PHY100 ─ ASTRONOMICAL OBSERVATORIES
Why do we need more than one type of telescope in order to observe space?
The differing wavelengths of various energies create different instrumental needs resulting in dissimilar detecting devices.
Telescopes rely on the interaction between energy and matter. The atomic matter that forms the telescope has to interpret the energy emitted from astronomical objects. This energy is in the form of electromagnetic waves.
Most of the universe is invisible to us because we only see the visible light portion of the electromagnetic spectrum.
When most people think of telescopes they think of visible light, or optical telescopes.
Types of Optical Telescopes
The refracting telescope uses lenses to form an image. The light is bent, or refracted, causing parallel light waves to converge at a focal point, while those that are not parallel converge at a focal plane. Most of the universe is invisible to us because we only see the visible light portion of the electromagnetic spectrum.
The reflecting telescope uses an arrangement of mirrors to form an image. This design allows for very large diameter objects to be observed. Reflecting telescopes come in many design variations and use other optical elements to improve image quality and place the image in a mechanically advantageous position.
Catadioptric telescopes have both lenses and mirrors. The combination increases the effective focal length of the telescope and they can be made into a more compact piece of equipment. For this reason, it is used mostly for cameras and other light in weight technologies.
Refracting Telescope
The first telescopes that were built were refractors.
The main advantages of the refracting telescope are that it is not fragile and rarely needs to be realigned; the inner part of it is sealed from the outside and does not need to be cleaned frequently as a result.
Main disadvantage is that all refractors suffer from an effect called chromatic aberration (‘color deviation or distortion’) that produces a rainbow of colors around the image. Physical disadvantage is that the glass lenses often have imperfections, which can damage the image.
Reflecting Telescopes
Reflecting telescopes fixed all of the problems of refracting telescopes by using mirrors.
There are two mirrors, one curved that is at the top of the telescope and a smaller one that sends light out of the side of the telescope tube so the image can be viewed without blocking the incoming light. This mirror scatters the light, which degrades the image to a certain degree.
The disadvantages are relatively minor, most notably that the optics of this telescope can fall out of alignment quite easily, and the reflector’s tube is open at one end, unlike the refractor, so it needs frequent cleaning.
Catadioptric Telescopes
The main advantages of Catadioptic telescopes are that they employ spherical surfaces that are easier to manufacture. By combining a moving primary mirror with a cassegrain configuration allow for large movements in the focal plane to accommodate cameras and CCDs.
A disadvantage to this design is that the secondary mirror blocks a portion of the light entering the tube.
Optical Telescopes
The difference between optical telescopes is the way in which they gather light through their “objective”, the part of the telescope that gathers light.
Radio Telescopes
Radio telescopes are directional radio antennas.
Dishes composed of conductive wire mesh whose openings are smaller than the wavelength being observed.
Most radio telescopes need to be large in order to accommodate radio's longer wavelengths and lower energies.
Radio telescopes dishes are made of either metal or wire mesh; either design still serves the same purpose. Radio waves are large, and as a result radio telescopes tend to be quite large too.
X-ray and Gamma-ray Telescopes
This type of telescope utilizes “glancing mirrors” and heavy metals which are able to reflect the rays a few degrees.
Gamma-ray telescopes use coded aperture masks. The pattern of the shadow that is created by the mask can be reconstructed to form an image.
These telescopes are usually located on satellites orbiting Earth since the Earth’s atmosphere is opaque to this part of the electromagnetic spectrum.
Purpose of Satellites in Space
Collect data, photos and other info from Earth and the many things that surround it.
Study outer space and earth’s atmosphere, track weather patterns and acquire intelligence.
Ground Based Observatories
For optical telescopes, most ground-based observatories are located far from major centers of population to avoid the effects of light pollution.
The ideal locations for modern observatories are sites that have dark skies, a large percentage of clear nights per year, and dry air.
High elevations are a very important condition. At high elevations, the Earth’s atmosphere is thinner, which minimizes the effect of atmospheric turbulence and allows better astronomical “seeing.”
Radio Observatories
Radio observatories are located far from major centers of population to avoid electromagnetic interference (EMI) from radio, television, radar, and other EMI emitting devices.
Radio observatories will be placed in valleys to further shield them from EMI.
Some of the major radio observatories are at Socorro, in New Mexico, Jodrell Bank in the UK, Arecibo, Puerto Rico and Parkes in New South Wales, Australia.
Satellites Past, Present and Future
PAST
Sputnik was the first satellite to be launched into orbit around Earth.
Launched in 1957 by the Soviet Union
It was a small silver ball, less than 1 foot across with antennas that sent out a “beep-beep-beep,” signaling it was the first satellite to make it successfully into space.
PRESENT
The Hubble Space Telescope (HST), launched in 1990 and still in space, is a large, space based observatory.
Has revolutionized astronomy by providing unprecedented deep and clear views of the universe, ranging from our own solar system to ancient, faraway galaxies formed 13.7 years ago after the Big Bang. It has also been instrumental in detecting black holes.
Hubble orbits earth every 96 minutes, 575 km above Earth’s surface.
FUTURE
The Herschel Space Observatory
Space-based telescope that will study the Universe by the light of the far-infrared and sub millimeter portions of the spectrum
It is expected to reveal new information about the earliest, most distant stars and galaxies, as well as those closer to home in space and time. It will also take a unique look at our own solar system. It is scheduled to be launched in early 2009.
The Gravity Recovery and Interior Laboratory, or Grail will fly twin spacecraft in tandem orbits around the moon for three months to measure its gravity field in unprecedented detail. It will be launched in 2011.
Kepler is a space borne telescope designed to survey distant stars to determine the prevalence of Earthlike planets. Scheduled to launch in 2009.
Juno will conduct an in-depth study of the giant gas planet Jupiter
A spacecraft will enter polar orbit around the planet to investigate the existence of an ice-rock core; determine the amount of global water and ammonia present in the atmosphere. It will be launched in august 2011.
The Nuclear Spectroscopic Telescope Array, or NuSTAR is a pathfinder mission that will study the sky through high energy X-rays. It will be launched in 2011
The “Pico” satellite is currently being designed and built at the University of Florida with the intent of creating a satellite that is small, inexpensive and easily mass-produced.
The Next Generation Space Telescope (NGST) is NASA’s next step in satellites. Set to be launched in 2013, the James Webb Space telescope is a large, infrared-optimized space telescope that is expected to find the first galaxies formed in the early universe.
Possible Exam Questions
- Why do we have different types of telescopes?
- What are the types of optical telescopes? Briefly explain how they work.
- Why are most observatories located at high elevations?