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Outgoing longwave radiation

December 20, 2023

In climate science, longwave radiation (LWR) is electromagnetic thermal radiation emitted by Earth's surface, atmosphere, and clouds. It may also be referred to as terrestrial radiation. This radiation is in the infrared portion of the spectrum, but is distinct from the shortwave (SW) near-infrared radiation found in sunlight.[1]: 2251 

Spectral intensity of sunlight (average at top of atmosphere) and thermal radiation emitted by Earth's surface.

Outgoing longwave radiation (OLR) is the longwave radiation emitted to space from the top of Earth's atmosphere.[1]: 2241  It may also be referred to as emitted terrestrial radiation. Outgoing longwave radiation plays an important role in planetary cooling.

Longwave radiation generally spans wavelengths ranging from 3–100 microns (μm). A cutoff of 4 μm is sometimes used to differentiate sunlight from longwave radiation. Less than 1% of sunlight has wavelengths greater than 4 μm. Over 99% of outgoing longwave radiation has wavelengths between 4 μm and 100 μm.[2]

The flux of energy transported by outgoing longwave radiation is typically measured in units of watts per meter squared (W m−2). In the case of global energy flux, the W/m2 value is obtained by dividing the total energy flow over the surface of the globe (measured in watts) by the surface area of the Earth, 5.1×1014 m2 (5.1×108 km2; 2.0×108 sq mi).[3]

Emitting outgoing longwave radiation is the only way Earth loses energy to space, i.e., the only way the planet cools itself.[4] Radiative heating from absorbed sunlight, and radiative cooling to space via OLR power the heat engine that drives atmospheric dynamics.[5]

The balance between OLR (energy lost) and incoming solar shortwave radiation (energy gained) determines whether the Earth is experiencing global heating or cooling (see Earth's energy budget).[6]

Planetary energy balance edit

 
The growth in Earth's energy imbalance from satellite and in situ measurements (2005–2019). A rate of +1.0 W/m2 summed over the planet's surface equates to a continuous heat uptake of about 500 terawatts (~0.3% of the incident solar radiation).[7][8]

Outgoing longwave radiation (OLR) constitutes a critical component of Earth's energy budget.[9]

The principle of conservation of energy says that energy cannot appear or disappear. Thus, any energy that enters a system but does not leave must be retained within the system. So, the amount of energy retained on Earth (in Earth's climate system) is governed by an equation:

[change in Earth's energy] = [energy arriving][energy leaving].

Energy arrives in the form of absorbed solar radiation (ASR). Energy leaves as outgoing longwave radiation (OLR). Thus, the rate of change in the energy in Earth's climate system is given by Earth's energy imbalance (EEI):

 .

When energy is arriving at a higher rate than it leaves (i.e., ASR > OLR, so that EEI is positive), the amount of energy in Earth's climate increases. Temperature is a measure of the amount of thermal energy in matter. So, under these circumstances, temperatures tend to increase overall (though temperatures might decrease in some places as the distribution of energy changes). As temperatures increase, the amount of thermal radiation emitted also increases, leading to more outgoing longwave radiation (OLR), and a smaller energy imbalance (EEI).[10]

Similarly, if energy arrives at a lower rate than it leaves (i.e., ASR < OLR, so than EEI is negative), the amount of energy in Earth's climate decreases, and temperatures tend to decrease overall. As temperatures decrease, OLR decreases, making the imbalance closer to zero.[10]

In this fashion, a planet naturally constantly adjusts its temperature so as to keep the energy imbalance small. If there is more solar radiation absorbed than OLR emitted, the planet will heat up. If there is more OLR than absorbed solar radiation the planet will cool. In both cases, the temperature change works to shift the energy imbalance towards zero. When the energy imbalance is zero, a planet is said to be in radiative equilibrium. Planets natural tend to a state of approximate radiative equilibrium.[10]

In recent decades, energy has been measured to be arriving on Earth at a higher rate than it leaves, corresponding to planetary warming. The energy imbalance has been increasing.[7][8] It can take decades to centuries for oceans to warm and planetary temperature to shift sufficiently to compensate for an energy imbalance.[11]

Emission edit

Thermal radiation is emitted by nearly all matter, in proportion to the fourth power of its absolute temperature.

In particular, the emitted energy flux,   (measured in W/m2) is given by the Stefan–Boltzmann law for non-blackbody matter:[12]

 

where   is the absolute temperature,   is the Stefan–Boltzmann constant (5.67...×10−8 W m−2 K−4), and   is the emissivity. The emissivity is a value between zero and one which indicates how much less radiation is emitted compared to what a perfect blackbody would emit.

