• see also:
  • astronomic "seeing"
  • light pollution
  • sky transparency and atmospheric extinction

• sky brightness refers to the visual perception of the sky and how it scatters and diffuses light.
• the background brightness of the night sky is an important factor in how well we can see celestial objects such as planets, stars, meteors and comets

• object visibility function = (object's extra-atmospheric luminance) exp(-extinction coeff x extinction function) / (twilight sky luminance + night sky luminance)¹⁾
• the main factors of whether an object will be visible on a clear night are:
  • the brightness of the object as viewed beyond earth's atmosphere
  • the optical extinction due to earth's atmosphere
    • dependent upon:
      • the object's elevation above the horizon (the higher the better) - see sky transparency and atmospheric extinction
      • sky transparency - see sky transparency and atmospheric extinction
  • the limiting night sky brightness (if the sky is brighter than the comet, you will not see it):
    • light pollution
    • airglow
    • starlight
    • zodiacal light
    • moon light
    • (see also light pollution)
  • if near twilight, the contours of background sky brightness during twilight
    • this depends upon:
      • depth of sun below the horizon
      • azimuth angle between sun and the comet
      • elevation of comet above horizon
  • for vision of faint objects in dark skies other factors become important:
    • visual dark adaptation
    • averted vision technique to utilise the rods instead of cones in your retina
    • visual aids such as binoculars or telescopes as these provide:
      • greater light gathering power
        • this vastly increases visibility with the limiting magnitude of a visible object increasing to 10 with a 50mm aperture optic and to 13 with a 200mm diameter telescope
      • greater threshold contrast (ability to see an object whose brightness is near the background brightness)
        • an 8“ aperture telescope has nearly 200x better threshold contrast than the naked eye
    • see astronomic viewing conditions
• a separate issue, is how well the object can be seen through a telescope
  • this largely depends upon how stable the atmosphere is - see astronomic "seeing"

• luminance quantifies the brightness of a surface or light source in a specific direction, measuring luminous intensity per unit projected area

• this is a hand held tool which is pointed at the zenith and uses a silicon photodiode with a filter sensitive to 390–600 nm wavelengths to detect luminance from the night sky. They are much too sensitive for twilight readings unless ND filters are used.
  • eg. Unihedron SQM L
• it converts light to a frequency signal, outputting values in magnitudes per square arcsecond (mag/arcsec²) - the higher the value, the darker the sky
• maximum SQM without light pollution is assumed to be 22 mag/arcsec² at the zenith (highest point in the sky) and this is limited by natural air glow, etc.
  • the max SQM also depends upon the wavelengths of light being detected
    • for Johnson U (blue) it is higher and R (red, and I (infrared) it is lower.

• cd/m² = 10.8×10⁴ × 10^{(-0.4*[value in mag/arcsec²])}
• SQM in mag/arcsec² = Log10([value in cd/m²]/108000)/-0.4

• the sun obviously also causes major effects on sky brightness before sunrise and after sunset
• if there is any sun above the horizon, only objects with magnitude brighter than about minus 2 (eg. Venus, Jupiter, moon, occasionally Mars at opposition) can be seen - albeit with difficulty in daylight
• remember the sun moves 15deg per hour due to earth's rotation but rate that it disappears depends upon latitude from the equator and the sun's declination (ie. season)
• the sun through the year follows the ecliptic which is tipped 23½° with respect to the celestial equator (the same plane as the equator on Earth).
• depending on the season and the observer’s latitude, the Sun may appear to set at a steep or a shallow angle relative to the horizon.
• at latitude more than 68° north or south, depending on the season, the Sun may not rise or set at all.
• Twilight Stages:
  • Civil Twilight (Sun 0° to 6° down):
    • only the brightest stars (magnitude 0 or brighter, like Sirius, Vega, Arcturus) and planets (Venus, Jupiter) are visible.
  • Nautical Twilight (Sun 6° to 12° down):
    • 1st magnitude stars appear as the sky gets darker.
  • Astronomical Twilight (Sun 12° to 18° down):
    • by the end of this period, 6th magnitude stars (naked-eye limit) become visible, particularly at the zenith.

• SQM rises in an almost linear fashion as the sun drops below the horizon up until 12deg below horizon then increase in darkness tapers off :²⁾

for Sun elevation (x) 0° up to -12°, the zenith SQM value ≈ -1.057x + 6.7489

for Sun elevation (x) 12° up to -18° the zenith SQM value ≈ -0.0744x² - 2.5768x - 0.5845

• object visibility function = (object's extra-atmospheric luminance) exp(-extinction coeff x extinction function) / (twilight sky luminance + night sky luminance)³⁾
• at 60min before sunrise a star near the sun would need to be brighter than mag 4.5 at 4deg above the horizon to be visible in standard photos, hence comets less bright would not be visible closer to the horizon and their tails which are usually less bright again would be washed out by twilight even higher above the horizon
• eg. a comet mag 4.7 at ~14deg vertical elevation from the sun and 25deg elongation from the sun will be about 3deg above horizon 1hr before sunrise and thus will not be visible due to the sky glow as it is too close to the sun for that brightness
• at sunset, if the object if high enough above the horizon, and bright enough, it may become visible for some time as the twilight darkens just before the comet sets and atmospheric extinction obliterates it
• before sunrise, if the object is bright enough and rises high enough to get past atmospheric extinction effects before twilight impacts, it may be visible for a short period until twilight obliterates it