Q&A

What determines the position of a star on the H-R diagram?

What determines the position of a star on the H-R diagram?

The position of a star along the main sequence is determined by its mass. High-mass stars emit more energy and are hotter than low-mass stars on the main sequence.

Why do a star’s properties depend on its mass?

Mass determines how hot the stellar core gets in response to gravitational contraction, and since the rate of nuclear burning is very sensitive to temperature, a star’s mass determines the energy production rate (luminosity), and whether/when gravitational contraction can lead to explosive release of energy for massive …

How does the mass of a star relate to the time it stays on the Hertzsprung Russell diagram?

In general, the more massive a star is, the shorter its lifespan on the main sequence. After the hydrogen fuel at the core has been consumed, the star evolves away from the main sequence on the HR diagram, into a supergiant, red giant, or directly to a white dwarf.

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Does the H-R diagram show mass?

Mass and luminosity are proportional to either – intrinsically bright stars are also very massive, and intrinsically faint stars tend to be rather low mass. This tells us that the Main Sequence in the H-R Diagram is not only a luminosity sequence, but also a mass sequence!

Why are HR diagrams important to astronomers?

The Hertzsprung-Russell diagram (HR diagram) is one of the most important tools in the study of stellar evolution. This reveals the true power of the HR diagram – astronomers can know a star’s internal structure and evolutionary stage simply by determining its position in the diagram.

What unit do astronomers use to measure the masses of stars?

Astronomical unit of mass The solar mass ( M ☉), 1.98892×1030 kg, is a standard way to express mass in astronomy, used to describe the masses of other stars and galaxies. It is equal to the mass of the Sun, about 333000 times the mass of the Earth or 1 048 times the mass of Jupiter.

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What determines a star’s mass?

A star’s life cycle is determined by its mass. A star’s mass is determined by the amount of matter that is available in its nebula, the giant cloud of gas and dust from which it was born. Over time, the hydrogen gas in the nebula is pulled together by gravity and it begins to spin.

What is the most basic property of a star that determines its location on the main sequence its temperature and luminosity?

Mass
Mass is the most important properties of the main-sequence stars. It determine their luminosity, surface temperature, radius, and lifetime.

Why do higher mass stars live shorter lives on the main sequence than lower mass stars?

Massive stars live shorter lives than the common small stars because even though they have a larger amount of hydrogen for nuclear reactions, their rate of consuming their fuel is very much greater.

Why are about 90\% of the stars we observe on the main sequence?

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Being on the main sequence means that the star is converting hydrogen to helium in the core. Since stars are made mostly of hydrogen, this process takes approximately 90\% of a star’s life. Thus it makes sense that the 90\% of the stars observed at some particular time would be undergoing this process.

What does H-R diagram tell us about stars?

The Hertzsprung-Russell Diagram is a tool that shows relationships and differences between stars. The position of each dot on the diagram tells us two things about each star: its luminosity (or absolute magnitude) and its temperature. The vertical axis represents the star’s luminosity or absolute magnitude.

How does an H-R diagram make it clear that giant stars are larger than main sequence stars of the same temperature?

How does an H-R diagram make it clear that giant stars are larger than main-sequence stars of the same temperature? An H-R diagram shows main-sequence stars to be lower on the luminosity scale and the giant stars higher on the luminosity scale.