Title: ASTR 2310: Chapter 6
1ASTR 2310 Chapter 6
- Astronomical Detection of Light
- The Telescope as a Camera
- Refraction and Reflection Telescopes
- Quality of Images
- Astronomical Instruments and Detectors
- Observations and Photon Counting
- Other Wavelengths
- Modern Telescopes
2Refracting / Reflecting Telescopes
0
Refracting Telescope Lens focuses light onto the
focal plane
Focal length
Reflecting Telescope Concave Mirror focuses
light onto the focal plane
Focal length
Almost all modern telescopes are reflecting
telescopes.
3Secondary Optics
0
In reflecting telescopes Secondary mirror, to
re-direct light path towards back or side of
incoming light path.
Eyepiece To view and enlarge the small image
produced in the focal plane of the primary optics.
4Disadvantages of Refracting Telescopes
0
- Chromatic aberration Different wavelengths are
focused at different focal lengths (prism effect).
Can be corrected, but not eliminated by second
lens out of different material.
- Difficult and expensive to produce All surfaces
must be perfectly shaped glass must be flawless
lens can only be supported at the edges.
5The Best Location for a Telescope
0
Far away from civilization to avoid light
pollution
6The Best Location for a Telescope (II)?
0
Paranal Observatory (ESO), Chile
http//en.wikipedia.org/wiki/Paranal_Observatory
On high mountain-tops to avoid atmospheric
turbulence (? seeing) and other weather effects
7The Powers of a TelescopeSize does matter!
0
1. Light-gathering power Depends on the surface
area A of the primary lens / mirror, proportional
to diameter squared
D
T p (D/2)2
8The Powers of a Telescope (II)?
0
2. Resolving power Wave nature of light gt The
telescope aperture produces fringe rings that set
a limit to the resolution of the telescope.
Astronomers cant eliminate these diffraction
fringes, but the larger a telescope is in
diameter, the smaller the diffraction fringes
are. Thus the larger the telescope, the better
its resolving power.
?min 1.22 (?/D) (radians)?
For optical wavelengths, this gives
?min
?min 11.6 arcsec / Dcm
The Spectrograph
A Multiwavelength Look at Cygnus A
NASAs Great Observatories in Space (III)?
Wavelengths and Colors
Chandra X-ray Observatory
Light as a Wave
Dark Side of the Moon
Atoms Electron Configuration
Secondary Optics
The Powers of a Telescope (II)?
Dark Side of the Moon
The Electromagnetic Spectrum
The Best Location for a Telescope (II)?
Radio Interferometry
Keplers Supernova with all three of NASAs Great
Observatories
Astronomical Telescopes
Adaptive Optics
Examples of Modern Telescope Design
Radio Astronomy
Infrared Astronomy
Spitzer Space Telescope
0
The Highest Tech Mirrors Ever!
Interferometry
Radio Telescopes
Seeing
CCD Imaging
NASAs Great Observatories in Space (I)?
0
0
0
Advances in Modern Telescope Design
Science of Radio Astronomy
NASAs Great Observatories in Space (IV)?
Disadvantages of Refracting Telescopes
Traditional Telescopes (II)?
The Largest Radio Telescopes
Spitzer Space Telescope Images
The Future of Space-Based Optical/Infrared
Astronomy
0
Kirchoffs laws
Hydrogen Lines
0
0
0
Refracting / Reflecting Telescopes
Ultraviolet Astronomy
Hubble Space Telescope Images
NASAs Great Observatories in Space (II)?
Light as Particles
Temperature and Heat
0
0
0
0
0
Temperature Scales
Planck Black Body Radiation
0
0
0
0
0
The Powers of a TelescopeSize does matter!
0
Infrared Telescopes
Planck and other Formulae
Example of Wiens law
0
The Best Location for a Telescope
0
0
0
0
0
0
0
0
Why is energy per photon so important?
0
0
Traditional Telescopes (I)?
0
0
Terrestrial Planet Finder
Light as a Wave
0
0
0
0
0
- Molecules Multiple atoms sharing/exchanging
electrons (H2O, CH4)? - Ions Single atoms where one or more
electrons have escaped (H)? - Binding energy Energy needed to let electron
escape - Permitted orbits or energy levels
- From quantum mechanics, only certain orbits are
allowed - Ground State Atom with electron in lowest
energy orbit - Excited State Atom with at least one atom in a
higher energy orbit - Transition As electron jumps from one energy
level orbit to another, atom must
release/absorb energy different, usually as
light. - Because only certain orbits are allowed, only
certain energy jumps are allowed, and atoms can
absorb or emit only certain energies
(wavelengths) of light. - In complicated molecules or solids many
transitions are allowed - Can use energy levels to fingerprint elements
and estimate temperatures.
