16 AS 17-2-16


 

Publ. Astron. Soc. Aust., 

 

2000, 17, 179–184

© Astronomical Society of Australia 2000 10.1071/AS00016    1323-3580/00/020179$05.00

 

Beauty and Astrophysics

 

Michael S. Bessell

 

Research School of Astronomy & Astrophysics, Institute of Advanced Studies, 
Australian National University, Private Bag, 

Weston Creek PO, ACT 2611, Australia 
bessell@mso.anu.edu.au, http://www.mso.anu.edu.au/~bessell 

 

Received 1999 October 30, accepted 2000 April 10

 

Abstract: 

 

 Spectacular colour images have been made by combining CCD images in three different
passbands using Adobe Photoshop. These beautiful images highlight a variety of astrophysical
phenomena and should be a valuable resource for science education and public awareness of science.
The wide field images were obtained at the Siding Spring Observatory (SSO) by mounting a Hasselblad
or Nikkor telephoto lens in front of a 2K 

 

¥ 

 

2K CCD. Options of more than 30 degrees or 6 degrees square
coverage are produced in a single exposure in this way. Narrow band or broad band filters were placed
between lens and CCD enabling deep, linear images in a variety of passbands to be obtained. We have
mapped the LMC and SMC and are mapping the Galactic Plane for comparison with the Molonglo Radio
Survey. Higher resolution images have also been made with the 40 inch telescope of galaxies and star
forming regions in the Milky Way. 

 

Keywords: 

 

techniques: image processing—surveys —miscellaneous 

 

1  Introduction

 

1.1 Foreword

 

I chose this title of this paper to remind the jaded
astronomers amongst us of the major reason why we
chose astronomy as a career. It also explains why there
are so many dedicated amateur astronomers and why the
general public readily supports astronomy. Astronomy,
combining beauty with mystery and wonder, remains a
formidable combination of attractions for the minds of
students and others with a restless intellect.

To a few theoreticians, 

 

E = mc

 

2

 

 represents the
highest form of beauty, but most of us are visual people
stimulated more by pictures than equations. I well
remember as a student attending Bart Bok’s public
lectures in Hobart and participating in his evocation of
the wonders of astronomy through his black and white
slides of the star-forming regions in Norma, Carina and
the Magellanic Clouds. This was for me, I thought.

In the current world many of the best students are
turning to economics and law and many students are
more attracted to astrology and creationism than to
mainstream science. In addition, within some of the
liberal arts disciplines, there has been an increasing
attack on the scientific method and the absolutism of
science. It is therefore essential for the ‘hard scientists’,
especially the physical scientists, to speak out in support
of the scientific method of determining the truth in the
physical world and to challenge the pessimistic outlook
of the Jeremiahs in the community with the optimism
from scientific discoveries both on Earth and elsewhere.

Part of this fight-back is not only to attract some of
the best students back into mainstream science, but to
educate all students and the general public about the
importance of the scientific method and the importance
of scientific research. A public better educated on these
matters is more likely to result in governments that
make well informed decisions and which will fund

research and education adequately for the betterment of
future generations.

School teachers, university lecturers and the media
all have an important part to play in this and to assist
them it is essential to provide a wide range of visual
stimuli that can attract attention, maintain interest and
affect the emotions. The coloured images from Mt
Wilson, NASA, the Anglo-Australian Observatory
(AAO) and more recently the Hubble space Telescope
(HST) are excellent resources, but in this day of visual
overload it is important to provide many new images of
high impact that can be used for many different pur-
poses and to provide these on a continuing basis.

 

1.2 Stimulus and Opportunities

 

In this paper I would like to give some of the results
from imaging projects that I have been involved with at
SSO using modest optics but with a large science grade
CCD. I hope that this will encourage some of you to
experiment with your own images and to utilise all these
images that have been produced in your lectures and
presentations.

