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Runaway greenhouse effect

November 28, 2023

Not to be confused with Tipping points in the climate system.

A runaway greenhouse effect occurs when a planet's atmosphere contains greenhouse gas in an amount sufficient to block thermal radiation from leaving the planet, preventing the planet from cooling and from having liquid water on its surface. A runaway version of the greenhouse effect can be defined by a limit on a planet's outgoing longwave radiation which is asymptotically reached due to higher surface temperatures evaporating water into the atmosphere, increasing its optical depth.[2] This positive feedback means the planet cannot cool down through longwave radiation (via the Stefan–Boltzmann law) and continues to heat up until it can radiate outside of the absorption bands[3] of the water vapour.

This 1902 article attributes to Swedish Nobel laureate (for chemistry) Svante Arrhenius a theory that coal combustion could eventually lead to a degree of global warming causing human extinction.[1]

The runaway greenhouse effect is often formulated with water vapour as the condensable species. The water vapour reaches the stratosphere and escapes into space via hydrodynamic escape, resulting in a desiccated planet.[4] This likely happened in the early history of Venus.

A runaway greenhouse effect would have virtually no chance of being caused by people.[5] Venus-like conditions on Earth require a large long-term forcing that is unlikely to occur until the sun brightens by some tens of percents, which will take a few billion years.[6]

History edit

While the term was coined by Caltech scientist Andrew Ingersoll in a paper that described a model of the atmosphere of Venus,[7] the initial idea of a limit on terrestrial outgoing infrared radiation was published by George Simpson in 1927.[8] The physics relevant to the, later-termed, runaway greenhouse effect was explored by Makoto Komabayashi at Nagoya university.[9] Assuming a water vapor-saturated stratosphere, Komabayashi and Ingersoll independently calculated the limit on outgoing infrared radiation that defines the runaway greenhouse state. The limit is now known as the Komabayashi–Ingersoll limit to recognize their contributions.[4]

Physics of the runaway greenhouse edit

 
Graph of tropopause optical depth by tropopause temperature, illustrating the Komabayashi–Ingersoll limit of 385 W/m² using equations and values from Nakajima et al. (1992) "A Study on the Runaway Greenhouse Effect with a One-Dimensional Radiative–Convective Equilibrium Model". The Komabayashi–Ingersoll limit is the value of outgoing longwave radiation (FIRtop) beyond which the lines do not intersect.

The runaway greenhouse effect is often formulated in terms of how the surface temperature of a planet changes with differing amounts of received starlight.[10] If the planet is assumed to be in radiative equilibrium, then the runaway greenhouse state is calculated as the equilibrium state at which water cannot exist in liquid form.[4] The water vapor is then lost to space through hydrodynamic escape.[11] In radiative equilibrium, a planet's outgoing longwave radiation (OLR) must balance the incoming stellar flux.

The Stefan–Boltzmann law is an example of a negative feedback that stabilizes a planet's climate system. If the Earth received more sunlight it would result in a temporary disequilibrium (more energy in than out) and result in warming. However, because the Stefan–Boltzmann response mandates that this hotter planet emits more energy, eventually a new radiation balance can be reached and the temperature will be maintained at its new, higher value.[3] Positive climate change feedbacks amplify changes in the climate system, and can lead to destabilizing effects for the climate.[3] An increase in temperature from greenhouse gases leading to increased water vapor (which is itself a greenhouse gas) causing further warming is a positive feedback, but not a runaway effect, on Earth.[10] Positive feedback effects are common (e.g. ice–albedo feedback) but runaway effects do not necessarily emerge from their presence. Though water plays a major role in the process, the runaway greenhouse effect is not a result of water vapor feedback.[11]

The runaway greenhouse effect can be seen as a limit on a planet's outgoing longwave radiation that, when surpassed, results in a state where water cannot exist in its liquid form (hence, the oceans have all "boiled away").[4] A planet's outgoing longwave radiation is limited by this evaporated water, which is an effective greenhouse gas and blocks additional infrared radiation as it accumulates in the atmosphere.[12] Assuming radiative equilibrium, runaway greenhouse limits on outgoing longwave radiation correspond to limits on the increase in stellar flux received by a planet to trigger the runaway greenhouse effect.[13] Two limits on a planet's outgoing longwave radiation have been calculated that correspond with the onset of the runaway greenhouse effect: the Komabayashi–Ingersoll limit[7][9] and the Simpson–Nakajima limit.[14][4][10] At these values the runaway greenhouse effect overcomes the Stefan–Boltzmann feedback so an increase in a planet's surface temperature will not increase the outgoing longwave radiation.[3]

The Komabayashi–Ingersoll limit was the first to be analytically derived and only considers a grey stratosphere in radiative equilibrium.[7][9] A grey stratosphere (or atmosphere) is an approach to modeling radiative transfer that does not take into account the frequency-dependence of absorption by a gas. In the case of a grey stratosphere or atmosphere, the Eddington approximation can be used to calculate radiative fluxes. This approach focuses on the balance between the outgoing longwave radiation at the tropopause, , and the optical depth of water vapor,  , in the tropopause, which is determined by the temperature and pressure at the tropopause according to the saturation vapor pressure. This balance is represented by the following equations[4]

 
Where the first equation represents the requirement for radiative equilibrium at the tropopause and the second equation represents how much water vapor is present at the tropopause.[4] Taking the outgoing longwave radiation as a free parameter, these equations will intersect only once for a single value of the outgoing longwave radiation, this value is taken as the Komabayashi–Ingersoll limit.[4] At that value the Stefan–Boltzmann feedback breaks down because the tropospheric temperature required to maintain the Komabayashi–Ingersoll OLR value results in a water vapor optical depth that blocks the OLR needed to cool the tropopause.[3]