Using a prism (or a grating), light can be split
up into different wavelengths (colors!) to
produce a spectrum.
0
- Hot objects glow (emit light) as seen in
PREDATOR, SSC Video, etc. - Heat (and collisions) in material causes
electrons to jump to high energy orbits, and as
electrons drop back down, some of energy is
emitted as light. - Reason for name Black Body Radiation
- In a solid body the close packing of the atoms
means than the electron orbits are complicated,
and virtually all energy orbits are allowed. So
all wavelengths of light can be emitted or
absorbed. A black material is one which readily
absorbs all wavelengths of light. These turn out
to be the same materials which also readily emit
all wavelengths when hot. - The hotter the material the more energy it emits
as light - As you heat up a filament or branding iron, it
glows brighter and brighter - The hotter the material the more readily it emits
high energy (blue) photons - As you heat up a filament or branding iron, it
first glows dull red, then bright red, then
orange, then if you continue, yellow, and
eventually blue
Light and Other Forms of Radiation
- Thermal energy is kinetic energy of moving
atoms and molecules - Hot material energy has more energy available
which can be used for - Chemical reactions
- Nuclear reactions (at very high temperature)?
- Escape of gasses from planetary atmospheres
- Creation of light
- Collision bumps electron up to higher energy
orbit - It emits extra energy as light when it drops back
down to lower energy orbit - (Reverse can happen in absorption of light)?
- Hot solids emit continuous spectra
- Hot gasses try to do this, but can only emit
discrete wavelengths - Cold gasses try to absorb these same discrete
wavelengths
- Energy absorbed/emitted depends on upper and
lower levels - Higher energy levels are close together
- Above a certain energy, electron can escape
(ionization)? - Series of lines named for bottom level
- To get absorption, lower level must be occupied
- Depends upon temperature of atoms
- To get emission, upper level must be occupied
- Can get down-ward cascade through many levels
Just as for optical telescopes, the resolving
power of a radio telescope depends on the
diameter of the objective lens or mirror ?min
1.22 ?/D.
Most infrared radiation is absorbed in the lower
atmosphere.
- Want temperature scale with energy proportional
to T - Celsius scale is arbitrary (Fahrenheit even
more so)? - 0o C freezing point of water
- 100o C boiling point of water
- By experiment, available energy 0 at Absolute
Zero 273oC (-459.7oF)? - Define Kelvin scale with same step size as
Celsius, but 0K -273oC Absolute Zero - Use Kelvin Scale for most astronomy work
- Available energy is proportional to T, making
equations simple (really! OK, simpler)? - 273K freezing point of water
- 373K boiling point of water
- 300K approximately room temperature
Recall Resolving power of a telescope depends on
diameter D.
?
In reflecting telescopes Secondary mirror, to
re-direct light path towards back or side of
incoming light path.
CCD Charge-coupled device
The Spitzer Space Telescope
- Planck formula gives intensity of light at each
wavelength - It is complicated. Well use two simpler
formulae which can be derived from it. - Wiens law tells us what wavelength has maximum
intensity - Stefan-Boltzmann law tells us total radiated
energy per unit area
- What is wavelength at which you glow?
- Room T 300 K so
- This wavelength is about 20 times longer than
what your eye can see. Thermal camera operates
at 7-14 µm. - What is temperature of the sun which has
maximum intensity at roughly 0.5 ?m?
The Chandra X-ray Telescope
Computer-controlled mirror support adjusts the
mirror surface (many times per second) to
compensate for distortions by atmospheric
turbulence
Recall Radio waves of ? 1 cm 1 m also
penetrate the Earths atmosphere and can be
observed from the ground.
2. Resolving power Wave nature of light gt The
telescope aperture produces fringe rings that set
a limit to the resolution of the telescope.
- Real life example Ultra-Violet light hitting
your skin (important in Laramie!)? - Threshold for chemical damage set by energy
(wavelength) of photons - Below threshold (long wavelengths) energy too
weak to cause chemical changes - Above threshold (short wavelength) energy
photons can break apart DNA molecules - Number of molecules damaged number of photons
above threshold - Very unlikely two photons can hit exactly
together to cause damage
- Ultraviolet radiation with ? lt 290 nm is
completely absorbed in the ozone layer of the
atmosphere.
