Datasets:

rlacombe

/

ClimateX

like 7

AR6_WGI

In SSP5-8.5, a scenario without climate change mitigation but with stringent air pollution control, PM levels decline through 2100, but high CH 4 levels hamper the decline in global surface ozone at least until 2080

high

train

AR6_WGI

These investigations have consistently shown that SRM could offset some of the effects of increasing greenhouse gases on global and regional climate, including the carbon and water cycles

high

train

AR6_WGI

However, there would be substantial residual or overcompensating climate change at the regional scales and seasonal time scales

high

train

AR6_WGI

The cooling caused by SRM would increase the global land and ocean CO 2 sinks (medium confidence), but this would not stop CO 2 from increasing in the atmosphere or affect the resulting ocean acidification under continued anthropogenic emissions

high

train

AR6_WGI

A sudden and sustained termination of SRM in a high CO 2 emissions scenario would cause rapid climate change

high

train

AR6_WGI

However, a gradual phase-out of SRM combined with emissions reduction and carbon dioxide removal (CDR) would avoid these termination effects

medium

train

AR6_WGI

Since AR5, more modelling work has been conducted with more sophisticated treatment of aerosol-based SRM approaches, but the uncertainties in cloud–aerosol–radiation interactions are still large

high

train

AR6_WGI

Modelling studies suggest that it is possible to stabilize multiple large-scale temperature indicators simultaneously by tailoring the deployment strategy of SRM options

medium

train

AR6_WGI

In contrast, cirrus cloud thinning, targeting longwave radiation, is expected to cause an increase in global mean precipitation

medium

train

AR6_WGI

If shortwave approaches are used to offset global mean warming, the magnitude of reduction in regional precipitation minus evapotranspiration (P–E) (Box TS.5), which is more relevant to freshwater availability, is smaller than precipitation decrease because of simultaneous reductions in both precipitation and evapotranspiration

medium

train

AR6_WGI

If SRM is used to cool the planet, it would cause a reduction in plant and soil respiration and slow the reduction of ocean carbon uptake due to warming

medium

train

AR6_WGI

The result would be an enhancement of the global land and ocean CO 2 sinks

medium

train

AR6_WGI

However, SRM would not stop CO 2 from increasing in the atmosphere or affect the resulting ocean acidification under continued anthropogenic emissions

high

train

AR6_WGI

A sudden and sustained termination of SRM in a high GHG emissions scenario would cause rapid climate change and a reversal of the SRM effects on the carbon sinks

high

train

AR6_WGI

However, a gradual phase-out of SRM combined with emissions reductions and CDR would avoid larger rates of changes

medium

train

AR6_WGI

For global climate indicators, evidence for abrupt change is limited, but deep ocean warming, acidification and sea level rise are committed to ongoing change for millennia after global surface temperatures initially stabilize and are irreversible on human time scales

very high

train

AR6_WGI

At the regional scale, abrupt responses, tipping points and even reversals in the direction of change cannot be excluded

high

train

AR6_WGI

Some processes suspected of having tipping points, such as the Atlantic Meridional Overturning Circulation (AMOC), have been found to often undergo recovery after temperature stabilization with a time delay

low

train

AR6_WGI

It is likely that under stabilization of global warming at 1.5°C, 2.0°C or 3.0°C relative to 1850–1900, the AMOC will continue to weaken for several decades by about 15%, 20% and 30% of its strength and then recover to pre-decline values over several centuries

medium

train

AR6_WGI

At sustained warming levels between 2°C and 3°C, there is limited evidence that the Greenland and West Antarctic ice sheets will be lost almost completely and irreversibly over multiple millennia; both the probability of their complete loss and the rate of mass loss increases with higher surface temperatures

high

train

AR6_WGI

At sustained warming levels between 3°C and 5°C, near-complete loss of the Greenland Ice Sheet and complete loss of the West Antarctic Ice Sheet is projected to occur irreversibly over multiple millennia (medium confidence); with substantial parts or all of Wilkes Subglacial Basin in East Antarctica lost over multiple millennia

low

train

AR6_WGI

For other hazards (e.g., ice-sheet behaviour, glacier mass loss and global mean sea level change, coastal floods, coastal erosion, air pollution, and ocean acidification) the time and/or scenario dimensions remain critical, and a simple and robust relationship with global warming level cannot be established

high

train

AR6_WGI

For global warming up to 2°C above 1850–1900 levels, paleoclimate records do not indicate abrupt changes in the carbon cycle

