and hydrological cycle. Rising temperatures will increase evaporation and lead to increases in precipitation, though there will be regional variations in rainfall. Both droughts and floods may become more frequent and more severe in different regions at different times, generally less snowfall and more rainfall under a warmer climate,[50] and dramatic changes in snowfall and snow melt are expected in mountainous areas. Higher temperatures will also affect water quality in ways that are not well understood. Possible impacts include increased eutrophication. Climate change could also mean an increase in demand for farm irrigation, garden sprinklers, and perhaps even swimming pools. There is now ample evidence that increased hydrologic variability and change in climate has and will continue to have a profound impact on the water sector. These effects will be seen through the hydrologic cycle, water availability, water demand, and water allocation at the global, regional, basin, and local levels.[51]

The United Nations' FAO states that by 2025, 1.9 billion people will live in countries or regions with absolute water scarcity, and two-thirds of the world population could be under stress conditions.[52] The World Bank adds that climate change could profoundly alter future patterns of both water availability and use, thereby increasing levels of water stress and insecurity, both at the global scale and in sectors that depend on water.[53]

Droughts Edit

This section is an excerpt from Effects of climate change § Droughts.[edit]

Climate change affects many factors associated with droughts. These include 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.[54][55]: 1057  In some tropical and subtropical regions of the world, there will probably be less rain due to global warming. This will make them more prone to drought. Droughts are set to worsen in many regions of the world. These include Central America, the Amazon and south-western South America. They also include West and Southern Africa. The Mediterranean and south-western Australia are also some of these regions.[55]: 1157 

Higher temperatures increase evaporation. This dries the soil and increases plant stress. Agriculture suffers as a result. This means even regions where overall rainfall is expected to remain relatively stable will experience these impacts.[55]: 1157  These regions include central and northern Europe. Without climate change mitigation, around one third of land areas are likely to experience moderate or more severe drought by 2100.[55]: 1157  Due to global warming droughts are more frequent and intense than in the past.[56]

Several impacts make their impacts worse. These are increased water demand, population growth and urban expansion in many areas.[57] Land restoration can help reduce the impact of droughts. One example of this is agroforestry.[58]

Floods Edit

This section is an excerpt from Effects of climate change § Floods.[edit]
Due to an increase in heavy rainfall events, floods are likely to become more severe when they do occur.[55]: 1155  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. These include changes in rain and snowmelt, but also soil moisture.[55]: 1156  Climate change leaves soils drier in some areas, so they may absorb rainfall more quickly. This leads to less flooding. Dry soils can also become harder. In this case heavy rainfall runs off into rivers and lakes. This increases risks of flooding.[55]: 1155 

Groundwater quantity and quality Edit

This section is an excerpt from Groundwater § Climate change.[edit]

The impacts of climate change on groundwater may be greatest through its indirect effects on irrigation water demand via increased evapotranspiration.[59]: 5  There is an observed declined in groundwater storage in many parts of the world. This is due to more groundwater being used for irrigation activities in agriculture, particularly in drylands.[60]: 1091  Some of this increase in irrigation can be due to water scarcity issues made worse by effects of climate change on the water cycle. Direct redistribution of water by human activities amounting to ~24,000 km3 per year is about double the global groundwater recharge each year.[60]

Climate change causes changes to the water cycle which in turn affect groundwater in several ways: There can be a decline in groundwater storage, and reduction in groundwater recharge and water quality deterioration due to extreme weather events.[61]: 558  In the tropics intense precipitation and flooding events appear to lead to more groundwater recharge.[61]: 582 

However, the exact impacts of climate change on groundwater are still under investigation.[61]: 579  This is because scientific data derived from groundwater monitoring is still missing, such as changes in space and time, abstraction data and "numerical representations of groundwater recharge processes".[61]: 579 

Effects of climate change could have different impacts on groundwater storage: The expected more intense (but fewer) major rainfall events could lead to increased groundwater recharge in many environments.[59]: 104  But more intense drought periods could result in soil drying-out and compaction which would reduce infiltration to groundwater.[62]