Surface edit

The emissivity of Earth's surface has been measured to be in the range 0.65 to 0.99 (based on observations in the 8-13 micron wavelength range) with the lowest values being for barren desert regions. The emissivity is mostly above 0.9, and the global average surface emissivity is estimated to be around 0.95.[13][14]

Atmosphere edit

The most common gases in air (i.e., nitrogen, oxygen, and argon) have a negligible ability to absorb or emit longwave thermal radiation. Consequently, the ability of air to absorb and emit longwave radiation is determined by the concentration of trace gases like water vapor and carbon dioxide.[15]

According to Kirchoff's law of thermal radiation, the emissivity of matter is always equal to its absorptivity, at a given wavelength.[12] At some wavelengths, greenhouse gases absorb 100% of the longwave radiation emitted by the surface.[16] So, at those wavelengths, the emissivity of the atmosphere is 1 and the atmosphere emits thermal radiation much like an ideal blackbody would. However, this applies only at wavelengths where the atmosphere fully absorbs longwave radiation.[citation needed]

Although greenhouse gases in air have a high emissivity at some wavelengths, this does not necessarily correspond to a high rate of thermal radiation being emitted to space. This is because the atmosphere is generally much colder than the surface, and the rate at which longwave radiation is emitted scales as the fourth power of temperature. Thus, the higher the altitude at which longwave radiation is emitted, the lower its intensity.[17]

Atmospheric absorption edit

The atmosphere is relatively transparent to solar radiation, but it is nearly opaque to longwave radiation.[18] The atmosphere typically absorbs most of the longwave radiation emitted by the surface.[19] Absorption of longwave radiation prevents that radiation from reaching space.

At wavelengths where the atmosphere absorbs surface radiation, some portion of the radiation that was absorbed is replaced by a lesser amount of thermal radiation emitted by the atmosphere at a higher altitude.[17]

When absorbed, the energy transmitted by this radiation is transferred to the substance that absorbed it.[18] However, overall, greenhouse gases in the troposphere emit more thermal radiation than they absorb, so longwave radiative heat transfer has a net cooling effect on air.[20][21]: 139 

Atmospheric window edit

Assuming no cloud cover, most of the surface emissions that reach space do so through the atmospheric window. The atmospheric window is a region of the electromagnetic wavelength spectrum between 8 and 11 μm where the atmosphere does not absorb longwave radiation (except for the ozone band between 9.6 and 9.8 μm).[19]

Gases edit

Greenhouse gases in the atmosphere are responsible for a majority of the absorption of longwave radiation in the atmsophere. The most important of these gases are water vapor, carbon dioxide, methane, and ozone.[22]

The absorption of longwave radiation by gases depends on the specific absorption bands of the gases in the atmosphere.[19] The specific absorption bands are determined by their molecular structure and energy levels. Each type of greenhouse gas has a unique group of absorption bands that correspond to particular wavelengths of radiation that the gas can absorb.[citation needed]

Clouds edit

The OLR balance is affected by clouds, dust, and aerosols in the atmosphere. Clouds tend to block penetration of upwelling longwave radiation, causing a lower flux of long-wave radiation penetrating to higher altitudes.[23] Clouds are effective at absorbing and scattering longwave radiation, and therefore reduce the amount of outgoing longwave radiation.

Clouds have both cooling and warming effects. They have a cooling effect insofar as they reflect sunlight (as measured by cloud albedo), and a warming effect, insofar as they absorb longwave radiation. For low clouds, the reflection of solar radiation is the larger effect; so, these clouds cool the Earth. In contrast, for high thin clouds in cold air, the absorption of longwave radiation is the more significant effect; so these clouds warm the planet.[24]

Details edit

The interaction between emitted longwave radiation and the atmosphere is complicated due to the factors that affect absorption. The path of the radiation in the atmosphere also determines radiative absorption: longer paths through the atmosphere result in greater absorption because of the cumulative absorption by many layers of gas. Lastly, the temperature and altitude of the absorbing gas also affect its absorption of longwave radiation.[citation needed]

OLR is affected by Earth's surface skin temperature (i.e, the temperature of the top layer of the surface), skin surface emissivity, atmospheric temperature, water vapor profile, and cloud cover.[9]

Day and night edit

The net all-wave radiation is dominated by longwave radiation during the night and in the polar regions.[25] While there is no absorbed solar radiation during the night, terrestrial radiation continues to be emitted, primarily as a result of solar energy absorbed during the day.

Relationship to greenhouse effect edit

 
Outgoing radiation and greenhouse effect as a function of frequency. The greenhouse effect is visible as the area of the upper red area, and the greenhouse effect associated with CO2 is directly visible as the large dip near the center of the OLR spectrum.[26]

The reduction of the outgoing longwave radiation (OLR), relative to longwave radiation emitted by the surface, is at the heart of the greenhouse effect.[27]

More specifically, the greenhouse effect may be defined quantitatively as the amount of longwave radiation emitted by the surface that does not reach space. On Earth as of 2015, about 398 W/m2 of longwave radiation was emitted by the surface, while OLR, the amount reaching space, was 239 W/m2. Thus, the greenhouse effect was 398-239 = 159 W/m2, or 159/398 = 40% of surface emissions, not reaching space.[28]: 968, 934 [29][30]

Effect of increasing greenhouse gases edit

When the concentration of a greenhouse gas (such as carbon dioxide (CO2), methane (CH4), nitrous oxide (N2O), and water vapor (H2O)) and is increased, this has a number of effects. At a given wavelength

  • the fraction of surface emissions that are absorbed is increased, decreasing OLR (unless 100% of surface emissions at that wavelength are already being absorbed);
  • the altitude from which the atmosphere emits that that wavelength to space increases (since the altitude at which the atmosphere becomes transparent to that wavelength increases); if the emission altitude is within the troposphere, the temperature of the emitting air will be lower, which will result in a reduction in OLR at that wavelength.

