1
 
 
 
EYES ON THE SKIES 
— 400 YEARS OF TELESCOPIC DISCOVERY 
2
Contents (w. Minimum durations) 
0. Prelude (1:13) ..................................................................................................... 3 
1. New views of the skies (09:20) .......................................................................... 4 
2. Bigger is better (06:30)..................................................................................... 25 
3. Technology to the rescue (06:30)..................................................................... 42 
4. From silver to silicon (05:15)........................................................................... 64 
5. Seeing the invisible (06:32).............................................................................. 77 
6. Beyond Earth (06:39) ....................................................................................... 94 
7. What’s next? (06:04) ...................................................................................... 110 
8. Postlude (00:46).............................................................................................. 124 
Total duration: 59 MIN
Yellow background: narrator (voice over)
Blue background: presenter (Dr. J.)
Footage:
• http://www.spacetelescope.org/videos/index.html
• Cuillandre
• Gemini
• TWAN
• Bernd Pr.
• Palomar obs.
• NASA HD
• Stephane Guisard
3
Legend:
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File downloaded, resolution medium, questionable copyrights
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Contact information
0. Prelude (1:13)
00:00
[A5]
By taking our sense of sight far beyond
the realm of our forebears'
imagination, these wonderful
instruments, the telescopes, open the
way to a deeper and more perfect
understanding of nature.
—René Descartes, 1637
00:10 (1)
Narrator: For millennia mankind gazed
out into the mesmerising night sky
without recognising the stars of our own
Milky Way Galaxy as other suns...
or the billions of sister galaxies making up
the rest of our Universe...
...or that we are merely punctuation in the
Universe’s 13.7 billion year-long story.
With only our eyes as observing tools we
had no means of finding solar systems
around other stars, or of determining
whether life exists elsewhere in the
Universe.
00:38 Dr. J [1.1.a.3 or 1.a.1.5]
Today we are well on our way to
unravelling many of the mysteries of the
Universe, living in what may be the most
remarkable age of astronomical discovery.
I am Dr. J and I will be your guide to the
Stars moving above landscapes. No
people. No telescopes. TWAN
footage.
Captivating. Deep. Cosmic. Back to
our roots.
CFHT_FullMoon_1080p_Cuillandr
e.avi (Credit: Canada-FranceHawaii
Telescope / Coelum)
TITLE music
4
telescope – the amazing instrument that
proved to be mankind’s gateway to the
Universe.
0:53
TITLE SEQUENCE
EYES ON THE SKIES
The story of the telescope
01:13
1. New views of the skies (09:20)
00:00 (2)
Narrator: Four centuries ago, in 1609, a
man walked out into the fields near his
home.
He pointed his homemade telescope at the
Moon, the planets and the stars.
His name was Galileo Galilei.
Image of Galileo Galilei
Astronomy would never be the same
again.
5
http://www.spacetelescope.org/imag
es/original/heic0719a.tif
(heic0719a.tif)
http://www.spacetelescope.org/imag
es/html/opo0328a.html
(Hubble_sombrero_galaxy_opo0328
a.tif)
6
01:40 (3)
Today, 400 years after Galileo first pointed
a telescope to the skies, astronomers use
giant mirrors on remote mountaintops to
survey the heavens.
VLT video
CFHT_Moonlight_720p_Cuillandre.
avi (Credit: Canada-France-Hawaii
Telescope / Coelum)
NRAO DVD With GBT, ALMA
and VLA
Radio telescopes collect faint chirps and
whispers from outer space.
Australian Telescope Array
Scientists have even launched telescopes
into space, high above the disturbing
effects of our atmosphere.
Shuttle launch
And the view has been breathtaking!
[MUSIC UP – dramatic fanfare,
celebration, earth shattering]
02:10 (4) (Take 1.6) Dr. J. in Virtual Studio
7
Dr. J: However Galileo did not, in fact,
invent the telescope. That credit goes to
Hans Lipperhey, a slightly obscure DutchGerman
spectacle maker. But Hans
Lipperhey never used this telescope to look
at the stars. Instead, he though his new
invention would mainly benefit seafarers
and soldiers.
H412034.jpg (Credit: Science
Photo Library)
See P. Borellus: De vero telescopii
inventore, 1655
Lipperhey came from Middelburg, then a
large trading city in the fledgling Dutch
Republic.
Zoom on Middelburg
2D View(s) of Middelburg.
Marketplace noises
(Middelburg_1657_Janssonius.jpg
)
Middelburg _22547_cleaned.tif
02:30 (5) (Take 5.3)
In 1608 Lipperhey found that when viewing
a distant object through a convex and a
concave lens the object would be
magnified, if the two lenses were placed at
just the right distance from one another.
Simple animation: parchment
paper extruded to tube with two
lenses.
Dissolve to 3D model of
8
The telescope was born!
Lipperhey’s telescope
Celebration sounds [aaahhh]
In September 1608 Lipperhey revealed his
new invention to Prince Maurits of the
Netherlands.
Look at picture through a lens
(Middelburg_Stadhuis.JPG)
(GNU)
[6] (Take 6.5)
He could not have chosen a more
advantageous moment because at that time
the Netherlands were embroiled in the 80
Years’ War with Spain.
The new spyglass could magnify objects
and so it could reveal enemy ships and
troops that were too distant to be seen by
the unaided eye. A very useful invention
indeed!
Full screen:
Scene(s) from 80-year war.
Prince Maurice at the Battle of
Nieuwpoort
Ch.1_battle_of_Nieuwpoort.jpg
Noise, cannons, screams, horses,
weapons, the smell of gun smoke
But the Dutch government never granted
Lipperhey a patent for his telescope.
Lipperhey’s patent application.
Nationaal Archief + p.15 in De
Telescoop
9
(Hans_Lipperhey_Patent_Applicat
ion.jpg)
(info@nationaalarchief.nl) USE
PROPER CITATION
The reason was that other merchants also
claimed the invention, especially
Lipperhey’s competitor Sacharias Janssen.
The dispute was never resolved.
Portrait of Janssen.
03:04 – img31.gif
http://pages.sbcglobal.net/ttauri/pa
ge5.html
And to this day, the true origins of the
telescope remain shrouded in mystery.
The whole scene (of Dr. J. in
Virtual Studio) slowly goes up in
smoke.
03:30 (6)
Narrator: Italian astronomer Galileo
Galilei, the father of modern physics, heard
about the telescope and decided to build his
own.
Galileo’s portrait.
10
Ch_1_Galileo-SPC-003-det.jpg
(OU)
Ch_1_Galileo-SPC-002.jpg (OU)
03:40 (7)
[Deep male voice]
[B2]
Galileo: About ten months ago, a report
reached my ears that a certain Fleming had
constructed a spyglass by means of which
visible objects, though very distant from the
eye of the observer, were distinctly seen as
if nearby.
Ch_1_Galileo-SPC-004.jpg (OU)
Ch_1_Galileo-SPC-001-det.tif
(OU)
03:55 (8)
Narrator: Galileo was the greatest scientist
of his time. He was also a strong supporter
of the new worldview advocated by Polish
astronomer Nicolaus Copernicus, who
proposed that the Earth orbited the Sun
instead of the other way around.
Animation changing from the
Ptolemaic world view into the
Copernican world view
Based on what he had heard of the Dutch
telescope, Galileo constructed his own
instruments. They were of a much better
quality.
3-d Galileo Telescope
telescope_galileo4comp.tif
11
04:15 [Deep male voice:] (9)
[C2]
Galileo: Finally, sparing neither labour nor
expense, I succeeded in constructing for
myself so excellent an instrument that
objects seen by means of it appeared nearly
one thousand times larger than when
regarded with our natural vision.
USE MARTIN’S DRAWING
The photo extrudes from a
drawing on parchment to a 3D
computer model of the telescope,
slowly turning
telescope_galileo4comp.tif
04:30 (10)
Narrator: It was time to train his telescope
on the heavens.
Image of Galileo
R102087.jpg (Credit: Science
Photo Library)
04:48 [Deep male voice:] (11)
[D2]
I have been led to the opinion and
conviction that the surface of the moon is
not smooth, uniform, and precisely
spherical as a great number of
philosophers believe it to be, but is uneven,
rough, and full of cavities and prominences,
being not unlike the face of the Earth.
Map of Padua and Padua night
scene
Galileo’s drawings of the moon on
old parchment
...
Ch_1_Galile
o_moon_3.tif
12
Ch_1_Galileo_moon_4.tif
05:05 (12) (Take 12.1.1)
Dr. J: A landscape of craters, mountains,
and valleys. A world like our own!
The parchment extrudes to the real
Moon that flies past Dr. J
Credit for the images:
NASA/Goddard Space Flight
Center Scientific Visualization
Studio.
Ch_1_moonrot_still.2161.tif
A few weeks later, in January 1610, Galileo
looked at Jupiter. Close to the planet he saw
four pricks of light that changed their
position on the sky night after night along
with Jupiter.
It was like a slow, cosmic ballet of satellites
orbiting the planet. These four pricks of
light would come to be known as the
Galilean moons of Jupiter.
Galileo’s drawings of the Jovian
satellites. Extrudes to the real view
of Jupiter
Take drawings on the following
pages and show them so that it
looks like the pricks of light are
moving
Ch_1_Galileo-1610-020v.tif
13
Ch_1_Galileo-1610-022v.tif
Ch_1_Galileo-1610-024v.tif
Ch_1_Galileo-1610-025v.tif
J:\EyesSkies\images\ch1\Ch_1_Ga
lileo-1610-026v.tif
14
What else did Galileo discover?
The phases of Venus! Just like the Moon,
Venus waxes and wanes from crescent to
full and back again.
Galileo’s drawings of the phases
of Venus. Extrudes to the real
view of Venus.
Galileo_venus_cleaned.jpg (OU)
(Credit: NASA/Johns Hopkins
Applied Physics Lab)
Strange appendages on either side of
Saturn.
Galileo’s drawings of Saturn,
Extrudes to the real view of
Saturn.
Dark spots on the face of the Sun. Galileo’s drawings of sunspots.
Extrudes to the real view of the
Sun.
Ch_1_Galileo-1613-Pt2-60detail.jpg
(OU)
Credit: Science@NASA
15
sunspot_bigspotfd.tif
http://sohowww.nascom.nasa.gov/
gallery/images/bigspotfd.html
(Credit: SOHO (ESA & NASA))
And, of course, stars. Thousands of them,
maybe even millions. Each too faint to be
seen by the naked eye.
Galileo’s drawings of the Pleiades.
Extrudes to the real view of the
Pleiades.
Galileo-1610-016c-
r_pleiades_clean.jpg
(David
e 10K tiff)
It was as if mankind had suddenly thrown
off its blindfold. There was a whole
Universe to discover out there.
Zoom out from Davide’s Pleiades,
so that huge amounts of stars
become visible.
06:00 (13)
Narrator: News about the telescope spread
across Europe like wildfire.
Old map of 17th
-century Europe
with arrows radiating away from
Padua.
In Prague, at the court of Emperor Rudolph
II, Johannes Kepler improved the design of
Zoom into Prague on map.
16
the instrument.
blaue_europe_2.tif
Portrait of Kepler comes up
(Johannes_Kepler_1610_cleaned.t
if)
In Antwerp, Dutch cartographer Michael
van Langren produced the first reliable
maps of the Moon, showing what he
believed to be continents and oceans.
Mark Antwerp.
Van Langren’s map of the moon
comes up.
http://www.lpod.org/?m=2006012
8
06:12 – cat65.JPG
And Johannes Hevelius, a wealthy brewer
in Poland, built huge telescopes at his
observatory in Danzig. This observatory
was so large that it covered three rooftops!
06:20 – Hevelius-1647-
062_1920.TIF (OU)
17
Johannes_Hevelius_portrait.png
(PD)
http://www.sil.si.edu/Exhibitions/
Voyages/2-24-Hevelius.jpg
(Ch_1_2-24-Hevelius.jpg)
(Smithsonian)
06:27 – Hevelius-1647-
qtr_1080.JPG
But the best instruments of the time were
probably constructed by Christiaan
Huygens in the Netherlands.
Portrait of Huygens, image of his
telescope come up.
06:30 – SIL14-H006-
17a_1080.TIF
18
Huygens-SPC-001.tif
In 1655, Huygens discovered Titan, the
largest moon of Saturn.
Huygens’ drawing of Saturn and
Titan comes up
Huygens_Saturn_1.jpg
(http://www.phys.uu.nl/~huygens/
huygens_en.htm)
A few years later, his observations revealed
Saturn’s ring system – something Galileo
had never understood.
Huygens’ drawing of Saturn’s ring
system comes up.
Huygens_Phases_of_Saturn_1.tif
And last but not least, Huygens saw dark
markings and bright polar caps on Mars.
Huygens’ drawing(s) of Mars
comes up
06:48 – Huygens-Mars
19
Could there be life on this remote, alien
world? The question occupies astronomers
to this day.
Alien.avi (martin)
Mars Rover image
07:08 (14) (Take 14.1.2)
Dr. J: The earliest telescopes were all
refracting telescopes that used lenses to
collect and bring together the starlight.
Later the lenses were replaced with mirrors.
This reflecting telescope was first built by
Niccolò Zucchi and later refined by Isaac
Newton.
Dr. J. demonstrates the principle
of the refractor
And then a reflector
Portrait of Newton.
Newton-LPCVanderbank_cleaned.tif
(Credit:
Image courtesy History of Science
Collections, University of
Oklahoma Libraries; copyright the
Board of Regents of the
University of Oklahoma)
20
Now in the late 18th century the largest
mirrors in the world were cast by William
Herschel, an organist turned astronomer,
who worked with his sister Caroline.
In their house in Bath, in England, the
Herschels poured red-hot molten metal into
a mould and when the whole thing had
cooled off, they would polish the surface so
that it would reflect starlight.
During the course of his life, Herschel built
more than 400 telescopes.
The largest of these was so huge
(Take 14.2.6)
that he needed four servants to operate all
the various ropes, wheels and pulleys that
were required to track the motions of the
stars across the night sky, which is of
course caused by the Earth’s rotation.
(SOUNDS OF WHEELS AND
PULLEYS)
R102151.jpg (Credit: Sheila Terry
/ Science Photo Library)
12.jpg (Credit: Kate Crennell {see
fortran@dpmail.co.uk})
herschel_houseDSC_0699.JPG
R102175.jpg (Credit: Royal
Astronomical Society / Science
Photo Library)
R102176.jpg (Credit: Royal
Astronomical Society / Science
Photo Library)
21
R102154.jpg (Credit: Royal
Astronomical Society / Science
Photo Library)
R102155.jpg (Credit: Royal
Astronomical Society / Science
Photo Library)
R102151.jpg (Credit: Sheila Terry
/ Science Photo Library)
Now Herschel was like a surveyor, he
scanned the heavens and catalogued
hundreds of new nebulae and binary stars.
