2.5.3: Radiation Interaction with the Atmosphere

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The diagram below shows the spectral intensity of downgoing solar radiation (UV and visible in red) and upgoing thermal radiation (IR in blue). The panels below the spectral intensity graph show the total percentage of radiation absorbed and scattered by the atmosphere as a function of wavelength, and divided up by the primary greenhouse gases in the atmosphere. Greenhouse gases are gases in the Earth’s atmosphere that can absorb and emit radiation, primarily infrared radiation.

The greenhouse gas that interacts with radiation across the largest number of wavelengths is water vapor (\(\ce{H2O}\)), which interacts strongly with the atmosphere, especially in the longer wavelength portion of the spectrum. Other gases, such as Carbon Dioxide (\(\ce{CO2}\)), Oxygen (\(\ce{O2}\)), Ozone (\(\ce{O3}\)), Methane (\(\ce{CH4}\)), and Nitrous Oxide (\(\ce{NO}\)) also interact with radiation.

undefined — Radiation transmitted by the atmosphere as a function of wavelength. Downgoing solar radiation is on the left, and upgoing thermal radiation is on the right, with the percentage of radiation absorbed and scattered by the Earth’s atmosphere below. Finally, the percentage of radiation absorbed and scattered is then divided by the major greenhouse gases in the panels at the bottom (CC BY-SA 3.0).

In the panel of the figure above showing the total percentage of radiation that is absorbed by the Earth’s atmosphere, you’ll notice white gaps. These are called Atmospheric Windows where the wavelength of radiation is able to pass through the atmosphere without interaction with greenhouse gases. Particularly notable is the visible portion of the electromagnetic energy spectrum that can pass through the atmosphere unimpeded. Also notable is the large amount of interference in the infrared portion of the spectrum. Earth’s atmosphere is practically transparent for shortwave radiation, and it strongly absorbs infrared radiation. This will be important for climate factors discussed in a later chapter.

Open-ended Question: Why do you think visible light (the peak of down-going solar radiation) is centered on an atmospheric window?

The interaction of atmospheric gases in Earth’s atmosphere is an important part of its energy balance. The greenhouse effect is the result of greenhouse gases absorbing and emitting outgoing infrared radiation emitted from Earth’s surface. Because Earth’s outgoing longwave radiation is partially absorbed by the atmosphere, this has a warming effect on Earth’s surface making it warmer than it would be otherwise. While the greenhouse effect has a bad reputation, this process has in fact allowed Earth to be habitable.

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