The size of the reduction in OLR will vary by wavelength. Even if OLR does not decrease at certain wavelengths (e.g., because 100% of surface emissions are absorbed and the emission altitude is in the stratosphere), increased greenhouse gas concentration can still lead to significant reductions in OLR at other wavelengths where absorption is weaker.[31]

When OLR decreases, this leads to an energy imbalance, with energy received being greater than energy lost, causing a warming effect. Therefore, an increase in the concentrations of greenhouse gases causes energy to accumulate in Earth's climate system, contributing to global warming.[31]

Surface budget fallacy edit

If the absorptivity of the gas is high and the gas is present in a high enough concentration, the absorption at certain wavelengths becomes saturated.[18] This means there is enough gas present to completely absorb the radiated energy at that wavelength before the upper atmosphere is reached.[citation needed]

It is sometimes incorrectly argued that this means an increase in the concentration of this gas will have no additional effect on the planet's energy budget. This argument neglects the fact that outgoing longwave radiation is determined not only by the amount of surface radiation that is absorbed, but also by the altitude (and temperature) at which longwave radiation is emitted to space. Even if 100% of surface emissions are absorbed at a given wavelength, the OLR at that wavelength can still be reduced by increased greenhouse gas concentration, since the increased concentration leads to the atmosphere emitted longwave radiation to space from a higher altitude. If the air at that higher altitude is colder (as is true throughout the troposphere), then thermal emissions to space will reduced, decreasing OLR.[31]: 413 

False conclusions about the implications of absorption being "saturated" are examples of the surface budget fallacy, i.e., erroneous reasoning that results from focusing on energy exchange at the surface, instead of focusing on the top-of-atmosphere (TOA) energy balance. [31]: 413 

Measurements edit

 
Example wavenumber spectrum of Earth's infrared emissions (400-1600 cm−1) measured by IRIS on Nimbus 4 in year 1970.[32]

Measurements of outgoing longwave radiation at the top of the atmosphere and of longwave radiation back towards the surface are important to understand how much energy is retained in Earth's climate system: for example, how thermal radiation cools and warms the surface, and how this energy is distributed to affect the development of clouds. Observing this radiative flux from a surface also provides a practical way of assessing surface temperatures on both local and global scales.[33] This energy distribution is what drives atmospheric thermodynamics.

OLR edit

Outgoing long-wave radiation (OLR) has been monitored and reported since 1970 by a progression of satellite missions and instruments.

Surface LW radiation edit

Longwave radiation at the surface (both outward and inward) is mainly measured by pyrgeometers. A most notable ground-based network for monitoring surface long-wave radiation is the Baseline Surface Radiation Network (BSRN), which provides crucial well-calibrated measurements for studying global dimming and brightening.[38]

Data edit

Data on surface longwave radiation and OLR is available from a number of sources including:

  • NASA GEWEX Surface Radiation Budget (1983-2007)[39]
  • NASA Clouds and the Earth’s Radiant Energy System (CERES) project (2000-2022)[40]

OLR calculation and simulation edit

 
Simulated wavenumber spectrum of the Earth's outgoing longwave radiation (OLR) using ARTS. In addition the black-body radiation for a body at surface temperature Ts and at tropopause temperature Tmin is shown.
 
Simulated wavelength spectrum of Earth's OLR under clear-sky conditions using MODTRAN.[41]

Many applications call for calculation of long-wave radiation quantities. Local radiative cooling by outgoing longwave radiation, suppression of radiative cooling (by downwelling longwave radiation cancelling out energy transfer by upwelling longwave radiation), and radiative heating through incoming solar radiation drive the temperature and dynamics of different parts of the atmosphere.[citation needed]

By using the radiance measured from a particular direction by an instrument, atmospheric properties (like temperature or humidity) can be inversely inferred. Calculations of these quantities solve the radiative transfer equations that describe radiation in the atmosphere. Usually the solution is done numerically by atmospheric radiative transfer codes adapted to the specific problem.

Another common approach is to estimate values using surface temperature and emissivity, then compare to satellite top-of-atmosphere radiance or brightness temperature.[25]

There are online interactive tools that allow one to see the spectrum of outgoing longwave radiation that is predicted to reach space under various atmospheric conditions.[41]

See also edit

References edit

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  37. ^ Kyle, H. L.; Arking, A.; Hickey, J. R.; Ardanuy, P. E.; Jacobowitz, H.; Stowe, L. L.; Campbell, G. G.; Vonder Haar, T.; House, F. B.; Maschhoff, R.; Smith, G. L. (May 1993). "The Nimbus Earth Radiation Budget (ERB) Experiment: 1975 to 1992". Bulletin of the American Meteorological Society. 74 (5): 815–830. Bibcode:1993BAMS...74..815K. doi:10.1175/1520-0477(1993)074<0815:TNERBE>2.0.CO;2.
  38. ^ Wild, Martin (27 June 2009). "Global dimming and brightening: A review". Journal of Geophysical Research. 114 (D10): D00D16. Bibcode:2009JGRD..114.0D16W. doi:10.1029/2008JD011470. S2CID 5118399.
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  40. ^ "What is CERES?". NASA. Retrieved 13 July 2023.
  41. ^ a b "MODTRAN Infrared Light in the Atmosphere". University of Chicago. Retrieved 12 July 2023.