HerschelW-1791-pl1_cleaned.tif
He also discovered that the Milky Way
must be a flat disc. And he even measured
the motion of the Solar System through that
disk by observing the relative motions of
the stars and the planets.
Herschel’s view of the Milky
Way.
Ch_1_HerschelW-1791-pl2.tif
22
Ch_1_HerschelW-1791-pl3.tif
And then on the 13th of March in 1781, he
discovered a new planet – Uranus.
Voyager images of Uranus and its
satellites.
Uranus4.jpg (Credit: Calvin
Hamilton)
Voyager_Uranus_computer_enhan
ced_GPN-2000-000440.jpg
It was over two hundred years until
NASA’s Voyager 2 spacecraft gave
astronomers their first close-up look of this
distant world.
08:24 (15)
Narrator: In the lush and fertile
countryside of central Ireland, William
Parsons, the third Earl of Rosse, built the
largest telescope of the 19th century.
Zoom-in on central Ireland.
Portrait of Lord Rosse.
With a metal mirror a whopping 1.8 metres
across, the giant telescope became known
as “The Leviathan of Parsonstown”.
23
William_Parsons_Earl_o
f_Rosse.jpg
Dissolving views of Lord Rosse’s
telescope. Both current views and
historical engravings.
R102124.jpg (Credit: Science
Photo Library)
R102226.jpg (Credit: Royal
Astronomical Society / Science
Photo Library)
On the occasional clear, moonless nights,
the Earl sat at the eyepiece, and sailed on a
journey through the Universe.
Try to visualize how he peered
through the telescope (...).
Astro images
To the Orion Nebula – now known to be a
stellar nursery.
Lord Rosse’s drawing of the Orion
Nebula, dissolving into Hubble
image.
24
http://www.spacetelescope.org/im
ages/html/heic0601a.html
On to the mysterious Crab Nebula, the
remnant of a supernova explosion.
Lord Rosse’s drawing of the Crab
Nebula, dissolving into VLT
image.
V700281-
Lord_Rosses_drawing_of_the_Cra
b_Nebula-SPL_2.jpg
08:47 – m1rosse
Crab_Nebula.jpg (Credit: NASA
and StSci)
25
And the Whirlpool Nebula? Lord Rosse
was the first to note its majestic spiral
shape.
A galaxy like our own, with intricate clouds
of dark dust and glowing gas, billions of
individual stars, and who knows – maybe
even planets like the Earth.
Lord Rosse’s drawing of the
Whirlpool Nebula, dissolving into
Hubble image. Zoom in on M51
and pan along its spiral arms.
v700026_interted.tif
(whirlpool_galaxy_heic0506a.tif)
The telescope had become our vessel to
explore the Universe.
09:20
Quick zoom out of M51; lots of
other stars and galaxies come into
view.
[use
http://www.spacetelescope.org/vid
eos/html/heic0506c.html]
2. Bigger is better (06:30)
0:00 (16) (Take 16.1.2)
Dr. J: At night, your eyes adapt to the
dark. Your pupils widen to let more light
into your eyes. As a result, you can see
dimmer objects, and fainter stars.
Dr. J. outside, at night.
Pan to starry background, where
more stars become visible.
26
Now imagine you had pupils one metre
across. You’d look pretty strange but
you’d also have supernatural eyesight!
And that’s what telescopes do for you.
Dr. J. walks out of view.
Starry background becomes
‘overexposed’
(Take 16.2.4)
A telescope is like a funnel. Its main lens
or mirror collects the starlight and brings it
all together into your eye.
Dr. J. walks in.
Background: Graphic of telescope
principle.
Real telescopes: Celestron refractor
and reflector
The bigger the lens or the mirror of a
telescope, the fainter the objects you can
see.
So size really is everything. But how big
can you make a telescope?
Well actually not too big if it’s a refractor.
The starlight has to pass through the main
lens. And so you can only support it
around its edge. Now if you make the lens
too big it becomes too heavy, and it starts
deforming under its own weight. That
means that the image will be distorted.
(Take 16.3.5)
The largest refractor in history was
completed in 1897, at Yerkes Observatory
outside Chicago. Its main lens was just
over one metre across. But its tube was an
incredible 18 metres long.
Full screen
Image(s) of Yerkes Observatory
and 40-inch refractor.
40_300_1.jpg
(8-9 images credit: Richard
Dreiser)
http://www.astrosurf.com/re/ritchey
_1929_plate01.jpg
(Ch.2_3_Old_Yerkes_40.jpg)
27
(Pedro Ré)
With the completion of the Yerkes
telescope, the builders of refracting
telescopes had pretty much reached their
limit.
You want bigger telescopes? Think
mirrors.
More Yerkes images.
Yerkes_40_inch_Refractor_Telesco
pe-2005.jpg
(Ch_1_Yerkes_40_inch_Refractor_
Telescope-2006.jpg) (Credit: Alain
Riazuelo)
[requested two more from
daniel_salo@wired.com and
rdd@yerkes.uchicago.edu]
In a reflecting telescope, the starlight
bounces off a mirror instead of passing
through a lens. That means that you can
make the mirror a lot thinner than a lens,
and you can support it from the back. The
result is that you can build a lot larger
mirrors than lenses.
Dr. J. has mirror in hand to show
what he’s talking about. Supported
by background graphic.
1:18 (17)
Narrator: Big mirrors came to southern
California a century ago.
Full-screen Google Earth zoom-in
on Southern California.
MARTIN
Back then, Mount Wilson was a remote
peak in the wilderness of the San Gabriel
mountains. The sky was clear and the
nights were dark.
Old photographs of snow-capped
mountains.
SnowInPasadena05Jan05_large.jpg
https://netfiles.uiuc.edu/walther/ww
w/archive.html (credit: Dirk
Bernhardt-Walther)
28
Mill_Creek_drainage,_San_Bernar
dino_National_Forest.jpg (Credit:
jcookfisher Creative Commons
Attribution 2.0)
Here, George Ellery Hale first built a 1.5
metre telescope. Smaller than Lord
Rosse’s retired Leviathan, it was of much
better quality. And at a much better site,
too.
Historical images of Hale and his
first reflectors.
http://www.fi.edu/learn/case-
files/hale-2863/
(hale_2863_photo.jpg) (Credit: The
Franklin Institute)
e-mail Peter Abrahams (60inch-
MWO-Apr49-GeneHancockBillMillerPhoto.jpg)
from
http://www.europa.com/~telscope/b
inotele.htm (Credit: Bill Miller)
ALSO:
http://www.astro.ucla.edu/~obs/ima
ges/hale2.jpg.
Credit: Huntington Library
29
Hale talked local businessman John
Hooker into financing a 2.5 metre
instrument.
Tonnes of glass and riveted steel were
hauled up Mount Wilson.
Historical images of the
construction of the Hooker
telescope.
R110/327.jpg (Credit: EMILIO
SEGRE VISUAL ARCHIVES /
AMERICAN INSTITUTE OF
PHYSICS / SCIENCE PHOTO
LIBRARY)
The Hooker telescope was completed in
1917. It would remain the largest telescope
in the world for 30 years.
Images of the Hooker telescope,
both old and current.
http://sunearthday.nasa.gov/2006/i
mages/locations_hale1.jpg
(locations_hale1.tif) (NASA:
Courtesy of the University of
Chicago)
ritchey_1929_plate31.tif (Credit:
Pedro Ré, George Willis Ritchey)
24_60_100inch_mount_wilson_sm
all.jpg (Credit: Pedro Ré, George
30
Willis Ritchey)
A big piece of cosmic artillery, ready to
attack the Universe.
R110328.jpg (Credit: HALE
OBSERVATORIES / SCIENCE
PHOTO LIBRARY)
2:14 (18) (Take 18.1.4)
Dr J: And attack it did.
Dr. J. in Virtual Studio
In a telescope dome?
Along with the incredible size of the new
telescope came transformations in the way
the image was viewed. Astronomers no
longer peered through the eyepiece of the
new giant. But instead collected the light
on photographic plates for hours on end.
whipple_moon.jpg (Credit: Pedro
Ré and Whipple)
Never before had anyone peered so far into
the cosmos.
(LIKE OLD SLIDES ON THE
DOME) (SLIDE PROJECTOR
CLICKING 6 TIMES)
Early photographic image(s) of the
sky.
Old_NGC4565_ritchey_1929_pla
te13.jpg (Credit: Pedro Ré, George
Willis Ritchey)
Old_M81_ritchey_plate14.jpg
(Credit: Pedro Ré, George Willis
Ritchey)
31
Old_M33_ritchey_1929_plate16.j
pg (Credit: Pedro Ré, George
Willis Ritchey)
Old_M33_ritchey_1929_plate15.j
pg (Credit: Pedro Ré, George
Willis Ritchey)
Spiral nebulae turned out to be brimming
with individual stars. Could they be
sprawling stellar systems like our own
Milky Way?
Early photographic images of spiral
nebulae.
Old_M31_ritchey_1929_plate17.j
pg (Credit: Pedro Ré, George
Willis Ritchey)
Old_M31_
ritchey_1929_plate18.jpg (Credit:
Pedro Ré, George Willis Ritchey)
Old_M31_ritchey_1929_plate19.j
pg (Credit: Pedro Ré, George
Willis Ritchey)
32
In the Andromeda Nebula, Edwin Hubble
discovered a particular type of star that
changes its brightness with clocklike
precision. From his observations Hubble
was able to deduce the distance to
Andromeda: almost a million light-years.
Portrait of Hubble.
http://www.fi.edu/learn/casefiles/hubble/
(use form:
http://www.fi.edu/learn/aboutus.ph
p) (undated_hubble_portrait.jpg)
(Credit: The Franklin Institute)
Hubble.mtwilson.tif
Hubble’s photo of M31, with
cepheid variable marked VAR.
(Take 18.2.1)
Spiral nebulae, like Andromeda, were
clearly individual galaxies in their own
right.
More photos of galaxies.
http://www.spacetelescope.org/ima
ges/html/heic0401e.html
(Ground_based_heic0401e.tif)
(Credit: ESA/INT/DSS2)
But that wasn’t the only incredible thing.
Most of these galaxies were found to be
moving away from the Milky Way. At
Mount Wilson, Hubble discovered that the
nearby galaxies were receding at small
velocities, whereas the distant galaxies
Hubble with Hooker telescope.
33
were moving away at a much faster pace.
H408137.jpg (Credit: HALE
OBSERVATORIES / SCIENCE
PHOTO LIBRARY)
Original version of Hubble
diagram.
http://spiff.rit.edu/classes/phys301/l
ectures/expand/hubble_fig1_full.gi
f from
http://spiff.rit.edu/classes/phys301/l
ectures/expand/expand.html
(Creative Commons License
Michael Richmond)
The conclusion? The Universe was
expanding.
More detailed graphic of receding
galaxies / expanding Universe.
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010135/index.html
(Credit: NASA)
The Hooker telescope had given scientists
the most profound astronomical discovery
of the 20th century.
Zoom / pan of image of Hooker
telescope.
R110264.jpg (Credit: DAN
SCHECHTER / SCIENCE
PHOTO LIBRARY)
3:27 (19)
Narrator: Thanks to the telescope, we
have traced the history of the Universe.
Google Earth zoom-out from
Southern California into space.
MARTIN
34
A little less than 14 billion years ago, the
Universe was born in a huge explosion of
time and space, matter and energy, called
the Big Bang.
Animation of big bang.
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010128/index.html
animations\ch2\010128
(credit: NASA)
Frank Summers animation of
galaxies forming and clustering
Tiny quantum ripples grew into dense
patches in the primordial brew. From
these, galaxies condensed.
Supercomputer simulation of
formation of large-scale structure
and galaxies:
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010118/index.html
animations\ch2\010118
(Credit: NASA/NCSA University
of Illinois)
http://www.spacetelescope.org/vide
os/html/heic0804d.html (Credit:
Klaus Dolag (MPA, Garching))
heic0804d.avi
A stunning variety of sizes and shapes. Voyage through zoo of galaxies.
35
http://www.spacetelescope.org/vide
os/html/heic0714g.html (Credit:
NASA, ESA and F. Summers
(STScI)) heic0714g.avi
Nuclear fusion in the cores of stars
produced new atoms. Carbon, oxygen,
iron, gold.
Zoom in onto a star, peer inside the
core; animation of nuclear fusion.
http://www.spacetelescope.org/vide
os/html/astro_ac.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen)
Supernova explosions blew these heavy
elements back into space. Raw material for
the formation of new stars. And planets!
Animation of supernova explosion
and resulting dust clouds.
http://www.spacetelescope.org/vide
os/html/heic0515a.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen) heic0515a.avi
Formation of solar system with
36
planets.
Someday, somewhere, somehow, simple
organic molecules evolved into living
organisms.
Life is one miracle in an ever-evolving
Universe.
We are stardust.
It’s a grand vision and a sweeping story.
Brought to us through telescopic
observations.
http://www.spacetelescope.org/vide
os/html/heic0712i.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen)) heic0712i.avi
+astro ao
http://www.nasa.gov/multimedia/i
magegallery/image_feature_398.ht
ml
Imagine: without the telescope we would
know about just six planets, one moon, and
a few thousand stars.
Astronomy would still be in its infancy.
(13:50)
Change into beautiful, impressive
rotating night sky.
TWAN or Cuillandre or Proschold
4:32 (20)
[Male voice:]
[E2]
Like buried treasures, the outposts of the
Universe have beckoned to the
adventurous from immemorial times.
Princes and potentates, political or
industrial, equally with men of science,
have felt the lure of the uncharted seas of
space, and through their provision of
instrumental means the sphere of
More impressive night sky footage,
ending in twilight and daybreak.
TWAN or Cuillandre or Proschold
MISSING
POEM.
George Ellery Hale
MUSICAL INTERLUDE (0:30)
37
exploration has rapidly widened.
4:56 (21)
Narrator: George Ellery Hale had one
final dream: to build a telescope twice as
large as the previous record holder.
Meet the grand old lady of 20th
century
astronomy. The five metre Hale telescope
at Palomar Mountain.
Over five hundred tonnes of moving
weight, yet so precisely balanced that it
moves as gracefully as a ballerina.
