Invite friends
I want  answers   advisors   relevant links   my network
Search 
For


How it works
  MEMBERS LOGIN
EMAIL ADDRESS  
PASSWORD  
 
Register!          Forgot password?


CATEGORY : SCIENCE
All Science Advice
Unanswered Queries
FileAgent Document Exchange
Council Members
Advisor Rankings
Top Rated Advisors
NameAsk Me Rate (in AA$)
Ammas.com, Ltd N/A
Anonymous Ajnabi N/A
usha gurnani N/A
Creative Services $50.00   
Dr.Anjna Agarwal N/A
sambasivan s $400.00   
PUNDALIK ADKAR N/A
Gaurav Paliwal $50.00   
Anoop C S $1.00   
Lathaa Manavalan $50.00   
More Advisors...

Home > Categories > Science and Technology > Science > View Advice  

Query from: Anonymous, United States, 04/30/11
Topic: SCIENCE      Submitted on: AnswerPod.com
Subject: Common Knowledge

Please provide your answer WITHOUT using links or attaching images, docs, etc. (You must still give your source, however).
Attention Council Members: If this query is in the wrong category, be sure to put it in the appropriate category.

Here is the question: What color is the sky

Rate = 2.5 (Rated by 2 Council Members)
[ This query closed ]
random/sunfire.jpeg
Response from: Dr.Anjna Agarwal,   
Featured Member on Ammas.com
Source: This information comes from my own knowledge.
WHY IS THE SKY BLUE?

The blue color of the sky is due to Rayleigh scattering. As light moves through the atmosphere, most of the longer wavelengths pass straight through. Little of the red, orange and yellow light is affected by the air.

However, much of the shorter wavelength light is absorbed by the gas molecules. The absorbed blue light is then radiated in different directions. It gets scattered all around the sky. Whichever direction you look, some of this scattered blue light reaches you. Since you see the blue light from everywhere overhead, the sky looks blue.

In short, the sky appears to be blue as perceived by the human eye. This is because the light from the sky is a result of the sunlight scattering. The sky can change and appear lots of colors, such as red, orange, yellow, pink, purple (at sunrise and sunset) and black (at night).

http://anu0562.blogspot.com/…

Rate = 2 (Rated by 1 Council Member)

Thank this advisor   
 
Response from: Nagarajan S,   
Featured Member on Ammas.com
Source: This information comes from my own knowledge.
Sky is light Blue.

Rate = 3 (Rated by 2 Council Members)

Thank this advisor   
 
Response from: n manohar rao,   
Featured Member on Ammas.com
Source: This information comes from my own knowledge.
light blue

Rate = 3 (Rated by 2 Council Members)

 
Response from: sambasivan s,   
Featured Member on Ammas.com
Source: http://math.ucr.edu/home/baez/physi…
BLUE.

A 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.

This is most correctly called the Tyndall effect, but it is more commonly known to physicists as Rayleigh scattering--after Lord Rayleigh, who studied it in more detail a few years later. He showed that the amount of light scattered is inversely proportional to the fourth power of wavelength for sufficiently small particles. It follows that blue light is scattered more than red light by a factor of (700/400)4 ~= 10.

Dust or Molecules?

Tyndall and Rayleigh thought that the blue colour of the sky must be due to small particles of dust and droplets of water vapour in the atmosphere. Even today, people sometimes incorrectly say that this is the case. Later scientists realised that if this were true, there would be more variation of sky colour with humidity or haze conditions than was actually observed, so they supposed correctly that the molecules of oxygen and nitrogen in the air are sufficient to account for the scattering. The case was finally settled by Einstein in 1911, who calculated the detailed formula for the scattering of light from molecules; and this was found to be in agreement with experiment. He was even able to use the calculation as a further verification of Avogadro's number when compared with observation. The molecules are able to scatter light because the electromagnetic field of the light waves induces electric dipole moments in the molecules.

Why not violet?

If shorter wavelengths are scattered most strongly, then there is a puzzle as to why the sky does not appear violet, the colour with the shortest visible wavelength. The spectrum of light emission from the sun is not constant at all wavelengths, and additionally is absorbed by the high atmosphere, so there is less violet in the light. Our eyes are also less sensitive to violet. That's part of the answer; yet a rainbow shows that there remains a significant amount of visible light coloured indigo and violet beyond the blue. The rest of the answer to this puzzle lies in the way our vision works. We have three types of colour receptors, or cones, in our retina. They are called red, blue and green because they respond most strongly to light at those wavelengths. As they are stimulated in different proportions, our visual system constructs the colours we see.