The processing into colour images is the most time
consuming and in many ways the most difficult step,
albeit the most rewarding. The most exciting moment is
the instant three different black and white images
combine to produce colour. There are invariably sur-
prises as, unlike earthly scenes of mountains, streams,
skies and people that we see every day, we often have
no idea of what colours or distribution of colours will
a p p e a r  i n  a n  a s t r o n o m i c a l  i m a g e .  I  b e l i e v e  t h a t
maximum impact of an image requires the skills of a
graphic designer/artist and an astronomer. There are few
people born with these skills but it raises the possibility
of collaborations. I can see many possible projects
involving astronomers and creative artists and more
specifically graphic design students, and even a major

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180 M. S. Bessell

 

project for producing an interactive CDROM of the
survey images.

Finally I hope that it will encourage amateur
astronomers and teachers from schools with access to
the new low and medium cost CCD systems to take on
the challenging but very rewarding and creative astro-
nomical colour imaging projects.

 

1.3 The Many Uses of Colour

 

There are many ways in which the use of colour
enhances the information in an astronomical image.
Although normal broad-band blue–green–red images
approximating the eye’s response can be used to
illustrate many topics in astrophysics, it is the use of
narrow-band images that provide more specific astro-
physical information, particularly that involving the gas
and dust in the interstellar medium. It is also the
transformation of images made in passbands in the UV,
IR or radio into optical colours that enhances our
insights into astrophysical properties or highlights the
unusual object. Such a technique has wide spread
applications, one of which is to illustrate the photo-
metric redshifts of distant galaxies. We also nowadays
often make use of false-colour images to record intensity
differences in an image made with a single passband.
Colour is therefore the best way to present most data,
but its use has been inhibited in the past by the expense
of colour reproduction in the main science journals.
However, with more and more electronic journals being
produced, the provision of coloured JPG files should not
be an added expense. David Malin (see e.g. Malin 1992)
has pioneered the use of colour in astronomical imaging
a n d  y o u  a r e  r e f e r e d  t o  t h e  A A O  i m a g e s  p a g e
(www.aao.gov.au/images.html) for his suite of images
derived from photographic plates and film, images that
inspired the CCD work reported here.

 

1.4 The Wide-field Imaging (WFI) Project

 

I had been experimenting at the 16 inch telescope with
the 2.3 m quartz optics reimaging camera and a 1K CCD
to provide UBVI and 

 

H

 

a

 

 images of the Magellanic
Clouds. But because the scale was a little low and access
to the imager camera was uncertain, John Hart sug-
gested I try out a commercial Nikon telephoto lens
bought many years earlier for an unsuccessful image
tube project. The results were excellent. So, when Anne
Green and Lawrence Cram made a request for 

 

H

 

a

 

images for comparison with their Molonglo Radio
Surveys of the galactic plane (Green et al. 1999; see
www.astrop.physics.usyd.edu.au/MGPS/) we decided
that this was the appropriate setup. Funds were provided
from Sydney University and the Institute for Advanced
Studies at the Australian National University for a col-
laborative WFI project and a computer and data drive
were purchased. A mechanical lens mount, filter holders
and CCD mounting brackets were made and the Nikon
imager providing a 6.8 degree field on a 2K CCD was

installed on the 16 inch telescope mount in place of the
existing telescope tube. Dome flat field screens and
lamps were also provided. For the first year we used a
CCD controller, computer and 2K CCD borrowed from
the other SSO and Mt Stromlo Observatory (MSO) tele-
scopes when they were unscheduled, but recently have
obtained a dedicated 2K CCD and controller for the
project. More details of the 

 

H

 

a

 

 survey can be found at
www.mso.anu.edu.au/~buxton/halpha.html.

We have also borrowed a Hasselblad lens from
another ANU Department and made a new mounting so
that we can image over 30 degrees of sky with a single
exposure. We have also used the 40 inch telescope to
obtain images at higher resolution of smaller objects,
especially galaxies outside the local group.

Table 1 gives the mountings, cameras, image scales
and field sizes.