Its 40 tonne mirror reveals stars 40 million
times fainter than the eye can see.
Old images of Hale telescope.
Hale_200_Jarrett.tif
Hale_200_Jarrett_notext.tif
(Contact: Tom Jarrett -
jarrett@ipac.caltech.edu)
Outsidedome.avi (Scott Kardel)
HaleDome_from_backside.JPG
(Credit: Tom Jarrett)
HaleDome_inTrees.JPG
(Credit: Tom Jarrett)
Hale_Sunset_throughSlit.JPG
(Credit: Tom Jarrett)
Completed in 1948, the Hale telescope
gave us unsurpassed views of planets, star
clusters, nebulae and galaxies.
38
Hale_Sunset_insideDome.JPG
(Credit: Tom Jarrett)
HaleDome_PalomarInterferometer.
jpg
(Credit: Tom Jarrett)
HaleDome_from_below.jpg
(Credit: Tom Jarrett)
Hale_IMG_1573.JPG (Scott
Kardel)
Hale_IMG_2449.JPG (Scott
Kardel)
39
Hale_IMG_7758.jpg (Scott Kardel)
Hale_IMG_7884.jpg (Scott Kardel)
halelapse.jpg (Scott Kardel)
halemilkyway.jpg (Scott Kardel)
Hale_palomarlgs.jpg (Scott
Kardel)
Giant Jupiter, with its many moons. Hale telescope image of Jupiter
(slow, panning zoom-out).
http://www.astro.caltech.edu/palom
ar/images/jarrett_jupiter-color.jpg
(Ch_2_jarrett_jupiter-color.jpg)
(Kardel)
40
jarrett_jupiter-invertbig.jpg
jarrett_jupiter-color.jpg
jup_JHK.jpg
jup_H.jpg
jup_K.jpg
jup_J.jpg
The stunning Flame Nebula.
ngc2024 Flame Nebula.jpg (Scott
Kardel)
Faint wisps of gas in the Orion Nebula. Hale telescope image of the Orion
Nebula (slow, panning zoom-out).
m42 orion nebula.jpg (Scott
Kardel)
M26mosaic6.tiff (Scott Kardel)
heic0512d.tif (Credit: © 2002 R.
Gendler, Photo by R. Gendler)
5:49 (22) (Take 22.1.5) Dr. J. in Virtual Studio. Telescope
41
Dr J: But could we go bigger still? Dome.
Well, soviet astronomers tried in the late
1970s.
High up in the Caucasus mountains, they
built the Bolshoi Teleskop Azimutalnyi –
sporting a primary mirror six metres in
diameter.
BTA_film1.avi
BTA_film.avi
Optical_telescopes_SAO-RAS.jpg
Mirror.jpg
001bolshoi
BTA-gor.jpg
But it never really lived up to its
expectations. It was simply too big, too
expensive, and too difficult.
So did telescope builders have to give up
at that point? Did they have to bury their
dreams of even bigger instruments?
Had the history of the telescope come to a
premature end?
Well, of course not. Today we have 10
metre telescopes in operation. And even
bigger ones are on the drawing board.
gemini_north_ppt_lgs_timelapse.
mov (archive)
42
silver_reflections_gemini_south.ti
f
http://www.gemini.edu/index.php?
q=node/16
observing_floor_hdtv.mov
What was the solution? New technologies.
(6:30)
3. Technology to the rescue (06:30)
0:00 (23) (Take 23.1.2)
Dr. J: Just as modern cars don’t look like
a Model T Ford anymore, so are present
day telescopes radically different from
their classic predecessors, like the five
metre Hale telescope.
For one thing, their mounts are much
smaller.
Dr. J. in front of MR image wall.
Background: black/white footage of
1920’s cars in New York.
NYC Beach Resort street scene
2_xx.jpg
http://www.tpcug.org/newsletter/nl
_2004/march2004/epson_scanner.ht
m [e-mailed
lamartin@tampabay.rr.com
05/08/08]
Image of 5-meter Hale telescope.
Hale_2675ds.jpg (Scott Kardel)
43
Hale_IMG_0657.JPG (Scott
Kardel)
The old-style mount is an equatorial one
where one of the axis is always mounted
parallel to the Earth’s rotation axis. In
order to keep track of the sky’s motion,
the telescope simply has to rotate around
this axis at the same speed with which the
Earth rotates.
Graphic animation to show the
principle of an equatorial mount.
MountEq-telescope2.mp4
Easy, but space-hungry. Examples of big, equatoriallymounted
telescopes.
The modern day altitude azimuth mounts
are much more compact. With a mount
like that, the telescope is pointed much
like a cannon. One simply chooses the
bearing, chooses the altitude, and off you
go.
Graphic animation of an alt-az
mount.
MountAz-telescope.mp4
The problem is to keep track of the sky’s
motion. The telescope pretty much has to
rotate around both axis, and at varying
speeds.
Essentially this only became possible once
telescopes were computer controlled.
(Take 23.2.2)
A smaller mount is cheaper to build.
Moreover, it fits into a smaller dome
which reduces the cost even further and it
improves the image quality.
Photos of compact alt-az mounts.
(FULL SCREEN)
44
Ch.3_1_Compact_Alt_Az_Mount
.JPG
Take the twin Keck Telescopes on Hawaii,
for example. Although their 10 metre
mirrors are twice as large as the one of the
Hale telescope, they nevertheless fit into
smaller domes than the one on Palomar
Mountain.
Keck _mirrors.mov
Keck_aerials.mov
Keck_Exterior Views.mov
Backup stills:
Ch.3_5_Keck_Telescope_View_I
nside.jpg (Courtesy W. M. Keck
Observatory)
Ch.2_1_Keck_Telescope_Inside.j
pg (Courtesy W. M. Keck
Observatory)
Comparison of Keck domes to Hale
dome.
45
Ch.3_3_Keck_Telescope_Two_D
omes.jpg (Credit: )
CF015301-2.tif
1:05 (24)
Narrator: Telescope mirrors have evolved
too. They used to be thick and heavy. Now
they’re thin and lightweight.
Gemini mirror. (Dr. J. no longer in
view)
MirrorCoatHDSelfCont.mov
Mirror shells that can be many metres
wide are cast in giant, rotating ovens. And
they are still less than 20 centimetres thick.
Footage of Arizona Mirror Lab.
http://thanks.arizona.edu/telescope/
Look on the
IAU400YrsClpLstDVD (MAKE
SURE THAT YOU FOLLOW
THE EDITING GUIDE
PROVIDED ON THE OTHER
DVD)
LSST oven spinning 02.avi
S08Mar24'20080329 12.31.33.avi
(from computer room)
LSST install cores 24.avi (pan of
oven without glass)
LSST glass load 04.avi (loading
glass in the oven)
LSST glass load 02.avi (loading
glass – almost empty)
(Credit: Large Binocular Telescope
Observatory (Ray Bertram), the
University of Arizona's Steward
Observatory Mirror Laboratory)
DVD from
46
rbertram@email.arizona.edu
An intricate support structure prevents the
thin mirror from cracking under its own
weight.
Footage/images of mirror cell
structure.
http://www.spaceref.com/news/vie
wpr.html?pid=18145
(Gmt1443.jpg)
http://www.gmto.org/newsitems/ne
ws_item.2005-05-19.6941718209
(DSC00315.jpg)
http://www.gmto.org/newsitems/ne
ws_item.2005-04-14.6941718209
(DSC00169.jpg)
http://mirrorlab.as.arizona.edu/TEC
H.php?navi=cast (030123.17r.jpg)
http://mirrorlab.as.arizona.edu/TEC
H.php?navi=gload
Computer controlled pistons and actuators
also help to keep the mirror in perfect
Close-ups of actuators.
(Japanese Subaru DVD video 1
47
shape. on disk (3:34 to 4:06))
1:32 (25) (Take 25.1.5)
Dr. J: This system is called active optics.
The idea is to compensate and to correct
any deformations of the main mirror
caused by gravity, the wind, or
temperature changes.
If available: graphics animation
showing active optics at work.
More of the Subaru video active
optics (Japanese Subaru DVD
video 1 03:34-04:06
http://www.eso.org/gallery/v/Video
s/Paranal/vid-07gb-99.mpg.html
(VERY LOW RES)
Now, a thin mirror also weighs much less.
That means that its whole supporting
structure, including the mount, can also be
a lot trimmer and lighter. And cheaper!
Drawing of telescope with thick
mirror (and heavy structure) and of
telescope with thin mirror (with
light-weight structure).
MARTIN
Now here’s the 3.6 metre New
Technology Telescope, built by European
astronomers in the late 1980s. It served as
a testbed for many of the new technologies
in telescope building. And even its
enclosure has nothing in common with
traditional telescope domes.
Footage of NTT, interior views.
Footage of NTT enclosure.
(requested from Herbert – ask Lars)
http://www.eso.org/gallery/v/Video
s/ESO_ENGL.flv.html (5.54)
The New Technology Telescope was a
great success.
More NTT footage, and/or NTT
science results.
It was time to break the six metre barrier.
2:13 (26)
Narrator: Mauna Kea Observatory sits on
the highest point in the Pacific, 4200
metres above sea level.
Mauna Kea footage.
Maunakea_moonrise_720p_Cuillan
2.avi (Credit: Canada-FranceHawaii
Telescope / Coelum)
mouna_kea_zoom.avi (archives)
OR MAYBE JUST SHOW IT
SITTING ABOVE THE
CLOUDS – GOOD PAN (Subaru
Japanese DVD video 1 0:52 to
1:16 OR video 2 0:00 to 0:22)
On the beaches of Hawaii, tourists enjoy Hawaiian beach scene: easy-going,
48
the Sun and the surf. But high above them
astronomers face chilling temperatures and
altitude sickness in their quest to unravel
the mysteries of the Universe.
tropical. Cross to scene of
astronomers/scientists in the snow
at Mauna Kea.
Maunaloa_inversion_hdtv_25fps.
avi
FOOTAGE FROM MAUNA
KEA VIDEO (Subaru Japanese
DVD video 2 3:58 to 4:30), BUT
NO TOURISTS – MAYBE
SOME FOOTAGE OF THE
VOLCANO (Subaru Japanese
DVD video 2 13:04 to 13:36)????
subaru_summit_snow_300.jpg (Fill
out form:
http://subarutelescope.org/Informati
on/Image/use.html)
from
http://subarutelescope.org/Gallery/t
ele_dome.html
The Keck Telescopes are among the
largest in the world. Their mirrors are 10
metres across, and wafer-thin.
Keck_telescope.mov
Backup stills:
CF015288.tif (Courtesy of W. M.
Keck Observatory, Photo credit:
Rick Peterson © 2007) USE THIS
IMAGE IF ANY
49
keckTwilight-hi.tif
IAUkecklaser1.jpg (Courtesy W.
M. Keck Observatory)
Tiled like a bathroom floor, they consist of
36 hexagonal segments, each controlled to
nanometre precision.
Keck_mirrors.mov
Backup stills:
Ch.3_4_Keck_Telescope_View_I
nside.jpg (Courtesy W. M. Keck
Observatory)
Ch.3_17_Keck_Mirror.tif (Credit:
Courtesy NASA/JPL-Caltech)
Ch.3_18_Keck_Primary_Mirror.
jpg (Credit: Courtesy NASA/JPL-
Caltech)
50
Keck_12_32.jpg (Courtesy W. M.
Keck Observatory)
These are true giants, devoted to observing
the heavens. The cathedrals of science.
More impressive views of the Keck
telescopes:
Keck_exterior_views.mov
Backup still:
Ch.3_10_Keck_Inside_View.jpg
(Courtesy W. M. Keck
Observatory)
Nightfall on Mauna Kea. The Keck
Telescopes begin collecting photons from
the far reaches of the cosmos. Their twin
mirrors combining to be effectively larger
than all earlier telescopes.
(Subaru Japanese DVD video 2
16:03 to end or video 1 7:47 to
8:01))
Sunset / nightfall on Mauna Kea.
Night shots of Keck telescopes.
Keck_Exteriour_views.mov
Backup stills:
51
CF015288.tif (Courtesy W. M.
Keck Observatory)
Ch.3_9_Keck_at_Sunset.jpg
(Courtesy of W. M. Keck
Observatory, Photo credit: Rick
Peterson © 2007)
What will be tonight’s catch? Zoom-in on starry sky.
Ch.3_15_Starry_Sky.jpg
Ch.3_16_Starry_Night_2.jpg
A pair of colliding galaxies, billions of
light-years away?
Zooming pan across image of
colliding galaxies.
http://www.spacetelescope.org/vide
os/html/mov/180px/heic0810c.html
(Credit: NASA, ESA, the Hubble
52
Heritage Team (STScI/AURA)ESA/Hubble
Collaboration and A.
Evans (University of Virginia,
Charlottesville/NRAO/Stony Brook
University), K. Noll (STScI), and J.
Westphal (Caltech))
A dying star, gasping its last breath into a
planetary nebula?
Zooming pan on planetary nebula.
http://www.spacetelescope.org/vide
os/html/images_a.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen))
Or maybe an extrasolar planet that might
harbour life?
Zooming pan on artistic rendering
of extrasolar planet.
http://www.spacetelescope.org/vide
os/html/mov/180px/astro_am.html
(Credit: ESA/Hubble (M.
Kornmesser & L. L. Christensen))
http://www.spacetelescope.org/vide
os/html/heic0807d.html (Credit:
ESA/Hubble (M. Kornmesser & L.
53
L. Christensen)) heic0807d.avi
On Cerro Paranal in the Chilean Atacama
Desert — the driest place on Earth — we
find by far the biggest astronomy machine
ever built: the European Very Large
Telescope.
Zoom from space down to Paranal:
http://www.spacetelescope.org/vide
os/html/hubblecast06b.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen), ESO)
hubblecast06b.avi
SPEED CHANGE
MUSICAL INTERLUDE
080727-P12-Paranal-from_Vista-
20d-14mm (Credit: Stephane
Guisard)
Zodet movies
VLT1_HD_720p50.mov (Very
Large Telescope General Views)
VLT2_HD_720p50.mov (VLT Unit
Telescope)
VLT3_HD_720p50.mov (VLT
Instruments)
VLT4_HD_720p50.mov (Laser
Guide Star Facility)
VLT7_HD_720p50.mov (VISTA
Telescope)
VLT9_HD_720p50.mov (desert
impressions)
VLT10_HD_720p50.mov
(observations)
54
VLT footage. Timelapse. From
Gonzalo.