External links edit

  • NOAA Climate Diagnostics Center
  • at the Wayback Machine (archived May 5, 2008)
  • at the Wayback Machine (archived September 27, 2007)
  • Planetary Energy Balance, Physical Geography

December 20, 2023
outgoing, longwave, radiation, climate, science, longwave, radiation, electromagnetic, thermal, radiation, emitted, earth, surface, atmosphere, clouds, also, referred, terrestrial, radiation, this, radiation, infrared, portion, spectrum, distinct, from, shortw. In climate science longwave radiation LWR is electromagnetic thermal radiation emitted by Earth s surface atmosphere and clouds It may also be referred to as terrestrial radiation This radiation is in the infrared portion of the spectrum but is distinct from the shortwave SW near infrared radiation found in sunlight 1 2251 Spectral intensity of sunlight average at top of atmosphere and thermal radiation emitted by Earth s surface Outgoing longwave radiation OLR is the longwave radiation emitted to space from the top of Earth s atmosphere 1 2241 It may also be referred to as emitted terrestrial radiation Outgoing longwave radiation plays an important role in planetary cooling Longwave radiation generally spans wavelengths ranging from 3 100 microns mm A cutoff of 4 mm is sometimes used to differentiate sunlight from longwave radiation Less than 1 of sunlight has wavelengths greater than 4 mm Over 99 of outgoing longwave radiation has wavelengths between 4 mm and 100 mm 2 The flux of energy transported by outgoing longwave radiation is typically measured in units of watts per meter squared W m 2 In the case of global energy flux the W m2 value is obtained by dividing the total energy flow over the surface of the globe measured in watts by the surface area of the Earth 5 1 1014 m2 5 1 108 km2 2 0 108 sq mi 3 Emitting outgoing longwave radiation is the only way Earth loses energy to space i e the only way the planet cools itself 4 Radiative heating from absorbed sunlight and radiative cooling to space via OLR power the heat engine that drives atmospheric dynamics 5 The balance between OLR energy lost and incoming solar shortwave radiation energy gained determines whether the Earth is experiencing global heating or cooling see Earth s energy budget 6 Contents 1 Planetary energy balance 2 Emission 2 1 Surface 2 2 Atmosphere 3 Atmospheric absorption 3 1 Atmospheric window 3 2 Gases 3 3 Clouds 3 4 Details 4 Day and night 5 Relationship to greenhouse effect 5 1 Effect of increasing greenhouse gases 5 2 Surface budget fallacy 6 Measurements 6 1 OLR 6 2 Surface LW radiation 6 3 Data 7 OLR calculation and simulation 8 See also 9 References 10 External linksPlanetary energy balance edit nbsp The growth in Earth s energy imbalance from satellite and in situ measurements 2005 2019 A rate of 1 0 W m2 summed over the planet s surface equates to a continuous heat uptake of about 500 terawatts 0 3 of the incident solar radiation 7 8 Outgoing longwave radiation OLR constitutes a critical component of Earth s energy budget 9 The principle of conservation of energy says that energy cannot appear or disappear Thus any energy that enters a system but does not leave must be retained within the system So the amount of energy retained on Earth in Earth s climate system is governed by an equation change in Earth s energy energy arriving energy leaving Energy arrives in the form of absorbed solar radiation ASR Energy leaves as outgoing longwave radiation OLR Thus the rate of change in the energy in Earth s climate system is given by Earth s energy imbalance EEI E E I A S R O L R displaystyle mathrm EEI mathrm ASR mathrm OLR nbsp When energy is arriving at a higher rate than it leaves i e ASR gt OLR so that EEI is positive the amount of energy in Earth s climate increases Temperature is a measure of the amount of thermal energy in matter So under these circumstances temperatures tend to increase overall though temperatures might decrease in some places as the distribution of energy changes As temperatures increase the amount of thermal radiation emitted also increases leading to more outgoing longwave radiation OLR and a smaller energy imbalance EEI 10 Similarly if energy arrives at a lower rate than it leaves i e ASR lt OLR so than EEI is negative the amount of energy in Earth s climate decreases and temperatures tend to decrease overall As temperatures decrease OLR decreases making the imbalance closer to zero 10 In this fashion a planet naturally constantly adjusts its temperature so as to keep the energy imbalance small If there is more solar radiation absorbed than OLR emitted the planet will heat up If there is more OLR than absorbed solar radiation the planet will cool In both cases the temperature change works to shift the energy imbalance towards zero When the energy imbalance is zero a planet is said to be in radiative equilibrium Planets natural tend to a state of approximate radiative equilibrium 10 In recent decades energy has been measured to be arriving on Earth at a higher rate than it leaves corresponding to planetary warming The energy imbalance has been increasing 7 8 It can take decades