 

Table 1. Camera focal lengths and fields

 

1.5 Acknowledgments

 

Major contributors to the project have been Michelle
Buxton (MSSSO) and Bob Watson (University of
Tasmania). They did many of the initial observations
and Bob developed all the IRAF scripts for the data
processing. Other students from the Universities of
Sydney, NSW and Wollongong have contributed to the
observing, together with a team of amateurs from
Coonabarabran organised by John Shobbrook who also
wrote the observing manual. In 1999 Paul Price took
over the 

 

H

 

a

 

 survey as an honours project and Newcastle
amateur Ken Hargreaves has done much observing.
Ralph Sutherland (MSSSO) has been indispensable for
his instructions on the use of Adobe Photoshop and his
inspired image processing. The workshop staffs at SSO
and MSO have been very supportive of the project both
in its construction and operation. Hwankyung Sung pro-
vided many of the 40 inch images from his work on
young star forming regions.

 

2  Atlas of Images

 

2.2 Preamble

 

Some examples of images from all these instruments
will be shown. The images do not represent limiting
observations but rather are illustrative of the information
content and the astrophysical problems that they can
address. The images are presented in a somewhat arbi-
trary progression from external galaxies to our galaxy,
the Milky Way, then move along the galactic plane from
Centaurus to Monocerotis commencing with the widest
field views to the narrow views. The aim is to integrate
what we see in our galaxy and the Magellanic Clouds
with what we see in more distant galaxies.

 

Name Focal length F no. Aperture Scale Field

Hasselblad 80 mm 2.8 60 mm 60 arcsec 30 deg.

Nikon  400 4.5 90 12 6.8

40 inch 8128  8 1016 0.6 0.3

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181 M. S. Bessell

 

Table 2. List of Images

 

No. Name Filters Camera Observer Notes

1a Antenna galaxies BV

 

H

 

a

 

40 inch msb Pair of colliding galaxies. Note knots of star forming regions
1b Centaurus A BO3

 

H

 

a

 

 40 inch b.w Radio galaxy. Note green [OIII] jet top left
1c M 95 BV

 

H

 

a

 

40 inch msb Theta galaxy. Note the low surface brightness outer arms
2a NGC 1365 BV

 

H

 

a

 

40 inch msb Famous barred spiral. Note the dust lane leading into the core
2b NGC 2997 BV

 

H

 

a

 

40 inch msb Grand Spiral. Note the HII regions in the spiral arms
2c NGC 6744 BV

 

H

 

a

 

40 inch msb A different type of barred spiral
3a M 31 BV

 

H

 

a

 

Nikon msb Andromeda galaxy. Note the dust lanes and HII regions
3b Magellanic Clouds BV

 

H

 

a

 

Hasselb msb The closest galaxies to the Milky Way
3c SMC BV

 

H

 

a

 

Nikon msb The SMC and wing + globular clusters 47 Tuc and NGC 362
4a SMC zoom BO3

 

H

 

a

 

Nikon msb The gas-rich SMC. The HII regions dominate in this image
4b LMC BO3

 

H

 

a

 

Nikon msb HII regions and the old stellar population in the bar
4c LMC zoom BO3

 

H

 

a

 

Nikon msb 30 Doradus and shells of HII regions dominate this image
5a 30 Doradus BVR 40 inch sung Three beautiful views of 30 Doradus. Stars dominate here
5b 30 Doradus BV

 

H

 

a

 

40 inch sung In this image stars and the gas share the stage
5c 30 Doradus BO3

 

H

 

a

 

40 inch sung Here the gas dominates. It appears 3 dimensional
6a Crux and pointers BV

 

H

 

a

 

Hasselb msb The archetypal view of the southern skies
6b Scorpio BV

 

H

 

a

 

Hasselb msb The huge constellation of Scorpio extends from the plane
6c Sag-Oph BV

 

H

 

a

 

Hasselb msb View looking toward the centre of the Milky Way
7a Jewel Box BV

 

H

 

a

 

40 inch b.w A young cluster of massive stars near the Southern Cross
7b NGC 2004 164V

 

H

 

a

 

HST b.dc.k A similar cluster in the LMC with many times more stars
7c NGC 2004 zoom 164V

 

H

 

a

 

HST b.dc.k These are HST images. Note the blue main sequence stars
8a NGC 2100 zoom 164V

 

H

 

a

 

HST b.dc.k Be stars (pink), red supergiants (orange);
8b NGC 330 zoom 164V

 

H

 

a

 

HST b.dc.k A supergiant (white)
8c NGC 346 BO3

 