The Simpson–Nakajima limit is lower than the Komabayashi–Ingersoll limit, and is thus typically more realistic for the value at which a planet enters a runaway greenhouse state.[11] For example, given the parameters used to determine a Komabayashi–Ingersoll limit of 385 W/m2, the corresponding Simpson–Nakajima limit is only about 293 W/m2.[4][10] The Simpson–Nakajima limit builds off of the derivation of the Komabayashi–Ingersoll limit by assuming a convective troposphere with a surface temperature and surface pressure that determines the optical depth and outgoing longwave radiation at the tropopause.[4][10]

The moist greenhouse limit edit

Because the model used to derive the Simpson–Nakajima limit (a grey stratosphere in radiative equilibrium and a convecting troposphere) can determine the water concentration as a function of altitude, the model can also be used to determine the surface temperature (or conversely, amount of stellar flux) that results in a high water mixing ratio in the stratosphere.[10] While this critical value of outgoing longwave radiation is less than the Simpson–Nakajima limit, it still has dramatic effects on a planet's climate. A high water mixing ratio in the stratosphere would overcome the effects of a cold trap and result in a "moist" stratosphere, which would result in the photolysis of water in the stratosphere that in turn would destroy the ozone layer and eventually lead to a dramatic loss of water through hydrodynamic escape.[3][11] This climate state has been dubbed the moist greenhouse effect, as the end-state is a planet without water, though liquid water may exist on the planet's surface during this process.[10]

Connection to habitability edit

The concept of a habitable zone has been used by planetary scientists and astrobiologists to define an orbital region around a star in which a planet (or moon) can sustain liquid water.[15] Under this definition, the inner edge of the habitable zone (i.e., the closest point to a star that a planet can be until it can no longer sustain liquid water) is determined by the outgoing longwave radiation limit beyond which the runaway greenhouse process occurs (e.g., the Simpson–Nakajima limit). This is because a planet's distance from its host star determines the amount of stellar flux the planet receives, which in turn determines the amount of outgoing longwave radiation the planet radiates back to space.[3] While the inner habitable zone is typically determined by using the Simpson–Nakajima limit, it can also be determined with respect to the moist greenhouse limit,[13] though the difference between the two is often small.[16]

Calculating the inner edge of the habitable zone is strongly dependent on the model used to calculate the Simpson–Nakajima or moist greenhouse limit.[3] The climate models used to calculate these limits have evolved over time, with some models assuming a simple one-dimensional, grey atmosphere,[4] and others using a full radiative transfer solution to model the absorption bands of water and carbon dioxide.[10] These earlier models that used radiative transfer derived the absorption coefficients for water from the HITRAN database, while newer models[17] use the more current and accurate HITEMP database, which has led to different calculated values of thermal radiation limits. More accurate calculations have been done using three-dimensional climate models[18] that take into account effects such as planetary rotation and local water mixing ratios as well as cloud feedbacks.[19] The effect of clouds on calculating thermal radiation limits is still in debate (specifically, whether or not water clouds present a positive or negative feedback effect).[3]

Runaway greenhouse effect in the Solar System edit

Venus edit

 
Venus' oceans may have boiled away in a runaway greenhouse effect.

A runaway greenhouse effect involving carbon dioxide and water vapor likely occurred on Venus.[20] In this scenario, early Venus may have had a global ocean if the outgoing thermal radiation was below the Simpson–Nakajima limit but above the moist greenhouse limit.[3] As the brightness of the early Sun increased, the amount of water vapor in the atmosphere increased, increasing the temperature and consequently increasing the evaporation of the ocean, leading eventually to the situation in which the oceans evaporated.

This scenario helps to explain why there is little water vapor in the atmosphere of Venus today. If Venus initially formed with water, the runaway greenhouse effect would have hydrated Venus' stratosphere,[10] and the water would have escaped to space.[7] Some evidence for this scenario comes from the extremely high deuterium to hydrogen ratio in Venus' atmosphere, roughly 150 times that of Earth, since light hydrogen would escape from the atmosphere more readily than its heavier isotope, deuterium.[21][22]

Venus is sufficiently strongly heated by the Sun that water vapor can rise much higher in the atmosphere and be split into hydrogen and oxygen by ultraviolet light. The hydrogen can then escape from the atmosphere while the oxygen recombines or bonds to iron on the planet's surface.[3] The deficit of water on Venus due to the runaway greenhouse effect is thought to explain why Venus does not exhibit surface features consistent with plate tectonics,[23] meaning it would be a stagnant lid planet.[24]

Carbon dioxide, the dominant greenhouse gas in the current Venusian atmosphere, owes its larger concentration to the weakness of carbon recycling as compared to Earth, where the carbon dioxide emitted from volcanoes is efficiently subducted into the Earth by plate tectonics on geologic time scales through the carbonate–silicate cycle,[25] which requires precipitation to function.[26]

Earth edit

Early investigations on the effect of atmospheric carbon dioxide levels on the runaway greenhouse limit found that it would take orders of magnitude higher amounts of carbon dioxide to take the Earth to a runaway greenhouse state.[10] This is because carbon dioxide is not anywhere near as effective at blocking outgoing longwave radiation as water is.[7] Within current models of the runaway greenhouse effect, carbon dioxide (especially anthropogenic carbon dioxide) does not seem capable of providing the necessary insulation for Earth to reach the Simpson–Nakajima limit.[10][11][5][6]

Debate remains, however, on whether carbon dioxide can push surface temperatures towards the moist greenhouse limit.[27][28] Climate scientist John Houghton wrote in 2005 that "[there] is no possibility of [Venus's] runaway greenhouse conditions occurring on the Earth".[29] However, climatologist James Hansen stated in Storms of My Grandchildren (2009) that burning coal and mining oil sands will result in runaway greenhouse on Earth.[30] A re-evaluation in 2013 of the effect of water vapor in the climate models showed that James Hansen's outcome would require ten times the amount of CO2 we could release from burning all the oil, coal, and natural gas in Earth's crust.[27]