low

test

AR6_WGI

Despite the wide range of model responses, uncertainty in atmospheric CO 2 by 2100 is dominated by future anthropogenic emissions rather than uncertainties related to carbon–climate feedbacks

high

train

AR6_WGI

The increase in global ocean heat content (Section TS.2.4) will likely continue until at least 2300 even for low emissions scenarios, and global mean sea level will continue to rise for centuries to millennia following cessation of emissions (Box TS.4) due to continuing deep ocean heat uptake and mass loss of the Greenland and Antarctic ice sheets

high

train

AR6_WGI

Possible abrupt changes and tipping points in biogeochemical cycles lead to additional uncertainty in 21st century atmospheric GHG concentrations, but future anthropogenic emissions remain the dominant uncertainty

high

train

AR6_WGI

Continued Amazon deforestation, combined with a warming climate, raises the probability that this ecosystem will cross a tipping point into a dry state during the 21st century

low

train

AR6_WGI

A key methodology is distillation – combining lines of evidence and accounting for stakeholder context and values – which helps ensure the information is relevant, useful and trusted for decision-making (see Core Concepts Box)

high

train

AR6_WGI

Since AR5, climate change information produced for climate services has increased significantly due to scientific and technological advancements and growing user awareness, requirements, and demand

very high

train

AR6_WGI

Discarding models that fundamentally misrepresent relevant processes improves the credibility of regional climate information generated from these ensembles

high

train

AR6_WGI

However, multi-model mean and ensemble spread are not a full measure of the range of projection uncertainty and are not sufficient to characterize low-likelihood, high-impact changes (Box TS.3) or situations where different models simulate substantially different or even opposite changes

high

train

AR6_WGI

Large single-model ensembles are now available and provide a more comprehensive spectrum of possible changes associated with internal variability

high

train

AR6_WGI

No-till farming, irrigation and crop expansion have similarly attenuated increases in summer hot extremes in some regions, such as central North America

medium

train

AR6_WGI

In some cases, even the sign of a projected change in regional climate cannot be trusted if relevant regional processes are not represented, for example, for variables such as precipitation and wind speed

medium

train

AR6_WGI

However, the performance of these techniques depends on that of the driving climate model: in particular, bias adjustment cannot overcome all consequences of unresolved or strongly misrepresented physical processes, such as large-scale circulation biases or local feedbacks

medium

train

AR6_WGI

Distilling regional climate information from multiple lines of evidence and taking the user context into account increases fitness, usefulness, relevance and trust in that information for use in climate services (Box TS.11) and decision-making

high

train

AR6_WGI

Since AR5, there has been a significant increase in the range and diversity of climate service activities

very high

train

AR6_WGI

Since AR5, climate change information produced in climate service contexts has increased significantly due to scientific and technological advancements and growing user awareness, requirements and demand

very high

train

AR6_WGI

They require different types of user–producer engagement depending on what the service aims to deliver

high

train

AR6_WGI

Realization of the full potential of climate services is often hindered by limited resources for the co-design and co-production process, including sustained engagement between scientists, service providers and users

high

train

AR6_WGI

An exception is the Southern Annular Mode (SAM), which has become systematically more positive (high confidence) and is projected to be more positive in all seasons, except for December–January–February (DJF), in high CO 2 emissions scenarios

high

train

AR6_WGI

The influence of stratospheric ozone forcing on the SAM trend has been reduced since the early 2000s compared to earlier decades, contributing to the weakening of its positive trend as observed over 2000– 2019

medium

train

AR6_WGI

Along latitudes, it is more uniform, with strong amplification of the temperature response towards the Arctic

medium

train

AR6_WGI

The decrease of SO 2 emissions since the 1980s reduces the damping effect of aerosols, leading to a faster increase in surface air temperature that is most pronounced at mid- and high latitudes of the Northern Hemisphere, where the largest emissions reductions have taken place

medium

train

AR6_WGI

Multi-decadal variation in anthropogenic aerosol emissions are thought to be a major contributor

medium

train

AR6_WGI

Future urbanization will amplify the projected air temperature under different background climates, with a strong effect on minimum temperatures that could be as large as the global warming signal

very high

train

AR6_WGI

Irrigation and crop expansion have attenuated increases in summer hot extremes in some regions, such as central North America

medium

train

AR6_WGI

The influence of stratospheric ozone forcing on the SAM trend has been reduced since the early 2000s compared to earlier decades, contributing to the weakening of its positive trend observed over 2000–2019