The Compton Gamma-Ray Observatory
- Light can also appear as particles, called
photons (explains, e.g., photoelectric effect). - A photon has a specific energy E, proportional to
the frequency f
Lighter mirrors with lighter support
structures, to be controlled dynamically by
computers
Radio astronomy reveals several features, not
visible at other wavelengths
The Hubble Space Telescope
- Launched in 1990 maintained and upgraded by
several space shuttle service missions throughout
the 1990s and early 2000s
Refracting Telescope Lens focuses light onto the
focal plane
Large dish focuses the energy of radio waves onto
a small receiver (antenna)?
- What is wrong with this picture?
- Front Not all primary colors (eg, pink,
magenta), also refraction angles inconsistent - Back Spectrum is Convergent I think done for
arts sake
Often very large to gather large amounts of light.
The Electromagnetic Spectrum, Light, Astronomical
Tools
- Chromatic aberration Different wavelengths are
focused at different focal lengths (prism effect).
Launched in 1999 into a highly eccentric orbit
that takes it 1/3 of the way to the moon!
- Wavelengths of light are measured in units of
nanometers (nm) or angstrom (Å)
The Powers of a Telescope (III)?
0
- Just 400 years ago (Oct. 9, 1604)?
- Then a bright, naked eye object (no telescopes)?
- Its still blowing up now 14 light years wide
and expanding at 4 million mph. - Theres material there at MANY temperatures, so
many wavelengths are needed to understand it.
Weather conditions and turbulence in the
atmosphere set further limits to the quality of
astronomical images
Spectral lines in a spectrum tell us about the
chemical composition and other properties of the
observed object
Wavelength
- More sensitive than photographic plates
However, from high mountain tops or high-flying
aircraft, some infrared radiation can still be
observed.
Operated from 1991 to 2000
- Neutral hydrogen clouds (which dont emit any
visible light), containing 90 of all the
atoms in the universe.
The Electromagnetic Spectrum
Floppy mirror
Launched in 2003
1. Light-gathering power Depends on the surface
area A of the primary lens / mirror, proportional
to diameter squared
Astronomers cant eliminate these diffraction
fringes, but the larger a telescope is in
diameter, the smaller the diffraction fringes
are. Thus the larger the telescope, the better
its resolving power.
3. Magnifying Power ability of the telescope to
make the image appear bigger.
- Ultraviolet astronomy has to be done from
satellites.
X-rays trace hot (million degrees), highly
ionized gas in the universe.
? Combine the signals from several smaller
telescopes to simulate one big mirror ?
Interferometry
Focal length
Can be corrected, but not eliminated by second
lens out of different material.
In order to observe forms of radiation other than
visible light, very different telescope designs
are needed.
1 nm 10-9 m 1 Å 10-10 m 0.1 nm
Mars with its polar ice cap
E hf
Frequency
c 300,000 km/s 3108 m/s
A Comet
Front cover Back cover
Infrared light traces warm dust in the universe.
In astronomy, we cannot perform experiments with
our objects (stars, galaxies, ).
From our text Horizons, by Seeds
D
- Molecules (often located in dense clouds, where
visible light is completely absorbed).
Reflecting Telescope Concave Mirror focuses
light onto the focal plane
Observation of high-energy gamma-ray emission,
tracing the most violent processes in the
universe.
- Avoids turbulence in Earths atmosphere
Warm dust in a young spiral galaxy
Eyepiece To view and enlarge the small image
produced in the focal plane of the primary optics.
- Data can be read directly into computer memory,
allowing easy electronic manipulations
- Several successful ultraviolet astronomy
satellites IUE, EUVE, FUSE
The 4-m Mayall Telescope at Kitt Peak National
Observatory (Arizona)?
For radio telescopes, this is a big problem
Radio waves are much longer than visible light
h 6.626x10-34 Js is the Planck constant.
A new VLT image of a possible planet around a
brown dwarf star.
A larger magnification does not improve the
resolving power of the telescope!
- Difficult and expensive to produce All surfaces
must be perfectly shaped glass must be flawless
lens can only be supported at the edges.
n3
Paranal Observatory (ESO), Chile
- Light waves are characterized by a wavelength
??and a frequency f.
?min 1.22 (?/D)?
