Climate change feedbacks

ThePlanck responseis the additionalthermal radiationobjects emit as they get warmer. Whether Planck response is a climate change feedback depends on the context. Inclimate sciencethe Planck response can be treated as an intrinsic part of warming that is separate fromradiativefeedbacks andcarbon cyclefeedbacks. However, the Planck response is included when calculatingclimate sensitivity.^{[4]: 95–96}

A feedback thatamplifiesan initial change is called apositive feedback^[12]while a feedback thatreducesan initial change is called anegative feedback.^[12]Climate change feedbacks are in the context of global warming, so positive feedbacks enhance warming and negative feedbacks diminish it. Naming a feedbackpositiveornegativedoes not imply that the feedback is good or bad.^[13]

The initial change that triggers a feedback may beexternally forced,or may arise through theclimate system'sinternal variability.^[14]: 2222External forcingrefers to "a forcing agent outside the climate system causing a change in the climate system"^[14]: 2229that may push the climate system in the direction of warming or cooling.^[15][16]External forcings may be human-caused (for example,greenhouse gas emissionsorland use change) or natural (for example,volcanic eruptions).^[14]: 2229

Planck response is "the most fundamental feedback in the climate system".^[19]: 19As the temperature of ablack bodyincreases, the emission of infrared radiation increases with the fourth power of itsabsolute temperatureaccording to theStefan–Boltzmann law.This increases the amount ofoutgoing radiationback into space as the Earth warms.^[18]It is a strong stabilizing response and has sometimes been called the "no-feedback response" because it is anintensive propertyof a thermodynamic system when considered to be purely a function of temperature.^[20]Although Earth has an effectiveemissivityless than unity, the ideal black body radiation emerges as a separable quantity when investigating perturbations to the planet's outgoing radiation.

The Planck "feedback" orPlanck responseis the comparable radiative response obtained from analysis of practical observations orglobal climate models(GCMs). Its expected strength has been most simply estimated from the derivative of theStefan-Boltzmann equationas -4σT³= -3.8 W/m²/K (watts per square meter per degree of warming).^[18][20]Accounting from GCM applications has sometimes yielded a reduced strength, as caused byextensive propertiesof the stratosphere and similarresidual artifactssubsequently identified as being absent from such models.^[20]

Most extensive "grey body" properties of Earth that influence the outgoing radiation are usually postulated to be encompassed by the other GCM feedback components, and to be distributed in accordance with a particularforcing-feedback formulationof the climate system.^[21]Ideally the Planck response strength obtained from GCMs, indirect measurements, and black body estimates will further converge as analysis methods continue to mature.^[20]

According toClausius–Clapeyron relation,saturation vapor pressureis higher in a warmer atmosphere, and so the absolute amount of water vapor will increase as the atmosphere warms. It is sometimes also called thespecific humidityfeedback,^[7]: 969becauserelative humidity(RH) stays practically constant over the oceans, but it decreases over land.^[23]This occurs because land experiences faster warming than the ocean, and a decline in RH has been observed after the year 2000.^[4]: 86

Since water vapor is agreenhouse gas,the increase in water vapor content makes the atmosphere warm further, which allows the atmosphere to hold still more water vapor. Thus, a positive feedback loop is formed, which continues until the negative feedbacks bring the system to equilibrium.^[7]: 969Increases in atmospheric water vapor have been detected fromsatellites,and calculations based on these observations place this feedback strength at 1.85 ± 0.32 m²/K. This is very similar to model estimates, which are at 1.77 ± 0.20 m²/K^[7]: 969Either value effectively doubles the warming that would otherwise occur from CO₂increases alone.^[24]Like with the other physical feedbacks, this is already accounted for in the warming projections underclimate change scenarios.^[11]

Thelapse rateis the rate at which an atmospheric variable, normallytemperatureinEarth's atmosphere,falls withaltitude.^[26][27]It is therefore a quantification of temperature, related to radiation, as a function of altitude, and is not a separate phenomenon in this context. The lapse rate feedback is generally a negative feedback. However, it is in fact a positive feedback in polar regions where it strongly contributed to polar amplified warming, one of the biggest consequences of climate change.^[28]This is because in regions with stronginversions,such as the polar regions, the lapse rate feedback can be positive because the surface warms faster than higher altitudes, resulting in inefficientlongwave cooling.^[29][30][31]

