Datasets:

rlacombe

/

ClimateX

like 6

AR6_WGI

Global ocean heat content continued to increase throughout this period, indicating continuous warming of the entire climate system

very high

train

AR6_WGI

Hot extremes also continued to increase during this period over land

high

train

AR6_WGI

Even in a continually warming climate, periods of reduced and increased trends in global surface temperature at decadal time scales will continue to occur in the 21st century

very high

train

AR6_WGI

Simulations and understanding of modes of climate variability, including teleconnections, have improved since AR5

medium

train

AR6_WGI

While anthropogenic forcing has contributed to multi-decadal mean precipitation changes in several regions, internal variability can delay emergence of the anthropogenic signal in long-term precipitation changes in many land regions

high

train

AR6_WGI

Several impact-relevant changes have not yet emerged from natural variability but will emerge sooner or later in this century depending on the emissions scenario

high

train

AR6_WGI

Ocean acidification and deoxygenation have already emerged over most of the global open ocean, as has a reduction in Arctic sea ice

high

train

AR6_WGI

New techniques and analyses drawing on several lines of evidence have provided greater confidence in attributing changes in regional weather and climate extremes to human influence

high

train

AR6_WGI

For example, the difference in observed warming trends between cities and their surroundings can partly be attributed to urbanization

very high

train

AR6_WGI

Multiple attribution approaches support the contribution of human influence to several regional multi-decadal mean precipitation changes

high

train

AR6_WGI

Understanding about past and future changes in weather and climate extremes has increased due to better observation-based datasets, physical understanding of processes, an increasing proportion of scientific literature combining different lines of evidence, and improved accessibility to different types of climate models

high

train

AR6_WGI

In SSP1-2.6 and SSP2-4.5, changes in ERF also explain about half of the changes in the range of warming

medium

train

AR6_WGI

For SSP5-8.5, higher climate sensitivity is the primary reason behind the upper end of the CMIP6- projected warming being higher than for RCP8.5 in CMIP5

medium

train

AR6_WGI

The differences in the few ESMs for which both emissions and concentration-driven runs were available for the same scenario are small and do not affect the assessment of global surface temperature projections discussed in Cross-Section Box TS.1 and Section TS.2

high

train

AR6_WGI

Multiple lines of evidence can be used to construct climate information on a global to regional scale and can be further distilled in a co-production process to meet user needs

high

train

AR6_WGI

Many global and regional climatic impact-drivers have a direct relation to global warming levels

high

train

AR6_WGI

Climate change has already altered CID profiles and resulted in shifting magnitude, frequency, duration, seasonality and spatial extent of associated indices

high

train

AR6_WGI

These include heat, cold, wet and dry hazards, both mean and extremes; cryospheric hazards (snow cover, ice extent, permafrost) and oceanic hazards (marine heatwaves)

high

train

AR6_WGI

Changes in GMST and GSAT over time differ by at most 10% in either direction

high

train

AR6_WGI

Temperatures as high as during the most recent decade (2011–2020) exceed the warmest centennial-scale range reconstructed for the present interglacial, around 6500 years ago [0.2°C to 1°C]

medium

train

AR6_WGI

The next most recent warm period was about 125,000 years ago during the last interglacial when the multi-centennial temperature range [0.5°C to 1.5°C] encompasses the 2011–2020 values

medium

train

AR6_WGI

Global surface temperature in any individual year could exceed 1.5°C relative to 1850–1900 by 2030 with a likelihood between 40% and 60% across the scenarios considered here

medium

train

AR6_WGI

Periods of reduced and increased global surface temperature trends at decadal time scales will continue to occur in the 21st century

very high

train

AR6_WGI

It is likely that there was a net anthropogenic forcing of 0.0–0.3 Wm–2 in 1850–1900 relative to 1750

medium

train

AR6_WGI

Beginning approximately 6500 years ago, global surface temperature generally decreased, culminating in the coldest multi-century interval of the post-glacial period (since roughly 7000 years ago), which occurred between around 1450 and 1850

high

train

AR6_WGI

Over the last 50 years, global surface temperature has increased at an observed rate unprecedented in at least the last two thousand years