VLTnight_hires.mov
Copyright ©ESO. Credits: Author:
Gonzalo Argandoña; Photography:
Alejandro Carrasco;
The VLT is really four telescopes in one.
Each sporting an 8.2 metre mirror.
http://www.spacetelescope.org/vide
os/html/hubblecast06b.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen), ESO)
Antu. Kueyen. Melipal. Yepun. Native
Mapuche names for the Sun, the Moon,
the Southern Cross and Venus.
Pan across the four UT’s. Names in
view.
http://www.spacetelescope.org/vide
os/html/hubblecast06c.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen), ESO)
hubblecast06c.avi
The huge mirrors were cast in Germany,
polished in France, shipped to Chile, and
then slowly transported across the desert.
Close ups of VLT mirror
production and transportation.
http://www.eso.org/public/outreach/
press-rel/pr-1997/phot-35-97.html
55
VLT_phot-35b-97-hires.jpg (Credit:
VLT_phot-35e-97-hires.jpg (Credit:
VLT_phot-35f-97-hires.jpg (Credit:
vlt_phot-35j-97-hires.jpg (Credit:
VLT_Kueyun_phot-15f-00.jpg
(Credit: ESO)
56
VLT_Kueyun_phot-15ac-00.jpg
(Credit: ESO)
At sunset, the telescope enclosures open
up. Starlight rains down on the VLT
mirrors. New discoveries are made.
VLT enclosures open. Sunset /
nightfall at VLT platform.
Credit: Stephane Guisard
MUSICAL BREAK
SGU-Paranal-Voie-lactee-V4-
720x576-mus-ok-en.avi
SGU-Paranal-Sagittaire-AT1-V8-
480x720-mus_sgu-ok-en.avi
SGU-Paranal-Magellan-UT4-V5-
720x480-mus-en.avi
SGU-
Paranal_3_rotating_galaxies_960x7
20.wmv
4:10 (27) (Take 27.1.3)
Dr. J: A laser pierces the night sky. It
projects an artificial star into the
atmosphere, 90 kilometres above our
heads.
Dr. J. in front of MR image wall.
Footage of Yepun AO laser.
Credit: Stephane Guisard
57
SGU-
Paranal_and_The_Laser_Guide_St
ar_1200x800.wmv (waiting for
high resolution – guisard (ask
Lars))
Wavefront sensors measure how the star’s
image is distorted by the atmospheric
turbulence.
Gemini animation of AO.
Luis’ animation of AO
end of GeminiNorthAnim.mov
http://www.gemini.edu/files/docma
n/press_releases/pr2003-
2/aoanim.mov (from
http://www.gemini.edu/index.php?
q=node/72)
Then, fast computers tell a flexible mirror
how it has to deform itself in order to
correct the distortion. In effect
untwinkling the stars.
This is called adaptive optics and it’s the
big magic trick of present day astronomy.
Without it, our view of the Universe
would look blurred by the atmosphere.
But with it, our images are razor-sharp.
Gemini animation of AO. X-fade
from non-AO image to AO-image,
to show the effect.
GeminiNorthAnim.mov
\http://www.cfht.hawaii.edu/Instru
ments/Imaging/AOB/Images/gc_re
d.gif
58
gemini_ao_bullets_orion_north_l
gs.jpg
(Take 27.3.5) (NO 27.2.x)
The other piece of optical wizardry is
known as interferometry.
The idea is to take the light from two
separate telescopes and to bring it together
in a single point, while preserving the
relative shifts between the lightwaves. If it
is done precisely enough the result is that
the two telescopes act as if they were part
of a single, colossal mirror as large as the
distance between them.
VLT5_HD_720p50.mov (VLT
Delay Lines and Interferometric
Laboratory)
Interferometry tunnels buried
below VLT platform.
Animation to show principle of
interferometry.
http://planetquest.jpl.nasa.gov/tech
nology/technology_index.cfm
Animations of installation of
adaptive optics in the Hale
Telescope AOSETUP.AVI
In effect, interferometry gives your
telescope eagle-like vision. It allows
smaller telescopes to reveal a level of
detail that would otherwise only be visible
with a much larger telescope.
Again: non-AO image compared to
AO-image.
ao_aooffon.jpg
http://www.astro.caltech.edu/palom
ar/AO/ (Scott Kardel)
59
http://www.astro.ucla.edu/~ghezgro
up/gc/pictures/aoMovie.shtml
The twin Keck Telescopes on Mauna Kea
regularly team up as an interferometer.
Keck_instruments.mov
Backup still:
PAN ACROSS THIS IMAGE
Keck_Interferometer_basepan.JPG
http://www2.keck.hawaii.edu/news/
science/if_science/if_science.html
In the case of the VLT, all four telescopes
can work together. In addition, several
smaller auxiliary telescopes can also join
the ranks in order to sharpen up the view
even more.
Footage of VLT, with auxiliary
telescopes.
What hasn’t been used
VLT1_HD_720p50.mov (Very
Large Telescope General Views)
VLT2_HD_720p50.mov (VLT
Unit Telescope)
VLT3_HD_720p50.mov (VLT
Instruments)
5:37 (28)
Narrator: Other big telescopes can be
found all over the globe.
Google Earth globe on background,
rotating in a way to show the
locations of big telescopes.
MARTIN
Subaru and Gemini North on Mauna Kea. Footage of Mauna Kea.
SUNSET AND NIGHT SHOTS –
VIDEO TWO OF SUBARU (15:04
TO 15:50)
Gemini South and the Magellan
Telescopes in Chile.
Footage of Cerro Pachon and Las
Campanas.
GNOutPAL.mov
http://apod.nasa.gov/apod/ap06090
1.html
60
Gemini_South_gs_cp_ext_tl_1ksq.
mov
(http://www2.gemini.edu/index.php
?set_albumName=Video&option=c
om_gallery&Itemid=39&include=v
iew_album.php)
Gemini_South_GSNightTimeLapse
.mov
(http://www2.gemini.edu/index.php
?set_albumName=Video&option=c
om_gallery&Itemid=39&include=v
iew_album.php)
The Large Binocular Telescope in
Arizona.
Footage of LBT.
[requested footage from
sally@firehousepictures.com]
video_oct05_large.AVI
video_zoom.mp4
video_aluminize.mpeg
video_newsrelease.mpg
They are constructed at the best available
sites. High and dry, clear and dark.
Maunaloa_inversion_hdtv_25fps.
avi
Their eyes are as large as swimming
pools.
Footage of LBT.
Generic images of large telescope
mirrors.
61
Ch.3_6_Subaru_Very_Large_Mirro
r.jpg (Credit: Michael Richmond,
Creative Commons License)
Gemini_MirrorPV.tif (Credit:
Gemini Observatory/AURA) ****
http://www2.gemini.edu/index.php?
set_albumName=album05&id=Mirr
orPV&option=com_gallery&Itemid
=39&include=view_photo.php
phot-44-99.jpg
Gemini_Mirror1104-wide.jpg
(http://www.gemini.edu/index.php?
q=node/110) (Credit: Gemini
Observatory/Kirk Pu'uohau-
Pummill)
All kitted out with adaptive optics to
counteract the blurring effects of the
atmosphere.
Footage of LBT.
62
Ch.3_14_LBT_Large_Mirror.jpg
(Credit: Photo courtesy of Large
Binocular Telescope
Observatory/Marc-Andre Besel and
Wiphu Rujopakarn
(Photographers))
And sometimes they can have the
resolution of a virtual behemoth, thanks to
interferometry.
More twin telescopes (LBT, Keck,
Magellan).
Ch.3_20_LBT_Dual_Mirrors.jpg
(Credit: Photo courtesy of Large
Binocular Telescope
Observatory/John Hill
(Photogrpaher))
Ch.3_21_LBT_Dual_Mirrors.jpg
(Credit: Photo courtesy of Large
Binocular Telescope
Observatory/Aaron Ceranski
(Photogrpaher))
Here’s what they’ve shown us.
63
Planets.
Nebulae.
Keck/Gemini/VLT images
keck_ao_4_68.jpg
keck_ao_4_145.TIF
keck_ao_4_146.JPG
gemini_ao_fig1full.tif
keck_ao_5_56.jpg
64
keck_ao_5_125.jpg
gemini_ao_gc_color_med.jpg
The actual sizes – and squashed shapes –
of some stars.
VLT ‘images’ of Regulus.
A cool planet orbiting a brown dwarf. VLT image of 2M1207.
http://www.eso.org/public/outreach/
press-rel/pr-2004/pr-23-04.html
http://www.eso.org/esopia/images/h
tml/phot-19b-06.html
And giant stars whirling around the core
of our Milky Way Galaxy, governed by
the gravity of a supermassive black hole.
AO-movie of stars in galactic
center.
We’ve come quite a way since Galileo’s
day.
6:30
Back to naked eye night sky view,
with horizon.
TWAN
4. From silver to silicon (05:15)
0:00 (29) (Take 29.1.4)
Dr. J: 400 years ago, when Galileo Galilei
wanted to show others what he saw
through his telescope, he had to make
drawings.
Dr. J. in virtual studio, holding and
flipping through an old book which
shows some of Galileo’s drawings.
The pockmarked face of the Moon. The
dance of the Jovian satellites. Sunspots.
Or the stars in Orion.
Galileo’s pencil sketches. (in the
background. Large!) (whichever
you haven’t used in the first
65
chapter)
03-48-1_cleaned.tif
Ch_1_Galileo-1613-Pt2-90-
detail.tif
Ch_1_Galileo_Moon_5.tif
He took his drawings and published them
in a small book, The Starry Messenger.
That was the only way he could share his
discoveries with others.
Images of Sidereus Nuncius.
Galileo-1610-001r.tif (OU)
Galileo-1610-016c-v.tif (OU)
Galileo-1610-pleiades.tif (OU)
For well over two centuries, astronomers
also had to be artists. Peering through
their eyepieces, they made detailed
drawings of what they saw.
Engraving of astronomer at
eyepiece (and/or Christoph
Scheiner with his sun projection
setup).
atlas_fotografico_lua-3.tif (Pedro
Ré and Lewis Morris Rutherfurd)
http://www.astrosurf.com/re/atlas_f
otografico_lua.pdf
The stark landscape of the Moon. A storm Examples of astronomical
66
in the atmosphere of Jupiter. The subtle
veil of gas in a distant nebula.
drawings.
http://www.sil.si.edu/Exhibitions/V
oyages/2-25-Silberschlag.jpg
http://www.sil.si.edu/Exhibitions/V
oyages/2-28-Smyth.jpg
http://www.sil.si.edu/Exhibitions/V
oyages/1-31a-kircher.jpg
Scheiner-1630-141.tif (OU)
And sometimes they over-interpreted what
they saw. Dark linear features on the
surface of Mars were thought to be canals
suggesting civilised life on the surface of
the red planet.
Drawings and maps showing
Martian canals.
IMAGE FROM BOOK
HIGH RESOLUTION:
Lowell-1906-00384-plate.tif (OU)
THE FOLLOWING IMAGES
ARE LOW RESOLUTION, SO
MAKE A COLLAGE…
67
Lowell-1895-00001-plate5.tif (OU)
Lowell-1895-00001-plate7.tif (OU)
Lowell-1895-00000-fp.tif (OU)
Lowell-1906-00044-plate.tif (OU)
We now know that the canals were an
optical illusion.
What astronomers really needed was an
objective way to record the light collected
by the telescopes without the information
first having to pass through their brains
and their drawing pens.
Photography came to the rescue.
Cross from canal-drawing to
current photograph of Mars (Fullscreen,
Dr. J. not in view)
68
http://www.spacetelescope.org/vide
os/html/astro_q.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen))
http://www.spacetelescope.org/vide
os/html/astro_z.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen))
(Take 29.2.1)
The first daguerreotype of the Moon. It was
made in 1840 by Henry Draper.
Photography was less than 15 years old, but
astronomers had already seized on its
revolutionary possibilities.
Dr. J. in front of MR image wall.
FULL SCREEN
First daguerrotype of the moon.
ch4_1whipple_history_astrophoto
graphy_timeline-7.tif
(low res, need rights)
atlas_fotografico_lua-2.tif (Pedro
Ré)
So how did photography work? Well the
sensitive emulsion of a photographic plate
contained small grains of silver halide.
Expose them to light, and they turn dark. So
the result was a negative image of the sky,
with dark stars on a light background.
But the real bonus was that a photographic
plate can be exposed for hours on end.
Footage showing the workings of
photographic emulsion (?).
http://www.astro.caltech.edu/palo
mar/galaxies.html (Scott Kardel)
or ngc6946r.gif
69
When you take in the night sky with your
own eyes, once they‘re dark adapted, you
don’t see more and more stars just by
looking longer.
Image of starry sky, as seen with
the naked eye.
MARTIN
But with a photographic plate you can do
just that. You can collect and add up the
light over hours on end. So a longer
exposure reveals more and more stars.
And more. And more. And then some.
Same image as seen through a
camera (camera viewer
information visible). Starry sky
gets brighter and brighter.
FULL SCREEN
MARTIN
(Take 29.3.3)
In the 1950s, the Schmidt telescope at the
Palomar Observatory was used to
photograph the entire northern sky.
48inch_schmidt_insidefull.mov
Alternatively:
Images of Schmidt telescope in
operation.
http://www.astr.ua.edu/keel/telesc
opes/palomar.html
(Palomar_p200b.jpg)
Old_Palomar_Drawing_1.jpg
(Credit: Pedro Ré, Russell W.
Porter)
Old_Palomar_Drawing_2.jpg
(Credit: Pedro Ré, Russell W.
70
Porter)
Almost 2000 photographic plates, each
exposed for nearly an hour. A treasure trove
of discovery.
Photographic plate from the book
Photography had turned observational
astronomy into a true science. Objective,
measurable, and reproducible.
But silver was slow. You had to be patient.
More and more astrophotographs.
plate01_keeler.jpg ...
...
plate69_keeler.jpg
(20 images)
2:14 (30)
Narrator: The digital revolution changed
all that.
Silicon replaced silver. Pixels replaced
grains.
Even in consumer cameras, we no longer
use photographic film. Instead, images are
recorded on a light-sensitive chip: a charge
coupled device, or CCD for short.
High-tech footage of digital
equipment and (for instance) Sloan
Digital Sky Survey CCD camera.
http://www.spacetelescope.org/vide
os/html/hubblecast10c.html
(Credit: Credit: ESA/Hubble (M.