medium

train

AR6_WGI

This is because of the opposing influence in the near to mid-term from stratospheric ozone recovery and increases in other greenhouse gases on the Southern Hemisphere summertime mid-latitude circulation

high

train

AR6_WGI

There is no consensus from models for a systematic change in amplitude of ENSO sea surface temperature (SST) variability over the 21st century in any of the SSP scenarios assessed

medium

train

AR6_WGI

Internal variability is the main driver of Pacific Decadal Variability (PDV) observed since the start of the instrumental records

high

train

AR6_WGI

Multiple lines of evidence, combining multi-model ensemble global projections with those coming from single-model initial-condition large ensembles, show that internal variability is largely contributing to the delayed or absent emergence of the anthropogenic signal in long-term regional mean precipitation changes

high

train

AR6_WGI

Internal variability in ocean dynamics dominates regional patterns on annual to decadal time scales

high

train

AR6_WGI

The anthropogenic signal in regional sea level change will emerge in most regions by 2100

medium

train

AR6_WGI

Time evolution of mechanisms operating at different time scales can modify the amplitude of the regional-scale response of temperature, and both the amplitude and sign of the response of precipitation, to anthropogenic forcing

high

train

AR6_WGI

Land-use and aerosol forcings and land–atmosphere feedback play important roles in modulating regional changes, for instance in weather and climate extremes

high

train

AR6_WGI

Multi-model mean and ensemble spread are not sufficient to characterize situations where different models simulate substantially different or even opposite changes

high

train

AR6_WGI

In addition, single-model initial-condition large ensembles of many realizations of internal variability are required to separate internal variability from forced changes

high

train

AR6_WGI

Northern Hemispheric anthropogenic aerosols weakened the regional monsoon circulations in South Asia, East Asia and West Africa during the second half of the 20th century, thereby offsetting the expected strengthening of monsoon precipitation in response to GHG-induced warming

high

train

AR6_WGI

During the 21st century, global land monsoon precipitation is projected to increase in response to GHG warming in all time horizons and scenarios

high

train

AR6_WGI

Over South and South East Asia, East Asia and the central Sahel, monsoon precipitation is projected to increase, whereas over North America and the far western Sahel it is projected to decrease

medium

train

AR6_WGI

At global and regional scales, near-term monsoon changes will be dominated by the effects of internal variability

medium

test

AR6_WGI

Contrary to the expected increase of precipitation under global warming, the Northern Hemisphere monsoon regions experienced declining precipitation from the 1950s to 1980s, which is partly attributable to the influence of anthropogenic aerosols

medium

train

AR6_WGI

A slowdown of the tropical circulation with global warming can partly offset the warming-induced strengthening of precipitation in monsoon regions

high

train

AR6_WGI

In the near term, global monsoon changes are likely to be dominated by the effects of internal variability and model uncertainties

medium

train

AR6_WGI

In the long term, global monsoon rainfall change will feature a robust north–south asymmetry characterized by a greater increase in the Northern Hemisphere than in the Southern Hemisphere and an east–west asymmetry characterized by enhanced Asian– African monsoons and a weakened North American monsoon

medium

train

AR6_WGI

The recent partial recovery and enhanced intensity of monsoon precipitation over West Africa is related to the growing influence of GHGs with an additional contribution due to the reduced cooling effect of anthropogenic aerosols, emitted largely from North America and Europe

medium

train

AR6_WGI

The annual contrast between the wettest and driest month of the year is likely to increase by 3–5% per degree Celsius in most monsoon regions in terms of precipitation, precipitation minus evaporation, and runoff

medium

train

AR6_WGI

For the North American monsoon, projections indicate a decrease in precipitation, whereas increased monsoon rainfall is projected over South and South East Asia and over East Asia

medium

train

AR6_WGI

West African monsoon precipitation is projected to increase over the central Sahel and decrease over the far western Sahel

medium

train

AR6_WGI

A collapse of the Atlantic Meridional Overturning Circulation could weaken the African and Asian monsoons but strengthen the Southern Hemisphere monsoons

high

train

AR6_WGI

It is very likely that mean temperatures have increased in all land regions and will continue to increase at rates greater than the global average

high

test

AR6_WGI

These changes are attributed to human influence in almost all regions (medium to high confidence) and will continue through the 21st century

high

train

AR6_WGI

In particular, extreme heat would exceed critical thresholds for health, agriculture and other sectors more frequently by the mid 21st century with 2°C of global warming