high

train

AR6_WGI

Temperatures as high as during the most recent decade (2011–2020) exceed the warmest centennial-scale range reconstructed for the present interglacial, around 6500 years ago [0.2°C to 1°C]

medium

train

AR6_WGI

The next most recent warm period was about 125,000 years ago during the Last Interglacial when the multi-centennial temperature range [0.5°C to 1.5°C] encompasses the 2011–2020 values

medium

train

AR6_WGI

During the mid-Pliocene Warm Period, around 3.3–3.0 million years ago, global surface temperature was 2.5°C to 4°C warmer

medium

train

AR6_WGI

Furthermore, the heating of the climate system continued during this period, as reflected in the continued warming of the global ocean (very high confidence) and in the continued rise of hot extremes over land

medium

train

AR6_WGI

Since 2012, global surface temperature has risen strongly, with the past five years (2016–2020) being the hottest five-year period between 1850 and 2020

high

train

AR6_WGI

Vertical bars are 5–95th percentile ranges of estimated global surface temperature for the Last Interglacial and mid-Holocene

medium

train

AR6_WGI

The other half arises because for central estimates of climate sensitivity, most scenarios show stronger warming over the near term than was estimated as ‘current’ in SR1.5

medium

train

AR6_WGI

If climate sensitivity lies near the lower end of the assessed very likely range, crossing the 1.5°C warming level is avoided in scenarios SSP1-1.9 and SSP1-2.6

medium

train

AR6_WGI

Global surface temperature in any individual year, in contrast to the 20-year average, could by 2030 exceed 1.5°C relative to 1850–1900 with a likelihood between 40% and 60%, across the scenarios considered here

medium

train

AR6_WGI

The uncertainty ranges for the period 2081–2100 continue to be dominated by the uncertainty in equilibrium climate sensitivity and transient climate response

very high

train

AR6_WGI

Continued GHG emissions greatly increase the likelihood of potentially irreversible changes in the global climate system (Box TS.9), in particular with respect to the contribution of ice sheets to global sea level change

high

train

AR6_WGI

Global mean concentrations of anthropogenic aerosols peaked in the late 20th century and have slowly declined since in northern mid-latitudes, although they continue to increase in South Asia and East Africa

high

train

AR6_WGI

The total anthropogenic effective radiative forcing (ERF) in 2019, relative to 1750, was 2.72 [1.96 to 3.48] W m–2

medium

train

AR6_WGI

The average magnitude and variability of volcanic aerosols since 1900 has not been unusual compared to at least the past 2500 years

medium

train

AR6_WGI

The centennial rate of change of CO 2 since 1850 has no precedent in at least the past 800,000 years (Figure TS.9), and the fastest rates of change over the last 56 million years were at least a factor of four lower

low

train

AR6_WGI

The increase since 1750 of 1137 ± 10 ppb (157.8%) far exceeds the range over multiple glacial–interglacial transitions of the past 800,000 years

high

train

AR6_WGI

N 2O concentration trends since 1980 are largely driven by a 30% increase in emissions from the expansion and intensification of global agriculture

high

train

AR6_WGI

Abundances of HFCs, which are replacements for CFCs and HCFCs, are increasing

high

train

AR6_WGI

Ice cores show increases in aerosols across the Northern Hemisphere mid-latitudes since 1700 and reductions since the late 20th century

high

train

AR6_WGI

Aerosol optical depth (AOD), derived from satellite- and ground-based radiometers, has decreased since 2000 over the mid-latitude continents of both hemispheres, but increased over South Asia and East Africa

high

train

AR6_WGI

Global carbonaceous aerosol budgets and trends remain poorly characterized due to limited observations, but black carbon (BC), a warming aerosol component, is declining in several regions of the Northern Hemisphere

low

train

AR6_WGI

Total aerosol ERF in 2019, relative to 1750, is −1.1 [−1.7 to −0.4] W m−2

medium

train

AR6_WGI

Since the mid-20th century, tropospheric ozone surface concentrations have increased by 30–70% across the Northern Hemisphere

medium

train

AR6_WGI

Future changes in surface ozone concentrations will be primarily driven by changes in precursor emissions rather than climate change