Kornmesser & L. L. Christensen))
hubblecast10c.avi
Professional CCDs are extremely efficient.
And to make them even more sensitive,
they are cooled down to well below
freezing, using liquid nitrogen.
ESO: Footage of astronomers
pumping liquid nitrogen into a
cryocamera.
71
ccd.jpg
http://astrwww.cwru.edu/news/Ne
wCamera.shtml (Credit: Warner
and Swasey Observatory, Case
Western Reserve University)
Herschel_Cryostat+IR-source.TIF
(Credit: ESA)
http://sci.esa.int/science-
e/www/object/index.cfm?fobjectid
=40183
Almost every photon is registered. As a
result, exposure times can be much
shorter.
Animation of the working of a
CCD (?).
http://www.spacetelescope.org/vide
os/html/hubblecast10d.html
(Credit: ESA/Hubble (M.
Kornmesser & L. L. Christensen))
hubblecast10d.avi
What the Palomar Observatory Sky
Survey achieved in an hour, a CCD can
now do in a few short minutes. Using a
smaller telescope.
Random astro-images
The silicon revolution is far from over.
Astronomers have built huge CCD
cameras with hundreds of millions of
pixels. And there’s more to come.
Views of big astronomical CCD
cameras being developed / built /
installed / used.
http://www.eso.org/instruments/om
egacam/
http://www.eso.org/gallery/v/Video
72
s/ESO_ENGL.flv.html
phot-04a-07-fullres.tif
http://www.eso.org/public/outreach
/press-rel/pr-2007/phot-04-07.html
http://www.vista.ac.uk/camera_ima
ges.html
VISTA_IR_Camera_To_Telescope
_2.JPG
VISTA_IRCamera_in_PrepLab1.jp
g
VISTA_Camera_to_Telescope.JPG
VISTA_Camera_on_Telescope.JP
G
73
IMGP4957-2048x1536.JPG
3:07 (31) (Take 31.1.5)
Dr. J: The big advantage of digital images
is that they’re, well, digital. They’re all set
and ready to be worked on with
computers.
Image processing timelapse
running in the background (cut out
computer screen)
http://www.spacetelescope.org/vide
os/html/hubblecast10f.html
(Credit: ESA/Hubble (M.
Kornmesser & L. L. Christensen))
hubblecast10f.avi
Astronomers use specialised software to
process their observations of the sky.
OR:
Closeup of computer screen where
Antennae Galaxies is being
tweaked.
Stretching, or contrast enhancing, reveals
the faintest features of nebulae or galaxies.
Antennae Galaxies being stretched
Colour coding enhances and brings out the
structures that would otherwise be difficult
to see.
Moreover, by combining multiple images
of the same object that were taken through
different colour filters, one can produce
spectacular composites that blur the
boundary between science and art.
Antennae Galaxies being
colourised
You too can benefit from digital
astronomy. It has never been so easy to dig
up and enjoy the amazing images of the
cosmos.
74
Pictures of the Universe are always just a
mouse click away!
4:01 (32)
Narrator: Robotic telescopes, equipped
with sensitive electronic detectors are
keeping watch over the sky, right now.
Telescope in operation
GEMINI?
CFHT/Cuillandre?
The Sloan telescope in New Mexico has
photographed and catalogued over a
hundred million celestial objects, measured
distances to a million galaxies, and
discovered a hundred thousand new
quasars.
But one survey is not enough. The
Universe is an ever-changing place.
Footage of the Sloan telescope.
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010136/index.html
(Credit: NASA/University of
Chicago and Adler Planetarium
and Astronomy Museum)
Icy comets come and go, leaving scattered
debris in their wake.
Comet:
http://www.spacetelescope.org/vid
eos/html/heic0508a.html
http://www.spacetelescope.org/vid
eos/html/heic0310d.html (Credit:
ESA/Hubble (M. Kornmesser & L.
75
Asteroids zip by.
L. Christensen))
http://www.spacetelescope.org/vid
eos/html/heic0508b.html (Credit:
(ESA/Hubble (M. Kornmesser &
L. L. Christensen)) heic0508b.avi
Flyby of an asteroid.
http://www.spacetelescope.org/vid
eos/html/astro_v.html Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen)
Distant planets orbit their mother stars,
temporarily blocking part of the star’s
light.
Animation of transiting exoplanet.
http://www.spacetelescope.org/vid
eos/html/heic0807e.html
(Credit: ESA/Hubble (M.
Kornmesser & L. L. Christensen))
76
Supernovas explode, while elsewhere new
stars are born.
Animation of supernova explosion
and of star formation.
http://www.spacetelescope.org/vid
eos/html/heic0712c.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen))
Pulsars flash, gamma-ray bursts detonate,
black holes accrete.
Animation of pulars, exploding
GRB, colliding galaxies.
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010144/index.html
animations\ch4\a010144
(Credit: NASA)
To keep track of these grand plays of
Nature, astronomers want to carry out allsky
surveys every year. Or every month.
Or twice a week.
At least that’s the ambitious goal of the
Large Synoptic Survey Telescope. If
completed in 2015, its three-gigapixel
camera will open up a webcam window on
the Universe. More than fulfilling
astronomers’ dreams, this reflecting
telescope will photograph almost the entire
sky every three nights.
(5:15)
Back to night sky as seen from
Earth.
Animation of LSST.
HD-LSST-lossless.mov (HUGE)
HD-comp-H.264.mov
LSST-50-H.264-high.mov
credit: Todd Mason, Mason
Productions / LSST Corporation
LSST glass load 04.avi (see note
from rbertram@email.arizona.edu
– not all of this video can be used.)
77
LSST install cores 11.avi (see note
from rbertram@email.arizona.edu
– not all of this video can be used.)
5. Seeing the invisible (06:32)
0:00 (33) (Take 33.1.1)
Dr. J: When you listen to your favourite
piece of music, your ears pick up on a
very wide range of frequencies, from the
deepest rumblings of the bass to the very
highest pitched vibrations.
Dr. J. in a concert hall?
Music: Orchestra playing
Beethoven’s Ninth.
Now imagine your ears were only
sensitive to a very limited range of
frequencies. You’d miss out on most of
the good stuff!
Same, but with adapted music
score, with limited frequency range
(but same overall volume!).
But that’s essentially the situations that
astronomers are in. Our eyes are only
sensitive to a very narrow range of light
frequencies: visible light. But we are
completely blind to all other forms of
electromagnetic radiation.
However, there are many objects in the
Universe that do emit radiation at other
parts of the electromagnetic spectrum.
Graphic showing the
electromagnetic spectrum (from
Hidden Universe).
OR
http://svs.gsfc.nasa.gov/vis/a01
0000/a010200/a010282/index.html
(not downloaded)
For example, in the 1930s it was
discovered by accident that there are radio
waves coming from the depths of space.
Some of these waves have the same
frequency as your favourite radio station,
Old images of the first radio
telescopes.
78
but they are weaker and of course there’s
nothing to listen to.
Dwingeloo_radio_telescope.JPG
http://commons.wikimedia.org/wiki
/Image:Dwingeloo_radio_telescope.
JPG (1950s) (Credit: Bryan Tong
Minh GNU Free Documentation
License, Version 1.2 or later)
Grote_Antenna_Wheaton.gif
http://en.wikipedia.org/wiki/Image:
Grote_Antenna_Wheaton.gif
(Public Domain)
Maybe Dr. J. tuning transistor
radio, and hearing the faint hiss and
crackle of radio noise?
(Take 33.2.2)
In order to “tune in” to the radio Universe,
you need some sort of receiver: a radio
telescope. Now for all but the longest
wavelengths, a radio telescope is just a
dish. Much like the main mirror of an
optical telescope.
But because radio waves are so much
longer than visible lightwaves, the surface
of a dish doesn’t have to be nearly as
smooth as the surface of a mirror. And
that’s the reason why it’s so much easier
to build a large radio telescope than it is to
build a large optical telescope.
Footage of Green Bank Telescope
or Effelsberg Telescope.
DVD from Robert Wagner
[footage of Green Bank requested
info@nrao.edu]
NRAO DVD With GBT, ALMA
and VLA
Extra stills:
http://www.mpifr-
bonn.mpg.de/public/vortraege_e.ht
ml
79
GB_historic_hi.tif (Credit: Image
courtesy of NRAO/AUI)
http://www.nrao.edu/imagegallery/
php/level3.php?id=288
gbt2_2005_hi.tif (Credit:
NRAO/AUI and Photographer Lee
Shapiro)
Aerial2001-Image22_hi.tif (Credit:
NRAO/AUI)
Aerial2001-Image3_hi.tif (Credit:
NRAO/AUI)
GBTDusk_hi.tif (Credit:
NRAO/AUI)
GBTSnow_hi.tif (Credit:
NRAO/AUI)
80
http://www.nrao.edu/imagegallery/
php/level2a.php?class=Historical&s
ubclass=Telescopes (NRAO)
300ft_before_hi.tif (Credit:
NRAO/AUI)
ReberTelescope1984_hi.tif (Credit:
NRAO/AUI)
ReberandRestoredTelescope1960_h
i.tif (Credit: NRAO/AUI)
Reber_telescope_hi.tif (Credit:
NRAO/AUI)
81
85foot_hi.tif (Credit: NRAO/AUI)
goldstone7.jpg (Credit:
NRAO/AUI)
Also, at radio wavelengths, it is much
easier to do interferometry. That is, to
increase the level of detail that can be seen
by combining the light from two separate
telescopes, as if they were part of a single,
giant dish.
Views of relatively small
interferometers (Cambridge?
Westerbork?)
Westerbork-sunset.jpg
http://commons.wikimedia.org/wiki
/Image:Westerbork-sunset.jpg
(Creative Commons Attribution
ShareAlike 3.0 Unported License
Roman Feiler)
(Take 33.3.1)
The Very Large Array in New Mexico, for
example, consists of 27 separate antennas,
each measuring 25 metres across. Now
each antenna can be moved around
individually, and in its most extended
configuration, the virtual dish mimicked
by the array measures 36 kilometres
across.
Footage of Very Large Array (full
screen, Dr. J. not in view anymore).
[VLA footage requested 25/06]
And again 30.7 Dave Finley
<dfinley@aoc.nrao.edu>
So what does the Universe look like in the
radio?
Well, for a start our Sun shines very
brightly at radio wavelengths. So does the
centre of our Milky Way Galaxy. But
there’s more.
Sweep across the sky (sun / Milky
Way centre), with radio contours or
color-coded radio map overlaid on
optical image (?)
OR
82
http://www.spacetelescope.org/vide
os/html/mov/180px/astro_aq.html
(Credit: ESA/Hubble (M.
Kornmesser & L. L. Christensen))
Pulsars are very dense stellar corpses that
emit radio waves only into a very narrow
beam. In addition, they rotate at speeds of
up to several hundred revolutions per
second. So in effect, a pulsar looks like a
rotating radio lighthouse. And what we see
from them is a very regular and fast
sequence of very short radio pulses. Hence
the name.
http://www.spacetelescope.org/vide
os/html/hst15_pulsar_beacon.html
(Credit: ESA/Hubble (M.
Kornmesser & L. L. Christensen))
(Take 33.4.3 OR was it 33.4.4? (The
last))
The radio source known as Cassiopeia A is
in fact the remnant of a supernova that
exploded in the 17th
century.
http://www.spacetelescope.org/vide
os/html/heic0609h.html
http://www.spacetelescope.org/vide
os/html/heic0609b.html
83
FULL SCREEN
Radio image of Cas A (and/or
combination with optical image and
Photoshop-effect of radio waves)
cas_a_vla_lg.jpg (Credit:
NRAO/AUI)
http://www.nrao.edu/imagegallery/
php/level3.php?id=395
Centaurus A, Cygnus A and Virgo A are
all giant galaxies that pour out huge
amounts of radio waves. Each galaxy is
powered by a massive black hole at its
centre.
Views of Cen A (and maybe the
others?), with radio wave effect. or
overlaid with radio image.
http://svs.gsfc.nasa.gov/vis/a01000
0/a010200/a010200/index.html
(Credit: NASA/Goddard Space
Flight Center Conceptual Image
Lab)
FULL SCREEN
(Take 33.5.3)
Some of these radio galaxies and quasars
are so powerful that their signals can still
be detected from a distance of 10 billion
light-years.
http://www.spacetelescope.org/vide
os/html/hst15_light_speed.html
And then there’s the faint, relatively shortwavelength
radio hiss that fills the entire
Universe. This is known as the cosmic
microwave background, and it is the echo
of the Big Bang. The very afterglow of the
Full-screen WMAP image,
zooming in until you just see (and
hear!) noise.
84
hot beginnings of the Universe. J:\EyesSkies\animations\ch4\a0101
44
2:22 (34)
Narrator: Each and every part of the
spectrum has its own story to tell. At
millimetre and submillimetre wavelengths,
astronomers study the formation of
galaxies in the early Universe, and the
origin of stars and planets in our own
Milky Way.
But most of this radiation is blocked by
water vapour in our atmosphere. To
observe it, you need to go high and dry.
Animation of electromagnetic
spectrum (from Hidden Universe).
Show how certain wavelengths are
blocked by the atmosphere.
jcmt.jpg
http://outreach.jach.hawaii.edu/pres
sroom/2003_casa/jcmt.jpg
(CREDIT: Nik Szymanek)
jcmt1.jpg
http://outreach.jach.hawaii.edu/pres
sroom/2004_marsperoxide/index.ht
ml (CREDIT: Nik Szymanek)
To Llano de Chajnantor, for example. At
five kilometres above sea level, this
surrealistic plateau in northern Chile is the
construction site of ALMA: the Atacama
Large Millimeter Array.
NRAO DVD With GBT, ALMA
and VLA
Alma.avi
Footage of Chajnantor.
http://www.eso.org/public/outreach
/broadcast/compilations/alma/hd/A
LMA2_PART1_HD_720p50.mov
http://www.eso.org/public/outreach
/broadcast/compilations/alma/hd/A
LMA2_PART2_HD_720p50.mov
http://www.eso.org/public/outreach
/press-rel/pr-2007/vid-32-
07_broadcast.html
CHAJNANTOR_HRES.mov (the
desert)
85
When completed in 2014, ALMA will be
the largest astronomical observatory ever
built.
64 antennas each weighing 100 tonnes,
will work in unison. Giant trucks will
spread them out over an area as large as
London to increase the detail of the image,
or bring them close together to provide a
wider view. Each move will be made with
millimetre precision.