H

 

a

 

40 inch msb The largest cluster of young massive stars in the SMC
9a Eta Carina BO3

 

H

 

a

 

Nikon msb The beautiful 

 

h

 

 Car nebula. Note the lace work
9b Eta Carina BO3

 

H

 

a

 

40 inch msb A closer view of the nebula and young clusters
9c Eta Carina BV

 

H

 

a

 

40 inch sung Note the strange variable 

 

h

 

 Car
10a Trumpler 24 BV

 

H

 

a

 

40 inch sung A young cluster and HII region
10b Bochum 14 BV

 

H

 

a

 

40 inch sung An HII region surrounding a Wolf Rayet star
10c Bochum 10 BV

 

H

 

a

 

40 inch sung Another young cluster and HII region
11a Lagoon & Trifid BO3

 

H

 

a

 

Nikon msb The well known Lagoon and Trifid nebula
11b Trifid BO3

 

H

 

a

 

40 inch msb A blue reflection nebula, HII region and dust lanes
11c Lagoon zoom BO3

 

H

 

a

 

Nikon msb Colour change shows the ionisation gradient
12a Lagoon inner BO3

 

H

 

a

 

40 inch msb Yellow near the hottest stars. Red shows lower ionisation
12b Lagoon inner BV

 

H

 

a

 

40 inch sung Beautiful dust lanes and starkly etched globules
12a Lagoon inner zoom BO3

 

H

 

a

 

40 inch msb Colours rotated to produce moody image—‘a Turner’
13a Eagle Nebula BO3

 

H

 

a

 

40 inch b.w Star forming region HST image available
13b Eagle Nebula zoom BO3

 

H

 

a

 

40 inch b.w Rotated field
13c CG4 Nebula BVR 40 inch msb Interesting reflection nebula with dust clouds
14a NGC 3603 BV

 

H

 

a

 

40 inch sung Young cluster
14b NGC 6188 BO3

 

H

 

a

 

Nikon b.w Another interesting obscured nebulosity
14c Pismis 24 BV

 

H

 

a

 

40 inch sung Young cluster
15a IRAS 10.60.100

 

m

 

IRAS IRAS From Sutherland & Bally
15b Orion-Eridanus BO3

 

H

 

a

 

Hasselb suth Wide field view mosaic
15c Orion BO3

 

H

 

a

 

Hasselb msb Showing Barnard’s Loop around the Orion constellation
16a

 

l

 

 Orionis BO3

 

H

 

a

 

Nikon msb The ‘bubble’ surrounding the O star 

 

l

 

 Orionis
16b Orion BO3

 

H

 

a

 

Nikon msb The region between the Belt and Sword of Orion
16c Horsehead Nebula BO3

 

H

 

a

 

40 inch sung The famous dark cloud in Orion
17a Orion Nebula BO3

 

H

 

a

 

40 inch msb Different views of the great nebula of Orion
17b Orion Nebula BV

 

H

 

a

 

40 inch msb Different filters highlight small ionisation differences
18a Orion Nebula S2

 

H

 

a

 

N2 KPNO 1m b.s The seeing is much better in these next images
18b Orion Nebula S2

 

H

 

a

 

N2 NTT 3.5m b.s Note the detail in this excellent ground based image
18c Orion Nebula S2

 

H

 

a

 

N2 HST b.s Note the stellar tails all pointing away from the trapezium
19a NGC 2264 N BV

 

H

 

a

 

40 inch sung Part of young cluster in Monocerotis
19b NGC 2264 W BV

 

H

 

a

 

40 inch sung Note the beautiful reflection nebula and dust clouds
19c Rosette Nebula BO3

 

H

 

a

 

Nikon murph Strong ionisation produces these unusual colouring
20a Vela-Puppis BO3

 

H

 

a

 

Hasselb msb This wide field view shows the comet Hale–Bopp lower right
20b Vela BO3

 

H

 

a

 

Nikon msb Note the [OIII] and 

 

H

 

a

 

 filaments of the SN remnant
20c Vela zoom BO3

 

H

 

a

 

Nikon msb Note the details of the twisted [OIII] filaments
21a Crab Nebula BO3

 

