Presentation is loading. Please wait.

Presentation is loading. Please wait.

Oct. 11, 2007 1 Review: BB radiation enables measure of both stellar temperature T, and surface flux, F s The shift of the peak λ, to have a maximum flux.

Published bySuzan Elizabeth Malone Modified over 8 years ago

Similar presentations

Presentation on theme: "Oct. 11, 2007 1 Review: BB radiation enables measure of both stellar temperature T, and surface flux, F s The shift of the peak λ, to have a maximum flux."— Presentation transcript:

1 Oct. 11, 2007 1 Review: BB radiation enables measure of both stellar temperature T, and surface flux, F s The shift of the peak λ, to have a maximum flux (brightness) at wavelength λ max, allows the BB spectrum temperature to be directly measured since Wien’s Law relates the two: λ max = 0.0029/T (for λ max in meters) or λ max = 2.95 x 10 6 /T (for λ max in nm, more usual unit) So Sun, with surface temp. T = 5500K, has λ max = 540nm The energy flux of the BB source (as measured per unit area on its surface) is proportional to the temperature T to 4 th power, by the Stefan-Boltzmann Law: F s = σ T 4 where σ = 5.7 x 10 -8 W/(m 2 - K 4 ) where K is the temperature in degrees Kelvin (note: σ = 5.7 x 10 -5 erg/(cm 2 - sec - K 4 ) if you use cm units instead or m for R and erg/sec instead of W) The total energy flux emitted from a BB source of radius R is its luminosity: L = 4πR 2 F s = 4πR 2 σ T 4 The total energy flux detected from a BB source with luminosity L at distance d is F = L / 4πd 2 (this is the inverse square law for light) NOTE: must distinguish surface flux, F s, from detected flux which we will call F

2 Oct. 11, 2007 2 How can we “scale” from Sun to T & R for stars? The wonders of BB radiation (so simple!) allow us to do direct “measurements” of stellar temperature, T, (on surface of a star) and the radius, R, of that stellar surface (= radius of star): –Measure star color (by using filters; discuss next week…) to first estimate λ max and thus T from Wien law –Use known (from parallax) distance of star and inverse square law to estimate luminosity, L, from measured flux, F –Use Stefan-Boltzmann law to estimate R from L and T Practice this with examples as in Box 5-2 in Text… You don’t need to “know” the constants (e.g. σ); just use RATIOS and the fundamental L ~ R 2 T 4 relation to scale from the values for the Sun

3 Oct. 11, 2007 3 On to spectra of light from the elements A given element (Hydrogen, Helium…. Iron) is composed of atoms with a well defined structure: nucleus (protons+neutrons) surrounded by a “cloud” of orbiting electrons in fixed orbits at discrete energy levels n = 1, 2, etc. as shown for H below: Electrons can only “Jump” from one n value to another and either lose (if n decreases) or gain (if n increases) energy. That energy loss/gain produces spectral lines in emission (energy given from electron to light) or absorption (energy given from the light to the electron) Energy levels in H Atom for Bohr model

4 Oct. 11, 2007 4 Spectral lines provide composition of Stars Each element (H…. Fe… U) has unique spectral lines since electron orbits differ since total electron number differs Light from the stars (Sun, Vega, etc.) show spectral lines primarily in absorption (dark lines) due to light from “hot” surface (BB continuum) shining up through “cooler” overlying stellar atmosphere. Corona (outermost “atmosphere”) of the Sun, visible in solar eclipse, shows spectral lines in emission since hot gas not shining through cool gas and since no BB continuum (corona is beyond edge of Sun) Demonstrate today in class with “Tower of Light” for spectra of H, He, Ne (emission line sources since hot gas in tube gives energy to electrons that then “drop” down to give back energy as light)

Download ppt "Oct. 11, 2007 1 Review: BB radiation enables measure of both stellar temperature T, and surface flux, F s The shift of the peak λ, to have a maximum flux."

Similar presentations

Universe Eighth Edition Universe Roger A. Freedman William J. Kaufmann III CHAPTER 5 The Nature of Light CHAPTER 5 The Nature of Light.