See also Edit

References Edit

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October 21, 2023
effects, climate, change, water, cycle, effects, climate, change, water, cycle, profound, have, been, described, intensification, strengthening, water, cycle, also, called, hydrologic, cycle, 1079, this, effect, been, observed, since, least, 1980, 1079, exampl. The effects of climate change on the water cycle are profound and have been described as an intensification or a strengthening of the water cycle also called hydrologic cycle 2 1079 This effect has been observed since at least 1980 2 1079 One example is the intensification of heavy precipitation events This has important negative effects on the availability of freshwater resources as well as other water reservoirs such as oceans ice sheets atmosphere and land surface The water cycle is essential to life on Earth and plays a large role in the global climate and the ocean circulation The warming of our planet is expected to cause changes in the water cycle for various reasons 3 For example warmer atmosphere can contain more water vapor which has effects on evaporation and rainfall Extreme weather heavy rains droughts heat waves is one consequence of a changing water cycle due to global warming These events will be progressively more common as the Earth warms more and more 1 Figure SPM 6 The underlying cause of the intensifying water cycle is the increased amount of greenhouse gases which lead to a warmer atmosphere through the greenhouse effect 3 Physics dictates that saturation vapor pressure increases by 7 when temperature rises by 1 C as described in the Clausius Clapeyron equation 4 The strength of the water cycle and its changes over time are of considerable interest especially as the climate changes 5 The essence of the overall hydrological cycle is the evaporation of moisture in one place and the precipitation in other places In particular evaporation exceeds precipitation over the oceans which allows moisture to be transported by the atmosphere from the oceans onto land where precipitation exceeds evapotranspiration and the runoff flows into streams and rivers and discharges into the ocean completing the cycle 5 The water cycle is a key part of Earth s energy cycle through the evaporative cooling at the surface which provides latent heat to the atmosphere as atmospheric systems play a primary role in moving heat upward 5 If water is available extra heat goes mostly into evaporation as it always does on the oceans otherwise it goes into raising air temperature 6 The availability of water plus the water holding capacity of the atmosphere which increases proportionally with temperature increase means that water plays a major role over the oceans and tropics but much less over continents and the polar regions This is why temperature increases dominate in the Arctic polar amplification and on land 6 Several inherent characteristics have the potential to cause sudden abrupt changes in the water cycle 7 1148 However the likelihood that such changes will occur during the 21st century is currently regarded as low 7 72 Contents 1 Causes 2 Observations and predictions 2 1 Changes to regional weather patterns 2 2 Potential for abrupt change 3 Measurement and modelling techniques 3 1 Intermittency in precipitation 3 2 Changes in ocean salinity 3 2 1 Salinity evidence for changes in the water cycle 3 3 Convection permitting models to predict weather extremes 4 Impacts on water management aspects 4 1 Water security 4 2 Water scarcity 4 2 1 Droughts 4 3 Floods 4 4 Groundwater quantity and quality 5 See also 6 ReferencesCauses Edit nbsp Where carbon goes when water flows 8 Global warming leads to changes in the global water cycle 9 These include first and foremost an increased water vapor pressure in the atmosphere This causes changes in precipitation patterns with regards to frequency and intensity as well as changes in groundwater and soil moisture Taken together these changes are often referred to as an intensification and acceleration of the water cycle 9 xvii Key processes that will also be affected are droughts and floods tropical cyclones glacier retreat snow cover ice jam floods and extreme weather events The increased amount of greenhouse gases in the atmosphere leads to a warmer atmosphere 3 The saturation vapor pressure of air increases with temperature which means that warmer air can contain more water vapor Because the air can contain more moisture and the land becomes warmer evaporation is enhanced As a consequence the increased amount of water in the atmosphere leads to more intense rainfall 10 This relation between temperature and saturation vapor pressure is described in the Clausius Clapeyron equation which states that saturation pressure will increase by 7 when temperature rises by 1 C 4 This is visible in measurements of the tropospheric water vapor which are provided by satellites 11 radiosondes and surface stations The IPCC AR5 concludes that tropospheric water vapor has