H

 

a

 

40 inch b.w Note the green [OIII], red 

 

H

 

a

 

 and blue synchrotron light
21b Helix Nebula BO3

 

H

 

a

 

40 inch b.w Planetary nebula. The blue and green colours have been reversed
21c Comet Hale-Bopp V Nikon msb Note the two globular clusters. The colours represent intensities

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182 M. S. Bessell

 

The images of the external spiral galaxies show
clearly the spatial distribution of the star forming
regions, the giant HII regions (like red beads in a
necklace) and the dust lanes lying along the arms and
reaching right into the centre of the galaxies. The central
bulges made up of older stars are also very obvious.
When we look at the wide field images of the Milky
Way we can recognise similar HII regions and dust
lanes and we can then zoom in on these to reveal bright
blue stars and shimmering curtains of ionised hydrogen.
We can see the results of extensive stellar winds and the
remnants of exploding stars with their delicate twisted
shock fronts. By providing deep images of the inter-
stellar region we can see the complicated interaction
between hot stars and gas and marvel at the beauty of
these interactions.

The image scale (12 arcsec/pixel) with the Nikon
lens is good for most large scale structure, but is unable
to resolve the fine collimation of the Herbig–Haro jets
associated with pre-main sequence stars or the disks of
distant planetary nebulae, both of which are a couple of
arcsec across. These are seen extremely well on the
films of the new AAO Schmidt 

 

H

 

a

 

 survey.

 

2.2 Filters Used

 

Many of the images combine two narrow band filters,

 

H

 

a

 

 (red) and [OIII] (green) with a short exposure B
(blue). These bands are actually red (6563 Å), green
(5007 Å) and blue (

 

ª

 

4300 Å). The combination of HII
(13.6 eV) and [OIII] (35.1 eV) with their significantly
different ionisation potentials traces the ionisation gradi-
ents. It highlights the hottest stars and the most energetic
shocks. A few images will be shown that feature more
subtle ionisation differences using [SII], 

 

H

 

a

 

 and [NII],
all ‘red’ lines but shown as RGB in order of wavelength.
Two images will also be shown with out-of-order
colours that result in more striking images.

 

2.3 List of Images

 

T h e  i m a g e s  a r e  a v a i l a b l e  f o r  v i e w i n g  f r o m
www.mso.anu.edu.au/~bessell/images/. Thumbnails of
the images are displayed three per line for 21 lines.
Table 2 lists the images and identifies them by line and
position. It also gives the filters comprising the BGR of
the colour image, the camera used (see Table 1), the
observers, and a brief comment about the image or
series of images. Detailed descriptions of many of the
astronomical objects can be found with David Malin’s
images at www.aao.gov.au/images.html. The shorthand
O3, S2, N2 is given for [OIII], [NII] and [SII] respect-
ively. The code for the observers is msb: Bessell; b.w:

Buxton & Watson; sung: Hwankyung Sung; murph:
Murphy; b.dc.k: Bessell, Da Costa & Keller; suth:
Sutherland; and s.b: Sutherland & Bally.

 

3  Discussion

 

3.1 Are the Colours Real? 

 

The colours that are seen, are ‘real’ colours, in dis-
tinction to the ‘false’colour images that one often sees
these days. The blue, green and red colours are assigned
to those actual observed colours in most cases; in the
few cases where they are not they are at least assigned in
the order of increasing wavelength. However, because
the images utilise at least one narrow band filter centred
on an emission line from ionised hydrogen, we ‘see’ the
gas brighter than the star light by a factor that is the ratio
of the width of the narrow band filter to the width of the
broad band filter that represents the eye’s colour band.
That is, we increase the brightness of the hot interstellar
gas in comparison to the brightness of the stars. We
draw attention to the star forming regions by the effect
that the hot stars have on the gas. We do not alter the
relative colours of stars but we make them fainter in
comparison to the brightness of the gas. But we do alter
the colour of the gas depending on which emission line
we choose to highlight.

