s of
electromagnetic waves. The largest absorption band of carbon dioxide is not far from the maximum in the thermal emission from ground, and it partly closes the window of transparency of water—explaining carbon dioxide's major heat-trapping effect. Greenhouse gases are infrared active, meaning that they absorb and emit
infrared radiation in the same long wavelength range as what is emitted by the Earth's surface, clouds and atmosphere. 99% of the Earth's dry atmosphere (excluding
water vapor) is made up of
nitrogen () (78%) and
oxygen () (21%). Because their
molecules contain
two atoms of the same element, they have no asymmetry in the
distribution of their electrical charges, with only an extremely minor effect from
collision-induced absorption. A further 0.9% of the atmosphere is made up by
argon (Ar), which is
monatomic, and so completely transparent to thermal radiation. On the other hand,
carbon dioxide (0.04%),
methane,
nitrous oxide and even less abundant
trace gases account for less than 0.1% of Earth's atmosphere, but because their molecules contain atoms of different elements, there is an asymmetry in
electric charge distribution which allows
molecular vibrations to interact with electromagnetic radiation. This makes them infrared active, and so their presence causes
greenhouse effect.
Radiative forcing (Earth's responsiveness to increases in greenhouse gas concentrations).
absorption coefficients of primary greenhouse gases. Water vapor absorbs over a broad range of wavelengths. Earth emits thermal radiation particularly strongly in the vicinity of the carbon dioxide 15-micron absorption band. The relative importance of water vapor decreases with increasing altitude. Earth absorbs some of the radiant energy received from the sun, reflects some of it as light, and reflects or radiates the rest back to space as
heat. A planet's surface temperature depends on this balance between incoming and outgoing energy. When
Earth's energy balance is shifted, its surface becomes warmer or cooler, leading to a variety of changes in global climate.
Radiative forcing is a metric calculated in watts per square meter, which characterizes the impact of an external change in a factor that influences climate. It is calculated as the difference in top-of-atmosphere (TOA) energy balance immediately caused by such an external change. A positive forcing, such as from increased concentrations of greenhouse gases, means more energy arriving than leaving at the top-of-atmosphere, which causes additional warming, while negative forcing, like from
sulfates forming in the atmosphere from
sulfur dioxide, leads to cooling. Within the lower atmosphere, greenhouse gases exchange thermal radiation with the surface and limit radiative heat flow away from it, which reduces the overall rate of upward radiative heat transfer. The increased concentration of greenhouse gases is also cooling the upper atmosphere, as it is much thinner than the lower layers, and any heat re-emitted from greenhouse gases is more likely to travel further to space than to interact with the fewer gas molecules in the upper layers. The upper atmosphere is also shrinking as the result. −1). On the other hand, the single CO vibrational band only absorbs IR at much shorter wavelengths (4.7 microns, or 2145 cm−1), where the emission of radiant energy from Earth's surface is at least a factor of ten lower. Oxidation of methane to , which requires reactions with the OH radical, produces an instantaneous reduction in radiative absorption and emission since is a weaker greenhouse gas than methane. However, the oxidations of CO and are entwined since both consume OH radicals. In any case, the calculation of the total radiative effect includes both direct and indirect forcing. A second type of indirect effect happens when chemical reactions in the atmosphere involving these gases change the concentrations of greenhouse gases. For example, the destruction of
non-methane volatile organic compounds (NMVOCs) in the atmosphere can produce ozone. The size of the indirect effect can depend strongly on where and when the gas is emitted. NMVOCs include a large variety of chemically different compounds, such as
benzene,
ethanol,
formaldehyde,
cyclohexane,
1,1,1-Trichloroethane and
acetone. Essentially, NMVOCs are identical to
volatile organic compounds (VOCs), but with methane excluded. Methane is excluded in
air-pollution contexts because it is not toxic. It is however a very potent greenhouse gas, with low reactivity and thus a long lifetime in the atmosphere. An important subset of NMVOCs are the non-methane hydrocarbons (NMHCs). The same process that converts NMVOCs to carbon dioxide can also lead to the formation of tropospheric ozone.
Halocarbons have an indirect effect because they destroy stratospheric ozone. Finally,
hydrogen can lead to ozone production and increases as well as producing stratospheric water vapor. --> == Contributions of specific gases to the greenhouse effect ==