As with the uncertainties in calculating the inner edge of the habitable zone, the uncertainty in whether CO2 can drive a moist greenhouse effect is due to differences in modeling choices and the uncertainties therein.[11][3] The switch from using HITRAN to the more current HITEMP absorption line lists in radiative transfer calculations has shown that previous runaway greenhouse limits were too high, but the necessary amount of carbon dioxide would make an anthropogenic moist greenhouse state unlikely.[31] Full three-dimensional models have shown that the moist greenhouse limit on surface temperature is higher than that found in one-dimensional models and thus would require a higher amount of carbon dioxide to initiate a moist greenhouse than in one-dimensional models.[18]

Other complications include whether the atmosphere is saturated or sub-saturated at some humidity,[18] higher CO2 levels in the atmosphere resulting in a less hot Earth than expected due to Rayleigh scattering,[3] and whether cloud feedbacks stabilize or destabilize the climate system.[19][18]

Complicating the matter, research on Earth's climate history has often used the term "runaway greenhouse effect" to describe large-scale climate changes when it is not an appropriate description as it does not depend on Earth's outgoing longwave radiation. Though the Earth has experienced a diversity of climate extremes, these are not end-states of climate evolution and have instead represented climate equilibria different from that seen on Earth today.[3] For example, it has been hypothesized that large releases of greenhouse gases may have occurred concurrently with the Permian–Triassic extinction event[32][33] or Paleocene–Eocene Thermal Maximum. Additionally, during 80% of the latest 500 million years, the Earth is believed to have been in a greenhouse state due to the greenhouse effect, when there were no continental glaciers on the planet, the levels of carbon dioxide and other greenhouse gases (such as water vapor and methane) were high, and sea surface temperatures (SSTs) ranged from 40 °C (104 °F) in the tropics to 16 °C (65 °F) in the polar regions.[34]

Distant future edit

See also: Future of Earth

Most scientists believe that a runaway greenhouse effect is inevitable in the long term, as the Sun gradually becomes more luminous as it ages, and spell the end of all life on Earth. As the Sun becomes 10% brighter about one billion years from now, the surface temperature of Earth will reach 47 °C (117 °F) (unless Albedo is increased sufficiently), causing the temperature of Earth to rise rapidly and its oceans to boil away until it becomes a greenhouse planet, similar to Venus today.

 
If countries cut greenhouse gas emissions significantly (lowest trace), the IPCC expects sea level rise by 2100 to be limited to 0.3 to 0.6 meters (1–2 feet).[35] However, in a worst case scenario (top trace), sea levels could rise 5 meters (16 feet) by the year 2300.[35]

According to the astrobiologists Peter Ward and Donald Brownlee in their book The Life and Death of Planet Earth,[36] the current loss rate is approximately one millimeter of ocean per million years due to the colder upper layer of the troposphere acting as a cold trap currently preventing Earth from permanently losing its water to space at present, even with manmade global warming (this is why manmade climate change in the near future will make extreme weather patterns worse in the short term, as a warmer atmosphere can hold more moisture due to it still being too cold to allow water vapor to escape into space), as well as being overshadowed by shorter-term changes in sea level, such as the currently rising sea level due to the melting of glaciers and polar ice, but the rate is gradually accelerating, as the sun gets warmer, to perhaps as fast as one millimeter every 1000 years, by ultimately making the atmosphere so hot that the cold trap is pushed even higher up until it eventually fails to prevent the water from being lost to space. Ward and Brownlee predict that there will be two variations of the future warming feedback: the "moist greenhouse" in which water vapor dominates the troposphere and starts to accumulate in the stratosphere and the "runaway greenhouse" in which water vapor becomes a dominant component of the atmosphere such that the Earth starts to undergo rapid warming, which could send its surface temperature to over 900 °C (1,650 °F), causing its entire surface to melt and killing all life, perhaps about three billion years from now. In both cases, the moist and runaway greenhouse states the loss of oceans will turn the Earth into a primarily-desert world. The only water left on the planet would be in a few evaporating ponds scattered near the poles as well as huge salt flats around what was once the ocean floor, much like the Atacama Desert in Chile or Badwater Basin in Death Valley. The small reservoirs of water may allow life to remain for a few billion more years.

As the Sun brightens, CO2 levels should decrease due to an increase of activity in the carbon-silicate cycle corresponding to the increase of temperature. That would mitigate some of the heating Earth would experience because of the Sun's increase in brightness.[3] Eventually, however, as the water escapes, the carbon cycle will cease as plate tectonics come to a halt because of the need for water as a lubricant for tectonic activity.[24]

Runaway refrigerator effect edit

Mars may have experienced the opposite of a runaway greenhouse effect: a runaway refrigerator effect. Through this effect, a runaway feedback process may have removed much of the carbon dioxide and water vapor from the atmosphere and cooled the planet. Water condensed on the surface, which led to carbon dioxide dissolving in the water and chemically binding to minerals. This reduced the greenhouse effect, lowering the temperature, causing more water to condense. The end result was lower temperatures, with water being frozen as subsurface permafrost, leaving only a thin atmosphere.[37][38]

See also edit

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Further reading edit

  • Steffen, Will; Rockström, Johan; Richardson, Katherine; Lenton, Timothy M.; Folke, Carl; Liverman, Diana; Summerhayes, Colin P.; Barnosky, Anthony D.; Cornell, Sarah E.; Crucifix, Michel; Donges, Jonathan F.; Fetzer, Ingo; Lade, Steven J.; Scheffer, Marten; Winkelmann, Ricarda; Schellnhuber, Hans Joachim (6 August 2018). "Trajectories of the Earth System in the Anthropocene". Proceedings of the National Academy of Sciences. 115 (33): 8252–8259. Bibcode:2018PNAS..115.8252S. doi:10.1073/pnas.1810141115. ISSN 0027-8424. PMC 6099852. PMID 30082409. We explore the risk that self-reinforcing feedbacks could push the Earth System toward a planetary threshold that, if crossed, could prevent stabilization of the climate at intermediate temperature rises and cause continued warming on a "Hothouse Earth" pathway even as human emissions are reduced. Crossing the threshold would lead to a much higher global average temperature than any interglacial in the past 1.2 million years and to sea levels significantly higher than at any time in the Holocene.