When we look up at the sky, the red cones respond to the small amount of scattered red light, but also less strongly to orange and yellow wavelengths. The green cones respond to yellow and the more strongly scattered green and green-blue wavelengths. The blue cones are stimulated by colours near blue wavelengths, which are very strongly scattered. If there were no indigo and violet in the spectrum, the sky would appear blue with a slight green tinge. However, the most strongly scattered indigo and violet wavelengths stimulate the red cones slightly as well as the blue, which is why these colours appear blue with an added red tinge. The net effect is that the red and green cones are stimulated about equally by the light from the sky, while the blue is stimulated more strongly. This combination accounts for the pale sky blue colour. It may not be a coincidence that our vision is adjusted to see the sky as a pure hue. We have evolved to fit in with our environment; and the ability to separate natural colours most clearly is probably a survival advantage.

Sunsets

When the air is clear the sunset will appear yellow, because the light from the sun has passed a long distance through air and some of the blue light has been scattered away. If the air is polluted with small particles, natural or otherwise, the sunset will be more red. Sunsets over the sea may also be orange, due to salt particles in the air, which are effective Tyndall scatterers. The sky around the sun is seen reddened, as well as the light coming directly from the sun. This is because all light is scattered relatively well through small angles--but blue light is then more likely to be scattered twice or more over the greater distances, leaving the yellow, red and orange colours. Blue Haze and Blue Moon

Clouds and dust haze appear white because they consist of particles larger than the wavelengths of light, which scatter all wavelengths equally (Mie scattering). But sometimes there might be other particles in the air that are much smaller. Some mountainous regions are famous for their blue haze. Aerosols of terpenes from the vegetation react with ozone in the atmosphere to form small particles about 200 nm across, and these particles scatter the blue light. A forest fire or volcanic eruption may occasionally fill the atmosphere with fine particles of 500--800 nm across, being the right size to scatter red light. This gives the opposite to the usual Tyndall effect, and may cause the moon to have a blue tinge since the red light has been scattered out. This is a very rare phenomenon, occurring literally once in a blue moon.

Opalescence

The Tyndall effect is responsible for some other blue coloration's in nature: such as blue eyes, the opalescence of some gem stones, and the colour in the blue jay's wing. The colours can vary according to the size of the scattering particles.

Rate = 4.5 (Rated by 2 Council Members)

Thank this advisor   
 
Response from: Suraj Manik,   
Registered Member on Ask Agent
Source: This information comes from my own knowledge.
The sky doesn't have a colour of its own, but when sun light enters our atmosphere, the light through the varying densities of air refracts and bends. We know that sunlight is considered as white light which comprises of all the colours in our spectrum, and different coulours have different wavelengths, which means they refract(bend) in different amounts. Hence during noon, the light hits the earth directly and passes through all the layers of air at a right angle, hence no refraction occurs and the sky illuminates to the natural sunlight coulour. At dawn or dusk, the light passes through the layers of air at an angle, causing it to bend toward the earth. Red refracts the least and violet refracts the most, hence the sky colour ranges from red to violet as the light bends and illuminates the particles present in our atmosphere.

Rate = 5 (Rated by 1 Council Member)

 
 
 
 
 
More Science Advice


 




Privacy Policy
Terms & Conditions
Ask Agent™ Tech Support/Help
Contact Us
Advertising Program
About the Ask Agent™ technology
Affiliate Program
Celebrity Queries
Latest Updates


Get the latest queries and responses via  Add Ammas Gadget to your iGoogle
Important Disclaimer: This question and answer system is open to the public. The opinions expressed are those of their individual authors, as attributed beside each item of advice. Neither the authors nor the information they provide are endorsed by this website. We recommend using common sense, making your own inquiries, and, if necessary, seeking professional advice before relying on material generated on this site.

Copyright © 1998 - 2014 Ammas.com.
Powered by Ask Agent
Patents filed since 2001 -- Request Patent Numbers
TOP