Secondary mirror
The detector needs to be cooled to -273 oC (-459
oF).
n2
Two colliding galaxies, triggering a burst of
star formation
Visible light has wavelengths between 4000 Å and
7000 Å ( 400 700 nm).
Segmented mirror
The only way to investigate them is by analyzing
the light (and other radiation) which we observe
from them.
Very hot gas in a cluster of galaxies
http//en.wikipedia.org/wiki/Paranal_Observatory
Newborn stars that would be hidden from our view
in visible light
- Ultraviolet radiation traces hot (tens of
thousands of degrees), moderately ionized gas in
the universe.
- Radio waves penetrate gas and dust clouds, so we
can observe regions from which visible light is
heavily absorbed.
- Extends imaging and spectroscopy to (invisible)
infrared and ultraviolet
Amplified signals are stored in computers and
converted into images, spectra, etc.
?min
High flying air planes or satellites
- Chandra is the first X-ray telescope to have
image as sharp as optical telescopes.
The Very Large Telescope (VLT)
Traditional primary mirror sturdy, heavy to
avoid distortions.
Spitzer Space Telescope
A ? (D/2)2
The Very Large Array (VLA) 27 dishes are
combined to simulate a large dish of 36 km in
diameter.
The 100-m Green Bank Telescope in Green Bank,
West Virginia.
For optical wavelengths, this gives
The energy of a photon does not depend on the
intensity of the light!!!
Focal length
- f and ? are related through
Need satellites to observe
Different colors of visible light correspond to
different wavelengths.
My Bet Renamed after Carl Sagan. Will use both
interferometry and coronagraphs to image
Earth-like planets.
- Discovered by a Wyoming grad student and
professor. The Cowboy Cluster an overlooked
Globular Cluster.
A dust-filled galaxy
On high mountain-tops to avoid atmospheric
turbulence (? seeing) and other weather effects
The 300-m telescope in Arecibo, Puerto Rico
False-color image to visualize brightness contours
? Use interferometry to improve resolution!
Nebula around an aging star
Shuttle launched, highly eccentric orbit. Grazing
incidence mirrors nested hyperboloids and
paraboloids.
n1
From our text Horizons, by Seeds
The northern Gemini Telescope on Hawaii
?min 11.6 arcsec / Dcm
Far away from civilization to avoid light
pollution
The James Webb Space Telescope
f c/?
- There is no dark side really. Its all dark.
-- Pink Floyd
Almost all modern telescopes are reflecting
telescopes.
WIRO 2.3m
Bad seeing
Good seeing
- A merger-product, and powerful radio galaxy.
NASA infrared telescope on Mauna Kea, Hawaii
More accurate, from Richard Berg
From our text Horizons, by Seeds
From our text Horizons, by Seeds
8.1-m mirror of the Gemini Telescopes
Saturn
9The Powers of a Telescope (III)?
0
- 3. Magnifying Power ability of the telescope to
make the image appear bigger.
A larger magnification does not improve the
resolving power of the telescope!
10Traditional Telescopes (I)?
0
Secondary mirror
Traditional primary mirror sturdy, heavy to
avoid distortions.
11Traditional Telescopes (II)?
0
The 4-m Mayall Telescope at Kitt Peak National
Observatory (Arizona)?
12Astronomical Telescopes
0
Often very large to gather large amounts of light.
In order to observe forms of radiation other than
visible light, very different telescope designs
are needed.
The northern Gemini Telescope on Hawaii
13Examples of Modern Telescope Design
0
The Very Large Telescope (VLT)
8.1-m mirror of the Gemini Telescopes
14Seeing
0
Weather conditions and turbulence in the
atmosphere set further limits to the quality of
astronomical images
Bad seeing
Good seeing
15Advances in Modern Telescope Design
Lighter mirrors with lighter support
structures, to be controlled dynamically by
computers
Floppy mirror
Segmented mirror
16Adaptive Optics
0
Computer-controlled mirror support adjusts the
mirror surface (many times per second) to
compensate for distortions by atmospheric
turbulence
17Interferometry
0
Recall Resolving power of a telescope depends on
diameter D.
? Combine the signals from several smaller
telescopes to simulate one big mirror ?
Interferometry
18CCD Imaging
0
CCD Charge-coupled device
- More sensitive than photographic plates
- Data can be read directly into computer memory,
allowing easy electronic manipulations
False-color image to visualize brightness contours
19The Spectrograph
0
Using a prism (or a grating), light can be split
up into different wavelengths (colors!) to
produce a spectrum.