November 28, 2023
runaway, greenhouse, effect, confused, with, tipping, points, climate, system, runaway, greenhouse, effect, occurs, when, planet, atmosphere, contains, greenhouse, amount, sufficient, block, thermal, radiation, from, leaving, planet, preventing, planet, from, . Not to be confused with Tipping points in the climate system A runaway greenhouse effect occurs when a planet s atmosphere contains greenhouse gas in an amount sufficient to block thermal radiation from leaving the planet preventing the planet from cooling and from having liquid water on its surface A runaway version of the greenhouse effect can be defined by a limit on a planet s outgoing longwave radiation which is asymptotically reached due to higher surface temperatures evaporating water into the atmosphere increasing its optical depth 2 This positive feedback means the planet cannot cool down through longwave radiation via the Stefan Boltzmann law and continues to heat up until it can radiate outside of the absorption bands 3 of the water vapour This 1902 article attributes to Swedish Nobel laureate for chemistry Svante Arrhenius a theory that coal combustion could eventually lead to a degree of global warming causing human extinction 1 The runaway greenhouse effect is often formulated with water vapour as the condensable species The water vapour reaches the stratosphere and escapes into space via hydrodynamic escape resulting in a desiccated planet 4 This likely happened in the early history of Venus A runaway greenhouse effect would have virtually no chance of being caused by people 5 Venus like conditions on Earth require a large long term forcing that is unlikely to occur until the sun brightens by some tens of percents which will take a few billion years 6 Contents 1 History 2 Physics of the runaway greenhouse 2 1 The moist greenhouse limit 3 Connection to habitability 4 Runaway greenhouse effect in the Solar System 4 1 Venus 4 2 Earth 4 2 1 Distant future 5 Runaway refrigerator effect 6 See also 7 References 8 Further readingHistory editWhile the term was coined by Caltech scientist Andrew Ingersoll in a paper that described a model of the atmosphere of Venus 7 the initial idea of a limit on terrestrial outgoing infrared radiation was published by George Simpson in 1927 8 The physics relevant to the later termed runaway greenhouse effect was explored by Makoto Komabayashi at Nagoya university 9 Assuming a water vapor saturated stratosphere Komabayashi and Ingersoll independently calculated the limit on outgoing infrared radiation that defines the runaway greenhouse state The limit is now known as the Komabayashi Ingersoll limit to recognize their contributions 4 Physics of the runaway greenhouse edit nbsp Graph of tropopause optical depth by tropopause temperature illustrating the Komabayashi Ingersoll limit of 385 W m using equations and values from Nakajima et al 1992 A Study on the Runaway Greenhouse Effect with a One Dimensional Radiative Convective Equilibrium Model The Komabayashi Ingersoll limit is the value of outgoing longwave radiation FIRtop beyond which the lines do not intersect The runaway greenhouse effect is often formulated in terms of how the surface temperature of a planet changes with differing amounts of received starlight 10 If the planet is assumed to be in radiative equilibrium then the runaway greenhouse state is calculated as the equilibrium state at which water cannot exist in liquid form 4 The water vapor is then lost to space through hydrodynamic escape 11 In radiative equilibrium a planet s outgoing longwave radiation OLR must balance the incoming stellar flux The Stefan Boltzmann law is an example of a negative feedback that stabilizes a planet s climate system If the Earth received more sunlight it would result in a temporary disequilibrium more energy in than out and result in warming However because the Stefan Boltzmann response mandates that this hotter planet emits more energy eventually a new radiation balance can be reached and the temperature will be maintained at its new higher value 3 Positive climate change feedbacks amplify changes in the climate system and can lead to destabilizing effects for the climate 3 An increase in temperature from greenhouse gases leading to increased water vapor which is itself a greenhouse gas causing further warming is a positive feedback but not a runaway effect on Earth 10 Positive feedback effects are common e g ice albedo feedback but runaway effects do not necessarily emerge from their presence Though water plays a major role in the process the runaway greenhouse effect is not a result of water vapor feedback 11 The runaway greenhouse effect can be seen as a limit on a planet s outgoing longwave radiation that when surpassed results in a state where water cannot exist in its liquid form hence the oceans have all boiled away 4 A planet s outgoing longwave radiation is limited by this evaporated water which is an effective greenhouse gas and blocks additional infrared radiation as it accumulates in the atmosphere 12 Assuming radiative equilibrium runaway greenhouse limits on outgoing longwave radiation correspond to limits on the increase in stellar flux received by a planet to trigger the runaway greenhouse effect 13 Two limits on a planet s outgoing longwave radiation have been calculated that correspond with the onset of the runaway greenhouse effect the Komabayashi Ingersoll limit 7 9 and the Simpson Nakajima limit 14 4 10 At these values the runaway greenhouse effect overcomes the Stefan Boltzmann feedback so an increase in a planet s surface temperature will not increase the outgoing longwave radiation 3 The Komabayashi Ingersoll limit was the first to be analytically derived and only considers a grey stratosphere in radiative equilibrium 7 9 A grey stratosphere or atmosphere is an approach to modeling radiative transfer that does not take into account the frequency dependence of absorption by a gas In