high

train

AR6_WGI

Relative sea level rise is very likely to virtually certain (depending on the region) to continue during the 21st century, contributing to increased coastal flooding in low- lying areas (high confidence) and coastal erosion along most sandy coasts

high

train

AR6_WGI

Sea level will continue to rise beyond 2100

high

train

AR6_WGI

Every region of the world will experience concurrent changes in multiple CIDs by mid-century or at 2°C global warming and above

high

train

AR6_WGI

Changes in many other regional CIDs have higher confidence later in the 21st century or at higher GWLs

high

train

AR6_WGI

In tropical regions, recent past temperature distributions have already shifted to a range different to that of the early 20th century

high

train

AR6_WGI

On regional-to-continental scales, trends of increased frequency of hot extremes and decreased frequency of cold extremes are generally consistent with the global-scale trends in mean temperature

high

train

AR6_WGI

At increasing warming levels, extreme heat will exceed critical thresholds for health, agriculture and other sectors more frequently

high

train

AR6_WGI

For example, by the end of the 21st century, dangerous humid heat thresholds, such as the National Oceanic and Atmospheric Administration (NOAA) heat index (HI) threshold of 41°C, will be exceeded much more frequently under the SSP5-8.5 scenario than under SSP1-2.6 and will affect many regions

high

train

AR6_WGI

In many tropical regions, the number of days per year where a heat index of 41°C is exceeded would increase by more than 100 days relative to the recent past under SSP5-8.5, while this increase will be limited to less than 50 days under SSP1-2.6

high

train

AR6_WGI

The number of days per year where temperature exceeds 35°C would increase by more than 150 days in many tropical areas, such as the Amazon basin and South East Asia, by the end of century for the SSP5-8.5 scenario, while it is expected to increase by less than 60 days in these areas under SSP1-2.6 (except for the Amazon Basin)

high

train

AR6_WGI

However, GHG forcing has driven increased contrasts in precipitation amounts between wet and dry seasons and weather regimes over tropical land areas (medium confidence), with a detectable precipitation increase in the northern high latitudes

high

train

AR6_WGI

The frequency and intensity of heavy precipitation events have increased over a majority of land regions with good observational coverage

high

train

AR6_WGI

A majority of land areas have experienced decreases in available water in dry seasons due to human-induced climate change associated with changes in evapotranspiration

medium

train

AR6_WGI

Global hydrological models project a larger fraction of land areas to be affected by an increase rather than by a decrease in river floods

medium

train

AR6_WGI

Extreme precipitation and pluvial flooding will increase in many regions around the world on almost all continents

high

train

AR6_WGI

The proportion of intense TCs, average peak TC wind speeds, and peak wind speeds of the most intense TCs will increase on the global scale with increasing global warming

high

train

AR6_WGI

Glaciers will continue to shrink and permafrost to thaw in all regions where they are present

high

train

AR6_WGI

Regional sea level change has been the main driver of changes in extreme sea levels across the quasi-global tide gauge network over the 20th century

high

train

AR6_WGI

With the exception of a few regions with substantial land uplift, relative sea level rise is very likely to virtually certain (depending on the region) to continue during the 21st century, contributing to increased coastal flooding in low-lying areas (high confidence) and coastal erosion along most sandy coasts

high

train

AR6_WGI

In the open ocean, acidification, changes in sea ice, and deoxygenation have already emerged in many areas

high

train

AR6_WGI

Marine heatwaves are also expected to increase around the globe over the 21st century

high

train

AR6_WGI

The probability of compound events has increased in the past due to human-induced climate change and will likely continue to increase with further global warming, including for concurrent heatwaves and droughts, compound flooding, and the possibility of connected sectors experiencing multiple regional extreme events at the same time (for example, in multiple breadbaskets)

high

train

AR6_WGI

In a number of regions (Southern Africa, the Mediterranean, North Central America, Western North America, the Amazon regions, South-Western South America, and Australia), increases in one or more of drought, aridity and fire weather

high

train

AR6_WGI

In another group of regions (North-Western, Central and Eastern North America, Arctic regions, North- Western South America, Northern, Western and Central and Eastern Europe, Siberia, Central, South and East Asia, Southern Australia and New Zealand), decreases in snow and/or ice or increases in pluvial/river flooding

high

train

AR6_WGI

Increases in heavy precipitation that can lead to pluvial floods

high

train

AR6_WGI

North Eastern Africa, East Southern Africa and Central Africa have experienced a decline in rainfall since about 1980 and parts of West Africa an increase

high

train