The atmosphere's temperature decreases with height in thetroposphere.Since emission of infrared radiation varies with temperature,longwave radiationescaping to space from the relatively cold upper atmosphere is less than that emitted toward the ground from the lower atmosphere. Thus, the strength of the greenhouse effect depends on the atmosphere's rate of temperature decrease with height. Both theory and climate models indicate that global warming will reduce the rate of temperature decrease with height, producing a negativelapse rate feedbackthat weakens the greenhouse effect.^[29]

Albedois the measure of how strongly the planetary surface can reflect solar radiation, which prevents its absorption and thus has a cooling effect. Brighter and more reflective surfaces have a high albedo and darker surfaces have a low albedo, so they heat up more. The most reflective surfaces areiceandsnow,so surface albedo changes are overwhelmingly associated with what is known as the ice-albedo feedback. A minority of the effect is also associated with changes inphysical oceanography,soil moistureand vegetation cover.^[7]: 970

The presence of ice cover andsea icemakes theNorth Poleand theSouth Polecolder than they would have been without it.^[32]Duringglacial periods,additional ice increases the reflectivity and thus lowers absorption of solar radiation, cooling the planet.^[33]But when warming occurs and the ice melts, darker land or open water takes its place and this causes more warming, which in turn causes more melting. In both cases, a self-reinforcing cycle continues until an equilibrium is found.^[34][35]Consequently, recentArctic sea ice declineis a key reason behind the Arctic warming nearly four times faster than the global average since 1979 (the start of continuous satellite readings), in a phenomenon known asArctic amplification.^[36][37]Conversely, the high stability of ice cover inAntarctica,where theEast Antarctic ice sheetrises nearly 4 km above the sea level, means that it has experienced very little net warming over the past seven decades.^{[38][39][40][41]}

As of 2021, the total surface feedback strength is estimated at 0.35 [0.10 to 0.60] W m²/K.^[4]: 95On its own, Arctic sea ice decline between 1979 and 2011 was responsible for 0.21 (W/m²) ofradiative forcing.This is equivalent to a quarter of impact from CO₂emissions over the same period.^[35]The combined change in all sea ice cover between 1992 and 2018 is equivalent to 10% of all the anthropogenicgreenhouse gas emissions.^[42]Ice-albedo feedback strength is not constant and depends on the rate of ice loss - models project that under high warming, its strength peaks around 2100 and declines afterwards, as most easily melted ice would already be lost by then.^[43]

WhenCMIP5models estimate a total loss of Arctic sea ice cover from June to September (a plausible outcome under higher levels of warming), it increases the global temperatures by 0.19 °C (0.34 °F), with a range of 0.16–0.21 °C, while the regional temperatures would increase by over 1.5 °C (2.7 °F). These calculations include second-order effects such as the impact from ice loss on regional lapse rate, water vapor and cloud feedbacks,^[44]and do not cause "additional" warming on top of the existing model projections.^[45]

Seen from below, clouds emit infrared radiation back to the surface, which has a warming effect; seen from above, clouds reflect sunlight and emit infrared radiation to space, leading to a cooling effect. Low clouds are bright and very reflective, so they lead to strong cooling, while high clouds are too thin and transparent to effectively reflect sunlight, so they cause overall warming.^[47]As a whole, clouds have a substantial cooling effect.^[7]: 1022However, climate change is expected to alter the distribution of cloudtypesin a way which collectively reduces their cooling and thus accelerates overall warming.^[7]: 975While changes to clouds act as a negative feedback in some latitudes,^[25]they represent a clear positive feedback on a global scale.^[4]: 95

As of 2021, cloud feedback strength is estimated at 0.42 [–0.10 to 0.94] W m²/K.^[4]: 95This is the largestconfidence intervalof any climate feedback, and it occurs because some cloud types (most of which are present over the oceans) have been very difficult to observe, so climate models don't have as much data to go on with when they attempt to simulate their behaviour.^[7]: 975Additionally, clouds have been strongly affected byaerosolparticles, mainly from the unfiltered burning ofsulfur-rich fossil fuels such ascoalandbunker fuel.Any estimate of cloud feedback needs to disentangle the effects of so-calledglobal dimmingcaused by these particles as well.^[48][49]