the case of a grey stratosphere or atmosphere the Eddington approximation can be used to calculate radiative fluxes This approach focuses on the balance between the outgoing longwave radiation at the tropopause F IRtop textstyle F text IRtop uparrow nbsp and the optical depth of water vapor t tp textstyle tau text tp nbsp in the tropopause which is determined by the temperature and pressure at the tropopause according to the saturation vapor pressure This balance is represented by the following equations 4 1 2 F IRtop 3 2 t tp 1 s T tp 4 t tp k v p T tp 1 g m v m displaystyle begin aligned frac 1 2 F text IRtop uparrow left frac 3 2 tau text tp 1 right amp sigma T text tp 4 tau text tp amp kappa v p T text tp frac 1 g frac m v bar m end aligned nbsp Where the first equation represents the requirement for radiative equilibrium at the tropopause and the second equation represents how much water vapor is present at the tropopause 4 Taking the outgoing longwave radiation as a free parameter these equations will intersect only once for a single value of the outgoing longwave radiation this value is taken as the Komabayashi Ingersoll limit 4 At that value the Stefan Boltzmann feedback breaks down because the tropospheric temperature required to maintain the Komabayashi Ingersoll OLR value results in a water vapor optical depth that blocks the OLR needed to cool the tropopause 3 The Simpson Nakajima limit is lower than the Komabayashi Ingersoll limit and is thus typically more realistic for the value at which a planet enters a runaway greenhouse state 11 For example given the parameters used to determine a Komabayashi Ingersoll limit of 385 W m2 the corresponding Simpson Nakajima limit is only about 293 W m2 4 10 The Simpson Nakajima limit builds off of the derivation of the Komabayashi Ingersoll limit by assuming a convective troposphere with a surface temperature and surface pressure that determines the optical depth and outgoing longwave radiation at the tropopause 4 10 The moist greenhouse limit edit Because the model used to derive the Simpson Nakajima limit a grey stratosphere in radiative equilibrium and a convecting troposphere can determine the water concentration as a function of altitude the model can also be used to determine the surface temperature or conversely amount of stellar flux that results in a high water mixing ratio in the stratosphere 10 While this critical value of outgoing longwave radiation is less than the Simpson Nakajima limit it still has dramatic effects on a planet s climate A high water mixing ratio in the stratosphere would overcome the effects of a cold trap and result in a moist stratosphere which would result in the photolysis of water in the stratosphere that in turn would destroy the ozone layer and eventually lead to a dramatic loss of water through hydrodynamic escape 3 11 This climate state has been dubbed the moist greenhouse effect as the end state is a planet without water though liquid water may exist on the planet s surface during this process 10 Connection to habitability editThe concept of a habitable zone has been used by planetary scientists and astrobiologists to define an orbital region around a star in which a planet or moon can sustain liquid water 15 Under this definition the inner edge of the habitable zone i e the closest point to a star that a planet can be until it can no longer sustain liquid water is determined by the outgoing longwave radiation limit beyond which the runaway greenhouse process occurs e g the Simpson Nakajima limit This is because a planet s distance from its host star determines the amount of stellar flux the planet receives which in turn determines the amount of outgoing longwave radiation the planet radiates back to space 3 While the inner habitable zone is typically determined by using the Simpson Nakajima limit it can also be determined with respect to the moist greenhouse limit 13 though the difference between the two is often small 16 Calculating the inner edge of the habitable zone is strongly dependent on the model used to calculate the Simpson Nakajima or moist greenhouse limit 3 The climate models used to calculate these limits have evolved over time with some models assuming a simple one dimensional grey atmosphere 4 and others using a full radiative transfer solution to model the absorption bands of water and carbon dioxide 10 These earlier models that used radiative transfer derived the absorption coefficients for water from the HITRAN database while newer models 17 use the more current and accurate HITEMP database which has led to different calculated values of thermal radiation limits More accurate calculations have been done using three dimensional climate models 18 that take into account effects such as planetary rotation and local water mixing ratios as well as cloud feedbacks 19 The effect of clouds on calculating thermal radiation limits is still in debate specifically whether or not water clouds present a positive or negative feedback effect 3 Runaway greenhouse effect in the Solar System editVenus edit nbsp Venus oceans may have boiled away in a runaway greenhouse effect A runaway greenhouse effect involving carbon dioxide and water vapor likely occurred on Venus 20 In this scenario early Venus may have had a global ocean if the outgoing thermal radiation was below the Simpson Nakajima limit but above the moist greenhouse limit 3 As the brightness of the early Sun increased the amount of water vapor in the atmosphere increased increasing the temperature and consequently increasing the evaporation of the ocean leading eventually to the situation in which the oceans evaporated This scenario helps to explain why there is little water vapor in the atmosphere of Venus today If Venus initially formed with water the runaway greenhouse effect would have hydrated Venus stratosphere 10 and the water would have escaped to space 7 Some evidence for this scenario comes from the extremely