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The Origin and Nature of Light

The Origin and Nature of Light. The Origin and Nature of Light. Celebration of Knowledge #2 (aka Exam #2) is Thursday March 8th in N210 Tailgate Party (aka exam review) is Wednesday March 7th in N210 from 4-6pm

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The Origin and Nature of Light

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  1. The Origin and Nature of Light

  2. The Origin and Nature of Light • Celebration of Knowledge #2 (aka Exam #2) is Thursday March 8th in N210 • Tailgate Party (aka exam review) is Wednesday March 7th in N210 from 4-6pm • HW #5 – Handed out in class Feb 27th on the topic of Luminosity Area and Temperature, and Due IN-CLASS Tuesday March 6th

  3. HW#6 – Masteringastronomy online homework on Properties of Light and Matter.Available March 1st , Due March 8th by 10am. The Origin and Nature of Light

  4. What can we learn by analyzing starlight? • A star’s temperature

  5. Find the hottest star(s), how do you know ?

  6. Star A Star A Star A Star D Star C Energy Output per second Energy Output per second Energy Output per second Star B V I B G Y O R Wavelength Wavelength V I B G Y O R V I B G Y O R Wavelength

  7. Which star is larger Star A or Star D? Star A Star D • Star A • Star D • Same Energy Output per second Wavelength V I B G Y O R

  8. visible range visible range Energy Output per second Energy Output per second Object A Object B Wavelength Wavelength V I B G Y O R V I B G Y O R visible range Energy Output per second visible range Energy Output per second Object C Object D Wavelength V I B G Y O R Wavelength V I B G Y O R Try to determine EVERYTHING about how these four stars compare!! Temp, Energy output, Color, size (area)…..

  9. But, where does light actually come from? electron Accelerating charges produce light – electromagnetic radiation!

  10. An atom consists of a small, dense nucleus (containing protons and neutrons) surrounded by electrons- Model Proposed by Niels Bohr 1913

  11. Atoms are mostly empty space A nucleus is about 10-15 m in size and the first electron orbits out at 10-10 m from the center of the atom – The size of the electron orbit is 100,000 times greater than the size of the nucleus

  12. So if a nucleus the size of an orange (10 cm) was located at the center of the football field, where would the electron be?End Zone?Grandstands?On Campus?In Tucson?

  13. If the electron’s orbit is 100,000 times bigger than the nucleus then the electron would be 10,000 m or 6.21 miles away from the center of the Football Field!Still in Tucson, up in the foothills shopping at La Encantada!!

  14. The electron should be thought of as a distribution or cloud of probability around the nucleus that on-average behave like a point particle on a fixed circular path

  15. Nucleus

  16. Nucleus Photons (light-waves) are emitted from an atom when an electron moves from a higher energy level to a lower energy level

  17. Nucleus Photons (light-waves) can also be absorbed by an atom when an electron moves from a lower energy level to a higher energy level

  18. Each chemical element produces its own unique set of spectral lines when it is excited

  19. We will study three types of spectra!!! prism Hot/Dense Energy Source Continuous Spectrum prism Hot low density cloud of Gas Emission Line Spectrum prism Hot/Dense Energy Source Cooler low density cloud of Gas Absorption LineSpectrum

  20. The type of spectrum given off depends on the objects involved Law #1 – The excited atoms within a hot dense object give off light of all colors (wavelengths) and produce a continuous spectrum -- a complete rainbow of colors (range of wavelengths) without any spectral lines.

  21. We will study three types of spectra!!! prism Hot/Dense Energy Source Continuous Spectrum

  22. The type of spectrum given off depends on the objects involved Law #2 – The excited atoms within a hot, cloud of gas give off only particular colors (wavelengths) of light and produce an emission line spectrum - a series of bright spectral lines against a dark background.

  23. We will study three types of spectra!!! prism Hot low density cloud of Gas Emission Line Spectrum

  24. The type of spectrum given off depends on the objects involved Law #3 – When the light from a hot dense object passes through a cool cloud of gas, the atoms within the cloud can absorb particular colors (wavelengths) of light and produce a absorption line spectrum - a series of dark spectral lines among the colors of the rainbow.

  25. We will study three types of spectra!!! prism Hot/Dense Energy Source Cooler low density cloud of Gas Absorption LineSpectrum

  26. Tutorial: Types of Spectra – p.41 • Work with a partner! • Read the instructions and questions carefully. • Discuss the concepts and your answers with one another. Take time to understand it now!!!! • Come to a consensus answer you both agree on. • If you get stuck or are not sure of your answer, ask another group.

  27. Tutorial: Light and Atoms – LT Handout • Work with a partner! • Read the instructions and questions carefully. • Discuss the concepts and your answers with one another. Take time to understand it now!!!! • Come to a consensus answer you both agree on. • If you get stuck or are not sure of your answer, ask another group.

  28. Imagine that you observe the Sun using a telescope in an orbit high above Earth’s atmosphere. Which of the following spectra would you observe by analyzing the sunlight? • dark line absorption spectrum • bright line emission spectrum • continuous spectrum • None of the above

  29. If an electron in an atom moves from an orbit with an energy of 5 to an orbit with an energy of 10, • a photon of energy 5 is emitted • a photon of energy 15 is emitted. • a photon of energy 5 is absorbed. • a photon of energy 15 is absorbed. • None of the above

  30. Which of these would cause a “Violet” or high energy absorption line? A. B. C. D. E. None of the above

  31. e- A B e- E D e- e- C e- e- Which of these shows the atom emitting the greatest amount of light?

  32. What physical situation makes this spectrum?

  33. The type of spectrum given off depends on the objects involved Law #3 – When the light from a hot dense object passes through a cool cloud of gas, the atoms within the cloud can absorb particular colors (wavelengths) of light and produce a absorption line spectrum - a series of dark spectral lines among the colors of the rainbow.

  34. prism Hot/Dense Energy Source Cooler low density cloud of Gas Absorption LineSpectrum

  35. What physical situation does a star like the sun present? A hot dense core surrounded by a low density outer atmosphere

  36. The Sun’s Spectrum

  37. All stars produce dark line absorption spectra

  38. What can we learn by analyzing starlight? • A star’s temperature • A star’s chemical composition

  39. Tutorial: Analyzing Spectra – p. 43 • Work with a partner! • Read the instructions and questions carefully. • Discuss the concepts and your answers with one another. Take time to understand it now!!!! • Come to a consensus answer you both agree on. • If you get stuck or are not sure of your answer, ask another group.

  40. Consider the dark line absorption spectra shown below for Star X and Star Z. What can you determine about the color of the two stars? Assume that the left end of each spectrum corresponds to shorter wavelengths (blue light) and that the right end of each spectrum corresponds with longer wavelengths (red light). Star X Star Z • Star X would appear blue and Star Z would appear red. • Star X would appear red and Star Z would appear blue. • Both stars would appear the same color. • The color of the stars cannot be determined from this information.

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