Spectral lines in a spectrum tell us about the
chemical composition and other properties of the
observed object
20Radio Astronomy
0
Recall Radio waves of ? 1 cm 1 m also
penetrate the Earths atmosphere and can be
observed from the ground.
21Radio Telescopes
0
Large dish focuses the energy of radio waves onto
a small receiver (antenna)?
Amplified signals are stored in computers and
converted into images, spectra, etc.
22Radio Interferometry
0
Just as for optical telescopes, the resolving
power of a radio telescope depends on the
diameter of the objective lens or mirror ?min
1.22 ?/D.
For radio telescopes, this is a big problem
Radio waves are much longer than visible light
The Very Large Array (VLA) 27 dishes are
combined to simulate a large dish of 36 km in
diameter.
? Use interferometry to improve resolution!
23The Largest Radio Telescopes
0
The 100-m Green Bank Telescope in Green Bank,
West Virginia.
The 300-m telescope in Arecibo, Puerto Rico
24Science of Radio Astronomy
0
Radio astronomy reveals several features, not
visible at other wavelengths
- Neutral hydrogen clouds (which dont emit any
visible light), containing 90 of all the
atoms in the universe.
- Molecules (often located in dense clouds, where
visible light is completely absorbed).
- Radio waves penetrate gas and dust clouds, so we
can observe regions from which visible light is
heavily absorbed.
25Infrared Astronomy
0
Most infrared radiation is absorbed in the lower
atmosphere.
However, from high mountain tops or high-flying
aircraft, some infrared radiation can still be
observed.
NASA infrared telescope on Mauna Kea, Hawaii
26Infrared Telescopes
Spitzer Space Telescope
WIRO 2.3m
27Ultraviolet Astronomy
0
- Ultraviolet radiation with ? lt 290 nm is
completely absorbed in the ozone layer of the
atmosphere.
- Ultraviolet astronomy has to be done from
satellites.
- Several successful ultraviolet astronomy
satellites IUE, EUVE, FUSE
- Ultraviolet radiation traces hot (tens of
thousands of degrees), moderately ionized gas in
the universe.
28NASAs Great Observatories in Space (I)?
0
The Hubble Space Telescope
- Launched in 1990 maintained and upgraded by
several space shuttle service missions throughout
the 1990s and early 2000s
- Avoids turbulence in Earths atmosphere
- Extends imaging and spectroscopy to (invisible)
infrared and ultraviolet
29Hubble Space Telescope Images
0
Mars with its polar ice cap
A dust-filled galaxy
Nebula around an aging star
30NASAs Great Observatories in Space (II)?
0
The Compton Gamma-Ray Observatory
Operated from 1991 to 2000
Observation of high-energy gamma-ray emission,
tracing the most violent processes in the
universe.
31NASAs Great Observatories in Space (III)?
0
- The Chandra X-ray Telescope
Launched in 1999 into a highly eccentric orbit
that takes it 1/3 of the way to the moon!
X-rays trace hot (million degrees), highly
ionized gas in the universe.
Two colliding galaxies, triggering a burst of
star formation
Very hot gas in a cluster of galaxies
Saturn
32Chandra X-ray Observatory
Shuttle launched, highly eccentric orbit. Grazing
incidence mirrors nested hyperboloids and
paraboloids.
33The Highest Tech Mirrors Ever!
- Chandra is the first X-ray telescope to have
image as sharp as optical telescopes.
34NASAs Great Observatories in Space (IV)?
0
The Spitzer Space Telescope
Launched in 2003
Infrared light traces warm dust in the universe.
The detector needs to be cooled to -273 oC (-459
oF).
35Spitzer Space Telescope Images
0
A Comet
Warm dust in a young spiral galaxy
Newborn stars that would be hidden from our view
in visible light
36Spitzer Space Telescope
- Discovered by a Wyoming grad student and
professor. The Cowboy Cluster a new Globular
Cluster.
37Keplers Supernova with all three of NASAs Great
Observatories
- Just 400 years ago (Oct. 9, 1604)?
- Then a bright, naked eye object (no telescopes)?
- Its still blowing up now 14 light years wide
and expanding at 4 million mph. - Theres material there at MANY temperatures, so
many wavelengths are needed to understand it.
38A Multiwavelength Look at Cygnus A
- A merger-product, and powerful radio galaxy.
39(No Transcript)
40The Future of Space-Based Optical/Infrared
Astronomy
The James Webb Space Telescope