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Chapter 3 Telescopes The tools of Astronomy Very Large Array (VLA), National Radio Astronomy Observatory (NRAO), Socorro, New Mexico (Radio telescope: 27 antennas , Y configuration, 25 meters diameter each) Reading assignment: Chapter 3 © 2010 Pearson Education, Inc. Let’s start with something basics How does your eye form an image? Light is refracted (bend) by the lens (converging lens) and forms an image in the retina. The pupil control the amount of light accepted by the lens. © 2010 Pearson Education, Inc. What is refraction? surface Incident ray Refracted ray Reflected ray © 2010 Pearson Education, Inc. • Refraction is the bending of light when it passes from one substance into another (substances with different refraction index). • Example: Light passing from air to glass. • For the ray to bend, it must hit the surface at an angle less than 90 degrees from the surface. • The lenses in your eyes uses refraction to focus light and produce an image. Refraction in a prism A simple model of a converging lens Refraction of light by a prism Keep in mind that light of different wavelengths (colors) are refracted at different angles © 2010 Pearson Education, Inc. An approximation of a converging (convex) lens by prisms and sections of prisms Focusing light with a converging lens • Refraction can cause parallel light rays to converge to a focus and form an image. © 2010 Pearson Education, Inc. Image Formation • The focal plane is where light from different directions comes into focus and form an image. • The image behind a single (convex) lens is actually upside-down! © 2010 Pearson Education, Inc. Focusing light, recording an image Digital cameras detect light and record images with an electronic device called ChargeCoupled Device (CCD). • A camera focuses light like an eye and captures the image with a detector. • The CCD detectors in digital cameras are similar to those used in modern telescopes. © 2010 Pearson Education, Inc. What are the two basic designs of telescopes? • Reflecting telescope: focuses light with mirrors. The curved (concave) mirror reflect light and forms an image • Refracting telescope: focuses light with lenses. The lens “bends” light by refraction and forms an image • The main (or primary) mirror or lens is also known as the objective of a telescope © 2010 Pearson Education, Inc. eyepiece Reflecting Telescopes opening Secondary mirror • Primary Mirror (Concave) A reflecting telescope has a primary mirror and secondary mirror. The secondary can be flat or curved. • The primary mirror is curved (concave) and can be supported from the back in several places so it can maintain the curvature. • The primary mirror can be spherical or parabolic. Some spherical mirror requires a corrector plate at the opening • Reflecting telescopes can have much greater diameters. •© 2010Modern telescopes are reflectors. Pearson Education, Inc. Mirrors in Reflecting Telescopes Twin Keck telescopes on Mauna Kea in Hawaii © 2010 Pearson Education, Inc. Segmented 10-meter mirror of a Keck telescope. The main mirror is composed of 36 hexagonal segments Refracting Telescopes • A refracting telescope uses a lens instead of a mirror Some disadvantages of refracting telescopes: • The lens separate light into different colors. It focuses light at different distances along the optical axis. This is known as chromatic aberration. • To correct for chromatic aberration it is necessary to use an objective composed two or three elements • Refracting telescopes need to be very long (large focal length), with large, heavy lenses. • Heavy lenses can be supported only from the edges . The weight flex the lens and distort the shape causing aberrations in the images. • Light passing through a lens can get absorbed. Absorption can be severe at UV and IR wavelengths • To manufacture a lens it is necessary to machine and polish at least two surfaces or more if the objective has 2 or 3 elements. More expensive. The largest refracting telescope is the 40 inch diameter Alvan Clark telescope at Yerkes observatory The UF Campus Observatory owns an 8” refracting telescope. It was manufactured about 90 years ago. The lens was built by the Alvan Clark company, the same company that build the 40” at Yerkes. © 2010 Pearson Education, Inc. The telescope size or diameter What are the two most important properties of a telescope? 1. 2. 