Thus, estimates of cloud feedback differ sharply between climate models. Models with the strongest cloud feedback have the highestclimate sensitivity,which means that they simulate much stronger warming in response to a doubling of CO₂(or equivalentgreenhouse gas) concentrations than the rest.^[9][10]Around 2020, a small fraction of models was found to simulate so much warming as the result that they had contradictedpaleoclimateevidence fromfossils,^[50][51]and their output was effectively excluded from the climate sensitivity estimate of theIPCC Sixth Assessment Report.^{[4]: 93 [52]}

There are positive and negative climate feedbacks from Earth's carbon cycle. Negative feedbacks are large, and play a great role in the studies ofclimate inertiaor of dynamic (time-dependent) climate change. Because they are consideredrelativelyinsensitive to temperature changes, they are sometimes considered separately or disregarded in studies which aim to quantify climate sensitivity.^[21][53]Global warming projections have includedcarbon cyclefeedbacks since theIPCC Fourth Assessment Report(AR4) in 2007.^[54]While the scientific understanding of these feedbacks was limited at the time, it had improved since then.^[55]These positive feedbacks include an increase inwildfirefrequency and severity, substantial losses fromtropical rainforestsdue to fires and drying and tree losses elsewhere.^[8]: 698TheAmazon rainforestis a well-known example due to its enormous size and importance, and because the damage it experiences from climate change is exacerbated by the ongoingdeforestation.The combination of two threats can potentially transform much or all of the rainforest to asavannah-like state,^[56][57][58]although this would most likely require relatively high warming of 3.5 °C (6.3 °F).^[59][60]

Altogether,carbon sinksin the land and ocean absorb around half of the current emissions. Their future absorption is dynamic. In the future, if the emissions decrease, the fraction they absorb willincrease,and they will absorb up to three-quarters of the remaining emissions - yet, theraw amountabsorbed will decrease from the present. On the contrary, if the emissions will increase, then the raw amount absorbed will increase from now, yet the fraction could decline to one-third by the end of the 21st century.^[3]: 20If the emissions remain very high after the 21st century, carbon sinks would eventually be completely overwhelmed, with the ocean sink diminished further and land ecosystems outright becoming a net source.^[8]: 677Hypothetically, very strongcarbon dioxide removalcould also result in land and ocean carbon sinks becoming net sources for several decades.^[8]: 677

FollowingLe Chatelier's principle,the chemical equilibrium of the Earth'scarbon cyclewill shift in response to anthropogenic CO₂emissions. The primary driver of this is the ocean, which absorbs anthropogenic CO₂via the so-calledsolubility pump.At present this accounts for only about one third of the current emissions, but ultimately most (~75%) of the CO₂emitted by human activities will dissolve in the ocean over a period of centuries: "A better approximation of the lifetime of fossil fuel CO₂for public discussion might be 300 years, plus 25% that lasts forever ".^[62]However, the rate at which the ocean will take it up in the future is less certain, and will be affected bystratificationinduced by warming and, potentially, changes in the ocean'sthermohaline circulation.It is believed that the single largest factor in determining the total strength of the global carbon sink is the state of theSouthern Ocean- particularly of theSouthern Ocean overturning circulation.^[5]

Chemical weatheringover the geological long term acts to remove CO₂from the atmosphere. With currentglobal warming,weathering is increasing, demonstrating significant feedbacks between climate and Earth surface.^[63]Biosequestrationalso captures and stores CO₂by biological processes. The formation ofshellsby organisms in the ocean, over a very long time, removes CO₂from the oceans.^[64]The complete conversion of CO₂to limestone takes thousands to hundreds of thousands of years.^[65]

Net primary productivityof plants' andphytoplanktongrows as the increased CO₂fuels their photosynthesis in what is known as theCO2 fertilization effect.Additionally, plants require less water as the atmospheric CO₂concentrations increase, because they lose less moisture toevapotranspirationthrough openstomata(the pores in leaves through which CO₂is absorbed). However, increased droughts in certain regions can still limit plant growth, and the warming beyond optimum conditions has a consistently negative impact. Thus, estimates for the 21st century show that plants would become a lot more abundant at high latitudes near the poles but grow much less near the tropics - there is onlymedium confidencethat tropical ecosystems would gain more carbon relative to now. However, there ishigh confidencethat the total land carbon sink will remain positive.^[8]: 677

