The sky is'nt so depressing when you have someone who loves you , find a partner and look at the sky together , you will never forget it
2007-02-02 17:31:13
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answer #1
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answered by scrapy626_420 3
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The light coming from the sun is white, which is to say all colors. As the light hit the atmosphere, scattering begins (it is called Rayleigh scattering). Now, lets say you are a molecule in the upper atmosphere. A photon of blue light hit a molecule and it scatters off in your direction. When you see this photon, which direction do you see it from? The sun, no! You see it from the direction of the first molecule. This is what happens billions of time before the light comes to the surface.
Blue and violet light are scattered more easily than red and orange, however, there is more blue light than violet light coming from the sun. Also, your senses are better at perievning blue than violet, so you see the entire sky as blue.
Unfortunatly, I can't put graphics up here, but that ought to give you a good idea.
2007-02-03 01:06:34
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answer #2
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answered by Walking Man 6
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The sky is blue partly because air scatters short-wavelength light in preference to longer wavelengths. Combined, these effects scatter (bend away in all directions) some short, blue light waves while allowing almost all longer, red light waves to pass straight through. When we look toward a part of the sky not near the sun, the blue color we see is blue light waves scattered down toward us from the white sunlight passing through the air overhead. Near sunrise and sunset, most of the light we see comes in nearly tangent to the Earth's surface, so that the light's path through the atmosphere is so long that much of the blue and even yellow light is scattered out, leaving the sun rays and the clouds it illuminates red.
Scattering and absorption are major causes of the attenuation of radiation by the atmosphere. Scattering varies as a function of the ratio of the particle diameter to the wavelength of the radiation. When this ratio is less than about one-tenth, Rayleigh scattering occurs in which the scattering coefficient varies inversely as the fourth power of the wavelength. At larger values of the ratio of particle diameter to wavelength, the scattering varies in a complex fashion described, for spherical particles, by the Mie theory; at a ratio of the order of 10, the laws of geometric optics begin to apply.
2007-02-03 03:21:30
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answer #3
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answered by Nitya 2
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clear cloudless day-time sky is blue because molecules in the air scatter blue light from the sun more than they scatter red light. When we look towards the sun at sunset, we see red and orange colours because the blue light has been scattered out and away from the line of sight.
The white light from the sun is a mixture of all colours of the rainbow. This was demonstrated by Isaac Newton, who used a prism to separate the different colours and so form a spectrum. The colours of light are distinguished by their different wavelengths. The visible part of the spectrum ranges from red light with a wavelength of about 720 nm, to violet with a wavelength of about 380 nm, with orange, yellow, green, blue and indigo between. The three different types of colour receptors in the retina of the human eye respond most strongly to red, green and blue wavelengths, giving us our colour vision.
Tyndall Effect
The first steps towards correctly explaining the colour of the sky were taken by John Tyndall in 1859. He discovered that when light passes through a clear fluid holding small particles in suspension, the shorter blue wavelengths are scattered more strongly than the red. This can be demonstrated by shining a beam of white light through a tank of water with a little milk or soap mixed in. From the side, the beam can be seen by the blue light it scatters; but the light seen directly from the end is reddened after it has passed through the tank. The scattered light can also be shown to be polarised using a filter of polarised light, just as the sky appears a deeper blue through polaroid sun glasses.
2007-02-03 04:18:51
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answer #4
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answered by bAdgIrL™ 4
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As you know white light is made up of 7 colours...
V - violet
I - indigo
B - Blue
G - Green
Y - yellow
O - orange
R - red
Now ,the colours on the top of the list have lesser wavelength, i.e
greater frequency than the ones near the bottom..
Hence they are are the ones refracted the most by the atmosphere....
Hence the sky seems to be a mixtue of violet,indigo and blue...
giving it a 'sky' blue colour...............
:)
2007-02-03 01:07:43
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answer #5
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answered by dexter 2
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That's the way God made it. I don't find it depressing at all. Blue is a beautiful color. The sky changes to many shades of blue.
2007-02-03 01:07:53
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answer #6
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answered by FL Girl 6
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The sky is blue partly because air scatters short-wavelength light in preference to longer wavelengths. Combined, these effects scatter (bend away in all directions) some short, blue light waves while allowing almost all longer, red light waves to pass straight through. When we look toward a part of the sky not near the sun, the blue color we see is blue light waves scattered down toward us from the white sunlight passing through the air overhead. Near sunrise and sunset, most of the light we see comes in nearly tangent to the Earth's surface, so that the light's path through the atmosphere is so long that much of the blue and even yellow light is scattered out, leaving the sun rays and the clouds it illuminates red.
Scattering and absorption are major causes of the attenuation of radiation by the atmosphere. Scattering varies as a function of the ratio of the particle diameter to the wavelength of the radiation. When this ratio is less than about one-tenth, Rayleigh scattering occurs in which the scattering coefficient varies inversely as the fourth power of the wavelength. At larger values of the ratio of particle diameter to wavelength, the scattering varies in a complex fashion described, for spherical particles, by the Mie theory; at a ratio of the order of 10, the laws of geometric optics begin to apply.
Why is the sky blue instead of violet?
Because of the strong wavelength dependence (inverse fourth power) of light scattering according to Raleigh's Law, one would expect that the sky would appear more violet than blue, the former having a shorter wavelength than the latter. There is a simple physiological explanation for this apparent conundrum. Simply put, the human eye cannot detect violet light in presence of light with longer wavelengths. There is a reason for this. It turns out that the human eye's high resolution color-detection system is made of proteins and chromophores (which together make up photoreceptor cells or "Cone" structures in the eye's fovea) that are sensitive to different wavelengths in the visible spectrum (400 nm–700 nm). In fact, there are three major protein-chromophore sensors that have peak sensitivities to yellowish-green (564 nm), bluish-green (534 nm), and blue-violet (420 nm) light. The brain uses the different responses of these chromophores to interpret the spectrum of the light that reaches the retina.
When one experimentally plots the sensitivity curves for the three color sensors (identified here as long (L), middle (M), and short (S) wavelength), three roughly "bell-curve" distributions are seen to overlap one another and cover the visible spectrum. We depend on this overlap for color sensing to detect the entire spectrum of visible light. For example, monochromatic violet light at 400 nm mostly stimulates the S receptors, but also slightly stimulates the L and M receptors, with the L receptor having the stronger response. This combination of stimuli is interpreted by the brain as violet. Monochromatic blue light, on the other hand, stimulates the M receptor more than the L receptor. Skylight is not monochromatic; it contains a mixture of light covering much of the spectrum. The combination of strong violet light with weaker blue and even weaker green and yellow strongly stimulates the S receptor, and stimulates the M receptor more than the L receptor. As a result, this mixture of wavelengths is perceived by the brain as blue rather than violet.
2007-02-03 02:42:31
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answer #7
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answered by catzpaw 6
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The sky was once red. I yelled to the sky,"I'm Blue and so are you!" and it turned the beautiful blue that I damned it to be.
2007-02-03 01:04:04
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answer #8
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answered by Ericqua 4
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The sky just reflects the ocean.
So paint the ocean in a diffrent color,
and you get a diffrent sky!
2007-02-03 01:05:11
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answer #9
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answered by Anonymous
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the nitrogen makes the sky blue. i learned that in earth science way back in the day.
2007-02-03 01:01:07
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answer #10
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answered by Dr. PHILlis (in training) 5
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