to centuries for oceans to warm and planetary temperature to shift sufficiently to compensate for an energy imbalance 11 Emission editThermal radiation is emitted by nearly all matter in proportion to the fourth power of its absolute temperature In particular the emitted energy flux M displaystyle M nbsp measured in W m2 is given by the Stefan Boltzmann law for non blackbody matter 12 M ϵ s T 4 displaystyle M epsilon sigma T 4 nbsp where T displaystyle T nbsp is the absolute temperature s displaystyle sigma nbsp is the Stefan Boltzmann constant 5 67 10 8 W m 2 K 4 and ϵ displaystyle epsilon nbsp is the emissivity The emissivity is a value between zero and one which indicates how much less radiation is emitted compared to what a perfect blackbody would emit Surface edit The emissivity of Earth s surface has been measured to be in the range 0 65 to 0 99 based on observations in the 8 13 micron wavelength range with the lowest values being for barren desert regions The emissivity is mostly above 0 9 and the global average surface emissivity is estimated to be around 0 95 13 14 Atmosphere edit The most common gases in air i e nitrogen oxygen and argon have a negligible ability to absorb or emit longwave thermal radiation Consequently the ability of air to absorb and emit longwave radiation is determined by the concentration of trace gases like water vapor and carbon dioxide 15 According to Kirchoff s law of thermal radiation the emissivity of matter is always equal to its absorptivity at a given wavelength 12 At some wavelengths greenhouse gases absorb 100 of the longwave radiation emitted by the surface 16 So at those wavelengths the emissivity of the atmosphere is 1 and the atmosphere emits thermal radiation much like an ideal blackbody would However this applies only at wavelengths where the atmosphere fully absorbs longwave radiation citation needed Although greenhouse gases in air have a high emissivity at some wavelengths this does not necessarily correspond to a high rate of thermal radiation being emitted to space This is because the atmosphere is generally much colder than the surface and the rate at which longwave radiation is emitted scales as the fourth power of temperature Thus the higher the altitude at which longwave radiation is emitted the lower its intensity 17 Atmospheric absorption editThe atmosphere is relatively transparent to solar radiation but it is nearly opaque to longwave radiation 18 The atmosphere typically absorbs most of the longwave radiation emitted by the surface 19 Absorption of longwave radiation prevents that radiation from reaching space At wavelengths where the atmosphere absorbs surface radiation some portion of the radiation that was absorbed is replaced by a lesser amount of thermal radiation emitted by the atmosphere at a higher altitude 17 When absorbed the energy transmitted by this radiation is transferred to the substance that absorbed it 18 However overall greenhouse gases in the troposphere emit more thermal radiation than they absorb so longwave radiative heat transfer has a net cooling effect on air 20 21 139 Atmospheric window edit Assuming no cloud cover most of the surface emissions that reach space do so through the atmospheric window The atmospheric window is a region of the electromagnetic wavelength spectrum between 8 and 11 mm where the atmosphere does not absorb longwave radiation except for the ozone band between 9 6 and 9 8 mm 19 Gases edit Greenhouse gases in the atmosphere are responsible for a majority of the absorption of longwave radiation in the atmsophere The most important of these gases are water vapor carbon dioxide methane and ozone 22 The absorption of longwave radiation by gases depends on the specific absorption bands of the gases in the atmosphere 19 The specific absorption bands are determined by their molecular structure and energy levels Each type of greenhouse gas has a unique group of absorption bands that correspond to particular wavelengths of radiation that the gas can absorb citation needed Clouds edit The OLR balance is affected by clouds dust and aerosols in the atmosphere Clouds tend to block penetration of upwelling longwave radiation causing a lower flux of long wave radiation penetrating to higher altitudes 23 Clouds are effective at absorbing and scattering longwave radiation and therefore reduce the amount of outgoing longwave radiation Clouds have both cooling and warming effects They have a cooling effect insofar as they reflect sunlight as measured by cloud albedo and a warming effect insofar as they absorb longwave radiation For low clouds the reflection of solar radiation is the larger effect so these clouds cool the Earth In contrast for high thin clouds in cold air the absorption of longwave radiation is the more significant effect so these clouds warm the planet 24 Details edit The interaction between emitted longwave radiation and the atmosphere is complicated due to the factors that affect absorption The path of the radiation in the atmosphere also determines radiative absorption longer paths through the atmosphere result in greater absorption because of the