Release of gases of biological origin would be affected by global warming, and this includes climate-relevant gases such asmethane,nitrous oxideordimethyl sulfide.^[67][68]Others, such asdimethyl sulfidereleased from oceans, have indirect effects.^[69]Emissions of methane from land (particularlyfrom wetlands) and of nitrous oxide from land and oceans are a known positive feedback.^[70]I.e. long-term warming changes the balance in the methane-related microbial community within freshwater ecosystems so they produce more methane while proportionately less is oxidised to carbon dioxide.^[71]There would also be biogeophysical changes which affect the albedo. For instance,larchin some sub-arctic forests are being replaced bysprucetrees. This has a limited contribution to warming, because larch trees shed their needles in winter and so they end up more extensively covered in snow than the spruce trees which retain their dark needles all year.^[72]

On the other hand, changes in emissions of compounds such sea salt, dimethyl sulphide, dust, ozone and a range of biogenic volatile organic compounds are expected to be negative overall. As of 2021, all of these non-CO₂feedbacks are believed to practically cancel each other out, but there is only low confidence, and the combined feedbacks could be up to 0.25 W m²/K in either direction.^[7]: 967

Permafrost is not included in the estimates above, as it is difficult to model, and the estimates of its role is strongly time-dependent as its carbon pools are depleted at different rates under different warming levels.^[7]: 967Instead, it is treated as a separate process that will contribute to near-term warming, with the best estimates shown below.

The Earth's two remaining ice sheets, theGreenland ice sheetand theAntarctic ice sheet,cover the world's largest island and an entire continent, and both of them are also around 2 km (1 mi) thick on average.^[78][79]Due to this immense size, their response to warming is measured in thousands of years and is believed to occur in two stages.^[7]: 977

The first stage would be the effect from ice melt onthermohaline circulation.Becausemeltwateris completely fresh, it makes it harder for the surface layer of water to sink beneath the lower layers, and this disrupts the exchange of oxygen, nutrients and heat between the layers. This would act as a negative feedback - sometimes estimated as a cooling effect of 0.2 °C (0.36 °F) over a 1000-year average, though the research on these timescales has been limited.^[7]: 977An even longer-term effect is the ice-albedo feedback from ice sheets reaching their ultimate state in response to whatever the long-term temperature change would be. Unless the warming is reversed entirely, this feedback would be positive.^[7]: 977

The total loss of the Greenland Ice Sheet is estimated to add 0.13 °C (0.23 °F) to global warming (with a range of 0.04–0.06 °C), while the loss of the West Antarctic Ice Sheet adds 0.05 °C (0.090 °F) (0.04–0.06 °C), and East Antarctic ice sheet 0.6 °C (1.1 °F)^[44]Total loss of the Greenland ice sheet would also increase regional temperatures in the Arctic by between 0.5 °C (0.90 °F) and 3 °C (5.4 °F), while the regional temperature in Antarctica is likely to go up by 1 °C (1.8 °F) after the loss of the West Antarctic ice sheet and 2 °C (3.6 °F) after the loss of the East Antarctic ice sheet.^[59][60]

These estimates assume that global warming stays at an average of 1.5 °C (2.7 °F). Because of thelogarithmic growthof thegreenhouse effect,^[4]: 80the impact from ice loss would be larger at the slightly lower warming level of 2020s, but it would become lower if the warming proceeds towards higher levels.^[44]While Greenland and the West Antarctic ice sheet are likely committed to melting entirely if the long-term warming is around 1.5 °C (2.7 °F), the East Antarctic ice sheet would not be at risk of complete disappearance until the very high global warming of 5–10 °C (9.0–18.0 °F)^[59][60]