increased by 3 5 over the last 40 years which is consistent with the observed temperature increase of 0 5 C 12 Observations and predictions Edit nbsp Predicted changes in average soil moisture for a scenario of 2 C global warming This can disrupt agriculture and ecosystems A reduction in soil moisture by one standard deviation means that average soil moisture will approximately match the ninth driest year between 1850 and 1900 at that location Since the middle of the 20th century human caused climate change has resulted in observable changes in the global water cycle 7 85 The IPCC Sixth Assessment Report in 2021 predicted that these changes will continue to grow significantly at the global and regional level 7 85 The report also found that Precipitation over land has increased since 1950 and the rate of increase has become faster since the 1980s and in higher latitudes Water vapour in the atmosphere in particular the troposhere has increased since at least the 1980s It is expected that over the course of the 21st century the annual global precipitation over land will increase due to a higher global surface temperature 7 85 The human influence on the water cycle can be observed by analysing the ocean s surface salinity and the precipitation minus evaporation P E patterns over the ocean Both are elevated 7 85 Research published in 2012 based on surface ocean salinity over the period 1950 to 2000 confirm this projection of an intensified global water cycle with salty areas becoming more saline and fresher areas becoming more fresh over the period 13 IPCC indicates there is high confidence that heavy precipitation events associated with both tropical and extratropical cyclones and atmospheric moisture transport and heavy precipitation events will intensify 14 A warming climate makes extremely wet and very dry occurrences more severe There can also be changes in atmospheric circulation patterns This will affect the regions and frequency for these extremes to occur In most parts of the world and under all emission scenarios water cycle variability and accompanying extremes are anticipated to rise more quickly than the changes of average values 7 85 Changes to regional weather patterns Edit Regional weather patterns across the globe are also changing due to tropical ocean warming The Indo Pacific warm pool has been warming rapidly and expanding during the recent decades largely in response to increased carbon emissions from fossil fuel burning 15 The warm pool expanded to almost double its size from an area of 22 million km2 during 1900 1980 to an area of 40 million km2 during 1981 2018 16 This expansion of the warm pool has altered global rainfall patterns by changing the life cycle of the Madden Julian Oscillation MJO which is the most dominant mode of weather fluctuation originating in the tropics Potential for abrupt change Edit Several characteristics of the water cycle have the potential to cause sudden abrupt changes of the water cycle 7 1148 The definition for abrupt change is a regional to global scale change in the climate system that happens more quickly than it has in the past indicating that the climate response is not linear 7 1148 There may be rapid transitions between wet and dry states as a result of non linear interactions between the ocean atmosphere and land surface For example a collapse of the Atlantic meridional overturning circulation AMOC if it did occur could have large regional impacts on the water cycle 7 1149 The initiation or termination of solar radiation modification could also result in abrupt changes in the water cycle 7 1151 There could also be abrupt water cycle responses to changes in the land surface Amazon deforestation and drying greening of the Sahara and the Sahel amplification of drought by dust are all processes which could contribute The scientific understanding of the likelihood of such abrupt changes to the water cycle is not yet clear 7 1151 Sudden changes in the water cycle due to human activity are a possibility that cannot be ruled out with current scientific knowledge However the likelihood that such changes will occur during the 21st century is currently regarded as low 7 72 Measurement and modelling techniques Edit nbsp The water cycleIntermittency in precipitation Edit Climate models do not simulate the water cycle very well 17 One reason is that precipitation is a difficult quantity to deal with because it is inherently intermittent 6 50 Often only the average amount is considered 18 People tend to use the term precipitation as if it was the same as precipitation amount What actually matters when describing changes to Earth s precipitation patterns is more than just the total amount it is also about the intensity how hard it rains or snows frequency how often duration how long and type whether rain or snow 6 50 New Zealand climatologist Kevin E Trenberth and former NCAR scientist has researched the characteristics of precipitation and found that it is the frequency and intensity that matter