cumulative absorption by many layers of gas Lastly the temperature and altitude of the absorbing gas also affect its absorption of longwave radiation citation needed OLR is affected by Earth s surface skin temperature i e the temperature of the top layer of the surface skin surface emissivity atmospheric temperature water vapor profile and cloud cover 9 Day and night editThe net all wave radiation is dominated by longwave radiation during the night and in the polar regions 25 While there is no absorbed solar radiation during the night terrestrial radiation continues to be emitted primarily as a result of solar energy absorbed during the day Relationship to greenhouse effect edit nbsp Outgoing radiation and greenhouse effect as a function of frequency The greenhouse effect is visible as the area of the upper red area and the greenhouse effect associated with CO2 is directly visible as the large dip near the center of the OLR spectrum 26 The reduction of the outgoing longwave radiation OLR relative to longwave radiation emitted by the surface is at the heart of the greenhouse effect 27 More specifically the greenhouse effect may be defined quantitatively as the amount of longwave radiation emitted by the surface that does not reach space On Earth as of 2015 about 398 W m2 of longwave radiation was emitted by the surface while OLR the amount reaching space was 239 W m2 Thus the greenhouse effect was 398 239 159 W m2 or 159 398 40 of surface emissions not reaching space 28 968 934 29 30 Effect of increasing greenhouse gases edit When the concentration of a greenhouse gas such as carbon dioxide CO2 methane CH4 nitrous oxide N2O and water vapor H2O and is increased this has a number of effects At a given wavelength the fraction of surface emissions that are absorbed is increased decreasing OLR unless 100 of surface emissions at that wavelength are already being absorbed the altitude from which the atmosphere emits that that wavelength to space increases since the altitude at which the atmosphere becomes transparent to that wavelength increases if the emission altitude is within the troposphere the temperature of the emitting air will be lower which will result in a reduction in OLR at that wavelength The size of the reduction in OLR will vary by wavelength Even if OLR does not decrease at certain wavelengths e g because 100 of surface emissions are absorbed and the emission altitude is in the stratosphere increased greenhouse gas concentration can still lead to significant reductions in OLR at other wavelengths where absorption is weaker 31 When OLR decreases this leads to an energy imbalance with energy received being greater than energy lost causing a warming effect Therefore an increase in the concentrations of greenhouse gases causes energy to accumulate in Earth s climate system contributing to global warming 31 Surface budget fallacy edit If the absorptivity of the gas is high and the gas is present in a high enough concentration the absorption at certain wavelengths becomes saturated 18 This means there is enough gas present to completely absorb the radiated energy at that wavelength before the upper atmosphere is reached citation needed It is sometimes incorrectly argued that this means an increase in the concentration of this gas will have no additional effect on the planet s energy budget This argument neglects the fact that outgoing longwave radiation is determined not only by the amount of surface radiation that is absorbed but also by the altitude and temperature at which longwave radiation is emitted to space Even if 100 of surface emissions are absorbed at a given wavelength the OLR at that wavelength can still be reduced by increased greenhouse gas concentration since the increased concentration leads to the atmosphere emitted longwave radiation to space from a higher altitude If the air at that higher altitude is colder as is true throughout the troposphere then thermal emissions to space will reduced decreasing OLR 31 413 False conclusions about the implications of absorption being saturated are examples of the surface budget fallacy i e erroneous reasoning that results from focusing on energy exchange at the surface instead of focusing on the top of atmosphere TOA energy balance 31 413 Measurements edit nbsp Example wavenumber spectrum of Earth s infrared emissions 400 1600 cm 1 measured by IRIS on Nimbus 4 in year 1970 32 Measurements of outgoing longwave radiation at the top of the atmosphere and of longwave radiation back towards the surface are important to understand how much energy is retained in Earth s climate system for example how thermal radiation cools and warms the surface and how this energy is distributed to affect the development of clouds Observing this radiative flux from a surface also provides a practical way of assessing surface temperatures on both local and global scales 33 This energy distribution is what drives atmospheric thermodynamics OLR edit Outgoing long wave radiation OLR has been monitored and reported since 1970 by a progression of satellite missions and instruments Earliest observations were with infrared interferometer