high

train

AR6_WGI

Stratospheric ozone has declined between 60°S–60°N by 2.2% from 1964–1980 to 2014–2017

high

train

AR6_WGI

Model estimates suggest no significant change in oxidizing capacity from 1850 to 1980

low

test

AR6_WGI

The proportion of tropical cyclones that are intense is expected to increase (high confidence), but the total global number of tropical cyclones is expected to decrease or remain unchanged

medium

train

AR6_WGI

In the tropics, since at least 2001 (when new techniques permit more robust quantification), the upper troposphere has warmed faster than the near-surface

medium

train

AR6_WGI

This has been accompanied by a strengthening of the Hadley Circulation in the Northern Hemisphere

medium

train

AR6_WGI

It is likely that human influence has contributed to the poleward expansion of the zonal mean Hadley cell in the Southern Hemisphere since the 1980s, which is projected to further expand with global warming

high

train

AR6_WGI

The frequency of intense extratropical cyclones is projected to decrease

medium

train

AR6_WGI

Projected changes in the intensity depend on the resolution of climate models

medium

test

AR6_WGI

With increasing global warming, some very rare extremes and some compound events (multivariate or concurrent extremes) with low likelihood in past and current climate will become more frequent, and there is a higher chance that events unprecedented in the observational record occur

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

Compound events and concurrent extremes contribute to increasing probability of low-likelihood, high-impact outcomes and will become more frequent with increasing global warming

high

train

AR6_WGI

Over the past four to six decades, it is virtually certain that the global ocean has warmed, with human influence extremely likely the main driver since the 1970s, making climate change irreversible over centuries to millennia

medium

train

AR6_WGI

A long-term increase in surface open ocean pH occurred over the past 50 million years, and surface ocean pH as low as recent times is uncommon in the last 2 million years

medium

test

AR6_WGI

Stratification (virtually certain), acidification (virtually certain), deoxygenation (high confidence) and marine heatwave frequency

high

train

AR6_WGI

The ocean is currently warming faster than at any other time since at least the last deglacial transition (medium confidence), with warming extending to depths well below 2000 m

very high

train

AR6_WGI

Ocean warming is irreversible over centuries to millennia, but the magnitude of warming is scenario-dependent from about the mid-21st century

medium

test

AR6_WGI

The warming will not be globally uniform, with heat primarily stored in Southern Ocean water-masses and weaker warming in the subpolar North Atlantic

high

train

AR6_WGI

Marine heatwaves have become more frequent over the 20th century (high confidence), approximately doubling in frequency (high confidence) and becoming more intense and longer since the 1980s

medium

train

AR6_WGI

It is extremely likely that human influence has contributed to this salinity change and that the large-scale pattern will grow in amplitude over the 21st century

medium

train

AR6_WGI

Direct observational records since the mid-2000s are too short to determine the relative contributions of internal variability, natural forcing and anthropogenic forcing to AMOC change

high

train

AR6_WGI

Western boundary currents and subtropical gyres have shifted poleward since 1993

medium

train

AR6_WGI

Subtropical gyres, the East Australian Current Extension, the Agulhas Current, and the Brazil Current are projected to intensify in the 21st century in response to changes in wind stress, while the Gulf Stream and the Indonesian Throughflow are projected to weaken

medium

train

AR6_WGI

All of the four main eastern boundary upwelling systems are projected to weaken at low latitudes and intensify at high latitudes in the 21st century

high

train

AR6_WGI

Ocean acidification and associated reductions in the saturation state of calcium carbonate – a constituent of skeletons or shells of a variety of marine organisms – is expected to increase in the 21st century under all emissions scenarios

high

train

AR6_WGI

A long-term increase in surface open ocean pH occurred over the past 50 million years (high confidence), and surface ocean pH as low as recent times is uncommon in the last 2 million years

medium

train

AR6_WGI

Over the past 2–3 decades, a pH decline in the ocean interior has been observed in all ocean basins

high

train

AR6_WGI

Deoxygenation is projected to continue to increase with ocean warming

high

train

AR6_WGI

The range of a smaller subset of organisms has shifted equatorward and to shallower depths

