Effective Temperature

5 Must Know Facts For Your Next Test

1. Effective temperature is used to determine the surface temperature of a star based on its observed luminosity and radius, rather than directly measuring the temperature.
2. The effective temperature of a star is the temperature of a perfect blackbody that would have the same total luminosity as the star.
3. A star's effective temperature is directly related to its position on the Hertzsprung-Russell (H-R) diagram, which plots the relationship between a star's luminosity and surface temperature.
4. As a star evolves off the main sequence, its effective temperature can change significantly, affecting its color and position on the H-R diagram.
5. The effective temperature of a star is an important parameter in understanding its overall energy output, as well as its stage of evolution and physical properties.

Review Questions

• Explain how effective temperature is used to determine the surface temperature of a star.
  • The effective temperature of a star is a measure of the surface temperature that takes into account the star's overall energy output and appearance. By applying the Stefan-Boltzmann law, which relates a blackbody's total energy output to its temperature, astronomers can calculate a star's effective temperature based on its observed luminosity and radius. This allows them to infer the actual surface temperature of the star, even if they cannot directly measure it.
• Describe the relationship between a star's effective temperature and its position on the Hertzsprung-Russell (H-R) diagram.
  • A star's effective temperature is a key factor in determining its position on the H-R diagram, which plots the relationship between a star's luminosity and surface temperature. Stars with higher effective temperatures appear hotter and bluer, while those with lower effective temperatures appear cooler and redder. As a star evolves off the main sequence, its effective temperature can change significantly, causing it to shift its position on the H-R diagram and revealing information about its stage of evolution and physical properties.
• Analyze how changes in a star's effective temperature can impact its overall energy output and evolution.
  • A star's effective temperature is directly related to its total energy output, as described by the Stefan-Boltzmann law. As a star evolves, its effective temperature can change, which in turn affects its luminosity and the amount of energy it radiates. For example, as a star transitions from the main sequence to become a red giant, its effective temperature decreases, but its luminosity increases significantly due to the expansion of its surface area. These changes in effective temperature are a crucial indicator of a star's evolutionary stage and can provide insights into its physical processes, such as the onset of nuclear fusion in different layers of the star's interior.