high deuterium to hydrogen ratio in Venus atmosphere roughly 150 times that of Earth since light hydrogen would escape from the atmosphere more readily than its heavier isotope deuterium 21 22 Venus is sufficiently strongly heated by the Sun that water vapor can rise much higher in the atmosphere and be split into hydrogen and oxygen by ultraviolet light The hydrogen can then escape from the atmosphere while the oxygen recombines or bonds to iron on the planet s surface 3 The deficit of water on Venus due to the runaway greenhouse effect is thought to explain why Venus does not exhibit surface features consistent with plate tectonics 23 meaning it would be a stagnant lid planet 24 Carbon dioxide the dominant greenhouse gas in the current Venusian atmosphere owes its larger concentration to the weakness of carbon recycling as compared to Earth where the carbon dioxide emitted from volcanoes is efficiently subducted into the Earth by plate tectonics on geologic time scales through the carbonate silicate cycle 25 which requires precipitation to function 26 Earth edit Early investigations on the effect of atmospheric carbon dioxide levels on the runaway greenhouse limit found that it would take orders of magnitude higher amounts of carbon dioxide to take the Earth to a runaway greenhouse state 10 This is because carbon dioxide is not anywhere near as effective at blocking outgoing longwave radiation as water is 7 Within current models of the runaway greenhouse effect carbon dioxide especially anthropogenic carbon dioxide does not seem capable of providing the necessary insulation for Earth to reach the Simpson Nakajima limit 10 11 5 6 Debate remains however on whether carbon dioxide can push surface temperatures towards the moist greenhouse limit 27 28 Climate scientist John Houghton wrote in 2005 that there is no possibility of Venus s runaway greenhouse conditions occurring on the Earth 29 However climatologist James Hansen stated in Storms of My Grandchildren 2009 that burning coal and mining oil sands will result in runaway greenhouse on Earth 30 A re evaluation in 2013 of the effect of water vapor in the climate models showed that James Hansen s outcome would require ten times the amount of CO2 we could release from burning all the oil coal and natural gas in Earth s crust 27 As with the uncertainties in calculating the inner edge of the habitable zone the uncertainty in whether CO2 can drive a moist greenhouse effect is due to differences in modeling choices and the uncertainties therein 11 3 The switch from using HITRAN to the more current HITEMP absorption line lists in radiative transfer calculations has shown that previous runaway greenhouse limits were too high but the necessary amount of carbon dioxide would make an anthropogenic moist greenhouse state unlikely 31 Full three dimensional models have shown that the moist greenhouse limit on surface temperature is higher than that found in one dimensional models and thus would require a higher amount of carbon dioxide to initiate a moist greenhouse than in one dimensional models 18 Other complications include whether the atmosphere is saturated or sub saturated at some humidity 18 higher CO2 levels in the atmosphere resulting in a less hot Earth than expected due to Rayleigh scattering 3 and whether cloud feedbacks stabilize or destabilize the climate system 19 18 Complicating the matter research on Earth s climate history has often used the term runaway greenhouse effect to describe large scale climate changes when it is not an appropriate description as it does not depend on Earth s outgoing longwave radiation Though the Earth has experienced a diversity of climate extremes these are not end states of climate evolution and have instead represented climate equilibria different from that seen on Earth today 3 For example it has been hypothesized that large releases of greenhouse gases may have occurred concurrently with the Permian Triassic extinction event 32 33 or Paleocene Eocene Thermal Maximum Additionally during 80 of the latest 500 million years the Earth is believed to have been in a greenhouse state due to the greenhouse effect when there were no continental glaciers on the planet the levels of carbon dioxide and other greenhouse gases such as water vapor and methane were high and sea surface temperatures SSTs ranged from 40 C 104 F in the tropics to 16 C 65 F in the polar regions 34 Distant future edit See also Future of Earth Most scientists believe that a runaway greenhouse effect is inevitable in the long term as the Sun gradually becomes more luminous as it ages and spell the end of all life on Earth As the Sun becomes 10 brighter about one billion years from now the surface temperature of Earth will reach 47 C 117 F unless Albedo is increased sufficiently causing the temperature of Earth to rise rapidly and its oceans to boil away until it becomes a greenhouse planet similar to Venus today nbsp If countries cut greenhouse gas emissions significantly lowest trace the IPCC expects sea level rise by 2100 to be limited to 0 3 to 0 6 meters 1 2 feet 35 However in a worst case scenario top trace sea levels could rise 5 meters 16 feet by the year 2300 35 According to the astrobiologists Peter Ward and Donald Brownlee in their book The Life and Death of Planet Earth 36 the current loss rate is approximately one millimeter of ocean per million years due to the colder upper layer of the troposphere acting as a cold trap currently preventing Earth from permanently losing its water to space at present even with manmade global warming this is why manmade climate change in the near future will make extreme weather patterns worse in the short term as a warmer atmosphere can hold more moisture due to it still being too cold to allow water vapor to escape into space as well as being overshadowed by shorter term changes in sea level such as the currently rising sea level due to the melting of glaciers and polar