Footage of ALMA.
http://www.eso.org/public/outreach
/press-rel/pr-2007/vid-32-
07_broadcast.html
ANIMATIONS_HRES.mov
3:20 (35) (Take 35.1.7)
Dr. J: Many objects in the Universe also
glow in the infrared. Discovered by
William Herschel, infrared radiation is
often also called “heat radiation” because
it is emitted by all relatively warm objects,
including humans.
Dr. J. in virtual studio.
Image of Herschel discovering
infrared radiation.
H408384.jpg (Credit: CCI Archives
/ Science Photo Library)
You may be more familiar with infrared
radiation than you think. Because on
Earth, this kind of radiation is used by
night vision goggles and cameras.
But to detect the faint infrared glow from
distant objects, astronomers need very
sensitive detectors, cooled down to just a
few degrees above absolute zero, in order
to suppress their own heat radiation.
Examples of night vision.
Robert Hurt’s images?
Cryogenically cooled detector.
http://solarsystem.nasa.gov/multim
edia/gallery/ SIRTF_Infrared.jpg
(35.2.3 or was it 35.2.4? (the last))
Today, most big optical telescopes are also
equipped with infrared cameras. They
allow you to see right through a cosmic
dust cloud, revealing the newborn stars
inside, something that just cannot be seen
in the optical.
Views of big IR instruments on big
ground based telescopes.
For example, take this optical image of the
famous stellar nursery in Orion. But look
how different it is when seen through the
eyes of an infrared camera!
M42 image; crossfade to infrared
image (McCraughean).
http://www.spacetelescope.org/ima
86
ges/html/heic0601a.html
http://www.spacetelescope.org/ima
ges/html/opo9713c.html
Being able to see in the infrared is also
very helpful when studying the most
distant galaxies. The newborn stars in a
young galaxy shine very brightly in the
ultraviolet. But then this ultraviolet light
has to travel for billions of years across the
expanding Universe. The expansion
stretches the lightwaves so that when they
are received by us, they’ve been shifted all
the way into the near-infrared.
Pan/zoom across infrared deep
field.
http://www.spacetelescope.org/ima
ges/html/heic0406b.html (Credit:
NASA, ESA and R. Thompson
(Univ. Arizona))
4:30 (36)
Narrator: This stylish instrument is the
MAGIC telescope on La Palma. It searches
the sky for cosmic gamma rays, the most
energetic form of radiation in Nature.
(Time lapse) Footage of MAGIC
telescope on La Palma.
rwagner@mppmu.mpg.de
Getting MAGIC footage and
animations from Peter Rixner and
the project scientist.
Lucky for us, the lethal gamma rays are
blocked by the Earth’s atmosphere. But
they do leave behind footprints for
astronomers to study. After hitting the
atmosphere, they produce cascades of
energetic particles. These, in turn, cause a
faint glow that MAGIC can see.
http://www.nasa.gov/mpg/108531
main_flashcam0001_NASA%20
WebV_1.mpg from
http://tv.gsfc.nasa.gov/G05-
016_space.htm
http://svs.gsfc.nasa.gov/vis/a01000
0/a010200/a010245/index.html
animations\ch5\010245
(Credit: NASA/Goddard Space
Flight Center Conceptual Image
Lab)
87
proton_1EeV.mov
http://astro.uchicago.edu/cosmus/p
rojects/aires/ (Credit: to author,
Creative Commons 2.5 Generic)
gamma_60zen_5km_800x600.mp
eg
protonshoweroverchicago.mpeg
gamma_60zen_5km_800x600_left
.mpeg
gamma_60zen_5km_800x600_rig
ht.mpeg
(give credit to us and to Sergio
Sciutto for AIRES)
Graphic showing cosmic gamma
rays and production of Cerenkov
radiation.
And here’s the Pierre Auger Observatory in
Argentina. It doesn’t even look like a
telescope. Pierre Auger consists of 1600
detectors, spread over 3000 square
kilometres. They catch the particle fallout
of cosmic rays from distant supernovas and
black holes.
Footage of Pierre Auger
Observatory.
See DVD
[REQUESTED FROM
oficina@pierre]
Pierre_Auger_Ingo_FD 01.tif
(Ingo 04/07)
Pierre_Auger_Ingo_FD 02.tif
(Ingo 04/07)
88
Pierre_Auger_Ingo_SD 01.tif
(Ingo 04/07)
Pierre_Auger_Ingo_SD 02.tif
(Ingo 04/07)
Pierre_Auger_Ingo_SD 03.tif
(Ingo 04/07)
tanque en los leones3.JPG
http://www.auger.org.ar/Auger_Su
r/Img/Fluorescencia_espejo.jpg
Auger_6.jpg
(ingo@cab.cnea.gov.ar)
http://www.auger.org.ar/Auger_Su
r/Img/los_leones_interior2.jpg
Auger_5.jpg
89
(ingo@cab.cnea.gov.ar)
http://www.auger.org.ar/Auger_Su
r/Img/Lidar2.jpg Auger_4.jpg
http://www.auger.org.ar/Auger_Su
r/Img/Vista%20anterior_Los%20L
eones.jpg Auger_3.jpg
(ingo@cab.cnea.gov.ar)
http://www.auger.org/photos/mega
pix/panorama/DSC01655.jpg
Auger_2.jpg
(ingo@cab.cnea.gov.ar)
http://www.auger.org/media/imag
e_highlights.html
http://www.fcaglp.unlp.edu.ar/~ex
tension/228/Allekotte/030.jpg
Auger_1.jpg
(ingo@cab.cnea.gov.ar)
http://www.fcaglp.unlp.edu.ar/~ex
tension/228/Allekotte/
And what about neutrino detectors, built in
deep mines or beneath the surface of the
ocean, or in the Antarctic ice. Could you
call those telescopes?
Well, why not? After all, they do observe
the Universe, even if they don’t capture
data from the electromagnetic spectrum.
SPstory07.mov
Icecube2007.mov
Footage or images of underwater
or under-ice neutrino detectors.
Animation of how they respond to
traversing neutrinos.
90
Neutrinos are elusive particles that are
produced in the Sun and supernova
explosions. They were even produced in the
Big Bang itself. Unlike other elementary
particles, neutrinos can pass through
regular matter, travel near the speed of light
and have no electric charge.
Although these particles may be difficult to
study, they are plentiful. Each second more
than 50 trillion electron neutrinos from the
Sun pass through you.
http://www.news.wisc.edu/newsph
otos/images/IceCube_aerial_view
05.jpg from
http://www.news.wisc.edu/newsph
otos/icecube.html
http://www.nsf.gov/news/news_im
ages.jsp?cntn_id=106781&org=N
SF
http://www.delawareonline.com/bl
ogs/uploaded_images/TwoTanks-
747438.jpg from
http://www.delawareonline.com/bl
ogs/antarctica.html
[public_affairs suketto.icrr.utokyo.ac.jp
e-mailed
05/08/08 and requested video
footage and permission for
images]
http://www.spacetelescope.org/vid
eos/html/mov/180px/astro_aq.html
(Credit: ESA/Hubble (M.
Kornmesser & L. L. Christensen))
astro_aq.avi
Maybe
http://svs.gsfc.nasa.gov/vis/a00000
0/a003400/a003428/index.html
animations\ch5\003428
(Credit: NASA/Goddard Space
Flight Center Scientific
Visualization Studio)
91
http://svs.gsfc.nasa.gov/vis/a00000
0/a003400/a003426/index.html
animations\ch5\003426
(Credit: NASA/Goddard Space
Flight Center Scientific
Visualization Studio)
or
http://svs.gsfc.nasa.gov/vis/a00000
0/a003400/a003412/index.html
animations\ch5\003411
animations\ch5\003412
(Credit: NASA/Goddard Space
Flight Center Scientific
Visualization Studio)
http://svs.gsfc.nasa.gov/vis/a00000
0/a003400/a003411/index.html
(Credit: NASA/Goddard Space
Flight Center Scientific
Visualization Studio)
Finally, astronomers and physicists have
joined forces to build gravitational wave
detectors. These “telescopes” do not
observe radiation or catch particles. Instead,
they measure tiny ripples in the very
structure of space-time – a concept
predicted by Albert Einstein’s theory of
relativity.
Stills of LIGO
Animation of how they detect
gravitational waves.
[emailed jrweiner@caltech.edu]
[e-mailed thomson@mit.edu
04/08/08 – responded and has
nothing – ccd to Jill Perry]
92
[e-mailed dbanegas@nsf.gov
04/08/08]
Creation of grav. waves:
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010143/index.html
animations\ch5\010143
(Credit: NASA)
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010142/index.html
animations\ch5\010142
(Credit: NASA)
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010140/index.html
animations\ch5\010140
(Credit: NASA)
With a stunning variety of instruments,
astronomers have opened up the full
spectrum of electromagnetic radiation, and
have even ventured beyond.
Cross fade of images in a variety
of wavelengths, but at the same
scale, of: Milky Way, M31, ...
http://www.spacetelescope.org/im
ages/html/heic0604a.html
93
http://www.spacetelescope.org/im
ages/html/heic0604d.html
http://www.spacetelescope.org/im
ages/html/heic0604b.html
http://www.spacetelescope.org/im
ages/html/heic0604f.html
http://www.spacetelescope.org/im
ages/html/heic0604e.html
http://www.spacetelescope.org/im
ages/html/heic0103f.html
But some observations simply can’t be
done from the ground.
The answer? Space telescopes.
Cross to deep space image (slowly
panning). Out of the distance
Hubble comes into view.
94
(6:32)
http://www.spacetelescope.org/vid
eos/html/heic0720b.html
6. Beyond Earth (06:39)
0:00 (37) (Take 37.1.5)
Dr. J: The Hubble Space Telescope.
It is by far the most famous telescope in
history. And for good reason. Hubble has
revolutionised so many fields in
astronomy.
(Dr. J. not in view)
Zoom in on and fly around Hubble
Space Telescope.
http://www.spacetelescope.org/vid
eos/html/heic0720b.html
http://www.spacetelescope.org/vid
eos/html/hubblecast06d.html
hubblecast06d.avi
http://www.spacetelescope.org/vid
eos/html/hubblecast06e.html
hubblecast06e.avi
http://www.spacetelescope.org/vid
eos/html/hubblecast06f.html
By modern standards, Hubble’s mirror is
actually quite small. It only measures about
2.4 metres across. But its location is
literally out of this world. High above the
blurring effects of the atmosphere, it has an
exceptionally sharp view of the Universe.
And what’s more, Hubble can see
ultraviolet and near-infrared light. This
light just cannot be seen by ground-based
telescopes because it is blocked by the
atmosphere.
95
hubblecast06f.avi
FULL SCREEN
Cameras and spectrographs, some as big as
a telephone booth, dissect and register the
light from distant cosmic shores.
http://www.spacetelescope.org/vid
eos/html/hubblecast10b.html
hubblecast10b.avi
Just like any ground-based telescope,
Hubble is upgraded from time to time.
Spacewalking astronauts carry out
servicing missions. Broken parts get
refurbished. And older instruments get
replaced with newer and state-of-the-art
technology.
Footage of servicing missions.
Susan.M.Hendrix@nasa.gov
http://www.nasa.gov/mission_page
s/hubble/servicing/SM4/multimedi
a/index.html
Hubble has become the powerhouse of
observational astronomy. And it has
transformed our understanding of the
cosmos.
More fly around Hubble, until it
points right at you. Zoom in on the
mirror, looking out to the stars.
Hst15_big_bang_to_hubble.avi
1:04 (38)
Narrator: With its keen eyesight, Hubble
observed seasonal changes on Mars... a
cometary impact on Jupiter... an edge-on
view of Saturn’s rings... and even the
surface of tiny Pluto.
Hubble images:
Changing seasons on Mars.
opo9715b.jpg (Credit: Phil James
(Univ. Toledo), Todd Clancy
(Space Science Inst., Boulder, CO),
Steve Lee (Univ. Colorado), and
NASA/ESA)
http://www.spacetelescope.org/ima
ges/html/opo9715b.html
+images_d?
96
opo9715b1.tif
opo9715b2.tif
opo9715b3.tif
PIA01248.tif (Credit: NASA Jet
Propulsion Laboratory (NASA-
JPL))
http://nix.ksc.nasa.gov/info;jsession
id=74u9fgpmst11?id=PIA01248&o
rgid=10
Impact of SL9 on Jupiter.
+astro_aa?
http://www.spacetelescope.org/vide
os/html/hst15_sl9_crash.html
http://www.spacetelescope.org/vide
os/html/hst15_sl9_jupiter_close.ht
ml
Reconstructed images of Pluto.
opo0609b.tif (Credit: NASA, ESA,
H. Weaver (JHU/APL), A. Stern
(SwRI), and the HST Pluto
Companion Search Team)
http://www.spacetelescope.org/ima
ges/html/opo0609b.html
It revealed the life cycle of stars, from
their very birth and baby days in a nursery
of dust-laden clouds of gas, all the way to
their final farewell: as delicate nebulae,
slowly blown into space by dying stars, or
as titanic supernova explosions that almost
outshine their home galaxy.
http://www.spacetelescope.org/vide
os/html/heic0712d.html
heic0712d.avi
97
supernova explosions and remnants.
+ heic0515a?
http://www.spacetelescope.org/vide
os/html/heic0712g.html
heic0712g.avi
Deep in the Orion Nebula, Hubble even
saw the breeding ground of new solar
systems: dusty disks around newborn stars
that may soon condense into planets.
Martin: Zoom on the Orion Nebula
Views of proplyds in M42.
MAKE A COLLAGE OF
THESE IMAGES – THEY ARE
SMALL
opo9545n.tif
http://www.spacetelescope.org/ima
ges/html/opo9545n.html
opo9545o.tif
http://www.spacetelescope.org/ima
ges/html/opo9545o.html
opo9424b.tif (Credit: C.R.
98
O'Dell/Rice University
NASA/ESA)
http://www.spacetelescope.org/ima
ges/html/opo9424b.html
opo0113b.jpg (Credit: J. Bally
(University of Colorado) and H.
Throop (SWRI))
http://www.spacetelescope.org/ima
ges/html/opo0113b.html
The space telescope studied thousands of
individual stars in giant globular clusters,
the oldest stellar families in the Universe.
http://www.spacetelescope.org/vide
os/html/heic0809d.html
http://www.spacetelescope.org/vide
os/html/heic0715e.html
And galaxies, of course. Never before had
astronomers seen so much detail. Majestic
spirals, absorbing dust lanes, violent
collisions.