for extremes and those are difficult to calculate in climate models 17 Changes in ocean salinity Edit See also Effects of climate change on oceans nbsp The yearly average distribution of precipitation minus evaporation The image shows how the region around the equator is dominated by precipitation and the subtropics are mainly dominated by evaporation Due to global warming and increased glacier melt thermohaline circulation patterns may be altered by increasing amounts of freshwater released into oceans and therefore changing ocean salinity Thermohaline circulation is responsible for bringing up cold nutrient rich water from the depths of the ocean a process known as upwelling 19 Seawater consists of fresh water and salt and the concentration of salt in seawater is called salinity Salt does not evaporate thus the precipitation and evaporation of freshwater influences salinity strongly Changes in the water cycle are therefore strongly visible in surface salinity measurements which has already been known since the 1930s 20 21 nbsp The global pattern of the oceanic surface salinity It can be seen how the by evaporation dominated subtropics are relatively saline The tropics and higher latitudes are less saline When comparing with the map above it can be seen how the high salinity regions match the by evaporation dominated areas and the lower salinity regions match the by precipitation dominated areas 22 The advantage of using surface salinity is that it is well documented in the last 50 years for example with in situ measurement systems as ARGO 23 Another advantage is that oceanic salinity is stable on very long time scales which makes small changes due to anthropogenic forcing easier to track The oceanic salinity is not homogeneously distributed over the globe there are regional differences that show a clear pattern The tropic regions are relatively fresh since these regions are dominated by rainfall The subtropics are more saline since these are dominated by evaporation these regions are also known as the desert latitudes 23 The latitudes close to the polar regions are then again less saline with the lowest salinity values found in these regions This is because there is a low amount of evaporation in this region 24 and a high amount of fresh meltwater entering the Arctic Ocean 25 The long term observation records show a clear trend the global salinity patterns are amplifying in this period 26 27 This means that the high saline regions have become more saline and regions of low salinity have become less saline The regions of high salinity are dominated by evaporation and the increase in salinity shows that evaporation is increasing even more The same goes for regions of low salinity that are become less saline which indicates that precipitation is intensifying only more 23 28 This spatial pattern is similar to the spatial pattern of evaporation minus precipitation The amplification of the salinity patterns is therefore indirect evidence for an intensifying water cycle To further investigate the relation between ocean salinity and the water cycle models play a large role in current research General Circulation Models GCMs and more recently Atmosphere Ocean General Circulation Models AOGCMs simulate the global circulations and the effects of changes such as an intensifying water cycle 23 The outcome of multiple studies based on such models support the relationship between surface salinity changes and the amplifying precipitation minus evaporation patterns 23 29 A metric to capture the difference in salinity between high and low salinity regions in the top 2000 meters of the ocean is captured in the SC2000 metric 20 The observed increase of this metric is 5 2 0 6 from 1960 to 2017 20 But this trend is accelerating as it increased 1 9 0 6 from 1960 to 1990 and 3 3 0 4 from 1991 to 2017 20 Amplification of the pattern is weaker below the surface This is because ocean warming increases near surface stratification subsurface layer is still in equilibrium with the colder climate This causes the surface amplification to be stronger than older models predicted 30 An instrument carried by the SAC D satellite Aquarius launched in June 2011 measured global sea surface salinity 31 32 Between 1994 and 2006 satellite observations showed an 18 increase in the flow of freshwater into the world s oceans partly from melting ice sheets especially Greenland 33 and partly from increased precipitation driven by an increase in global ocean evaporation 34 Salinity evidence for changes in the water cycle Edit Essential processes of the water cycle are precipitation and evaporation The local amount of precipitation minus evaporation often noted as P E shows the local influence of the water cycle Changes in the magnitude of P E are often used to show changes in the water cycle 20 35 But robust conclusions about changes in the amount of precipitation and evaporation are complex 36 About 85 of the earth s evaporation and 78 of the precipitation happens over the ocean surface