Astro 1050 Mon. Feb. 9, 2004
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Today: Review exam 1 |
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Continue Chapter 5 |
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Chapter 5: Astronomical
Tools
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Properties of light are fundamental |
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Almost everything we know about the
universe outside our solar system comes from interpreting the light from
distant objects. |
Radiation: Two different
kinds
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Something that “radiates”, or spreads
out in “rays” |
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High speed particles (eg. high speed
neutrons ejected from a disintegrating atomic nucleus) |
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Electromagnetic radiation: |
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Towards shorter “wavelength” and higher
energy: |
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Visible light, Ultraviolet light,
X-Rays, Gamma-Rays |
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Towards longer “wavelength” and lower
energy: |
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Visible light, Infrared radiation,
microwaves, radio waves |
Properties of Light
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Light has both wave and particle
properties |
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Travels like a wave |
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Interacts with matter like a
particle: “photon” |
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Full explanation involves quantum
mechanics |
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For most cases we can just choose the
right “model” from the above two choices |
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Photons, unlike particles in other
kinds of “radiation,” are particles of “pure energy” |
Light is an
electromagnetic wave
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Changing electric fields generates
magnetic fields |
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Changing magnetic fields generates
electric fields |
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Can set up a cycle where one field
causes the other: |
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The E and B fields oscillate in
strength, and the disturbance moves forward. |
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To describe the wave you need to
specify |
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Direction it is moving |
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Strength of the fields (its intensity) |
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Frequency or Wavelength of the
oscillation (u and l are inversely related) |
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Orientation of the electric E
field: up or sideways (polarization) |
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You do not need to specify its speed |
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In a vacuum all lightwaves move at the
same speed c = 3´108
m/s |
The Electromagnetic Spectrum
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Radio waves |
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Microwaves |
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Infrared |
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Visible |
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Ultra-violet |
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X-Rays |
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Gamma rays |
Relationship between
Energy and Wavelength of Light
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Short wavelength Ţ High energy photons |
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Long
wavelength Ţ Low energy
photons |
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Intensity µ total energy (per area
per second)
µ (# of photons per area per
second)
´ (energy per photon) |
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Example with falling rain: |
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Amount of rain µ (# of
raindrops) ´ (volume per drop) |
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Why is energy per photon
so important?
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Modified example: Hailstorm (with your car outside in it) |
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Threshold for damage to car set by size
of individual hailstones |
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Below threshold hailstones cause no
dents |
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Above threshold they cause bigger dents |
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Number of dents = number of hailstones
bigger than threshold |
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Very unlikely two small hailstones can
hit exactly together to cause dent |
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Real life example: Ultra-Violet light hitting your skin |
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Threshold for chemical damage set by
energy (wavelength) of photons |
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Below threshold (long wavelengths)
energy too weak to cause chemical changes |
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Above threshold (short wavelength)
energy photons can break apart DNA
molecules |
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Number of molecules damaged = number of
photons above threshold |
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Very unlikely two photons can hit
exactly together to cause damage |
Numerical Relationship
between
wavelength and photon energy
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Inverse relationship: Smaller l means more energetic |
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c = speed of light = 3.00 ´ 108 m/s |
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h = Planck’s constant = 6.63 ´ 10-34 joules x s |
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Note:
Joule is a unit of energy
1 Joule/second = 1 Watt |
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Energy of a single photon of 0.5 mm visible
light? |
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Seems very small, but this is roughly
the energy it takes to chemically modify a single molecule. |
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Photons from a 100 W lightbulb (assuming all 100W goes into light?) |
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Optical Telescopes and
Cameras
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Properly curved lenses and mirrors can
form “Images” |
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All the light leaving one point on
object gets “reassembled” at one point on the image. |
Refracting vs. Reflecting
Telescopes
Why do astronomers need
large telescopes?
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Large telescopes can collect more light |
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Can detect fainter objects |
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Have more light for specialized
analysis. |
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Large telescopes can form more detailed
images |
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Waves spread out as they go through an
opening. |
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The larger the opening, the less they
spreads out. |
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The longer the wavelength the more they
spread out |
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Angle of spread q µ l/D where D is Diameter of telescope |
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Radio telescopes have to be much bigger
than visible ones |
Kinds of measurements
made with telescopes
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Measure brightness of objects
(photometry) |
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Record images using electronic “CCD”
detectors |
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Split it into different wavelengths
with “spectrometers” |
Dark Side of the Moon
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“There is no dark side really. It’s all dark.” -- Pink Floyd |
Dark Side of the Moon
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What is wrong with this picture? |
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Front: Not all primary colors (eg,
pink, magenta), also refraction angles inconsistent |
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Back: Spectrum is Convergent – I think
done for art’s sake |
Observing over the entire
electromagnetic spectrum
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Different phenomena produce different
wavelength waves |
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Ordinary stars: Visible light |
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Cool planets or dust clouds: Infrared light |
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Moving charged particles, cool
molecules: Radio waves |
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Very hot objects: X-Rays and Gamma Rays |
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Quasars: ALL wavelengths |
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Only visible, some IR, and radio make
it through atmosphere |
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Need to observe from space for other
wavelengths |
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Going into space also lets you obtain
more detailed images |
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On Earth telescope size isn’t only
limit on image resolution |
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Temperature fluctuations in atmosphere
cause “seeing” (blurring) |
Bad “seeing”/Good
“seeing”
Active/Adaptive Optics
Hubble Space Telescope
(HST)
Chandra X-ray Observatory
Radio Telescopes
Infrared Telescopes
Infrared Telescopes
The Electromagnetic Spectrum
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Radio waves |
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Microwaves |
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Infrared |
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Visible |
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Ultra-violet |
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X-Rays |
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Gamma rays |
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