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Sky brightness refers to thevisual perception of thesky and how itscatters anddiffuses light. The fact that the sky is not completely dark atnight is easily visible. If light sources (e.g. theMoon andlight pollution) were removed from thenight sky, only directstarlight would be visible.
The sky's brightness varies greatly over the day, and the primary cause differs as well. Duringdaytime, when theSun is above the horizon, thedirect scattering ofsunlight is the overwhelmingly dominant source of light. Duringtwilight (the duration aftersunset or beforesunrise until or since, respectively, the full darkness of night), the situation is more complicated, and a further differentiation is required.
Twilight (bothdusk anddawn) is divided into three 6° segments that mark the Sun's position below the horizon. Atcivil twilight, the center of the Sun's disk appears to be between 1/4° and 6° below the horizon. Atnautical twilight, the Sun'saltitude is between –6° and –12°. Atastronomical twilight, the Sun is between –12° and –18°. When the Sun's depth is more than 18°, the sky generally attains its maximum darkness.
Sources of the night sky's intrinsic brightness includeairglow, indirect scattering ofsunlight, scattering ofstarlight, andlight pollution.[1]
When physicistAnders Ångström examined the spectrum of theaurora borealis, he discovered that even on nights when the aurora was absent, its characteristic green line was still present. It was not until the 1920s that scientists were beginning to identify and understand theemission lines in aurorae and of the sky itself, and what was causing them. The green line Angstrom observed is in fact an emission line with a wavelength of 557.7 nm, caused by the recombination of oxygen in the upper atmosphere.
Airglow is the collective name of the various processes in the upper atmosphere that result in the emission of photons, with the driving force being primarilyUV radiation from the Sun. Several emission lines are dominant: a green line from oxygen at 557.7 nm, a yellow doublet from sodium at 589.0 and 589.6 nm, and red lines from oxygen at 630.0 and 636.4 nm.
The sodium emissions come from a thinsodium layer approximately 10 km thick at an altitude of 90–100 km, above themesopause and in the D-layer of theionosphere. The red oxygen lines originate at altitudes of about 300 km, in the F-layer. The green oxygen emissions are more spatially distributed. How sodium gets to mesospheric heights is not yet well understood, but it is believed to be a combination of upward transport ofsea salt andmeteoritic dust.
In daytime, sodium and red oxygen emissions are dominant and roughly 1,000 times as bright as nighttime emissions because in daytime, the upper atmosphere is fully exposed to solar UV radiation. The effect is however not noticeable to the human eye, since the glare ofdirectly scattered sunlight outshines and obscures it.
Indirectly scattered sunlight comes from two directions. From the atmosphere itself, and from outer space. In the first case, the Sun has just set but still illuminates the upper atmosphere directly. Because the amount of scattered sunlight is proportional to the number of scatterers (i.e. air molecules) in the line of sight, the intensity of this light decreases rapidly as the Sun drops further below the horizon and illuminates less of the atmosphere.
When the Sun's altitude is < -6° 99% of the atmosphere inzenith is in the Earth's shadow and second order scattering takes over. At the horizon, however, 35% of the atmosphere along the line of sight is still directly illuminated, and continues to be until the sun reaches -12°. From -12° to -18° only the uppermost parts of the atmosphere along the horizon, directly above the spot where the Sun is, is still illuminated. After that, all direct illumination ceases and astronomical darkness sets in.
A second source sunlight is thezodiacal light, which is caused by reflection and scattering of sunlight on interplanetary dust. Zodiacal light varies quite a lot in intensity depending on the position of the Earth, location of the observer, time of year, and composition and distribution of the reflecting dust.
Not only sunlight is scattered by the molecules in the air. Starlight and the diffuse light of theMilky Way are also scattered by the air, and it is found that stars up toV magnitude 16 contribute to the diffuse scattered starlight.
Other sources such as galaxies and nebulae don't contribute significantly.
The total brightness of all the stars was first measured by Burns in 1899, with a calculated result that the total brightness reaching earth was equivalent to that of 2,000 first-magnitude stars[2] with subsequent measurements by others.[3]
Light pollution is an ever-increasing source of sky brightness inurbanized areas. In densely populated areas that do not have stringent light pollution control, the entire night sky is regularly 5 to 50 times brighter than it would be if all lights were switched off, and very often the influence of light pollution is far greater than natural sources (including moonlight). Withurbanization and light pollution, one third of humanity, and the majority of those in developed countries, cannot see theMilky Way.[4]
When the Sun has just set, the brightness of the sky decreases rapidly, thereby enabling the viewing of the airglow that is caused from such high altitudes that they are still fully sunlit until the Sun drops more than about 12° below the horizon. During this time, yellow emissions from the sodium layer and red emissions from the 630 nm oxygen lines are dominant, and contribute to the purplish color sometimes seen during civil and nautical twilight.
After the Sun has also set for these altitudes at the end of nautical twilight, the intensity of light emanating from earlier mentioned lines decreases, until the oxygen-green remains as the dominant source.
When astronomical darkness has set in, the green 557.7 nm oxygen line is dominant, and atmospheric scattering of starlight occurs.
Differential refraction causes different parts of the spectrum to dominate, producing agolden hour and ablue hour.
The following table gives the relative and absolute contributions to night sky brightness at zenith on a perfectly dark night at middle latitudes without moonlight and in the absence of anylight pollution.
| Cause | Surface brightness [S10] | Percentage |
|---|---|---|
| Airglow | 145 | 65 |
| Zodiacal light | 60 | 27 |
| Scatteredstarlight | ~15 | 7 |
(The S10 unit is defined as the surface brightness of a star whose V-magnitude is 10 and whose light is smeared over one square degree, or 27.78 mag arcsec−2.)
The total sky brightness in zenith is therefore ~220 S10 or 21.9 mag/arcsec² in the V-band. Note that the contributions from Airglow and Zodiacal light vary with the time of year, the solar cycle, and the observer's latitude roughly as follows:
whereS is the solar 10.7 cm flux in MJy, and various sinusoidally between 0.8 and 2.0 with the 11-year solar cycle, yielding an upper contribution of ~270 S10 at solar maximum.
The intensity of zodiacal light depends on theecliptic latitude and longitude of the point in the sky being observed relative to that of the Sun. At ecliptic longitudes differing from the Sun's by > 90 degrees, the relation is
whereβ is the ecliptic latitude and is smaller than 60°, when larger than 60 degrees the contribution is that given in the table. Along the ecliptic plane there are enhancements in the zodiacal light where it is much brighter near the Sun and with a secondary maximum opposite the Sun at 180 degrees longitude (thegegenschein).
In extreme cases natural zenith sky brightness can be as high as ~21.0 mag/arcsec², roughly twice as bright as nominal conditions.