Universe Eighth Edition Universe Roger A. Freedman William J. Kaufmann III CHAPTER 5 The Nature of Light CHAPTER 5 The Nature of Light.
Blackbody Radiation. Blackbody = something that absorbs all electromagnetic radiation incident on it. A blackbody does not necessarily look black. Its.

Blackbody Radiation. Blackbody = something that absorbs all electromagnetic radiation incident on it. A blackbody does not necessarily look black. Its.
Astronomical Spectroscopy. The Electromagnetic Spectrum.

Astronomical Spectroscopy. The Electromagnetic Spectrum.
The Nature of Light Chapter Five.

The Nature of Light Chapter Five.
Radiation and Spectra Chapter 5

Radiation and Spectra Chapter 5
Chapter 4 The Origin and Nature of Light

Chapter 4 The Origin and Nature of Light
Electromagnetic Radiation

Electromagnetic Radiation
Spectral lines Photon energy Atomic structure Spectral lines Elements in stars Masses of stars Mass-luminosity relation Reading: sections 16.5, 16.7, 6.2.

Spectral lines Photon energy Atomic structure Spectral lines Elements in stars Masses of stars Mass-luminosity relation Reading: sections 16.5, 16.7, 6.2.
Astronomy 1 – Winter 2011 Lecture 8; January 24 2011.

Astronomy 1 – Winter 2011 Lecture 8; January
Electromagnetic Radiation Electromagnetic radiation - all E-M waves travel at c = 3 x 10 8 m/s. (Slower in water, glass, etc) Speed of light is independent.

Electromagnetic Radiation Electromagnetic radiation - all E-M waves travel at c = 3 x 10 8 m/s. (Slower in water, glass, etc) Speed of light is independent.
This Set of Slides This set of slides covers finding distance in space, parallax review and limitations, some more physics (of light), the Inverse Square.

This Set of Slides This set of slides covers finding distance in space, parallax review and limitations, some more physics (of light), the Inverse Square.
PTYS/ASTR 206Telescopes and Imaging 2/1/07 Plus … Telescopes and Imaging Blackbody Radiation and Spectroscopy.

PTYS/ASTR 206Telescopes and Imaging 2/1/07 Plus … Telescopes and Imaging Blackbody Radiation and Spectroscopy.
Astronomy 1 – Winter 2011 Lecture 7; January 19 2011.

Astronomy 1 – Winter 2011 Lecture 7; January
Light Astronomy 315 Professor Lee Carkner Lecture 4.

Light Astronomy 315 Professor Lee Carkner Lecture 4.
Light is a wave or electric and magnetic energy The speed of light is 186,000 mi/s = 300,000 km/s.

Light is a wave or electric and magnetic energy The speed of light is 186,000 mi/s = 300,000 km/s.
Properties of Stars. Distance Luminosity (intrinsic brightness) Temperature (at the surface) Radius Mass.

Properties of Stars. Distance Luminosity (intrinsic brightness) Temperature (at the surface) Radius Mass.
Stars Introduction To “Atomic Astrophysics and Spectroscopy” (AAS) Anil Pradhan and Sultana Nahar Cambridge University Press 2011 Details at: www.astronomy.ohio-state.edu/~pradhan/Book/book.html.

Stars Introduction To “Atomic Astrophysics and Spectroscopy” (AAS) Anil Pradhan and Sultana Nahar Cambridge University Press 2011 Details at:
Black Body Radiation Physics 113 Goderya Chapter(s): 7 Learning Outcomes:

Black Body Radiation Physics 113 Goderya Chapter(s): 7 Learning Outcomes:
Quiz 1 Each quiz sheet has a different 5-digit symmetric number which must be filled in (as shown on the transparency, but NOT the same one!!!!!) Please.

Quiz 1 Each quiz sheet has a different 5-digit symmetric number which must be filled in (as shown on the transparency, but NOT the same one!!!!!) Please.
Solar Spectrum. Bit of Administration …. c = 3 x 10 8 m/sec = 3 x 10 5 km/secc = 3 x 10 8 m/sec = 3 x 10 5 km/sec Reading Reading –BSNV pp. 153 - 168.

Solar Spectrum. Bit of Administration …. c = 3 x 10 8 m/sec = 3 x 10 5 km/secc = 3 x 10 8 m/sec = 3 x 10 5 km/sec Reading Reading –BSNV pp

Similar presentations

Ads by Google