Hertzsprung – Russell Diagram A plot of the luminosity as a function of the surface temperature for different radii stars.
Hertzsprung - Russell Diagram The Hertzsprung -Russell (H-R) Diagram is a graph that plots stars color (spectral type or surface temperature) vs. its luminosity (intrinsic brightness or absolute magnitude). On it, astronomers plot stars' color, temperature, luminosity, spectral type, and evolutionary stage. There are 3 very different types of stars:luminositymagnitudeastronomers Most stars, including the sun, are "main sequence stars," fueled by nuclear fusion converting hydrogen into helium. For these stars, the hotter they are, the brighter. These stars are in the most stable part of their existence; this stage generally lasts for about 5 billion years."main sequence stars,"nuclear fusionhydrogenhelium As stars begin to die, they become giants and supergiants (above the main sequence). These stars have depleted their hydrogen supply and are very old. The core contracts as the outer layers expand. These stars will eventually explode (becoming a planetary nebula or supernova, depending on their mass) and then become white dwarfs, neutron stars, or black holes (again depending on their mass).supergiantsmain sequencedepending on their mass Smaller stars (like our Sun) eventually become faint white dwarfs (hot, white, dim stars) that are below the main sequence. These hot, shrinking stars have depleted their nuclear fuels and will eventually become cold, dark, black dwarfs.white dwarfs
Sometimes the labels are a little different: The vertical position represents the star's luminosity. This could be the luminosity in watts. More commonly it is in units of the Sun's luminosity. In either case, a ``ratio scale'' is used. Absolute magnitude is also commonly used. The horizontal position represents the star's surface temperature. Sometimes this is labelled in by the temperature in Kelvins. Highest temperatures go to the left. (It's traditional.) Normally the temperature is given using a ``ratio scale.'' Sometimes the stars spectral class (OBAFGKM) is used. One could also use a measure of color as seen through filters. Hertzsprung – Russell Diagram
Basics of the HR diagram In a Hertzsprung-Russell diagram, each star is represented by a dot. One uses data from lots of stars, so there are lots of dots. The position of each dot on the diagram corresponds to the star's luminosity and its temperature. The vertical position represents the star's luminosity. The horizontal position represents the star's surface temperature.
How it works: Stefan-Boltzmann’s Law: Hertzsprung – Russell Diagram L A = T4T4 Where L is the luminosity in Watts A is the surface area F is the Stefan-Boltzmann constant = 5.67 x W/m 2 – K 4 T is the surface temperature in Kelvin
How it works: Stefan-Boltzmann’s Law: Hertzsprung – Russell Diagram L A = T4T4 L=4 R 2 T 4
Some fancy stuff: Hertzsprung – Russell Diagram L =4 LL LL R2R2 T4T4 R2R2 R2R2 T4T4 T4T4 ()))(( L = LL LL R2R2 T4T4 R2R2 R2R2 T4T4 T4T4 ()))(( = LL R2R2 T4T4 But: Where is the symbol for the sun
Therefore: Hertzsprung – Russell Diagram L = LL R2R2 T4T4 R2R2 T4T4 ())( 1 If luminosity and radius are given as the fraction of the luminosity and radius of the sun, and recalling that T = 5800 K, then =L fractional T4T4 R fractional Where L fractional and R fractional are the fraction of the suns luminosity and radius.
AND, using logarithms: Hertzsprung – Russell Diagram =Log (L fractional )T4T4 R fractional Log () =Log (L fractional )+ Log (T 4 )R fractional Log () =Log (L fractional )4 Log TR fractional Log ()
AND, using logarithms: Hertzsprung – Russell Diagram =Log (L fractional )4 Log TR fractional Log () y = mx + b On a Log – Log graph, the L vs T graph is a straight line for a given radius star
Hertzsprung – Russell Diagram =Log (L fractional )4 Log TR fractional Log () y = mx + b
H-R Diagram for the nearest stars to the solar system Hertzsprung – Russell Diagram
Most stars fall on a band, called the main sequence. Main sequence – the band on an H-R Diagram upon which most stars fall. Hertzsprung – Russell Diagram
=Log (L fractional )4 Log TR fractional Log () y = mx + b
Determination of Masses Binary Stars X R
Determination of Masses Binary Stars X M = v 2 R G R
Determination of Masses Binary Stars - Types Visual Binaries – Binary stars which are far enough apart and bright enough to be observed and monitored separately. Spectroscopic Binaries – Binary stars which are too far away to be distinguished visually. There motion can be determine though their spectra, and the Doppler Shifts associated with the orbits of the stars.
Mass-Luminosity Relationship Luminosity vs. Mass is plotted for the Sun and all Main Sequence stars in binary systems that have good mass measurements shows that a Main Sequence star's Luminosity is very strongly correlated with its Mass: Data shows that L M 4
Using this relation, we can label regions on the HR diagram according to the mass of the corresponding stars. Our conclusion: Different stars have different masses. Among all stars with the same mass, almost all have the same properties. The most massive stars are the most luminous.
Based on experimental evidence: * Stars spend most of their lives as main sequence stars. * During its lifetime, the surface temperature and luminosity stays pretty much constant. Something else could happen in the star birth process. Something else could happen in the star death process. * The star's mass determines what the temperature and luminosity is during the star's main sequence lifetime. More mass -> hotter. More mass -> more luminous. Also, more mass -> bigger. Hertzsprung – Russell Diagram
* Strong correlation between Luminosity and Temperature. * Hotter stars are Brighter than cooler stars along the M-S. * About 85% of nearby stars, including the Sun, are on the M-S. All other stars differ in size: Giants & Supergiants: * Very large radius, but same masses as M-S stars White Dwarfs: * Very compact stars: ~ R earth but with ~ M sun The most prominent feature of the H-R diagram is the Main Sequence (M-S):