spectrometer and radiometer IRIS instruments developed for the Nimbus program and deployed on Nimbus 3 and Nimbus 4 34 35 These Michelson interferometers were designed to span wavelengths of 5 to 25 mm Improved measurements were obtained starting with the Earth Radiation Balance ERB instruments on Nimbus 6 and Nimbus 7 36 37 These were followed by the Earth Radiation Budget Experiment scanners and the non scanner clarification needed on NOAA 9 NOAA 10 and Earth Radiation Budget Satellite also the Clouds and the Earth s Radiant Energy System instruments aboard Aqua Terra Suomi NPP and NOAA 20 and the Geostationary Earth Radiation Budget instrument GERB instrument on the Meteosat Second Generation MSG satellite Surface LW radiation edit Longwave radiation at the surface both outward and inward is mainly measured by pyrgeometers A most notable ground based network for monitoring surface long wave radiation is the Baseline Surface Radiation Network BSRN which provides crucial well calibrated measurements for studying global dimming and brightening 38 Data edit Data on surface longwave radiation and OLR is available from a number of sources including NASA GEWEX Surface Radiation Budget 1983 2007 39 NASA Clouds and the Earth s Radiant Energy System CERES project 2000 2022 40 OLR calculation and simulation edit nbsp Simulated wavenumber spectrum of the Earth s outgoing longwave radiation OLR using ARTS In addition the black body radiation for a body at surface temperature Ts and at tropopause temperature Tmin is shown nbsp Simulated wavelength spectrum of Earth s OLR under clear sky conditions using MODTRAN 41 Many applications call for calculation of long wave radiation quantities Local radiative cooling by outgoing longwave radiation suppression of radiative cooling by downwelling longwave radiation cancelling out energy transfer by upwelling longwave radiation and radiative heating through incoming solar radiation drive the temperature and dynamics of different parts of the atmosphere citation needed By using the radiance measured from a particular direction by an instrument atmospheric properties like temperature or humidity can be inversely inferred Calculations of these quantities solve the radiative transfer equations that describe radiation in the atmosphere Usually the solution is done numerically by atmospheric radiative transfer codes adapted to the specific problem Another common approach is to estimate values using surface temperature and emissivity then compare to satellite top of atmosphere radiance or brightness temperature 25 There are online interactive tools that allow one to see the spectrum of outgoing longwave radiation that is predicted to reach space under various atmospheric conditions 41 See also editEffective temperature Satellite temperature measurement Shortwave radiationReferences edit a b Matthews J B R Moller V van Diemenn R Fuglesvedt J R et al 2021 08 09 Annex VII Glossary In Masson Delmotte Valerie Zhai Panmao Pirani Anna Connors Sarah L Pean Clotilde et al eds Climate Change 2021 The Physical Science Basis Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change PDF IPCC Cambridge University Press pp 2215 2256 doi 10 1017 9781009157896 022 ISBN 9781009157896 Petty Grant W 2006 A first course in atmospheric radiation 2 ed Madison Wisc Sundog Publ p 68 ISBN 978 0 9729033 1 8 What is the Surface Area of the Earth Universe Today Retrieved 1 June 2023 Earth s Heat Balance Energy Education University of Calgary Retrieved 12 July 2023 Singh Martin S O Neill Morgan E 2022 Thermodynamics of the climate system Physics Today 75 7 30 37 doi 10 1063 PT 3 5038 Retrieved 12 July 2023 Kiehl J T Trenberth Kevin E February 1997 Earth s Annual Global Mean Energy Budget Bulletin of the American Meteorological Society 78 2 197 208 Bibcode 1997BAMS 78 197K doi 10 1175 1520 0477 1997 078 lt 0197 EAGMEB gt 2 0 CO 2 a b Loeb Norman G Johnson Gregory C Thorsen Tyler J Lyman John M et al 15 June 2021 Satellite and Ocean Data Reveal Marked Increase in Earth s Heating Rate Geophysical Research Letters 48 13 Bibcode 2021GeoRL 4893047L doi 10 1029 2021GL093047 a b Joseph Atkinson 22 June 2021 Earth Matters Earth s Radiation Budget is Out of Balance NASA Earth Observatory a b Susskind Joel Molnar Gyula Iredell Lena 21 August 2011 Contributions to Climate Research Using the AIRS Science Team Version 5 Products SPIE Optics and Photonics 2011 NASA Technical Reports Server hdl 2060 20110015241 a b c Earth s Radiation Balance CIMSS University of Wisconsin Retrieved 25 April 2023 Wallace Tim 12 Sep 2016 Oceans Are Absorbing Almost All of the Globe s Excess Heat The New York Times Retrieved 12 July 2023 a b Stefan Boltzmann law amp Kirchhoff s law of thermal radiation tec science com 25 May 2019 Retrieved 12 July 2023 ASTER global emissivity database 100 times more detailed than its predecessor NASA Earth Observatory Retrieved 10 October 2022 Joint Emissivity Database Initiative NASA Jet Propulsion Laboratory Retrieved 10 October 2022 Wei Peng Sheng Hsieh Yin Chih Chiu Hsuan Han Yen Da Lun Lee Chieh Tsai Yi Cheng Ting Te Chuan 6 October 2018 Absorption coefficient