For example, in the three images of 30 Doradus (line
5) we see very graphically the effect of changing the
combination of filters used. Replacing the narrow green
filter with a broad green filter weakens the green light
from the gas compared to the starlight. Finally, replacing
the narrow red filter with a broad red filter weakens the
red light from the gas. The images shift from being star
dominated to gas dominated and the colour of the gas
changes while the colour of the stars stays the same.

In most of the images that are shown, by combining
narrow band green ([OIII]) and narrow band red (

 

H

 

a

 

)
light, we produce a yellow colour when the [OIII] line is
similar in strength to the 

 

H

 

a

 

 line; we see this for
example in the Lagoon and Trifid Nebulae (line 11)
where the ionisation is produced by radiation from
imbedded hot stars. Colour gradients between red and
yellow show the varying strength of these lines as the
radiation temperature of the gas changes.

However, in supernova remnants, like the Crab (line
21) and Vela (line 20) some of the ionisation results
from high energy shocks and in these cases the [OIII]
lines can be strong while 

 

H

 

a

 

 is very weak. In that case
the gas will appear green. We also see regions in SN
remnants where there is a series of ionisation fronts,
some green while others are yellow and red illustrating
the complex ionisation structure and interaction between
collisions and radiation. The use of [SII], 

 

H

 

a

 

 and [NII]
filters as seen in the series of Orion images from KPNO,
NTT and HST (line 18) shows more subtle ionisation
differences.

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Beauty and Astrophysics 183

 

3.2 What is Reality in an Image?

 

We distort ‘reality’ in many of our images in several
ways. CCDs are linear detectors that faithfully record
the relative brightnesses. However, our eyes are loga-
rithmic detectors so is it more ‘real’ to process the CCD
data to be logarithmic? We do this anyway in our data
processing as explained below. But we need to do other
distortions as well. The range of intensities that the eye
can see, or the monitor or hard copy can provide, is
l i m i t e d .  T h e r e  i s  a  g r e a t  a d v a n t a g e  i n  f u r t h e r
compressing the intensity scale so as to keep detail in
the bright areas of an image as well as in the fainter part.
Photographic plates and prints did this a little by their
non-linearity at the bright end but we can achieve it
much better digitally. For example, in the images of
galaxies (lines 1, 2 and 3) the nuclear regions and bulges
of these galaxies tend to be much, much brighter than
the outskirts. We have tried as hard as possible to retain
the information in those bright regions, whilst enhancing
the brightness and contrast in the outer spiral arm
regions. The nuclear ring in NGC 2997 is just visible
and the dust lanes with their imbedded star forming
regions are seen in these barred spirals to reach into the
central regions. Such details are not obvious in pre-
viously published images showing the outer regions.

Another way we distort reality, or rather we enhance
reality, is by emphasising the hot interstellar regions.
Normal broad-band optical images of galaxies and gal-
actic fields mainly show stars. Within a narrow dynamic
range these stars are coloured although the brighter ones
are invariably white because the images are saturated.
However, we know that in most galaxies, in particular in
spiral galaxies and disk galaxies like the Milky Way and
the Magellanic Clouds, the gas content is very high and
in fact often dominates the mass distribution in the disk.
Is it ‘real’ then to show a picture that mostly ignores a
major physical component? By enhancing the faint light
of ionised hydrogen as we have done in our images we
are bringing to attention an important mass component.
For example, in the wide field view of the Milky Way
(line 6) we begin to see that the galactic plane is bathed
in a sea of ionised gas and all the bright HII regions are
probably connected. In the SMC and LMC (lines 3 and
4) we see galaxies that are dominated by gas, which is
what they are. So these images bring a new perspective
and in many ways are more ‘real’ than previous
‘reality’. We still cannot see the neutral hydrogen but by
c o m b i n i n g  t h e  P a r k e s  m u l t i b e a m  s u r v e y
( w w w . a t n f . c s i r o . a u / r e s e a r c h / m u l t i b e a m /
multibeam.html) with these images, using another
colour, we should be able to encompass that as well. So
the difficulty and challenge is to present a beautiful
image whilst retaining and emphasising the important
physical information, the integrity of the object.