3. Light-collecting area: Telescopes with a larger mirrors or lenses (larger diameter) have a large collecting area. It will act as a “light bucket”. A large collecting area can gather a greater amount of light in a shorter time. A telescope with a large collecting area can observe fainter object Angular resolution: Telescopes that have larger mirrors or lenses are capable of taking images with greater detail. Both the light-collecting area and the angular resolution are increased by a larger lens or mirror. © 2010 Pearson Education, Inc. Light-Collecting Area ( Or Light-Gathering Power) • A telescope’s diameter tells us its light-collecting area: A = π (D/2)² A= Area D= Diameter The diameter of the telescope D (the diameter of the lens or mirror) is normally referred as the aperture of the telescope • The light-gathering power is proportional to the area of the objective • The light-gathering power is proportional to the diameter square • • The largest telescopes currently in use have diameters in the range of 8-10 meters. The largest single mirror telescope is the 10.4 meter diameter telescope in the Canary Island (Spain). The mirror is composed of 36 small hexagonal mirror. UF is a partner in the GTC (Gran Telescopio de Canarias) © 2010 Pearson Education, Inc. Question How does the collecting area of a 10-meter telescope compare with that of a 2-meter telescope? a) It’s 5 times greater. b) It’s 10 times greater. c) It’s 25 times greater. © 2010 Pearson Education, Inc. Question How does the collecting area of a 10-meter telescope compare with that of a 2-meter telescope? A = π (D/2)² a) It’s 5 times greater. b) It’s 10 times greater. c) It’s 25 times greater. Ratio of the diameters is 10/2 = 5 The ratio of the collecting area is 5² =25 © 2010 Pearson Education, Inc. Angular size and angular separation Read “More precisely 0-1, Angular Measure” (See page 12) Angular size of an object depends on two parameters • The physical size of the object • The distance to the object Angular size is measured in units of angle (degrees, arcmin and arcsec) Angular size = Physical Size Distance Approximate formula (valid for small angles): Angular Size = Physical size 360 degrees 2 π x distance Angular size = Physical size x 360 degrees/ (2 π x distance) Example: Physical size of the Moon Angular size = 0.5 degrees Distance = 380,000 km © 2010 Pearson Education, Inc. The resolving power of a telescope Angular Resolution • The resolving power is the minimum angular separation that the telescope can distinguish © 2010 Pearson Education, Inc. Angular Resolution • The ultimate limit to resolution comes from interference of light waves within a telescope. • Larger telescopes (larger diameter of lens or mirror) are capable of greater resolution. • The angular resolution is proportional to the wavelength and inversely proportional to the diameter D of the lens or mirror • Angular resolution = 0.25 (/D) • in micrometer (10^-6 m), D in meters • High resolution means that the telescope can distinguish details that are separated by small angular distance © 2010 Pearson Education, Inc. The effect of the telescope aperture (diameter of lens or mirror) in the resolution Example: Resolving a binary star Small aperture Medium aperture Large aperture © 2010 Pearson Education, Inc. Angular Resolution • Airy disc Diffraction rings • • • • • • • • Close-up of the image of a star taken by the Hubble Space Telescope © 2010 Pearson Education, Inc. The image of a star produced by a telescope is not a point source The central spot and the rings in this image of a star are produced by the phenomenon called diffraction of light (Light behave like a wave) Light passing through a circular aperture produce this diffraction pattern. The opening of a telescope is circular The central bright spot, called the Airy disc increases in diameter when the diameter of a telescope decreases. Larger diameter telescopes produce a small Airy disc and have better resolving power There is a limit in the angular resolution that a telescope can achieve. It depends on its diameter. This limit in the resolution is known as the diffraction limit. Angular resolution = 0.25 (/D) The angular resolution of a telescope is given in arc seconds Airy discs and the resolution of a telescope Airy disc produced by a green laser beam on a circular aperture. In a telescope, the diameter of the Airy disc produced by a star increases if the diameter of the aperture decreases Intensity distribution of Airy discs of two sources (stars) Airy discs patterns, point spread function and resolution. An example: stars in a stellar cluster © 2010 Pearson Education, Inc. An example of images of the Andromeda Galaxy with different resolutions (Using telescopes of different apertures) Aperture of a telescope: the diameter of the mirror or lens. 10 arc minutes (10’) (very small aperture) 1 arc minute (1’) 5 arc seconds (5”) Resolution of the human eye: ~0.5 arc minutes (0.5’) © 2010 Pearson Education, Inc. 1 arc second (1”) (Large aperture) The focal length of a converging lens f is the focal length f is the distance from the lens to the focal point, where the image forms. Valid for parallel rays (distant objects) © 2010 Pearson Education, Inc. The magnification of a telescope • • • • • • • The magnification of a telescope is how many times bigger an object looks through a telescope compared to how it looks with the naked eye. The focal length of a telescope (Ft) is the equivalent distance from the lens or mirror to the plane where the image forms. The focal length of an eyepiece (Fe) is the distance between the lens of the eyepiece and the point where the image