Colliding galaxies
http://www.spacetelescope.org/vide
99
os/html/heic0810c.html
http://www.spacetelescope.org/vide
os/html/heic0810b.html
Extremely long exposures of blank
regions of sky even revealed thousands of
faint galaxies billions of light-years away.
Photons that were emitted when the
Universe was still young. A window into
the distant past, shedding new light on the
ever-evolving cosmos.
Hubble Deep Field fly-through
Heic0714g
2:16 (39) (Take 39.1.2)
Dr. J: Hubble is not the only telescope in
space.
Dr. J. in front of MR image wall.
Background: Hubble flies out of
view...
This is NASA’s Spitzer Space Telescope,
launched in August 2003. In a way, it is
Hubble’s equivalent for the infrared.
...and Spitzer flies into view.
[we should have HD footage
already?]
(Take 39.2.1)
Spitzer has mirror that is only 85
centimetres across. But the telescope is
hiding behind a heat shield that protects it
from the Sun. And its detectors are tucked
away in a dewar filled with liquid helium.
Here the detectors are cooled down to just
a few degrees above absolute zero making
them very very sensitive.
Footage of Spitzer. Exploded view
of telescope.
http://www.spitzer.caltech.edu/feat
ures/hd/index.shtml
http://www.spitzer.caltech.edu/feat
ures/hd/files/Showcase4_XPlanets-
HD.m4v
Spitzer has revealed a dusty Universe.
Dark, opaque clouds of dust glow in the
infrared when heated from within.
Full screen: Glowing dust clouds.
(Dr. J. no longer visible)
100
Ophcloud_spitzer.jpg (Credit:
NASA JPL-Caltech, HarvardSmithsonian
CfA)
http://apod.nasa.gov/apod/ap08021
5.html
m45_spitzerR.jpg (Credit: NASA,
JPL-Caltech, J. Stauffer (SSC,
Caltech))
http://apod.nasa.gov/apod/ap07041
3.html
Shock waves from galaxy collisions sweep
up dust in telltale rings and tidal features,
new sites for ubiquitous star formation.
Dusty structures and super star
clusters in galaxy mergers.
http://gallery.spitzer.caltech.edu/Im
agegallery/image.php?image_name
=ssc2006-11a
http://gallery.spitzer.caltech.edu/Im
agegallery/image.php?image_name
=sig06-005
101
http://gallery.spitzer.caltech.edu/Im
agegallery/image.php?image_name
=ssc2008-14a
(Take 39.3.3)
Dust is also produced in the aftermath of a
star’s death. Spitzer found that planetary
nebulae and supernova remnants are laden
with dust particles, the prerequisite
building blocks of future planets.
Infrared images of planetary
nebulae and supernova explosions.
snake_spitzer_big.jpg (Credit: S.
Carey (SSC/Caltech), JPL-Caltech,
NASA))
http://apod.nasa.gov/apod/ap07092
4.html
At other infrared wavelengths, Spitzer can
also see right through a dust cloud,
revealing the stars inside, hidden in their
dark cores.
Spitzer view of ‘dust-cloaked’ star
forming region.
ssc2008-03a1.jpg (Credit: NASA /
JPL-Caltech / CfA)
http://cosmiclog.msnbc.msn.com/ar
chive/2008/02/12/659870.aspx
(Take 39.4.3)
Finally, the space telescope’s
spectrographs have studied the
atmospheres of extrasolar planets – gas
giants like Jupiter, that race around their
parent stars in just a few days.
Animation of transiting planet,
combined with representation of
Spitzer observations (?).
http://www.spitzer.caltech.edu/feat
ures/hd/files/Showcase4_XPlanets-
HD.m4v
AND/OR
102
http://www.spacetelescope.org/vid
eos/html/heic0807c.html
http://www.spacetelescope.org/vid
eos/html/heic0807b.html
heic0807b.avi
(Take 39.5.2)
So what about X-rays and gamma rays?
Well, they are completely blocked by the
Earth’s atmosphere. And so without space
telescopes, astronomers would be totally
blind to these energetic forms of radiation.
Dr. J. in virtual studio.
Electromagnetic spectrum (from
Hidden Universe) and atmospheric
transmission graphic, now
focussing on high-energy radiation.
X-ray and gamma ray space telescopes
reveal the hot, energetic and violent
Universe of galaxy clusters, black holes,
supernova explosions, and galaxy
collisions. http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010141/index.html
J:\EyesSkies\animations\ch5\01014
1
(Credit: NASA)
103
http://www.spacetelescope.org/vide
os/html/heic0810c.html
heic0810.avi
(Take 39.5.2 Pu 4)
They are very hard to build, though.
Energetic radiation passes right through a
conventional mirror. X-rays can only be
focused with nested mirror shells made of
pure gold. And gamma rays are studied
with sophisticated pinhole cameras, or
stacked scintillators that give off brief
flashes of normal light when struck by a
gamma ray photon.
Images of nested mirrors and of
gamma-ray detectors.
S68-03354.jpg (Credit: NASA
Johnson Space Center (NASA-
JSC))
http://nix.larc.nasa.gov/info;jsessio
nid=4fl8bpr50av80?id=S68-
03354&orgid=8
STS037-51-006.jpg (Credit: NASA
Johnson Space Center (NASA-
JSC))
http://nix.larc.nasa.gov/info;jsessio
nid=4fl8bpr50av80?id=STS037-51-
006&orgid=8
KSC-01PP-0192.jpg (Credit:
NASA Kennedy Space Center
(NASA-KSC))
http://nix.larc.nasa.gov/info;jsessio
nid=4fl8bpr50av80?id=KSC-01PP-
104
0192&orgid=5
(Take 39.6.4 (39.6.2 also good))
In the 1990s, NASA operated the
Compton Gamma Ray Observatory. At the
time, it was the largest and most massive
scientific satellite ever launched. A fully
fledged physics lab in space.
Footage / animation of CGRO.
cgro_iau.tar.gz
Zipped file in images folder
Deorbit_AEOS-CGRO.mpg
cgro_vvu.mov
Deploy_CGRO.jpg
Cartoon_CGRO.tif
cgro_0003356.jpg
cgro_9134213.jpg
CGRO_launch.tif
CGRO_line_labels.tif
Deploy_CGRO.jpg
Poster_CGRO.tif
CGRO_line_nolabels.tif
[e-mailed
newman@lheamail.gsfc.nasa.gov
23/07/08 and 30/07/08]
[e-mailed
myersjd@lheamail.gsfc.nasa.gov
04/08/08]
[e-mailed
gehrels@milkyway.gsfc.nasa.gov
04/08/08]
john.d.myers@nasa.gov e-mailed
05/08/08 – will
In 2008, Compton was succeeded by
GLAST: the Gamma Ray Large Area
Space Telescope. It will study everything
in the high-energy Universe from dark
matter to pulsars.
Launch of GLAST; animation of
GLAST in orbit.
Launch:
ksc_061108_glast_launch_1080i.m
ov
http://www.nasa.gov/multimedia/h
d/index.html
105
http://svs.gsfc.nasa.gov/vis/a01000
0/a010200/a010251/index.html
animations\ch5\010200
(Credit: NASA/Goddard Space
Flight Center, Music composed by
Nolan Gasser, © 2008, Music
performed by the American Brass
Quintet)
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010172/index.html
animations\ch6\010164_without_m
ap
(Credit: NASA/Goddard Space
Flight Center)
also:
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010166/index.html
animations\ch6\a010166
(Credit: NASA/Goddard Space
Flight Center Conceptual Image
Lab)
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010164/index.html
animations\ch6\010164_with_map
(Credit: NASA/Goddard Space
Flight Center Conceptual Image
Lab)
Gamma ray sky moving:
106
http://svs.gsfc.nasa.gov/vis/a00000
0/a003400/a003439/index.html
animations\ch6\003439
animations\ch6\010164_without_m
ap
(Credit: NASA/Goddard Space
Flight Center Scientific
Visualization Studio)
Animation:
animations\ch6\003439_2
(Take 39.7.2)
Meanwhile, astronomers have two X-ray
telescopes in space. NASA’s Chandra Xray
Observatory and ESA’s XMM-Newton
Observatory are both studying the hottest
places in the Universe.
Footage of Chandra and XMM-
Newton.
From Kim and Megan
O:\VIDEO\EyesSkies\videos06\
CXO_Bshot_AprilHobart/
O:\VIDEO\EyesSkies\videos06\
CXO_Bshot_DanaBerry/
XMM1111.jpg
http://www.esa.int/esaCP/ESAPPM
F18ZC_index_1.html#subhead1
4:46 (40)
Narrator: This is what the sky looks like
with X-ray vision.
Extended features are clouds of gas, heated
to millions of degrees by shock waves in
supernova remnants.
Chandra Milky Way mosaic (zoom
/ pan).
gcenter_xray_rgb.ps (Credit:
NASA/UMass/D.Wang et al.)
Binary black holes?
The bright point sources are X-ray
binaries: neutron stars or black holes that
suck in matter from a companion star. This
hot, infalling gas emits X-rays.
107
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010140/index.html
animations\ch5\010140
(Credit: NASA)
Likewise, X-ray telescopes reveal
supermassive black holes in the cores of
distant galaxies. Matter that spirals inward
gets hot enough to glow in X-rays just
before it plunges into the black hole and
out of sight.
X-ray image of distant galaxy,
transforming into animation of
matter falling into supermassive
black hole.
http://svs.gsfc.nasa.gov/vis/a01000
0/a010200/a010200/index.html
(Credit: NASA/Goddard Space
Flight Center Conceptual Image
Lab)
Hot but tenuous gas also fills the space
between individual galaxies in a cluster.
Sometimes, this intracluster gas is shocked
and heated even more by colliding and
merging galaxy clusters.
X-ray images / representations of
intracluster gas.
1e0657_H1.jpg 1e0657_H2.tif
(Credits: X-ray:
NASA/CXC/CfA/M.Markevitch,
Optical and lensing map:
NASA/STScI,
Magellan/U.Arizona/D.Clowe,
Lensing map: ESO WFI)
http://www.esa.int/esa-
mmg/mmg.pl?b=b&keyword=Bull
et%20Cluster&single=y&start=2
108
Even more exciting are gamma ray bursts,
the most energetic events in the Universe.
These are catastrophic terminal explosions
of very massive, rapidly spinning stars.
In less than a second, they release more
energy than the Sun does in 10 billion
years.
Animation of a GRB (from
precursor to afterglow).
OR
http://svs.gsfc.nasa.gov/vis/a00000
0/a003400/a003439/index.html
5:48 (41) (Take 41.1.2)
Dr. J: Hubble, Spitzer, Chandra, XMMNewton
and GLAST are all versatile
giants.
But some space telescopes are much
smaller and have much more focused
missions.
Dr. J. in front of MR image wall.
Background: images of big space
telescopes.
O:\VIDEO\EyesSkies\videos06\
CXO_Bshot_AprilHobart/
O:\VIDEO\EyesSkies\videos06\
CXO_Bshot_DanaBerry/
Take COROT, for example. This French
satellite is devoted to stellar seismology
and the study of extrasolar planets.
Footage of COROT’s planet
detection technique.
corot 5_vue avant_hires.jpg
(Credit: ESA/CNES/D. Ducros)
http://www.esa.int/esa-
mmg/mmg.pl?b=b&keyword=exop
lanet&single=y&start=7
109
corot_2_hires.jpg (Credit:
ESA/CNES/D. Ducros)
http://www.esa.int/esa-
mmg/mmg.pl?b=b&keyword=CO
ROT&single=y&start=9
http://www.esa.int/esa-
mmg/mmg.pl?b=b&keyword=CO
ROT&single=y&start=2
http://www.esa.int/esa-
mmg/mmg.pl?b=b&keyword=CO
ROT&single=y&start=34
[e-mailed francoise.baillypoirot@cnes.fr
04/08/08]
sequence_complete_courbe_15110
5.mov
anim_corot_ecorche_1205.mov
Or NASA’s Swift satellite, a combined Xray
and gamma ray observatory designed
to unravel the mystery of gamma ray
bursts.
Footage of Swift.
J:\EyesSkies\animations\ch6\SWIF
T animation
(Credit: NASA/Goddard Space
Flight Center Scientific
Visualization Studio)
ONLY HAVE STANDARD
DEFINITION
110
(Take 41.2.1)
And then there’s WMAP, the Wilkinson
Microwave Anisotropy Probe. In just over
two years in space, it had already mapped
the cosmic background radiation to
unprecedented detail. WMAP gave
cosmologists the best view yet of one of
the earliest phases of the Universe, more
than 13 billion years ago.
Footage of WMAP and its results:
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010121/index.html
animations\ch6\010121
(Credit: NASA)
also:
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010123/index.html
animations\ch6\010123
(Credit: NASA)
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010122/index.html
animations\ch6\010122
(Credit: NASA)
Opening up the space frontier has been one
of the most exciting developments in the
history of the telescope.
So what’s next?
(6:39)
7. What’s next? (06:04)
In Arizona, the first mirror has been cast for
the Giant Magellan Telescope. This huge
instrument will be built at the Las
Campanas Observatory in Chile. Its seven
mirrors, each well over eight metres across,
will be arranged like the petals of a flower.
And together they will capture more than
CompleteGMTAnim2.mov
(Courtesy of Carnegie
111
four times the amount of light any current
telescope can catch.
Observatories) THIS IS THE
SAME VIDEO, BUT WITH AN
EXTRA SHORT SHOT WITH
STARS REFLECTED OFF THE
MIRRORS
Low
GMT-AE-Full-D1-CL.mov (Low)
F-D1-CL.mov (Courtesy of
Carnegie Observatories)
GMT-Wide-sun.tif (Courtesy of
Carnegie Observatories)
The Californian Thirty Meter Telescope,
planned for 2015, is more like a giant
version of Keck. Hundreds of individual
segments make up one enormous mirror as
tall as a six-storey apartment.
Animation of TMT.
O:\VIDEO\EyesSkies\videos03\
Ch.3_tmt_animation.avi
Or:
Ch.3_26_TMT_Concept_1.jpg
(Credit: the TMT Observatory
Corporation)
Ch.3_32_TMT_Concept_tertiar
y_and_primary_mirrors.jpg
(Credit: the TMT Observatory
Corporation)
112
Ch.3_29_TMT_Concept_4.gif
(Credit: the TMT Observatory
Corporation)
In Europe, plans are ready for a European
Extremely Large Telescope. At 42 metres
in diameter, its mirror will be as large as an
Olympic swimming pool - twice the surface
area of the Thirty Meter Telescope.