Methane hydrates ormethane clathratesare frozen compounds where a large amount ofmethaneis trapped within acrystalstructure of water, forming a solid similar toice.^[80]On Earth, they generally lie beneathsedimentson theoceanfloors, (approximately 1,100 m (3,600 ft) below the sea level).^[81]Around 2008, there was a serious concern that a large amount of hydrates from relatively shallow deposits in the Arctic, particularly around theEast Siberian Arctic Shelf,could quickly break down and release large amounts of methane, potentially leading to 6 °C (11 °F) within 80 years.^[82][83]Current research shows that hydrates react very slowly to warming, and that it's very difficult for methane to reach the atmosphere after dissociation on the seafloor.^[84][85]Thus, no "detectable" impact on the global temperatures is expected to occur in this century due to methane hydrates.^[8]: 677Some research suggests hydrate dissociation can still cause a warming of 0.4–0.5 °C (0.72–0.90 °F) over several millennia.^[86]

Earth is athermodynamic systemfor which long-term temperature changes follow theglobal energy imbalance(EEIstands forEarth's energy imbalance):

${\displaystyle EEI\equiv ASR-OLR}$

whereASRis the absorbedsolar radiationandOLRis theoutgoing longwave radiationat top of atmosphere. WhenEEIis positive the system is warming, when it is negative they system is cooling, and when it is approximately zero then there is neither warming or cooling. TheASRandOLRterms in this expression encompass many temperature-dependent properties and complex interactions that govern system behavior.^[87]

In order to diagnose that behavior around arelativelystableequilibrium state,one may consider aperturbationtoEEIas indicated by the symbol Δ. Such a perturbation is induced by aradiative forcing(ΔF) which can be natural or man-made. Responses within the system to either return towards the stable state, or to move further away from the stable state are called feedbacksλΔT:

${\displaystyle \Delta EEI=\Delta F+\lambda \Delta T}$.

Collectively the feedbacks are approximated by thelinearizedparameterλand the perturbed temperatureΔTbecause all components of λ (assumed to be first-order to act independently and additively) are also functions of temperature, albeit to varying extents, by definition for a thermodynamic system:

${\displaystyle \lambda =\sum _{i}\lambda _{i}=(\lambda _{wv}+\lambda _{c}+\lambda _{a}+\lambda _{cc}+\lambda _{p}+\lambda _{lr}+...)}$.

Some feedback components having significant influence onEEIare: ${\displaystyle wv}$= water vapor, ${\displaystyle c}$= clouds, ${\displaystyle a}$= surface albedo, ${\displaystyle cc}$= carbon cycle, ${\displaystyle p}$= Planck response, and ${\displaystyle lr}$= lapse rate. All quantities are understood to be global averages, whileTis usually translated to temperature at the surface because of its direct relevance to humans and much other life.^[21]

The negative Planck response, being an especially strong function of temperature, is sometimes factored out to give an expression in terms of the relative feedback gainsg_ifrom other components:

${\displaystyle \lambda =\neg \lambda _{p}\times (1-\sum _{i}g_{i})}$.

For example${\displaystyle g_{wv}\approx 0.5}$for the water vapor feedback.

Within the context of modern numerical climate modelling and analysis, the linearized formulation has limited use. One such use is to diagnose the relative strengths of different feedback mechanisms. An estimate ofclimate sensitivityto a forcing is then obtained for the case where the net feedback remains negative and the system reaches a new equilibrium state (ΔEEI=0) after some time has passed:^{[19]: 19–20}

${\displaystyle \Delta T={\frac {\Delta F}{\lambda _{p}\times (1-\sum _{i}g_{i})}}}$.

Uncertainty over climate change feedbacks has implications for climate policy. For instance, uncertainty over carbon cycle feedbacks may affect targets for reducing greenhouse gas emissions (climate change mitigation).^[89]Emissions targets are often based on a target stabilization level of atmospheric greenhouse gas concentrations, or on a target for limiting global warming to a particular magnitude. Both of these targets (concentrations or temperatures) require an understanding of future changes in the carbon cycle.^[8]: 678

If models incorrectly project future changes in the carbon cycle, then concentration or temperature targets could be missed. For example, if models underestimate the amount of carbon released into the atmosphere due to positive feedbacks (e.g., due to thawing permafrost), then they may also underestimate the extent of emissions reductions necessary to meet a concentration or temperature target.^{[8]: 678 [90]}

• Climate variability and change
• Climate inertia
• Complex system
• Effects of climate change
• Parametrization (climate)
• Tipping points in the climate system