forms The magnification of a telescope is the ratio M = Ft/Fe The magnification is a number, it has no units The magnification of a telescope can be changed by changing the eyepiece. Eyepieces of different focal length (Fe) provide different magnifications Magnifications around 250-350 are a practical limit for a telescope. Under good sky conditions and with good optics, it can be as high as 600 Increasing the magnification of a telescope does not increase its resolution © 2010 Pearson Education, Inc. What do astronomers do with telescopes? • Imaging: taking images of object or large area of the sky • Spectroscopy: breaking light into spectra and analyze the spectral lines • Photometry: measure the intensity of light and variation in the intensity or brightness of the light from an object. Obtaining the light curve of an object. The brightness of an object can be expressed in an scale called magnitude. • Astrometry: Measure the position (distance and angle) of an object in the sky or the position respect to another object • Timing: measuring how the light output from an object varies with time and keeping a precise timing of those variations © 2010 Pearson Education, Inc. A CCD (Charge Coupled Device) used in astronomy • Electronic cameras used in Astronomy use a CCD’s •The small elements in a CCD sensitive to light are called pixels. •A CCD has millions of pixels •When light strike a pixel it will develop an electric charge proportional to the intensity of light. •The charge in each pixel is read by the electronics controlled by a computer and stored as an array of numbers © 2010 Pearson Education, Inc. An image of a CCD How a CCD store the information and produces an image? • The charge in each pixel is read and stored as an array of numbers in a computer • To display the image, the array of number is send to a computer monitor or screen. • The value of each number is converted into intensity and displayed in the screen. •The intensity is proportional to the value of the number. © 2010 Pearson Education, Inc. Imaging • • • • • • © 2010 Pearson Education, Inc. At the present the astronomical detectors for taking images in astronomy are CCD (Charge Couple Device) No more use of photographic plates in professional astronomical observatories. Astronomical detectors generally record only one color of light at a time. They generate a black/white image. Several images taken with color filters must be combined to make full-color pictures. Normally the color filters are red, green and blue (RGB) The software combining the images assign the colors to each of them and produce a color image. Imaging • Some astronomical detectors can record forms of light our eyes can’t see. • Example: X-rays, Gamma rays. IR, UV • Color is sometimes used to represent different energies of non-visible light. • Some of the “color” images may not represent actual colors. Different wavelength are assigned different colors. Images at some wavelengths can be at radio, UV, X-rays or Gamma-rays © 2010 Pearson Education, Inc. Example of “color” images of Mars taken by the MAVEN spacecraft after its arrival in September, 2014. The images were taken in UV light reflected from Hydrogen and Oxygen © 2010 Pearson Education, Inc. Spectroscopy • A spectrograph separates the different wavelengths of light before they hit the detector. • A diffraction grating is used to separate the colors or wavelengths. • A diffraction grating has a few thousand lines per mm • The diffraction grating shown here in the spectrograph is a reflection diffraction grating © 2010 Pearson Education, Inc. Spectroscopy • Graphing the relative brightness of light at each wavelength shows the details in a spectrum. © 2010 Pearson Education, Inc. Photometry and timing The example to the right is of the light curve of a star with variable brightness • • • • • A light curve represents a series of brightness measurements made over a period of time. The technique use a reference star that show no change in brightness. The brightness of the variable star is calibrated against the reference star This technique can detect variable stars and variability in astronomical objects An important application: Measuring the variation of brightness from a star allows the detection the transit of an exoplanet in front of a star Exoplanet: Planet in orbit around other stars © 2010 Pearson Education, Inc. A summary • What are the two most important properties of a telescope? – Collecting area determines how much light a telescope can gather. – Angular resolution is the minimum angular separation a telescope can distinguish. – Both properties, collecting area and angular resolution improve when the diameter of the lens or primary mirror increases • What are the two basic designs of telescopes? – Refracting telescopes focus light with lenses. – Reflecting telescopes focus light with mirrors. – The vast majority of professional telescopes are reflectors. © 2010 Pearson Education, Inc. Summary • What do astronomers do with telescopes? – Imaging – Spectroscopy – Photometry – Astrometry – Timing © 2010 Pearson Education, Inc. Atmospheric Blurring How does Earth’s atmosphere affect groundbased observations? • The best ground-based sites for astronomical observatories are: – calm atmosphere (not too windy, atmosphere less turbulent) – High altitude (less atmosphere to see through, less absorption) – dark sky (far from city lights, low light pollution) – dry (few cloudy nights) © 2010 Pearson Education, Inc. Light Pollution • Scattering of human-made light in the atmosphere is a growing problem for astronomy. © 2010 Pearson Education, Inc. Effect of atmospheric blurring in the formation of an image The light coming from a star comes from a point source, the rays will add (constructive interference) or subtract (destructive interference) , causing the image to “twinkle” The light coming from a planet comes from many points in the disk. Planets normally do not twinkle © 2010 Pearson Education, Inc. • Rays of light are distorted by the turbulence in the terrestrial atmosphere. •The rays are deflected and travel using slightly different path. •The rays interfere, adding or subtracting which causes the image to “twinkle” • And individual image forms, each lasting for a fraction of a second but its position changes continuously • In a long exposure, the individual images form a disk. • If the atmosphere is turbulent, the diameter of the disk is large ( A condition called bad seeing) Twinkling and Turbulence Bright star field viewed with ground-based telescope Same star field viewed with Hubble Space Telescope Turbulent air flow in Earth’s atmosphere and distorts our view, causing stars to appear to twinkle. In a long exposure, the image of a star looks bigger due to the random motion of the instantaneous location of the image around a central location © 2010 Pearson Education, Inc. An example of “bad” seeing The turbulence in terrestrial atmosphere distort the image of these lunar craters. The large crater is Clavius © 2010 Pearson Education, Inc. Adaptive Optics A technique to reduce the effect of the atmosphere Without adaptive optics With adaptive optics A technique to reduce the effect of the atmosphere is called Adaptive optics. It consist in rapidly changing the shape of a telescope’s mirror to compensate for some of the effects of turbulence. © 2010 Pearson Education, Inc. Location of observatories: in a calm, high, dark and dry place Summit of Mauna Kea, Hawaii Altitude 14,000 feet (4,000 m) Some of the telescopes: Gemini North: 8.1 m, Keck twins: 10 m, Subaru: 8.3 m © 2010 Pearson Education, Inc. • The best observing sites are atop remote mountains. • Some of the best places are: Hawaii (Mauna Kea) North of Chile (Cerro Tololo, Cerro Pachon, Cerro Paranal) The Canary Island South-West US (Texas, New Mexico) Why do we put telescopes into space? Telescopes in space are not affected by the blurring effect, absorption of light and light pollution of the terrestrial atmosphere The Hubble Space Telescope • In orbit since 1990. Still in operations • 2.4 m diameter mirror (solid) • It can observe in near UV, visual and IR • Cost about 2.5 billions US $ • Next space telescope: James Webb Telescope • 6.5 m diameter, 18 hexagonal mirrors . Projected launch date : 2018 •It will have instruments for mainly the IR •Estimated cost: 8 billion US$ (maximum authorized by Congress) © 2010 Pearson Education, Inc. Hubble Ultra-Deep field Image of a field taken by Hubble Telescope in the constellation Fornax. The size of the field is about 1/10 the size of the full Moon A good example of the high resolution that can be achieved in space. Very faint galaxies can be imaged (no light pollution!) © 2010 Pearson Education, Inc. The TMT (Thirty Meter Telescope) telescope The primary mirror is composed of 492 segments It will be located at the Mauna Kea observatory (Hawaii) Projected date for beginning of operations is 2022. Cost: around 1.2 billion US dollars The size of the mirrors in the 30 m TMT, the 10 m Keck and the 5 m (200 inch) Hale (Mount Palomar) telescopes © 2010 Pearson Education, Inc. The ELT 39 meter European telescope in Cerro Armazones (Chile) © 2010 Pearson Education, Inc. Transmission in Atmosphere • Only the longer wavelengths of radio and the visible light pass easily through Earth’s atmosphere. • We need telescopes high in the atmosphere to observe in the IR part of the spectrum • To extend the observations into the UV, X-Ray and Gamma ray it is necessary to have telescopes in space © 2010 Pearson Education, Inc. Summary • How does Earth’s atmosphere affect ground-based observations? – Telescope sites are chosen to minimize the problems of light pollution, atmospheric turbulence, and bad weather. • Why do we put telescopes into space? – Some wavelength of light other than radio and visible do not pass through Earth’s atmosphere. – Much sharper images are possible because there is no atmospheric turbulence. – No light pollution from light scattered in the terrestrial atmosphere allows long exposure for recording very