Chapter19a

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Transcript Chapter19a 

Atmospheric Optics - I
Recap
• Condensation
above the Earth surface
produces clouds.
• Clouds
are divided into 4 main groups:
♦ High
♦ Middle
♦ Low
♦ Clouds with vertical development
• Satellites
give a bird’s eye view of
clouds.
an astronaut’s
♦ Geostationary satellites
♦ Polar-orbiting satellites
• Infrared
images can provide a threedimensional view of the clouds:
♦ Height of the cloud
♦ Temperature of the cloud
•
•
•
Color
The human eye is sensitive to the visible part of the electromagnetic spectrum
(l=0.4-0.7 mm):
♦ Intensity - light or dark;
♦ Wavelength – color.
♦ We see the objects because they emit and/or interact with light
(reflection, transmission, absorption, refraction, scattering, diffraction)
Perception of color:
♦ Each color corresponds to a particular
wavelength.
♦ White: all wavelengths are present with
equal intensity;
♦ Black: no light is emitted and/or reflected
from the object.
Color of emitted light and temperature:
♦ The sun appears white.
♦ Colder stars look redder (lmax is longer than lmax of the sun).
♦ Hotter stars look bluer (lmax is shorter than lmax of the sun).
Scattering of light
• The
scattering of light in the atmosphere depends on the size of
the scattering particles, R, and on the wavelength, l, of the
scattered light.
• Geometric
scattering: R>>l
♦ Rain drops (R~10-100 mm)
l
R
♦ All wavelengths equally scattered
♦ Optical effects: white clouds
• Mie
scattering: R~l
♦ Aerosols (R~0.01-1 mm)
l
R
♦ Red scattered better than blue
♦ Blue moon, blue sun
• Rayleigh
scattering: R<<l
♦ Air molecules (R~0.0001-0.001 mm)
♦ Blues scattered better than red
♦ Blue sky, blue mountains, red sunsets
l
R
White Clouds
White clouds
• Description: the clouds appear white or grey.
• Physical process: geometric scattering by rain drops.
• Explanation:
•
♦ Visible light at all l is scattered in all directions.
♦ Clouds are optically thick with respect to light scattering but
they do not absorb light well.
♦ The thicker the cloud is the more light is scattered
backwards and less solar light reaches the bottom of the
cloud. Therefore thicker clouds appear darker.
♦ At the bottom of very thick clouds the raindrops are even
larger and absorb sun light better. These clouds look even
darker.
Conclusion: By the appearance of the cloud one can judge
whether it will rain and how strong the storm will be.
Blue Sky
• Description:
on clear days the sky is blue and on hazy days the sky is
white.
• Physical process: Rayleigh scattering by air molecules.
• Explanation:
shorter
l (violet, blue) are
scattered more
efficiently by air
molecules than
longer l (red).
• Conclusion:
Clear
sky, distant objects
have a bluish hue.
Blue Mountains
•
Crepuscular Rays
Light scattered underneath low clouds
♦ “the sun is drawing up water”, “Jacob’s ladder”
Recap: blue sky and white clouds
•
• salt particles.
•
•
White Sky
Description: on hazy days the sky is white.
Physical process: geometric scattering by dust and
Explanation: all l are scattered equally well.
Conclusion: By the color of the sky we can judge the
quality of the air, the dust load or the humidity of
the air.
Extraterrestrial skies
Moon sky
Mars at noon
Mars at sunset
Venus sky
Titan
The Color of the Sun
The Color of the Sun
•
• fine dust particles.
•
The Color of The Sun
Description: at sunrise and sunset the sun is yellow, orange
or red
Physical process: Rayleigh scattering by air molecules and
•
Explanation: on clear days only the blue light is scattered
away, on hazy days the yellow and the orange wavelengths
are also scattered and only the red remains in the direct
solar light.
Conclusion: Red sunsets suggest that there is dust in the
air (pollution, haze over the ocean, volcanic activity, dust
storms).
Blue Moon
•
• Physical process: Mie scattering by dust particles.
•
Description: the moon appears blue.
•
Explanation: When the size of the dust particles is
approximately equal to the visible wavelengths the
red light is scattered better than the blue light.
Conclusion: one can guess what is the size of the
particles in the air.
Reflection and Refraction of Light
• The
speed of light in vacuum
is c=300,000 km/s
• Snell’s
law: The angle of
incidence is equal to the
angle of reflection.
• Light
that enters a moredense medium slows down and
bends toward the normal.
• Light
that exits a moredense medium speeds up and
bends away from the normal.
•
True and apparent position of objects
Due to the refraction of
light the objects on the
sky appear higher than
they actually are.
♦ Star location and
scintillations;
♦ Timing of the sunset
and the sunrise;
♦ The sun on the horizon
looks flattened;
♦ Twilight.
The Timing of the Sunset & Sunrise
We see the sun before it actually rises above the horizon and after it
sets below the horizon.
Twilight
Flattening of the Sun’s Disk at Sunset
Green flash
Flattening of the Moon
Refraction by the Earth’s atmosphere (image from ISS)
http://www.sundog.clara.co.uk/atoptics/phenom.htm