Friday 10 January 2020

astrophysics - How the Hertzsprung-Russell Diagram allows us to calculate distance to stars


I understand how to interpret a H-R diagram, in the sense that I know that the upper right top corner is occupied by cool stars, but they are very luminous so they must be big; and the bottom left corner are hot stars, not luminous, so they are small in size. However, I have tried to read a textbook and look online, but have yet to understand how from this information, we can measure the distance to stars of undefined distance.



Answer



There are two main techniques that I know of for using HR diagrams to measure distance. The first is to, basically, plot a group of stars that were likely all formed at the same time (that is, a cluster) with apparent brightness against color. Because the stars are all in the same cluster, they are at nearly the same distance. So you can find the distance to the cluster by finding how much you have to shift the diagram up or down to get it to line up with either a similar HR diagram of a cluster at a known distance or an HR diagram of stars with parallax distances.


The second way is called "tip of the red giant branch", typically used with galaxies where the main sequence won't be as well defined as it is for single clusters. As a star ages it moves through the HR-diagram on paths at different rates. Most of the star's lifetime is spent on the line where it burns hydrogen in its core, known as the "main sequence". As the fusing layer expands due to the growth of the inert core in the center, the star moves up and to the right (brighter and redder) on the diagram. For stars with mass less than around 1.6 times the sun's, the pressure and temperature eventually get high enough that helium begins fusing, in a process called the helium flash, causing the core to expand and cool, making the outer layers of the star contract. That moves the star back down and to the left in the HR-diagram, leaving a kind of "cusp" in the path through the HR diagram. The location of that cusp is called the "tip of the red giant branch". Because we know the luminosity and color of that tip, when we find it on an HR diagram of stars in a galaxy, we can work out a lot of information about the galaxy (redshift, distance, etc).


No comments:

Post a Comment

Understanding Stagnation point in pitot fluid

What is stagnation point in fluid mechanics. At the open end of the pitot tube the velocity of the fluid becomes zero.But that should result...