Optics and Telescopes

1. Optics and Telescopes Lecture 11

2. Why do we use telescopes? • Human eyes are lenses! • Using larger lenses…  collect more light  magnification

3. Larger lens can make brighter and magnified images.

4. Change in direction of travel

6. Refraction light travels at the fastest speed (e.g., speed of light) in vacuum.

8. Refraction of light by lens

9. Parallel light rays from distant objects • If a lens is located very far from the light source, only a few of the light rays are entering the lens. • These rays are essentially parallel.

10. Extended object Extended image • A lens creates an extended image of an extended object. • each point on an extended object passes through a lens and produces an image of that point. • collection of point images = image of an extended object.

11. Refractive Telescope Objective lens (light-gathering) + eyepiece (making image) Light-gathering power = area of the objective lens magnification = focal length of objective lens focal length of eyepiece lens

12. Refractive Telescope

13. Disadvantages of refractive telescope • Hard to make defect free lenses (especially larger one) • Glass is opaque to certain wavelengths (UV is 100% blocked!) • Very difficult to make larger lens • Large lenses are heavy  gravitational distortion

14. Angle of reflection requals angle of incidence i Law of Reflection Perpendicular to mirror surface incidence angle = reflection angle i r Reflected light ray Incident light ray Mirror

15. Reflection : Mirror acts as a lens

16. Newtonian Telescope

17. Different designs of Reflecting telescopes • Prime focus is good but inconvenient.

18. All Modern telescopes are Reflecting telescopes Gemini Telescope (8m) Primary mirror secondary mirror Cassegrain focus Large mirrors (nearly defect free : error is less than 8.5 nanometers) are much easier to make. Hollowed mirror base (honeycomb)

19. Secondary mirror making a hole in the image? Secondary mirror (or Cassegrain focus hole) does not make a hole in the focused image. However, support structure creates a diffraction spike from a point source.

20. Spherical Aberration Different parts of a spherically concave mirror reflect light to slightly different points  image bluring A solution parabolic mirror (harder to make) correcting lens

21. Angular resolution Because of diffraction of light (light waves spread out from a point), there is a limit in angular resolution Diffraction-limited angular resolution θ = angular resolution in arcseconds λ = wavelength of light, in meters D = diameter of telescope, in meters (example) Keck telescope, red light. …

22. Hawaii, Mauna Kea

23. Light Pollution

24. Effect of Earth Atmosphere • Light = wave • Perfect waveform got deformed due to turbulence in atmosphere… breeze turbulence in atmosphere

25. Adaptive Optics Using a nearby star (e.g., point source), reshape the mirror so that it can become a perfect (diffraction limited) point source. Active Optics wind shakes tip/tilt correction

26. Eliminate the effect of Atmosphere (Adaptive Optics)

27. Power of Adaptive Optics

28. Power of Adaptive Optics

29. Laser-guided Adaptive Optics

30. In summary… Important Concepts Important Terms Refraction/reflection Focal length light-gatheringpower light pollution Aberration (chromatic, spherical) • Refractive telescope • disadvantages • Reflective telescope • various designs • Angular resolution • Active Optics • Adaptive Optics • Chapter/sections covered in this lecture : sections 6-1 through 6-3