Radiation and Spectra Chapter 5 Light Radiation and Spectra Chapter 5
What is Light? Newton Maxwell Quantum Mechanics Prism shows white light contains all colors Light made of particles (photons) Maxwell Theory of electricity and magnetism Light is electromagnetic waves Produced by wiggling electrons Radiation = production of light Quantum Mechanics Light is both: particle and wave
Waves Wavelength ( l ) Frequency ( f ) Distance between crests (or troughs) Frequency ( f ) How often it repeats (wiggles up and down) Measured in Hertz (Hz) number of times per sec
Waves Speed c = 3 x 108 m/s Wavelength inversely related to frequency c = lf Wavelength inversely related to frequency l = c / f high frequency = short wavelength low frequency = long wavelength
Particles as Waves “Wave Packet” particle/photon = localized wave
Properties of Light Color Carries energy (heat) Depends on frequency blue = high frequency = short wavelength red = low frequency = long wavelength Carries energy (heat) Photon energy E = h f high frequency = high energy = blue low frequency = low energy = red h = Planck’s constant
Red light has ____ than blue light. A. larger frequency, energy, and wavelength B. smaller frequency, energy, and wavelength C. larger frequency and energy, but smaller wavelength D. smaller frequency and energy, but larger wavelength
All types of light travel at the same speed - Which of the following travels fastest? } radio waves infrared (heat) waves microwaves blue light waves none of the above All are types of light! All types of light travel at the same speed - the “speed of light”, c
Propagation of Light Photons travel in straight lines energy spread over larger area at larger distances produces 1/r2 decrease in brightness Double distance - brightness decreases by 4
If a 100-watt light bulb is placed 10 feet away from you, and an identical 100-watt light bulb is placed 100 feet away from you, which will appear brighter? The closer one The farther one They will appear the same brightness How much fainter will the far one appear compared to the close one? Twice as faint 10 times fainter 100 times fainter 1000 times fainter ~ 1/r2
Electromagnetic Spectrum Visible light: red, orange, yellow, green, blue, indigo, violet (ROYGBIV) Invisible Light: Ultraviolet = bluer than blue Infrared = redder than red Other wavelengths: Short: X-rays, gamma-rays Long: microwave, radio
Which kind of electromagnetic radiation has a wavelength longer than that of visible light? A. infrared B. ultraviolet C. x-rays D. gamma rays E. none of the above
What’s the wavelength of my favorite radio station? Link to: http://eosweb.larc.nasa.gov/EDDOCS/wavelength.html
Thermal Radiation All objects radiate (thermal radiation) Objects made of atoms Atoms (and their electrons) vibrate Wiggling electrons radiate, producing light Bigger objects produce more light Higher temperature = stronger vibration Hotter objects emit more light Perfect absorber is black Absorbed light (energy) heats object Temperature increases until emitted energy = absorbed energy Emitted radiation called Blackbody Radiation Thermal radiation emitted by most objects similar to blackbody
Blackbody Radiation Laws Luminosity, L L = energy emitted per second Luminosity for a spherical object (a star) L = 4p R2 s T4 R = radius (size) of star; T = temperature double size, luminosity increases by 2x2 = 4 double temperature; luminosity increases by 2x2x2x2 = 16 Stefan-Boltzmann Law
Luminosity Temperature and Size Part I WORKBOOK EXERCISE: Luminosity Temperature and Size Part I (pages 33-35 in workbook)
Blackbody Radiation
Blackbody Radiation Laws Color Wavelength where most light emitted lmax = 3 x 106 / T T in Kelvin; lmax in nanometers (1 nm=10-9m) Cool stars are red Hot stars are blue Color indicates temperature! Wien’s Law As T , Wavelength , Color = redder As T , Wavelength , Color = bluer
Homework: WORKBOOK EXERCISE Blackbody Radiation (pages 37-40 in workbook)
The graph above shows blackbody spectra for three different stars The graph above shows blackbody spectra for three different stars. Which of the stars is at the highest temperature? Star A Star B Star C Because peak energy emission occurs at shortest wavelength
Doppler Shift Originally discovered using sound waves Moving object emits light with slightly different color Frequency (pitch) of approaching object is higher Blueshift Wavelength shorter (shifted blueward) Frequency (pitch) of receeding object is lower Redshift Wavelength longer (shifted redward)
Doppler Shift Redshift Blueshift
Spectroscopy Prism separates light into different colors Continuous spectrum contains all colors Example: blackbody spectrum
Spectroscopy Absorption Line Spectrum Some colors are missing (discrete lines) Solar Spectrum N.A.Sharp, NOAO/NSO/Kitt Peak FTS/AURA/NSF
Spectroscopy Emission Line spectrum Only certain colors are present (discrete lines) Spectrum for each element unique (like fingerprints)
Model Atom Nucleus contains protons and neutrons number of protons = element (1 proton = hydrogen, 2 protons = helium, etc.) number of neutrons about same as protons Isotope = different number of neutrons hydrogen helium Isotopes of hydrogen
Model Atom Electrons orbit nucleus Number of electrons = number of protons Ionization = removing electrons Only certain orbits are allowed hydrogen helium
Atomic Absorption Atom absorbs photon energy electron “jumps” to higher energy orbit only certain discrete orbits are allowed Atom can absorb only discrete colors (energies)
Atomic Emission Electron “jumps” to a lower energy orbit Atom emits photon can emit only discrete colors same colors (wavelengths/energies) as absorption
Atomic Energy Levels Energy Levels Different for each element each element has unique set of absorption/emission lines
Kirchoff’s Laws Continuous spectrum Emission line spectrum Produced by hot solid (or dense gas) Emission line spectrum Produced by hot, low density gas Absorption line spectrum Produced when continuous source is viewed through cooler low density gas
Kirchoff’s Laws Absorption lines same wavelengths as emission lines Gas can only absorb and emit at certain discrete frequencies/wavelengths/energies
WORKBOOK EXERCISE: “Types of Spectra” (pages 41-42 in workbook)
If you analyze the light from a low density object (such as a cloud of interstellar gas), which type of spectrum do you see? dark line absorption spectrum bright line emission spectrum continuous spectrum
Imagine that you observe the Sun while in your space ship far 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