faint objects © 2010 Pearson Education, Inc. 6.4 Telescopes and Technology Let’s explore the following topics: • How can we observe invisible light (radio, IR, UV, X-rays and Gamma rays)? • How can multiple telescopes work together and what is the advantage of multiple telescopes working together? © 2010 Pearson Education, Inc. How can we observe invisible light? • A standard satellite dish is essentially a telescope for observing radio waves (It is called a radio telescope) © 2010 Pearson Education, Inc. Radio Telescopes • A radio telescope is like a giant mirror that reflects radio waves to a focus. • The image shows the 300 meter (1000 ft) diameter radio telescope in Arecibo (Puerto Rico) © 2010 Pearson Education, Inc. ALMA (Atacama Large Millimeter Array) • The ALMA radio telescope (Interferometer) is located in the Atacama desert (North of Chile) at an altitude of 5,000 meter (16.500 feet) . • It consist of 66 antennas, each 7 to 12 m diameters used as an interferometer to achieve a resolution about 5 times better than the Hubble telescope . •It work in the wavelength range from 0.3 to 9.6 mm •Cost: about 1.5 billion US dollars. © 2010 Pearson Education, Inc. ALMA A view of some of the antennas. In the background, the Magellanic Clouds, the Southern Cross and the Milky Way © 2010 Pearson Education, Inc. Infrared and Ultraviolet Telescopes SOFIA (IR) • • • Spitzer (IR) Infrared and ultraviolet light telescopes operate like visible-light telescopes but need to be high or above the atmosphere to “see” at these wavelengths. A UF Ph.D. graduate, Dr. Jim De Buizer is a scientist with SOFIA observatory. UV telescopes were carried in Space Shuttle Missions ASTRO 1 and ASTRO 2. Crew member in charge of the telescope on those missions was the astronaut and a UF Ph.D. graduate Dr. Ron Parise (deceased) © 2010 Pearson Education, Inc. X-Ray Telescopes • X-ray telescopes also need to be above the atmosphere. • X-rays are absorved by the terrestrial atmosphere Chandra X-Ray Observatory (launched in 1999) Named after the Indian-American astrophysicist Subramanyan Chandrasekhar (Nobel prize in physics) © 2010 Pearson Education, Inc. X-Ray Telescopes • Focusing of X-rays requires special mirrors. • Mirrors are arranged to focus X-ray photons through grazing bounces off the surface. © 2010 Pearson Education, Inc. Gamma-Ray Telescopes Fermi Gamma-Ray Observatory Launched in 2008 Named after Enrico Fermi © 2010 Pearson Education, Inc. • Gamma-ray telescopes also need to be in space. Gamma radiation doesn’t reach the ground. • Focusing gamma rays is extremely difficult. • For the Fermi telescope, the detectors are scintillation detector, an array of 12 crystals (Sodium Iodide) • The detectors are arranged in a 3-D matrix. That allow to determine the direction from where the gamma ray came from How can multiple telescopes work together? © 2010 Pearson Education, Inc. Interferometry • Interferometry is a technique that consist in linking two or more telescopes and combining the signal from them. What is the advantage? • The resolution obtained is equivalent to the resolution of a single large radio telescope of an equivalent diameter equal to the separation. A couple of examples: The ALMA radio telescope The VLA array in Socorro, New Mexico © 2010 Pearson Education, Inc. Interferometry Very Large Array (VLA) in Socorro, New Mexico Part of the National Radio Astronomical Observatory © 2010 Pearson Education, Inc. • Easiest to do with radio telescopes because of the longer wavelengths • Now possible with infrared and visible-light telescopes • Interferometry consist of combining the light (or signals) from two or more telescopes. • In long wavelength radio telescopes the signals are transmitted by coaxial cables or waveguides. • In optical, IR and short wavelength radio telescopes, the signals is transmitted by optic fiber Interferometry in visible and IR light wavelengths An example: The ESO (European Southern Observatory) VLT telescopes in Cerro Paranal (Chile) The VLT (Very Large Telescopes) are 4 telescopes that can combine the light to make up a large telescope with an equivalent diameter equal to the separation between them. The primary mirror of each telescope has a diameter of 8.2 meters © 2010 Pearson Education, Inc. Future of Astronomy in Space? • The Moon would be an ideal observing site. • The lack of atmosphere make it ideal for observing at almost all wavelengths (radio, UV,IR, X-Ray and Gamma-Rays) • Radio telescopes located in the far side of the Moon will be shielded from radio interference © 2010 Pearson Education, Inc. Summary • How can we observe invisible light? – Telescopes for invisible light are usually modified versions of reflecting telescopes. – Telescopes used for observing invisible light such as X-ray, Gamma rays, UV and IR must be in space. • How can multiple telescopes work together? – Linking multiple telescopes using the interferometer technique enables them to produce the angular resolution of a much larger telescope. © 2010 Pearson Education, Inc.