 

3.3 Image Processing

 

Finally, some specifics about the observing procedure
and image processing. We aim to take three images
through each filter with the telescope slightly offset
between each exposure in the set of three. The three
images through each filter are bias subtracted and flat
fielded, then superimposed and combined by median
filtering to produce a single grey image without cosmic
rays and bad columns. The combined images through
different filters are registered onto a reference image
using the programs GEOMAP and GEOTRAN within
IRAF. The 16 bit FITS files are then imported into
PHOTOSHOP using a program written by Ralph
Sutherland. This program, which generates 8 bit
PHOTOSHOP data, samples the image and suggests
upper and lower levels for the conversion. It also offers
linear or logarithmic scaling. Most of the images shown
here have had logarithmic scaling for all three colours
(channels). (Sometimes special effects can be produced
by combining logarithmic scaling in one or more colours
with linear scaling in another.) We often need to reim-
port images with different levels chosen, especially near
the sky to ensure that faint detail is not lost and to maxi-
mise the 256 levels in PHOTOSHOP by not wasting
them.

In PHOTOSHOP the images are copied into the R, G
or B channel of a new image and then manipulated by
adjusting levels, linearity and contrast. The manipu-
lation of the levels and curves is where the artistic
endeavour is required; however, one also needs to
address what story is being told in order to determine
how best to present the data. This is where the astron-
omy is needed together with the preconceived ideas of
what a coloured astronomical picture should look like.
Generally, we feel that the background sky should be
dark with no dominant colour; that the bulk of the stars
should be white or their colours soft shades of blue–
white, white, yellow or orange. Normally, blue stars
come out blue–white, most stars come out white and red
giants are generally deep yellow. The glowing inter-
stellar region then produces its own unexpected colours.
An image can of course be produced without any a
priori astronomical knowledge and this would be an
interesting exercise for an artist, but with one exception
I will not present any such images here.

The HST images of the Magellanic cloud clusters
(lines 7 and 8) show more subtle colours. Because the
blue colour in the PHOTOSHOP image it represents the
far ultraviolet colour of the star, the brightness of the
blue image of the hot stars is much brighter than normal
optical images. As a consequence, these stars come out
very blue. But if those hot stars have strong 

 

H

 

a

 

 emission
(the Be stars), they appear pink in the colour image; you
can see the high proportion of Be stars in these Cloud

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184 M. S. Bessell

 

clusters. In addition, the great drop in UV light (com-
pared to blue light) between an AF star and a KM star
makes the AF stars white in the colour images and the
KM stars orange.

We have made no attempt to produce real intensities
in our manipulations. The intensity mappings are,
however, monotonic although not linear. The manipu-
lations are done for their impact without undermining
the astrophysics. Where exact quantitative data are
required this is best done with the individual 

 

linear

 

monochromatic images in IRAF. We have generated
good magnitudes or good stellar free 

 

H

 

a

 

 images by
subtracting or dividing the individual images in IRAF.
Michael Murphy (UNSW) has also identified many
probable planetary nebulae and Be stars in the Magel-
lanic Clouds by doing photometry on 

 

H

 

a-[OIII] and
[OIII]-continuum images (see Murphy & Bessell 2000).

3.4 Future Work

Paul Price (Price 1999) is doing an honours project
completing the Ha survey and comparing it with
specific portions of the the Molonglo Radio Survey

(Green et al. 1999) and the MSX IR Galactic Plane
Survey (Cohen 1999) (http://gibbs1.plh.af.mil/). We are
also completing the wide-field Hasselblad survey of the
whole galactic plane visible from SSO and exploring
with a commercial organisation the possibility of
making an interactive CDROM using all the CCD
images we have processed. However, generating colour
images is very time consuming so it is unlikely that
much more can be done without additional resources.

Acknowledgments

I would like to thank David Malin for suggestions that
led to considerable improvements in the paper and for
inspiring the pursuit of beauty in astronomical colour
imaging.

References
Cohen, M. 1999, personal communication 
Green, A. J., Cram, L. E., Large, M. I., & Ye, T. 1999, ApJS, 122,

207 
Malin, D. F. 1992, QJRAS, 33, 321 
Murphy, M. E. & Bessell, M. S. 1999, MNRAS, 311, 741 
Price, P. A. 1999, personal communication

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