high

train

AR6_WGI

Phenological metrics associated with the life cycles of many organisms have also changed over the last two decades or longer

high

train

AR6_WGI

The Arctic Ocean is projected to become practically sea ice-free in late summer under high CO 2 emissions scenarios by the end of the 21st century

high

train

AR6_WGI

Glaciers will continue to lose mass at least for several decades even if global temperature is stabilized

very high

train

AR6_WGI

Since the late 1970s, Arctic sea ice area and thickness have decreased in both summer and winter, with sea ice becoming younger, thinner and more dynamic

very high

train

AR6_WGI

It is very likely that anthropogenic forcing, mainly due to greenhouse gas increases, was the main driver of this loss, although new evidence suggests that anthropogenic aerosol forcing has offset part of the greenhouse gas-induced losses since the 1950s

medium

train

AR6_WGI

This practically sea ice-free state will become the norm for late summer by the end of the 21st century in high CO 2 emissions scenarios

high

train

AR6_WGI

Arctic summer sea ice varies approximately linearly with global surface temperature, implying that there is no tipping point and observed/ projected losses are potentially reversible

high

train

AR6_WGI

For each additional 1°C of warming (up to 4°C above the 1850–1900 level), the global volume of perennially frozen ground to 3 m below the surface is projected to decrease by about 25% relative to the present volume

medium

train

AR6_WGI

However, these decreases may be underestimated due to an incomplete representation of relevant physical processes in ESMs

low

train

AR6_WGI

Under RCP2.6 and RCP8.5, respectively, glaciers are projected to lose 18% ± 13% and 36% ± 20% of their current mass over the 21st century

medium

train

AR6_WGI

It is virtually certain that the Greenland Ice Sheet has lost mass since the 1990s, with human influence a contributing factor

medium

train

AR6_WGI

Projections of future Greenland ice-mass loss (Box TS.4, Table 1; Figure TS.11e) are dominated by increased surface melt under all emissions scenarios

high

train

AR6_WGI

The total Antarctic ice mass losses were dominated by the West Antarctic Ice Sheet, with combined West Antarctic and Peninsula annual loss rates increasing since about 2000

very high

test

AR6_WGI

Mass losses from West Antarctic outlet glaciers, mainly induced by ice shelf basal melt (high confidence), outpace mass gain from increased snow accumulation on the continent

very high

train

AR6_WGI

Human activities were very likely the main driver of observed GMSL rise since 1971, and new observational evidence leads to an assessed sea level rise over the period 1901 to 2018 that is consistent with the sum of individual components contributing to sea level rise, including expansion due to ocean warming and melting of glaciers and ice sheets

high

train

AR6_WGI

Sea level responds to greenhouse gas (GHG) emissions more slowly than global surface temperature, leading to weaker scenario dependence over the 21st century than for global surface temperature

high

train

AR6_WGI

This slow response also leads to long-term committed sea level rise, associated with ongoing ocean heat uptake and the slow adjustment of the ice sheets, that will continue over the centuries and millennia following cessation of emissions

high

train

AR6_WGI

By 2100, GMSL is projected to rise by 0.28– 0.55 m (likely range) under SSP1-1.9 and 0.63–1.01 m (likely range) under SSP5-8.5 relative to the 1995–2014 average

medium

train

AR6_WGI

New analyses and paleo-evidence since AR5 show this rate is very likely faster than during any century over at least the last three millennia

high

train

AR6_WGI

Since AR5, there is strengthened evidence for an increase in the rate of GMSL rise since the mid-20th century, with an average rate of 2.3 [1.6–3.1] mm yr–1 over the period 1971–2018 increasing to 3.7 [3.2–4.2] mm yr–1 for the period 2006–2018

high

test

AR6_WGI

By 2300, GMSL will rise 0.3–3.1 m under low CO 2 emissions (SSP1-2.6)

low

train

AR6_WGI

Under high CO 2 emissions (SSP5-8.5), projected GMSL rise is between 1.7 and 6.8 m by 2300 in the absence of MICI and by up to 16 m considering MICI

low

train