ice but the rate is gradually accelerating as the sun gets warmer to perhaps as fast as one millimeter every 1000 years by ultimately making the atmosphere so hot that the cold trap is pushed even higher up until it eventually fails to prevent the water from being lost to space Ward and Brownlee predict that there will be two variations of the future warming feedback the moist greenhouse in which water vapor dominates the troposphere and starts to accumulate in the stratosphere and the runaway greenhouse in which water vapor becomes a dominant component of the atmosphere such that the Earth starts to undergo rapid warming which could send its surface temperature to over 900 C 1 650 F causing its entire surface to melt and killing all life perhaps about three billion years from now In both cases the moist and runaway greenhouse states the loss of oceans will turn the Earth into a primarily desert world The only water left on the planet would be in a few evaporating ponds scattered near the poles as well as huge salt flats around what was once the ocean floor much like the Atacama Desert in Chile or Badwater Basin in Death Valley The small reservoirs of water may allow life to remain for a few billion more years As the Sun brightens CO2 levels should decrease due to an increase of activity in the carbon silicate cycle corresponding to the increase of temperature That would mitigate some of the heating Earth would experience because of the Sun s increase in brightness 3 Eventually however as the water escapes the carbon cycle will cease as plate tectonics come to a halt because of the need for water as a lubricant for tectonic activity 24 Runaway refrigerator effect editMars may have experienced the opposite of a runaway greenhouse effect a runaway refrigerator effect Through this effect a runaway feedback process may have removed much of the carbon dioxide and water vapor from the atmosphere and cooled the planet Water condensed on the surface which led to carbon dioxide dissolving in the water and chemically binding to minerals This reduced the greenhouse effect lowering the temperature causing more water to condense The end result was lower temperatures with water being frozen as subsurface permafrost leaving only a thin atmosphere 37 38 See also edit nbsp Climate change portalAtmosphere of Venus an example of a runaway greenhouse effect Greenhouse and icehouse Earth TRAPPIST 1bReferences edit Hint to Coal Consumers The Selma Morning Times Selma Alabama US 15 October 1902 p 4 Carbonic acid refers to carbon dioxide when dissolved in water Kaltenegger Lisa 2015 Greenhouse Effect In Gargaud Muriel Irvine William M Amils Ricardo Cleaves Henderson James eds Encyclopedia of Astrobiology Springer Berlin Heidelberg p 1018 doi 10 1007 978 3 662 44185 5 673 ISBN 9783662441848 a b c d e f g h i j k l m n o Catling David C Kasting James F 13 April 2017 Atmospheric evolution on inhabited and lifeless worlds Cambridge ISBN 9780521844123 OCLC 956434982 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link a b c d e f g h i j k Nakajima Shinichi Hayashi Yoshi Yuki Abe Yutaka 1992 A Study on the Runaway Greenhouse Effect with a One Dimensional Radiative Convective Equilibrium Model J Atmos Sci 49 23 2256 2266 Bibcode 1992JAtS 49 2256N doi 10 1175 1520 0469 1992 049 lt 2256 asotge gt 2 0 co 2 a b Scoping of the IPCC 5th Assessment Report Cross Cutting Issues PDF Thirty first Session of the IPCC Bali 26 29 October 2009 Report Archived PDF from the original on 9 November 2009 Retrieved 24 March 2019 a b Hansen James Sato Makiko Russell Gary Kharecha Pushker 2013 Climate sensitivity sea level and atmospheric carbon dioxide Philosophical Transactions of the Royal Society A Mathematical Physical and Engineering Sciences 371 2001 20120294 arXiv 1211 4846 Bibcode 2013RSPTA 37120294H doi 10 1098 rsta 2012 0294 PMC 3785813 PMID 24043864 a b c d e Ingersoll Andrew P 1969 The Runaway Greenhouse A History of Water on Venus PDF Journal of the Atmospheric Sciences 26 6 1191 1198 Bibcode 1969JAtS 26 1191I doi 10 1175 1520 0469 1969 026 lt 1191 TRGAHO gt 2 0 CO 2 G C SIMPSON C B F R S ON SOME STUDIES IN TERRESTRIAL RADIATION Vol 2 No 16 Published March 1928 Quarterly Journal of the Royal Meteorological Society 55 229 73 1929 Bibcode 1929QJRMS 55Q 73 doi 10 1002 qj 49705522908 ISSN 1477 870X a b c Komabayasi M 1967 Discrete Equilibrium Temperatures of a Hypothetical Planet with the Atmosphere and the Hydrosphere of One Component Two Phase System under Constant Solar Radiation Journal of the Meteorological Society of Japan Series II 45 1 137 139 doi 10 2151 jmsj1965 45 1 137 ISSN 0026 1165 a b c d e f g h i j k Kasting J F 1988 Runaway and moist greenhouse atmospheres and the evolution of Earth and Venus Icarus 74 3 472 494 Bibcode 1988Icar 74 472K doi 10 1016 0019 1035 88 90116 9 PMID 11538226 a b c d e f Goldblatt Colin Watson Andrew J 13 September 2012 The runaway greenhouse implications for future climate change geoengineering and planetary atmospheres Philosophical Transactions of the Royal Society A Mathematical Physical and Engineering Sciences 370 1974 4197 4216 arXiv 1201 1593 Bibcode 2012RSPTA 370 4197G doi 10 1098 rsta 2012 0004 PMID 22869797 S2CID 7891446 Greenhouse Gases Monitoring References National Centers for Environmental Information NCEI www ncdc noaa gov Retrieved 6 June 2019 a b Kopparapu Ravi Kumar Ramirez Ramses Kasting James F Eymet Vincent Robinson Tyler D Mahadevan Suvrath Terrien Ryan C Domagal Goldman Shawn Meadows Victoria 26 February 2013 Habitable Zones Around Main Sequence Stars New Estimates The Astrophysical Journal 765 2 131 arXiv 1301 6674 Bibcode 2013ApJ 765 131K doi 10 1088 0004 637X 765 2 131 ISSN 0004 637X S2CID 76651902 G C SIMPSON C B F R S ON SOME STUDIES IN TERRESTRIAL RADIATION Vol 2 No 16 Published March 1928 Quarterly Journal of the Royal Meteorological Society 55 229 73 1929 Bibcode 1929QJRMS 55Q 73 doi 10 1002 qj 49705522908 ISSN 1477 870X Kasting James