All main sequence stars (including the Sun) are powered by the fusion of hydrogen (H) into helium (He). Fusion of hydrogen requires temperatures of more than 10 million Kelvin. Above this temperature, the fusion rate is strongly dependent on temperature: a small increase in temperature results in a MUCH higher fusion rate. Because fusion is so temperature-sensitive, in a main-sequence star, fusion of hydrogen into helium occurs only in the hot, dense central core. All main sequence stars (including the Sun) are in hydrostatic equilibrium. That is, the inward force of gravity, which tends to compress the star, is balanced by the outward force due to the pressure. (For a review of hydrostatic equilibrium within the Sun, you can go to the lectures for Wednesday, January 8.) Show The observable properties of main sequence stars, such as their surface temperature, luminosity, and radius, are all dictated by the mass of the star. Thus, the main sequence is a MASS sequence. Consider taking a star and increasing its mass by pouring a little extra hydrogen gas onto it.
L = M3.5 where L is the luminosity of a main sequence star (in units of the Sun's luminosity) and M is the mass of a main sequence star (in units of the Sun's mass). For instance, a star with a mass of M = 2 Msun will have a luminosity of L = 23.5 = 11 Lsun (2) Fusion is stabilized by a natural pressure-temperature thermostat.Also humans cannot manufacture stars, they have figured out how to make bombs powered by nuclear fusion. In a fusion bomb, the fusion reactions last for only a tiny fraction of a second. In the Sun, fusion reactions have been going on for 4.6 billion years. This leads to the question:Why doesn't the Sun explode like a hydrogen bomb? The main reason why the Sun doesn't blow itself to bits in a runaway fusion reaction is that the physical relation among the pressure, temperature, and fusion rate creates a natural thermostat which keeps the center of the Sun (and the center of any other main sequence star) at a steady temperature. A thermostat is any feedback device which acts to keep the temperature of a system nearly constant. (If you've ever been curious how the thermostat in a home heating system works, you can go to the ``How Stuff Works'' web site.) Basically, when the temperature drops too low, the thermostat increases the rate at which heat is generated. When the temperature rises too high, the thermostat decreases the rate at which heat is generated. How does a star's natural thermostat work? Consider what would happen if you increased the fusion rate in a star's core:
Now consider what would happen if you decreased the fusion rate in a star's core:
(3) High-mass main sequence stars have shorter lifetimes than low-mass stars.A star's ``lifetime'' on the main sequence is how long it takes to use up the hydrogen in its core. The luminosity (L) of a star is a measure of rapidly it is using up its hydrogen. The mass (M) of a star is a measure of how much fuel it has. The time it takes to use up the fuel is proportional to its amount of fuel (M) divided by the rate of fuel consumption (L). Expressed more mathematically,t = M/L , where t = lifetime (in units of the Sun's lifetime) M = mass (in units of the Sun's mass) L = luminosity (in units of the Sun's luminosity. Note that since L = M3.5, The Sun will not be able to convert all its mass into helium. For one thing, the Sun was not made of pure hydrogen when it formed 4.6 billion years ago. For another, only the hydrogen in the Sun's core is able to be fused; the hydrogen in the Sun's outer layers is at too cool a temperature to fuse. Mathematical models of the Sun's interior lead to the conclusion that the Sun will run out of hydrogen in its core after a lifetime of tsun = 10 billion years. (Thus, the Sun is middle-aged, nearly halfway through its main sequence lifetime.) Consider a star of mass M = 0.2 Msun. Its lifetime will be Similar calculations can be done for stars of other masses. Very hot and luminous stars (of spectral type `O' and `B') have short lifetimes; if you see an `O' or `B' main sequence star, you know it must be much younger than the Sun. However, cool and dim stars (of spectral type `K' or `M') have long lifetimes; if you see a `K' or `M' main sequence star, it might be older than the Sun. (On the other hand, it might be younger.) Do high mass stars spend more time on the main sequence?Lifespans for main sequence stars have a vast range. Whilst our Sun will spend 10 billion years on the main sequence, a high-mass, ten solar-mass (10MSun) star will only last 20 million years (2.0× 107 years) on the main sequence. A star with a only half the mass of Sun can spend 80 billion years on the main sequence.
Do main sequence stars live longer?Our Sun has been a main sequence star for about 5 billion years. As a medium-sized star, it will continue to shine for about 5 billion more years. Most stars are on the main sequence.
Do higher mass stars last longer?The more fuel, the more supply of material for fusion the star has and so the longer the star can live. The fuel is hydrogen atoms and the number of hydrogen atoms is greater in high mass stars than it is in lower mass stars. Thus, the higher the mass of the star, the longer its lifetime can be.
Which have longer main sequence lifetimes low or high mass stars Why?A main sequence star is powered by fusion of hydrogen into helium in its core. Fusion is stabilized by a natural pressure-temperature thermostat. High-mass main sequence stars have shorter lifetimes than low-mass main sequence stars.
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Do high mass stars live longer on the Main Sequence?
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