where measurements are difficult 37 38 Precipitation on the one hand only has long term accurate observation records over land surfaces where the amount of rainfall can be measured locally called in situ Evaporation on the other hand has no long time accurate observation records at all 37 This prohibits confident conclusions about changes since the industrial revolution The AR5 Fifth Assessment Report of the IPCC creates an overview of the available literature on a topic and labels the topic then on scientific understanding They assign only low confidence to precipitation changes before 1951 and medium confidence after 1951 because of the scarcity of data These changes are attributed to human influence but only with medium confidence as well 39 There have been limited changes in regional monsoon precipitation observed over the 20th century because increases caused by global warming have been neutralized by cooling effects of anthropogenic aerosols Different regional climate models project changes in monsoon precipitation whereby more regions are projected with increases than those with decreases 2 Convection permitting models to predict weather extremes Edit The representation of convection in climate models has so far restricted the ability of scientists to accurately simulate African weather extremes limiting climate change predictions 40 Convection permitting models CPMs are able to better simulate the diurnal cycle of tropical convection the vertical cloud structure and the coupling between moist convection and convergence and soil moisture convection feedbacks in the Sahel The benefits of CPMs have also been demonstrated in other regions including a more realistic representation of the precipitation structure and extremes A convection permitting 4 5 km grid spacing model over an Africa wide domain shows future increases in dry spell length during the wet season over western and central Africa The scientists concludes that with the more accurate representation of convection projected changes in both wet and dry extremes over Africa may be more severe 41 In other words both ends of Africa s weather extremes will get more severe 42 Impacts on water management aspects EditSee also Effects of climate change The human caused changes to the water cycle will increase hydrologic variability and therefore have a profound impact on the water sector and investment decisions 9 They will affect water availability water resources water supply water demand water security and water allocation at regional basin and local levels 9 Water security Edit This section is an excerpt from Water security Climate change edit Impacts of climate change that are tied to water affect people s water security on a daily basis They include more frequent and intense heavy precipitation which affects the frequency size and timing of floods 43 Also droughts can alter the total amount of freshwater and cause a decline in groundwater storage and reduction in groundwater recharge 44 Reduction in water quality due to extreme events can also occur 45 558 Faster melting of glaciers can also occur 46 Global climate change will probably make it more complex and expensive to ensure water security 47 It creates new threats and adaptation challenges 48 This is because climate change leads to increased hydrological variability and extremes Climate change has many impacts on the water cycle These result in higher climatic and hydrological variability which can threaten water security 49 vII Changes in the water cycle threaten existing and future water infrastructure It will be harder to plan investments for future water infrastructure as there are so many uncertainties about future variability for the water cycle 48 This makes societies more exposed to risks of extreme events linked to water and therefore reduces water security 49 vII Water scarcity Edit This section is an excerpt from Water scarcity Climate change edit Climate change could have significant impacts on water resources around the world because of the close connections between the climate and hydrological cycle Rising temperatures will increase evaporation and lead to increases in precipitation though there will be regional variations in rainfall Both droughts and floods may become more frequent and more severe in different regions at different times generally less snowfall and more rainfall under a warmer climate 50 and dramatic changes in snowfall and snow melt are expected in mountainous areas Higher temperatures will also affect water quality in ways that are not well understood Possible impacts include increased eutrophication Climate change could also mean an increase in demand for farm irrigation garden sprinklers and perhaps even swimming pools There is now ample evidence that increased hydrologic variability and change in climate has and will continue to have a profound impact on the water sector These effects will be seen through the hydrologic cycle water availability water demand and water allocation at the