F Whitmire Daniel P Reynolds Ray T January 1993 Habitable Zones around Main Sequence Stars Icarus 101 1 108 128 Bibcode 1993Icar 101 108K doi 10 1006 icar 1993 1010 PMID 11536936 Kopparapu Ravi Kumar Ramirez Ramses M SchottelKotte James Kasting James F Domagal Goldman Shawn Eymet Vincent 15 May 2014 Habitable Zones Around Main Sequence Stars Dependence on Planetary Mass The Astrophysical Journal 787 2 L29 arXiv 1404 5292 Bibcode 2014ApJ 787L 29K doi 10 1088 2041 8205 787 2 L29 ISSN 2041 8205 S2CID 118588898 Crisp David Kevin J Zahnle Robinson Tyler D Goldblatt Colin August 2013 Low simulated radiation limit for runaway greenhouse climates Nature Geoscience 6 8 661 667 Bibcode 2013NatGe 6 661G doi 10 1038 ngeo1892 hdl 2060 20160002421 ISSN 1752 0908 S2CID 37541492 a b c d Leconte Jeremy Forget Francois Charnay Benjamin Wordsworth Robin Pottier Alizee December 2013 Increased insolation threshold for runaway greenhouse processes on Earth like planets Nature 504 7479 268 271 arXiv 1312 3337 Bibcode 2013Natur 504 268L doi 10 1038 nature12827 ISSN 0028 0836 PMID 24336285 S2CID 2115695 a b Yang Jun Cowan Nicolas B Abbot Dorian S 27 June 2013 Stabilizing Cloud Feedback Dramatically Expands the Habitable Zone of Tidally Locked Planets The Astrophysical Journal 771 2 L45 arXiv 1307 0515 Bibcode 2013ApJ 771L 45Y doi 10 1088 2041 8205 771 2 L45 ISSN 2041 8205 S2CID 14119086 S I Rasoonl amp C de Bergh 1970 The Runaway Greenhouse Effect and the Accumulation of CO2 in the Atmosphere of Venus Nature 226 5250 1037 1039 Bibcode 1970Natur 226 1037R doi 10 1038 2261037a0 PMID 16057644 S2CID 4201521 T M Donahue J H Hoffmann R R Hodges Jr A J Watson Venus was wet a measurement of the ratio of deuterium to hydrogen Science 216 1982 pp 630 633 De Bergh B Bezard T Owen D Crisp J P Maillard B L Lutz Deuterium on Venus observations from Earth Science 251 1991 pp 547 549 Taylor Fredric W Svedhem Hakan Head James W February 2018 Venus The Atmosphere Climate Surface Interior and Near Space Environment of an Earth Like Planet Space Science Reviews 214 1 35 Bibcode 2018SSRv 214 35T doi 10 1007 s11214 018 0467 8 ISSN 0038 6308 a b Driscoll P Bercovici D November 2013 Divergent evolution of Earth and Venus Influence of degassing tectonics and magnetic fields Icarus 226 2 1447 1464 Bibcode 2013Icar 226 1447D doi 10 1016 j icarus 2013 07 025 S2CID 122173586 Nick Strobel Venus Archived from the original on 12 February 2007 Retrieved 17 February 2009 Walker James C G Hays P B Kasting J F 1981 A negative feedback mechanism for the long term stabilization of Earth s surface temperature Journal of Geophysical Research Oceans 86 C10 9776 9782 Bibcode 1981JGR 86 9776W doi 10 1029 JC086iC10p09776 ISSN 2156 2202 a b Kunzig Robert Will Earth s Ocean Boil Away National Geographic Daily News 29 July 2013 How Likely Is a Runaway Greenhouse Effect on Earth MIT Technology Review Archived from the original on 22 April 2015 Retrieved 1 June 2015 Houghton J 4 May 2005 Global Warming Rep Prog Phys 68 6 1343 1403 Bibcode 2005RPPh 68 1343H doi 10 1088 0034 4885 68 6 R02 S2CID 250915571 How Likely Is a Runaway Greenhouse Effect on Earth MIT Technology Review Archived from the original on 22 April 2015 Retrieved 1 June 2015 Goldblatt Colin Robinson Tyler D Zahnle Kevin J Crisp David August 2013 Low simulated radiation limit for runaway greenhouse climates Nature Geoscience 6 8 661 667 Bibcode 2013NatGe 6 661G doi 10 1038 ngeo1892 hdl 2060 20160002421 ISSN 1752 0894 S2CID 37541492 Benton M J Twitchet R J 2003 How to kill almost all life the end Permian extinction event PDF Trends in Ecology amp Evolution 18 7 358 365 doi 10 1016 S0169 5347 03 00093 4 Morante Richard 1996 Permian and early Triassic isotopic records of carbon and strontium in Australia and a scenario of events about the Permian Triassic boundary Historical Biology An International Journal of Paleobiology 11 1 289 310 doi 10 1080 10292389609380546 Price Gregory Paul J Valdes Bruce W Sellwood 1998 A comparison of GCM simulated Cretaceous greenhouse and icehouse climates implications for the sedimentary record Palaeogeography Palaeoclimatology Palaeoecology 142 3 4 123 138 Bibcode 1998PPP 142 123P doi 10 1016 s0031 0182 98 00061 3 a b Anticipating Future Sea Levels EarthObservatory NASA gov National Aeronautics and Space Administration NASA 2021 Archived from the original on 7 July 2021 Brownlee David and Peter D Ward The Life and Death of Planet Earth Holt Paperbacks 2004 ISBN 978 0805075120 Mars Astronomy Notes Retrieved 28 May 2023 Kite E S Mischena M A Fan B Morgan A M Wilson S A Richardson M L 2022 Changing spatial distribution of water flow charts major change in Mars s greenhouse effect Science Advances 8 21 eabo5894 doi 10 1126 sciadv abo5894 PMC 9132440 PMID 35613275 Further reading editSteffen Will Rockstrom Johan Richardson Katherine Lenton Timothy M Folke Carl Liverman Diana Summerhayes Colin P Barnosky Anthony D Cornell Sarah E Crucifix Michel Donges Jonathan F Fetzer Ingo Lade Steven J Scheffer Marten Winkelmann Ricarda Schellnhuber Hans Joachim 6 August 2018 Trajectories of the Earth System in the Anthropocene Proceedings of the National Academy of Sciences 115 33 8252 8259 Bibcode 2018PNAS 115 8252S doi 10 1073 pnas 1810141115 ISSN 0027 8424 PMC 6099852 PMID 30082409 We explore the risk that self reinforcing feedbacks could push the Earth System toward a planetary threshold that if crossed could prevent stabilization of the climate at intermediate temperature rises and cause continued warming on a Hothouse Earth pathway even as human emissions are reduced Crossing the threshold would lead to a much higher global average temperature than any interglacial in the past 1 2 million years and to sea levels significantly higher than at any time in the Holocene Retrieved from https en wikipedia org w index php title Runaway greenhouse effect amp oldid 1186818162, wikipedia, wiki, book, books, library,

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