Unlocking the Mystery of Fire in Space

In summary: Supernova explosions).In summary, Stars generate energy through nuclear fusion - exactly like a large nuclear bomb. The core of the sun is so hot and under such pressure that hydrogen atoms fuse together to form helium, releasing huge quantities of energy. This process is not the same as fire, which requires oxygen. The sun and stars are essentially the same thing, with the only difference being that a sun is a star with planets around it. Scientists used to believe that the sun was a burning ball of fuel, but now we know it is sustained by nuclear fusion. This process only occurs in stars with a high amount of pressure and energy, causing hydrogen atoms to fuse and release energy. This process continues until
  • #1
Bubonic Plague
95
0
First let's work our way up.

1. For a fire to start, oxygen has to be present, yes?

2. There is no oxygen in space(vacuum), yes?

Since they are surrounded by vacuum, they have absolutely no way to obtain the oxygen to support combustion. Then how is it that the Sun and stars can burn?

Just a little question too, what is the difference between the Suns and the stars?
 
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  • #2
Stars don't "burn" the way fire does. You are right that fire requires oxygen. Stars generate energy through nuclear fusion - exactly like a large nuclear bomb. The core of the sun is so hot and under such pressure that hydrogen atoms fuse together to form helium, releasing huge quantities of energy, mostly in the form of visible light.

A sun and a star are pretty much the same thing. Typically (i think) a sun is a star with planets around it.
 
  • #3
"mostly in the form of visible light"...not really...this is a very small part of it...
 
  • #4
I have heared that before scientists understood nuclear fusion they believed that the sun must be a burning ball of some fuel such as coal. From this assumption they came to the conlusion that the sun could only have been in existence for so many years before all of this fuel was used up. Does anyone know what this value for the life of the sun was?
 
  • #5
I don't know when anyone ever calculated it as a ball of fire... but back in the 19th century, a common hypothesis was that it was producing light by gravitational contraction continually heating it up. Kelvin got an age of ~30 million years this way, about ~4 billion too low.
 
  • #6
Originally posted by damgo
I don't know when anyone ever calculated it as a ball of fire... but back in the 19th century, a common hypothesis was that it was producing light by gravitational contraction continually heating it up. Kelvin got an age of ~30 million years this way, about ~4 billion too low.

Thanks. My physics teacher must have made that bit up. I'm in year 11 at school (15 years old) so he's probably simplified it.
 
  • #7
Originally posted by Bubonic Plague
Then how is it that the Sun and stars can burn?

Like russ_watters said, stars are not burning fires. They are collections of matter that release energy from fusion reactions in the core.

Typically, they are huge collections of mostly hydrogen gas. This is all compressed together by gravity. In the core, the compression is so great that the hydrogen atoms fuse together to form helium. That releases some energy. That is the "fire". Like bogdan said, it's not all visible light.

This is for stars in their "main sequence" (active part of their "lifetime") of course. "Dead" stars (black holes, neutron stars, white dwarfs) have used up their fuel.

The kind of fire we are familiar with here on Earth is a different kind of energy release...it's the rapid oxidation (insertion of oxygen) of a combustable material (fuel). That rapid oxidation releases energy (the flames and heat).
 
  • #8
"mostly in the form of visible light"...not really...this is a very small part of it...
I always thought the radiation was centered on the visible spectrum in the blue range. Not sure though.
 
  • #9
The sun's photosphere is about 5,800K, which peaks at 500nm, which is in the yellow.
 
  • #10
Typically, they are huge collections of mostly hydrogen gas. This is all compressed together by gravity. In the core, the compression is so great that the hydrogen atoms fuse together to form helium. That releases some energy. That is the "fire". Like bogdan said, it's not all visible light.

Why hydrogen being compressed into helium? Why not let's say carbon being compressed into zinc or something like that?

How is it that hydrogen can change into another element helium under pressure? Can other elements do so too?

Why won't the heat like "set fire" to the rest of the stores of hydrogen, just like how the hydrogen in my test tube goes 'pop' when i insert a burning splinter?

Forgive me, I'm not trying to be difficult or anything. I just like to tresh things out, allows me to understand better.
 
  • #11
Greetings BP !

As you may be aware, hydrogen is the first
element - which means it has one electron in
the orbital around the atomic nuclei. The atomic nuclei
of hydrogen is one proton. Hydrogen has isotops -
one proton+one neutron = deutirium and
one proton+two neutrons = tritium.
The next element is helium (with two protons) and
so on - up Mendeleyev's Element's table.

Nuclear Fusion is a process when atomic nuclei
join together. For example - deuterium and
tritium fusion is a process during which
the two neuclei join together and become a helium
nuclei with one neutron and energy in the form of
EM wave radiation released.

Nuclear Fusion is only achived when we have
atomic nuclei at very high energies - like
the pressure and energies at the core of the Sun
(caused by gravity). The reason for this is that
the nuclei are both charged with a positive electric
charge (the protons) and like charges repel.
For the nuclei to fuse they have to have sufficient
energy to come close enough together, despite
the electric repulsion, for the nuclear forces to take
over and combine them.

Now, atomic nuclei that are fused have lesser energy
per proton/neutron than the separate nuclei
prior to the fusion reaction. Here, I'm not talking
about their kinetic energy, but about the energy of
the nuclear forces in the nuclei.

So, we have nuclear fusion in stars' cores.
Now, the release of energy from the reaction
is not happenning for all elements. The energy
gained from each fusion reaction decreases as heavier
elements are fused together into even heavier
elements. At a certain point - the 54th element = iron
(if my memory serves me right...), the reaction
no longer produces energy. This the reason
why in addition to hydrogen which comprises
about 90% of the matter in the Universe, helium and
iron are the most common elements (the iron is
produced from dying stars that run out of their
hydrogen supply, and the helium was created
with the hydrogen at about a 1 to 10 ratio after
the BB).

