1 / 46

Light, Astronomical Observations, and the Sun

Light, Astronomical Observations, and the Sun. Terms. Spectrum A range of something, e.g. colors Spectra Plural of spectrum Incandescent Hot enough to glow (emit visible light radiation). Terms. Wavelength ( λ ) Length of one wave from peak to peak Shorter wavelength = more energy

spyridon-galen
Télécharger la présentation

Light, Astronomical Observations, and the Sun

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Light, Astronomical Observations, and the Sun

  2. Terms • Spectrum • A range of something, e.g. colors • Spectra • Plural of spectrum • Incandescent • Hot enough to glow (emit visible light radiation)

  3. Terms • Wavelength (λ) • Length of one wave from peak to peak • Shorter wavelength = more energy • For visible light • Shorter wavelength = BLUE • Longer wavelength = RED

  4. Terms • Light-year • Distance traveled by light in one year • 5,900,000,000,000 miles • Measure of distance, not time

  5. Light, Astronomical Observations, & the Sun PSCI 131: Light, Astronomical Observations, & The Sun • Signals From Space • Spectroscopy • The Doppler Effect • Optical Telescopes • Radio and Orbiting Telescopes • The Structure of the Sun

  6. Signals from Space PSCI 131: Light, Astronomical Observations, & The Sun • The electromagnetic (EM) spectrum • Energy waves (radiation) emitted by matter

  7. The EM Spectrum PSCI 131: Light, Astr. Observations, & The Sun – Signals from Space

  8. EM Radiation from Celestial Objects PSCI 131: Light, Astr. Observations, & The Sun – Signals from Space • EM energy is emitted from many objects • Stars • Black holes • Supernovae (exploding stars) • Etc. • Not the same as reflected energy • Moons, planets, etc. reflect energy from stars

  9. EM Radiation from Celestial Objects PSCI 131: Light, Astr. Observations, & The Sun – Signals from Space • Emitted radiation can be collected and used to study the object • Telescopes: optical, radio, space-based • Spectroscopy

  10. Spectroscopy PSCI 131: Light, Astr. Observations, & The Sun

  11. Spectroscopy PSCI 131: Light, Astronomical Observations, & The Sun • Using radiation from an object to learn about that object • Most astronomical observations can only use radiation • Most objects too far away to visit

  12. Visible Light Spectra PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy • Visible light can be split into its component wavelengths (colors) • Creates continuous, bright-line, and dark-line spectra • Spectra can give key information about the object the light came from

  13. Visible Light Spectra PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy (Low-temp) (Incandescent) CONTINUOUS BRIGHT-LINE DARK-LINE

  14. Visible Light Spectra PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy • Visible light can be split into its component wavelengths (colors) • Creates continuous, bright-line, and dark-line spectra • Spectra can give key information about the object the light came from

  15. Continuous Spectrum PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy • Shows surface temperature of object • Shows total energy emitted by object

  16. Continuous Spectrum Shows Surface Temp PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy COOLER HOTTER

  17. Continuous Spectrum Shows Total Energy PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy • Proportional to fourth power of object’s surface temperature • Example: if Star B is twice as hot as Star A… • …Star B emits 2 x 2 x 2 x 2 = 16 times more energy that Star A

  18. Dark-Line Spectrum PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy • Light from star’s interior passes through gas composing star’s exterior Interior Exterior gases

  19. Dark-Line Spectrum PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy • Shows what elements are present in object • Each element absorbs a unique pattern of visible light wavelengths From: mail.colonial.net

  20. Dark-Line Spectrum PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy • Shows what elements are present in object • Each element absorbs a unique pattern of visible light wavelengths From: mail.colonial.net

  21. Bright-Line Spectrum PSCI 131: Light, Astronomical Observations, & The Sun - Spectroscopy • Shows what elements are present in object • Each element emits a unique wavelength pattern when heated From: intro.chem.okstate.edu

  22. The Doppler Effect PSCI 131: Light, Astr. Observations, & The Sun Sheldon’s Doppler Effect costume

  23. The Doppler Effect PSCI 131: Light, Astronomical Observations, & The Sun – Doppler Effect • Apparent shift in wavelength relative to a stationary observer The Doppler Effect with sound waves. Longer apparent wavelength = lower frequency.