Animation of E-ELT.
E_ELT.avi
NEW ELT anis from Herbert in
1080p (for Koenig)!
These future monsters, optimised for
infrared observations, will all be outfitted
with sensitive instruments and adaptive
optics.
More E-ELT
Extra stills:
Ch.2_15_ELT_Concept.jpg
Ch.2_16_ELT_Concept.tif
Ch.2_17_ELT_Concept.jpg
They should reveal the very first generation
of galaxies and stars in the history of the
Universe.
Simulations of ELT science.
Moreover, they may provide us with the
first true picture of a planet in another solar
Simulations of exoplanet
detection.
113
system. http://www.eso.org/gallery/v/Vide
os/ESO_ENGL.flv.html (1.57)
For radio astronomers, 42 meters is
peanuts. They hook up many smaller
instruments to synthesise a much larger
receiver.
Image of radio antenna; zoom out
to show it to be part of an array.
In the Netherlands, the Low Frequency
Array, or LOFAR, is under construction.
Fibre optics will connect 30 000 antennas
to a central supercomputer. The novel
design has no moving parts, but it can
observe in eight different directions
simultaneously.
LOFAR footage.
DVD Footage requested from:
boekhorst@astron.nl
signaalverwerkingskast
LOFAR.jpg (Credit: ASTRON)
aardappelplanten plus sensor.jpg
(Credit: ASTRON)
Agro sensor.jpg (Credit:
ASTRON)
Figure01-LOFAR Press ReleaseApril
2007.png (Credit: ASTRON)
114
First LOFAR station Exloo.jpg
(Credit: ASTRON)
foto 060.jpg (Credit: ASTRON)
Geophone - three-axis vibration
sensor.jpg (Credit: ASTRON)
H4 n.jpg (Credit: ASTRON)
HBA Antennas.jpg (Credit:
ASTRON)
LOFAR antennes.jpg (Credit:
ASTRON)
Astron_Logo_1000.jpg (Credit:
ASTRON)
115
[boekhorst@astron.nl ]
LOFAR animation at lower right
of
http://www.lofar.org/p/geninfo.ht
m
LOFAR technology will probably find its
way into the Square Kilometre Array,
which is now topping the wish-list of radio
astronomers.
The international array will be built in
Australia or South Africa. Large dish
antennas and small receivers will team up
to provide incredibly detailed views of the
radio sky.
And with a total collecting area of one
square kilometre, the new array will be by
far the most sensitive radio instrument ever
constructed.
animations.
skaAnimation_high.mpg
SKA_3.tif
(greenwood@skatelescope.org)
(Credit: SKA Program
Development Office under
contract to Xilostudios)
Through Helen sim:
Colin Greenwood
Executive Officer
SKA Program Development
Office
Jodrell Bank Centre for
Astrophysics
Rm 3.116, Alan Turing Building
the University of Manchester
Oxford Road
Manchester
M13 9PL, UK
Tel: +44 (0)161 275 4063
Fax: +44 (0)161 275 4049
Email:
greenwood@skatelescope.org
Web: www.skatelescope.org
116
Evolving galaxies, powerful quasars,
blinking pulsars – no single source of
radio waves will be safe from the spying
eyes of the Square Kilometre Array.
The instrument will even look for possible
radio signals from extraterrestrial
civilisations.
SKA science.
http://svs.gsfc.nasa.gov/vis/a010000
/a010200/a010205/index.html
animations\ch7\010205
(Credit: NASA/Goddard Space
Flight Center Conceptual Image
Lab)
And what about space?
Well, after its fifth and final servicing
mission, the Hubble Space Telescope will
be on active duty until 2013 or so.
Around that time, its successor will be
launched.
Footage of HST servicing.
http://science.nationalgeographic.c
om/science/wallpaper/first-service-
mission.html
Ariane 5 launch.
launch-ariane-atv-2008-03-
09_qt_high.mov (Credits: ESA)
(super low) http://www.esa.int/esa-
mmg/mmg.pl?b=b&type=V&singl
e=y&start=38&size=b
Meet the James Webb Space Telescope, a
space infrared observatory named after a
former NASA administrator.
http://svs.gsfc.nasa.gov/vis/a01000
0/a010100/a010124/index.html
animations\ch7\JWST1
(Credit: NASA)
animations\ch7\JWST2
(Credit: NASA/Goddard Space
Flight Center Conceptual Image
Lab
117
jwst_720p.m2v (Credit:
NASA/Goddard Space Flight
Center Conceptual Image Lab)
(low)
O:\VIDEO\EyesSkies\videos07\08j
wstb_depall_dv.mov
O:\VIDEO\EyesSkies\videos07\de
ployment.mov
O:\VIDEO\EyesSkies\videos07\jw
st_telescope_stowqt.mov
O:\VIDEO\EyesSkies\videos07\JW
STAnimation.mpg
Extra footage: WEBB DVD
Once in space, its 6.5 metre segmented
mirror unfolds like a blooming flower –
one seven times as sensitive as Hubble’s.
Closeup of mirror deployment.
A large sunshade keeps the optics and the
low-temperature instruments in permanent
shadow, allowing them to operate near a
whopping minus 233 degrees Celsius.
Closeup of sunshade and
instruments.
Extra:
jwst_new6(nasa).tif OR
jwst_new6.jpg (Credit: NASA
(Northup Grumman, ESA & CSA)
http://www.jwst.nasa.gov/images_j
wst.html
118
The James Webb Space Telescope won’t
orbit the Earth. Instead, it will be parked
1.5 million kilometres from our planet, in a
wide orbit around the Sun.
Animation showing JWST’s orbit.
Jwst_g?
Half a century ago, the Hale telescope on
Palomar Mountain was the largest in
history. Now, an even bigger one will be
flying into the depths of space.
hale_5m_outsidefull.mov
Zoom out to show more and more
surrounding Universe.
We can only speculate about the exciting
discoveries it will make. Stay tuned!
3:27 (43)
(Part 1: 43.1.6
Part 2: 43.1.7)
Dr. J: Meanwhile, creative engineers come
up with revolutionary designs for new
telescopes all the time.
Dr. J. in virtual studio.
In Canada, scientists have built a so-called
“liquid mirror telescope”. In this kind of
telescope the starlight is reflected not by a
solid mirror but rather by the curved
surface of a rotating reservoir of liquid
mercury.
Because of their design, mercury
telescopes can only look straight up, but
their advantage is that they’re relatively
cheap and easy to build.
Images of LMT:
180718main_3-7-m1.JPG
(Credit: Guy Plante (Laval))
http://www.nasa.gov/centers/ames/
multimedia/images/2007/liquidmir
ror.html
180724main_6-mMirror.jpg
(Credit: Paul Hickson (UBC))
Low
119
Radio astronomers want to put a LOFARlike
array of small antennas onto the
surface of the Moon, as far away as
possible from terrestrial sources of
interference.
Animation of radio telescope on
moon...
.
http://www.spacetelescope.org/vide
os/html/astro_ba.html
(SD)
Who knows, one day there might even be a
big optical telescope on the far side of the
Moon.
...and of big optical telescope on
moon.
OR just Moon:
http://svs.gsfc.nasa.gov/vis/a00000
0/a003400/a003444/index.html
animations\ch1\a003400
(Credit: NASA/Goddard Space
Flight Center Scientific
Visualization Studio)
And using space telescopes and occulting
disks, X-ray astronomers hope to improve
their eyesight tremendously in the future.
They may even succeed in imaging the
very edge of a black hole.
Images of future x-ray space
telescopes and what it might
deliver.
4:11 (44)
Narrator: One day, the telescope may
answer one of the most profound questions
puzzling humanity: are we alone in the
Zoom in on nebula.
120
Universe?
http://www.spacetelescope.org/vid
eos/html/heic0715c.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen)) heic0715c.avi
We know that there are other solar systems
out there. We suspect there are even planets
like Earth, with liquid water. But... is there
life?
Simulations of exoplanets and
Earth-like planets.
ftp://ftp.eso.org/pub/pad/broadcasti
ng/NR-2007/VNR22/ …
ANIMATIONS_BROADCAST.m
ov
Locating such extrasolar planets proves
difficult. They are often hidden from
astronomers by the intense light radiated by
their mother stars.
Interferometers launched into the darkness
of space may provide a novel answer.
Right now NASA is considering a project
called the Terrestrial Planet Finder. And in
Europe, scientists are designing the Darwin
Array.
TPF/Darwin footage.
[e-mailed
Randal.K.Jackson@jpl.nasa.gov
09/08/08]
OR
http://www.spacetelescope.org/vid
eos/html/heic0720e.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen)) heic0720e.avi
121
http://www.spacetelescope.org/vid
eos/html/heic0720d.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen)) heic0720d.avi
http://www.spacetelescope.org/vid
eos/html/heic0720c.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen)) heic0720c.avi
Six space telescopes orbit the Sun in
formation. Lasers control their mutual
distances to the nearest nanometre.
Together they have incredible resolving
power, cancelling out the light from
overbearing stars so scientists can actually
see Earth-like planets around other stars.
More of the same; simulations of
planet detections.
Next astronomers must study the light
reflected by the planet. It carries the
spectroscopic fingerprint of the planet’s
atmosphere.
Images of Earth-like planets.
218069main_HSTMethaneunlabeled_
20080319_HI.jpg
http://www.spacetelescope.org/vid
122
eos/html/hst15_exoplanet.html
http://www.nasa.gov/mission_page
s/hubble/science/exoplanet_transit.
html
Who knows, in 15 years time we may
detect the signatures of oxygen, methane
and ozone. The signposts of life.
Zoom in: images of possible life
forms.
(MARTIN)
5:19 (45)
(Take 45.1.7)
Dr. J: The Universe is full of surprises.
The sky never ceases to impress.
Night sky above horizon;
silhouette figure walks outside and
points telescope. (Dr. J. not in
view)
FAST MOTION, FAST MUSIC
Slowly rotating sky.
USE Bernd Proschold
No wonder that hundreds of thousands of
amateur astronomers across the globe go
out every clear night to marvel at the
cosmos.
USE Babak-MM2.avi (7 seconds
long)
Babak-MM4.avi and BabakMM5.avi
are also good, but both
are fast and a bit jumpy when
slowed down (TWAN footage)
(Additional: Stellafane footage.
http://www.ct-
astronomer.com/stellafane2006.ht
m
summit pan 1.jpg (Credit: Phil
Harrington)
123
summit pan 3.jpg (Credit: Phil
Harrington)
summit pan 4.jpg (Credit: Phil
Harrington)
Stellafane_panorama01.jpg (Phil
Harrington)
Stellafane_panorama03.jpg (Phil
Harrington
Webmaster@Stellafane.com)
http://stellafane.org/post_conv/200
5_conv/2005_conv.html )
Their telescopes are much better than the
instruments used by Galileo. Their digital
images even surpass the photographic
images taken by professionals just a few
decades ago.
Examples of amateur results.
http://www.ct-
astronomer.com/astrophotos.htm
http://astrosurf.com/sguisard/
SGU-Cone-Rosette-STL-200mm-
M-cp8.jpg
SGU-Baade_Window-STL-
300mm-M-cp8.jpg
SGU-Etacar-070513-FS128-STL-
H15x20m-RVB8x10m-VRGLL-L-
124
cp8.jpg
SGU-LMC-300mm-V5-M-cp8.jpg
SGU-rhooph-060402-fsq-
50x5min-800A-S-ps-cp.jpg
SGU-ic434-v2_filtered-ps2-S.jpg
Astronomers’ quest for cosmic
understanding, their telescopic exploration
of the Universe, is only 400 years old.
There’s still a lot of uncharted territory out
there.
(6:04)
Mosaic of nice space images; more
and more images are added (they
become smaller and smaller), until
a grid of many dozens of images is
visible.
8. Postlude (00:46)
0:00 (46)
Narrator: We’ve come a long way since
Galileo began charting the heavens with
his telescope four centuries ago.
Today we still observe the Universe with
telescopes, not only from Earth but in the
limitless regions of space.
The seed of humanity lies in our seemingly
endless supply of ingenuity and curiosity.
We have just begun answering some of the
greatest questions conceived. We have
charted over 300 planets around other stars
http://www.spacetelescope.org/vide
os/html/heic0719f.html (Credit:
ESA/Hubble (M. Kornmesser & L.
L. Christensen)) heic0719f.avi
BUT replace Messier etc w.
Lipperhey, Janssen, Galileo,
Kepler, Newton etc.
TWAN footage
End: Visuals: Stars moving above
telescopes
125
in our own Milky Way and located organic
molecules on planets around far flung
stars.
These incredible discoveries may seem
like the zenith of human exploration, but
the best is undoubtedly yet to come...
You too can join the discoverers.
Look up and wonder.
00:46
SGU_Zodiacal_Light_and_Milky_
Way_1280x720.wmv
Bernd Proschold:
END TITLES
This movie is dedicated to ..
Executive producer/director
Lars Lindberg Christensen, ESA/ESO
Art director/production designer
Martin Kornmesser, ESA/ESO
3D animations & rendering
Martin Kornmesser, ESA/ESO
Luis Calcada, ESO
DVD Authoring
Andre Roquette
Written by
Govert Schilling
Lars Lindberg Christensen, ESA/ESO
Researcher
Laura Simurda, ESA/ESO
Editing
Martin Kornmesser, ESA/ESO
126
Cinematographer
Peter Rixner
Music & Sound Effects
by
movetwo - Axel Kornmesser & Markus Löffler
Sound engineering and Mix
Peter Rixner, www.perix.de
Lead scientist
Dr. J a.k.a. Dr. Joe Liske (ESO)
Stunt coordinator
NN
English Narration
Howard Cooper
German Narration
Greek Narration
Manolis Zoulias & Dionysios Simopoulos
Translations
SUOMI
FRANÇAIS
Celine Peroux (European Southern Observatory)
DEUTSCH
ΕΛΛΗΝΙΚΑ
Manolis Zoulias (Academy of Athens, Greece)
Thanks to
American Institute of Physics/Emilio Segrè Visual Archives
Chandra X-ray Observatory Center
Hale Observatories
NASA
Space Telescope Science Institute
Spitzer Science Centre
The World at Night
Museum Boerhaave (Leiden)
In particular thanks to
Lars Bachmann (SDC)
Robert Hurt (NASA/SSC)
Anne Rhodes
Pedro Russo
127
Frank Summers (NASA/STScI)
Babak Tafreshi
And of course: our families!
www.eyesontheskies.org • www.spacetelescope.org • www.astronomy2009.org