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Spectra What determines the “color” of a beam of light? The answer is its frequency, or equivalently, its wavelength. We see different colors because.

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Presentation on theme: "Spectra What determines the “color” of a beam of light? The answer is its frequency, or equivalently, its wavelength. We see different colors because."— Presentation transcript:

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2 Spectra What determines the “color” of a beam of light? The answer is its frequency, or equivalently, its wavelength. We see different colors because our eyes react differently to electromagnetic waves of different frequencies. A prism splits a beam of light up into the familiar "rainbow" of colors because light rays of different wavelengths are bent, or affected by refraction and dispersion, as they pass through a prism—red light is bent the least, violet light is bent the most. (ROY G BIV)

3 The Electromagnetic Spectrum

4 Spectrograph Any hot radiating object, will produce a continuous spectrum of light.

5 Spectrum Light Intensity as a function of Wavelength. Wavelength Intensity

6 Spectrum Light Intensity as a function of Frequency. f = c/ Frequency Intensity

7 Blackbody Radiation Stefan-Boltzman Law Energy Flux E =  T 4 As the temperature increases, the energy output increases more dramatically Stefan-Boltzmann Constant  = 5.6705 x 10 -5 erg cm 2 /K 4 s

8 Blackbody Spectrum Energy Intensity (Shape of Spectrum) E = 2 hc 2 / 5 [e hc/ kT - 1] -1 Planck’s Constant h = 6.625 x 10 -27 erg-sec Boltzmann Constant k = 1.38 x 10 -16 erg/K Speed of Light c = 3 x 10 8 m/s

9 The Sun as a Blackbody Radiator (T=5800K)

10 Hot Radiating Objects Imagine a piece of metal placed in a hot furnace. At first, the metal becomes warm, although its visual appearance doesn't change. As it heats up, it begins to glow dull red, then orange, brilliant yellow, and finally white hot. Objects that emit light energy are called blackbody radiators. How do we explain this energy increase and change in color?

11 Wien's law relates the temperature T of an object to the wavelength maximum at which it emits the most radiation. Mathematically, if we measure T in kelvins and the wavelength maximum ( ) in nanometers, we find that* max = 3,000,000/T *3,000,000 is an approximation of the true value 2,900,000 (just like 300000000 m/s approximates the speed of light 299792458. Wien’s Radiation Law

12 The Sun has a surface temperature of 5800 K. max = 3,000,000/T max = 3,000,000/5800 = 517.2 nm (green-YELLOW-orange) Solar Spectrum Peak

13 Wein’s Law and Color As the temperature of a radiating object goes up, 1) it emits more light, 2) the peak of its maximum emission moves to higher energies. (higher f, shorter )

14 T = 98.6 0 F = 5/9(98.6-32) = 37 0 C = (37 + 273) = 310 Kelvin max = 3,000,000/T max = 3,000,000/310 = 9677 nm infrared (heat) Human max

15 Spectral Sensitivity of Electromagnetic Detectors

16 Different Wavelength Views of Our Sun What you see depends upon what range of wavelengths you look at.

17 The Sky at Many Wavelengths Visual, Ultraviolet, Radio and X-ray images of the Ring Nebula (M56).

18 Atomic Spectra

19 Absorption Spectrum Photons with the correct energy, are absorbed by the gas surrounding the continuous source. They are re-radiated in all directions yielded a decrease in light from wavelengths corresponding to the energies of atoms in the gas.

20 Emission Spectrum Seen against the background of space, only the photons emitted by the excited atoms in the gas are seen. These wavelengths only come from allowed energies in the atoms of the gas.

21 Emission and Absorption In order to absorb energy, radiation must contain photons of the energy that corresponds to energy differences found within the atom. Absorption of these photons excites the electrons to higher energy states. Electrons, like humans would rather be couch potatoes, so they soon give up their energy to seek the lowest energy state. To give up energy they emit photons that have energies corresponding to the energy differences needed to cascade down. They can do this in steps, emitting lots of low energy photons, or all at once, emitting one large energy photon.

22 Energy Level Schematic Solar System Analogy for an... Atom –Massive StarMassive Nucleus –Planets in orbitElectrons in Orbit –Kepler’s LawsConservation of Energy – and Angular Momentum

23 Atomic Energy States The minimum energy state (lowest electron orbit) is the ground state.

24 Atomic Energy Levels

25 Emission and Absorption In order to absorb energy, radiation must contain photons of the energy that corresponds to energy differences found within the atom. Absorption of these photons excites the electrons to higher energy states. Electrons, like humans would rather be couch potatoes, so they soon give up their energy to seek the lowest energy state. To give up energy they emit photons that have energies corresponding to the energy differences needed to cascade down. They can do this in steps, emitting lots of low energy photons, or all at once, emitting one large energy photon.

26 Energy Transitions E1E1 E2E2 E3E3 E4E4 E5E5 e-

27 This photon’s was too short! E = hf = hc/ E1E1 E2E2 E3E3 E4E4 E5E5 e-

28 This photon’s was just right! E = hf = hc/ E 2 -E 1 = E E1E1 E2E2 E3E3 E4E4 E5E5 e-

29 Wow! E 2 -E 1 = E E1E1 E2E2 E3E3 E4E4 E5E5 e-

30 Here It Comes Again! E 3 -E 2 = E … NOT! E1E1 E2E2 E3E3 E4E4 E5E5 e-

31 Fickle electron? E 3 -E 2 = E E1E1 E2E2 E3E3 E4E4 E5E5 e-

32 Yahoo! I feel energized! E1E1 E2E2 E3E3 E4E4 E5E5 e-

33 I’m Getting Sleepy... E1E1 E2E2 E3E3 E4E4 E5E5 e-

34 Ahhhhhh Photon Energy = E 3 -E 1 E1E1 E2E2 E3E3 E4E4 E5E5 e-

35 Going Down EITHER THIS: E 3 -E 1 OR THIS E 3 -E 2 AND THIS E 2 -E 1 E1E1 E2E2 E3E3 e- Photon Energies E 3 -E 1 = (E 3 -E 2 ) + (E 2 -E 1 )

36 Atomic Energy Transitions Hydrogen Atom Energy Level Model

37 HeliumCarbon Atomic Energy Levels Are Unique A Spectrum can give you information about temperature, chemical composition, and density.

38 Molecular Energy States Molecules have unique energy states also.

39 Atomic Signatures Atomic Spectra are like… All Unique, Get the picture?

40 Atomic Spectra Mug Shots

41 Atomic Energy Levels Energy of a Photon E = hf  hc  Atomic Energy Level Difference  E = E n - E m = h(f n -f m )

42 Infrared A foggy day in visual light, and the same picture with a sensitive infrared camera. Fog is opaque to visible wavelengths and transparent in the infrared wavelengths

43 Transparency of Earth’s Atmosphere

44 The Orion Nebula Infrared, Visual and X-ray images in the direction of Orion.  -Orion the red star (Betelguese) and  -Orion the blue (Rigel)

45 The Visible Solar Spectrum Absorption Spectrum: Continuous spectrum with absorption lines

46 Stellar Spectra

47

48 Solar Composition

49 Spectrum Parameters* Observations of Spectra Yield: 1. Distance (1/R 2, assuming intrinsic brightness known) 2. Temperature (color, peak wavelength intensity) 2. Chemical Composition (spectral lines) 3. Densities (spectral line strengths) 4. Velocities (doppler shift) *Light contains a LOT of information!

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