  24. Red and Blue Shift PSCI 131: Light, Astronomical Observations, & The Sun – Doppler Effect • Light waves undergo Doppler Effect

  25. Red/Blue Shifts Change Dark-Line Spectra PSCI 131: Light, Astronomical Observations, & The Sun – Doppler Effect • Star moving away from Earth = RED shift • Star approaching Earth = BLUE shift

  26. Optical Telescopes PSCI 131: Light, Astr. Observations, & The Sun

  27. Optical Telescopes PSCI 131: Light, Astr. Observations, & The Sun – Optical Telescopes • Gather visible light radiation • Concentrate it at a focal point, creating magnified image • Two types • Refracting • Reflecting

  28. Optical Telescopes: Refracting PSCI 131: Light, Astr. Observations, & The Sun – Optical Telescopes From: www.odec.ca

  29. Optical Telescopes: Refracting PSCI 131: Light, Astr. Observations, & The Sun – Optical Telescopes • Advantages • Inexpensive • Lens doesn’t have to be perfect to make a decent image • Drawbacks • Chromatic aberration reduces image quality, limits maximum telescope size • Chromatic aberration: “halo” of color around image caused by refracted light

  30. Optical Telescopes: Reflecting PSCI 131: Light, Astr. Observations, & The Sun – Optical Telescopes From: odec.ca

  31. Optical Telescopes: Reflecting PSCI 131: Light, Astr. Observations, & The Sun – Optical Telescopes • Advantages • No chromatic aberration • Can be very large, so higher magnification • Drawbacks • More expensive • Tiny flaws in mirror can greatly reduce image quality From: www.odec.ca

  32. Radio & Orbiting Telescopes PSCI 131: Light, Astr. Observations, & The Sun

  33. Radio Telescopes PSCI 131: Light, Astr. Observations, & The Sun – Radio & Space Telescopes • Gather radio waves from space • These signals are extremely faint • Collecting dish must be very large

  34. Radio Telescopes PSCI 131: Light, Astr. Observations, & The Sun – Radio & Space Telescopes From: amazing-space.stsci.edu

  35. Radio Telescope at Arecibo, Puerto Rico PSCI 131: Light, Astr. Observations, & The Sun – Radio & Space Telescopes World’s largest & most sensitive R.T. Diameter: 1000 ft Depth: 167 ft Weight of receiver: 900 tons

  36. Orbiting Telescopes PSCI 131: Light, Astr. Observations, & The Sun – Radio & Space Telescopes • Optical, radio, gamma-ray, X-ray, infrared • No atmospheric or human “noise”

  37. The Hubble Space Telescope PSCI 131: Light, Astr. Observations, & The Sun – Radio & Space Telescopes Type: Reflecting Years in operation: 24 Orbit height: 347 miles Orbital speed: 25,000 ft/sec Length: 43 ft Mirror diameter: 7.9 ft Farthest object observed: 13 billion light years away (76,700,000,000,000,000,000,000 miles) From: nasa.gov

  38. Structure of the Sun PSCI 131: Light, Astr. Observations, & The Sun

  39. The Sun’s Composition PSCI 131: Light, Astr. Observations, & The Sun – The Sun • Form: gaseous • Density: slightly greater than water • Hydrogen: 90% • Helium: almost 10% • Other trace elements: less than 1%

  40. The Sun’s Emissions PSCI 131: Light, Astr. Observations, & The Sun – The Sun • The sun emits two things into space: • Radiation, including visible light • Solar wind, streams of protons & electrons

  41. The Sun’s Layers PSCI 131: Light, Astr. Observations, & The Sun – The Sun Numbers are in order of increasing depth 2. CHROMOSPHERE 5. RADIATION ZONE 4. CONVECTION ZONE 6. CORE 3. PHOTOSPHERE 1. CORONA Modified from: visual.merriam-webster.com

  42. Corona (during solar eclipse) PSCI 131: Light, Astr. Observations, & The Sun – The Sun’s Layers From: mreclipse.com

  43. Chromosphere PSCI 131: Light, Astr. Observations, & The Sun – The Sun’s Layers From: astroguyz.com

  44. Photosphere: closeup view PSCI 131: Light, Astr. Observations, & The Sun – The Sun’s Layers Source of visible light Covered by granules produced by convection “Boiling” appearance Movie: Visiting the photosphere for one hour From: www.astronomynotes.com

  45. The Sun’s Engine PSCI 131: Light, Astr. Observations, & The Sun – The Sun • Matter is converted to energy in the core • Nuclear fusion reactions • Hydrogen + hydrogen = helium + energy • 4 billion tons per second • E = mc2 c: speed of light (186,000 miles/second)

  46. End of Light & The Sun Chapter

More Related