of carbon dioxide across atmospheric troposphere layer Heliyon 4 10 e00785 Bibcode 2018Heliy 400785W doi 10 1016 j heliyon 2018 e00785 PMC 6174548 PMID 30302408 Greenhouse Gas Absorption Spectrum Iowa State University Retrieved 13 July 2023 a b Pierrehumbert R T January 2011 Infrared radiation and planetary temperature PDF Physics Today American Institute of Physics pp 33 38 a b c Hartmann Dennis L 2016 Global Physical Climatology 2nd ed Elsevier pp 53 62 ISBN 978 0 12 328531 7 a b c Oke T R 2002 09 11 Boundary Layer Climates doi 10 4324 9780203407219 ISBN 978 0 203 40721 9 Manabe S Strickler R F 1964 Thermal Equilibrium of the Atmosphere with a Convective Adjustment J Atmos Sci 21 4 361 385 Bibcode 1964JAtS 21 361M doi 10 1175 1520 0469 1964 021 lt 0361 TEOTAW gt 2 0 CO 2 Wallace J M Hobbs P V 2006 Atmospheric Science 2 ed Academic Press ISBN 978 0 12 732951 2 Schmidt G A R Ruedy R L Miller A A Lacis 2010 The attribution of the present day total greenhouse effect PDF J Geophys Res vol 115 no D20 pp D20106 Bibcode 2010JGRD 11520106S doi 10 1029 2010JD014287 archived from the original PDF on 22 October 2011 D20106 Web page Archived 4 June 2012 at the Wayback Machine Kiehl J T Trenberth Kevin E 1997 Earth s Annual Global Mean Energy Budget Bulletin of the American Meteorological Society 78 2 197 208 Bibcode 1997BAMS 78 197K doi 10 1175 1520 0477 1997 078 lt 0197 eagmeb gt 2 0 co 2 Clouds amp Radiation Fact Sheet earthobservatory nasa gov 1999 03 01 Retrieved 2023 05 04 a b Wenhui Wang Shunlin Liang Augustine J A May 2009 Estimating High Spatial Resolution Clear Sky Land Surface Upwelling Longwave Radiation From MODIS Data IEEE Transactions on Geoscience and Remote Sensing 47 5 1559 1570 Bibcode 2009ITGRS 47 1559W doi 10 1109 TGRS 2008 2005206 ISSN 0196 2892 S2CID 3822497 Gavin Schmidt 2010 10 01 Taking the Measure of the Greenhouse Effect NASA Goddard Institute for Space Studies Science Briefs Archived from the original on 21 April 2021 Retrieved 13 January 2022 Schmidt Gavin A Ruedy Reto A Miller Ron L Lacis Andy A 2010 10 16 Attribution of the present day total greenhouse effect Journal of Geophysical Research 115 D20 D20106 Bibcode 2010JGRD 11520106S doi 10 1029 2010jd014287 ISSN 0148 0227 S2CID 28195537 Chapter 7 The Earth s Energy Budget Climate Feedbacks and Climate Sensitivity Climate Change 2021 The Physical Science Basis PDF IPCC 2021 Retrieved 24 April 2023 Raval A Ramanathan V 1989 Observational determination of the greenhouse effect Nature 342 6251 758 761 doi 10 1038 342758a0 S2CID 4326910 Raval A Ramanathan V 1990 Observational determination of the greenhouse effect Global Climate Feedbacks Proceedings of the Brookhaven National Laboratory Workshop 5 16 Retrieved 24 April 2023 a b c d Pierrehumbert Raymond T 2010 Principles of Planetary Climate Cambridge University Press ISBN 978 0 521 86556 2 Hansel Rudolf A et al 1994 IRIS Nimbus 4 Level 1 Radiance Data V001 Goddard Earth Sciences Data and Information Services Center GES DISC Greenbelt MD USA Retrieved 14 October 2022 Price A G Petzold D E February 1984 Surface Emissivities in a Boreal Forest during Snowmelt Arctic and Alpine Research 16 1 45 doi 10 2307 1551171 ISSN 0004 0851 JSTOR 1551171 Hanel Rudolf A Conrath Barney J 10 October 1970 Thermal Emission Spectra of the Earth and Atmosphere from the Nimbus 4 Michelson Interferometer Experiment Nature 228 5267 143 145 doi 10 1038 228143a0 PMID 16058447 S2CID 4267086 Hanel Rudolf A Conrath Barney J Kunde Virgil G Prabhakara C 20 October 1970 The Infrared Interferometer Experiment on Nimbus 3 Journal of Geophysical Research 75 30 5831 5857 doi 10 1029 jc075i030p05831 hdl 2060 19700022421 Jacobowitz Herbert Soule Harold V Kyle H Lee House Frederick B 30 June 1984 The Earth Radiation Budget ERB Experiment An overview Journal of Geophysical Research Atmospheres 89 D4 5021 5038 doi 10 1029 JD089iD04p05021 Kyle H L Arking A Hickey J R Ardanuy P E Jacobowitz H Stowe L L Campbell G G Vonder Haar T House F B Maschhoff R Smith G L May 1993 The Nimbus Earth Radiation Budget ERB Experiment 1975 to 1992 Bulletin of the American Meteorological Society 74 5 815 830 Bibcode 1993BAMS 74 815K doi 10 1175 1520 0477 1993 074 lt 0815 TNERBE gt 2 0 CO 2 Wild Martin 27 June 2009 Global dimming and brightening A review Journal of Geophysical Research 114 D10 D00D16 Bibcode 2009JGRD 114 0D16W doi 10 1029 2008JD011470 S2CID 5118399 NASA GEWEX Surface Radiation Budget NASA Retrieved 13 July 2023 What is CERES NASA Retrieved 13 July 2023 a b MODTRAN Infrared Light in the Atmosphere University of Chicago Retrieved 12 July 2023 External links editNOAA Climate Diagnostics Center NASA Earth Observatory Outgoing Heat Radiation Office of Satellite Data Processing and Distribution Radiation Budget at the Wayback Machine archived May 5 2008 Meteorological Satellite Center Japan Meteorological Agency at the Wayback Machine archived September 27 2007 Planetary Energy Balance Physical Geography Retrieved from https en wikipedia org w index php title Outgoing longwave radiation amp oldid 1185634160, wikipedia, wiki, book, books, library,

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