global regional basin and local levels 51 The United Nations FAO states that by 2025 1 9 billion people will live in countries or regions with absolute water scarcity and two thirds of the world population could be under stress conditions 52 The World Bank adds that climate change could profoundly alter future patterns of both water availability and use thereby increasing levels of water stress and insecurity both at the global scale and in sectors that depend on water 53 Droughts Edit This section is an excerpt from Effects of climate change Droughts edit Climate change affects many factors associated with droughts These include 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 54 55 1057 In some tropical and subtropical regions of the world there will probably be less rain due to global warming This will make them more prone to drought Droughts are set to worsen in many regions of the world These include Central America the Amazon and south western South America They also include West and Southern Africa The Mediterranean and south western Australia are also some of these regions 55 1157 Higher temperatures increase evaporation This dries the soil and increases plant stress Agriculture suffers as a result This means even regions where overall rainfall is expected to remain relatively stable will experience these impacts 55 1157 These regions include central and northern Europe Without climate change mitigation around one third of land areas are likely to experience moderate or more severe drought by 2100 55 1157 Due to global warming droughts are more frequent and intense than in the past 56 Several impacts make their impacts worse These are increased water demand population growth and urban expansion in many areas 57 Land restoration can help reduce the impact of droughts One example of this is agroforestry 58 Floods Edit This section is an excerpt from Effects of climate change Floods edit Due to an increase in heavy rainfall events floods are likely to become more severe when they do occur 55 1155 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 These include changes in rain and snowmelt but also soil moisture 55 1156 Climate change leaves soils drier in some areas so they may absorb rainfall more quickly This leads to less flooding Dry soils can also become harder In this case heavy rainfall runs off into rivers and lakes This increases risks of flooding 55 1155 Groundwater quantity and quality Edit This section is an excerpt from Groundwater Climate change edit The impacts of climate change on groundwater may be greatest through its indirect effects on irrigation water demand via increased evapotranspiration 59 5 There is an observed declined in groundwater storage in many parts of the world This is due to more groundwater being used for irrigation activities in agriculture particularly in drylands 60 1091 Some of this increase in irrigation can be due to water scarcity issues made worse by effects of climate change on the water cycle Direct redistribution of water by human activities amounting to 24 000 km3 per year is about double the global groundwater recharge each year 60 Climate change causes changes to the water cycle which in turn affect groundwater in several ways There can be a decline in groundwater storage and reduction in groundwater recharge and water quality deterioration due to extreme weather events 61 558 In the tropics intense precipitation and flooding events appear to lead to more groundwater recharge 61 582 However the exact impacts of climate change on groundwater are still under investigation 61 579 This is because scientific data derived from groundwater monitoring is still missing such as changes in space and time abstraction data and numerical representations of groundwater recharge processes 61 579 Effects of climate change could have different impacts on groundwater storage The expected more intense but fewer major rainfall events could lead to increased groundwater 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Change Masson Delmotte V P Zhai A Pirani S L Connors C Pean S Berger N Caud Y Chen L Goldfarb M I Gomis M Huang K Leitzell E Lonnoy J B R Matthews T K Maycock T Waterfield O Yelekci R Yu and B Zhou eds Cambridge University Press Cambridge United Kingdom and New York NY US pp 1055 1210 doi 10 1017 9781009157896 010 a b c d Caretta M A A Mukherji M Arfanuzzaman R A Betts A Gelfan Y Hirabayashi T K Lissner J Liu E Lopez Gunn R Morgan S Mwanga and S Supratid 2022 Chapter 4 Water In Climate Change 2022 Impacts Adaptation and Vulnerability Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change H O Portner D C Roberts M Tignor E S Poloczanska K Mintenbeck A Alegria M Craig S Langsdorf S Loschke V Moller A Okem B Rama eds Cambridge University Press Cambridge UK and New York NY US pp 551 712 doi 10 1017 9781009325844 006 IAH 2019 CLIMATE CHANGE ADAPTATION amp GROUNDWATER Strategic Overview Series Retrieved from https en wikipedia org w 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