Why does the sky after sunset mimic the blackbody spectrum?
Physics Asked on June 2, 2021
There are several answers on this site and elsewhere about why the sky is blue and why sunsets are reddish. But I could not find anything that discusses the relationship between the blackbody spectrum and the spectrum of colors seen above the horizon after sunset.
In particular, the "physical spectrum" (meaning the set of colors seen in the sky at increasing altitude above the horizon) after sunset looks identical to the blackbody spectrum. Perhaps this is related to the fact that sunlight is approximately blackbody to begin with, but I can’t find any source that discusses this. For example, consider the following questions:
-
If sunlight had an "even" spectrum in the visible range, instead of blackbody, would sunsets look considerably different? Would they stop looking like the blackbody spectrum?
-
Is the color spectrum at each fixed location in the sky actually a blackbody spectrum (whose color temperature varies with altitude), or only approximately a blackbody spectrum? (Assume even that the sun is a perfect blackbody.)
-
Since sunlight is blackbody, is it inevitable that any type of scattering would create a blackbody-like gradation of colors in the sky, i.e., not necessarily Rayleigh scattering?
In short, why does the physical spectrum of colors seen in the sky after sunset mimic the blackbody spectrum?
One Answer
Red/orange, white and blue are the colors you see when the intensity of light as a function of frequency (or wavelength) is very roughly linear across the visible range. To get other hues, you need narrow peaks or troughs in the spectrum, and Rayleigh scattering and blackbodies don't produce such spectra for different reasons.
Spectra from Rayleigh scattering are monotonic in the frequency. Blackbody spectra of different temperatures are all translated copies of a single shape on a log chart, as seen here:
At around 6000 K the visible part is roughly flat (white), at lower temperatures it's brighter at the red end, and at higher temperatures it's brigher at the violet end (but not sharply peaked there, so it appears blue, not violet).
So it's coincidence in the sense that Rayleigh scattering and blackbody emission are totally different processes, but not coincidence in the sense that you can expect to get similar colors from any physical process that doesn't produce narrow peaks or troughs in the spectrum.
Answered by benrg on June 2, 2021
Add your own answers!
Ask a Question
Get help from others!
Recent Answers
- haakon.io on Why fry rice before boiling?
- Jon Church on Why fry rice before boiling?
- Joshua Engel on Why fry rice before boiling?
- Peter Machado on Why fry rice before boiling?
- Lex on Does Google Analytics track 404 page responses as valid page views?
Recent Questions
- How can I transform graph image into a tikzpicture LaTeX code?
- How Do I Get The Ifruit App Off Of Gta 5 / Grand Theft Auto 5
- Iv’e designed a space elevator using a series of lasers. do you know anybody i could submit the designs too that could manufacture the concept and put it to use
- Need help finding a book. Female OP protagonist, magic
- Why is the WWF pending games (“Your turn”) area replaced w/ a column of “Bonus & Reward”gift boxes?