For "heavier" (more protons) elements the reaction
draws energy and the opposite reaction - Nuclear
Fission - which is atomic nuclei "falling apart" into
"lighter" nuclei, takes place.

Atomic power plants in fact harness the energy
released by Nuclear Fission.

More questions ?

"Does dice play God ?"

Live long and prosper.
 
  • #12
drag, I'm sure that's a good explanation, but far too long to read.

Why hydrogen being compressed into helium? Why not let's say carbon being compressed into zinc or something like that?
Because there is very little of anything else in the Sun. Its virtually all hydrogen. Hydrogen was the only element existing in the early universe. All others were created in stars.

How is it that hydrogen can change into another element helium under pressure?
It doesn't change, you just combine two atoms into one. I'm going to guess here that you're in 8th or 9th grade (from that experiment you mention), but you've learned a little about atoms, right? A hydrogen atom has 1 proton, a helium atom has two. Combine two hydrogen atoms and you get a helium atom (1+1=2). Simple. And that's why they call it "fusion" - you fuse two atoms together. It also just so happens that doing this releases vast quantities of energy.

Can other elements do so too?
Yes. Pretty much the whole lower half of the periodic table can all do this. Most of those reactions don't produce nearly the energy as hydrogen fusion though. Atoms that are too big won't create stable new atoms (there is a limit to the size of an atom).

Why won't the heat like "set fire" to the rest of the stores of hydrogen, just like how the hydrogen in my test tube goes 'pop' when i insert a burning splinter?
Great experiment. I remember doing it. As you correctly noted in your first post, there is no oxygen in space, so the sun can't explode in that way. And fusion requires a specific temperature/pressure combination to occur. The sun is in a naturally occurring balance. Some stars (larger than the sun) late in life will lose that balance and begin to shrink and cool, which increases the pressure eventually causing the fusion to accelerate and the sun to explode.
Forgive me, I'm not trying to be difficult or anything. I just like to tresh things out, allows me to understand better.
Thats the entire point of this forum.
 
  • #13
Bubonic - Great questions! And you've gotten some thorough replies. Looks like the only two questions not answered yet (or not correctly) are these two:

1) What's the difference between the "Sun" and stars?

Correct answer: "Sun" is the the proper name of one and only one star in the universe. Ours. No other star can properly be called "the Sun." That's it's name. Many stars have their own name, too, like Rigel, and Alpha Centauri.

"Star" is a generic term. I believe the Greek (?) translation is "Sol" which gives rise to words like our "Solar" system. Technically, other stars with planets around them are called "planetary systems" not "solar systems."

2) Jack asked: a) Was the Sun ever thought to be a burning ball of coal? b) how long would that have burned?

Answer: a) Yes. b) About 5,000 years.

Explanation: In the mid-1800s, during the Industrial Revolution, coal was the most common form of fuel used. As such, it became the next in the long line of suggested solar fuels. In 1848 a young German doctor named Julius Robert Mayer used the annual Solar energy output recently calculated by Herschel and Pouillet to estimate the likely lifetime of the Sun if it burned coal. The answer of 5,000 made it obvious that coal was not the solar fuel or the Sun would have burned up a long time ago.
 
  • #14
the two neuclei join together and become a helium
A hydrogen atom has 1 proton, a helium atom has two. Combine two hydrogen atoms and you get a helium atom (1+1=2). Simple. And that's why they call it "fusion" - you fuse two atoms together. It also just so happens that doing this releases vast quantities of energy.

In that case, why won't it like

*Numbers in the brackets are the proton numbers.

Possibility 1:
Hydrogen(1) and Hydrogen(1) combine to form Helium(2), then 2 Heliums(2) get compressed until they form Beryllium(4), then 2 Berylliums(4) get compressed to form Oxygen(8), then 2 Oxygens(8) get compressed to form Sulphur(16), so on and so forth?

or

Possibility 2:
Hydrogen(1) and Hydrogen(1) combine to form Helium(2), then maybe 1 Helium(2) and 1 Hydrogen(1) get compressed to form Lithium(3), the maybe 1 Beryllium(4)(an element that may form in the Sun as speculated in Possibility 1) and 1 Lithium(3) get compressed to to form Nitrogen(7), then maybe Nitrogen(7) gets compressed with Oxygen(8)(an element that may form in the Sun as speculated in Possibility 1) to form Phosphorus(15), so on and so forth?

What is the difference between fusion reactions and exothermic reactions?

I'm going to guess here that you're in 8th or 9th grade (from that experiment you mention), but you've learned a little about atoms, right?

I'm in Secondary 4, but i don't know how that translates to the Grade system. Yep!

Great experiment. I remember doing it.

When the teacher isn't looking, we'd have a 'pop' competition. We'll try and compete to see who can do the loudest 'pop'. Childish really, but when your're bored to death and driven up the wall by long school hours, even the most mediocre drop of fun does wonders.

I remember reading somewhere that things in space need to "push" something out from behind them to move, so how is it photons can move through space?

Bubonic - Great questions!

thx :smile:
 
  • #15
More good questions! :)
In that case, why won't it like...
It does! There is helium-helium fusion, and later the CNO cycle that go on. It just so happens that these reactions don't kick in until the star is very old and very compressed. Once you get to iron, fusion is no longer favorable: proton-proton repulsion (like charges and all that) stops the process. Some old stars have huge shells of iron because of this.
What is the difference between fusion reactions and exothermic reactions?
A fusion reaction is one where two atoms merge to create a bigger atom. An exothermic reaction is one that releases heat (energy) -- like many chemical reactions, which alter molecules but not individual atoms.
I remember reading somewhere that things in space need to "push" something out from behind them to move, so how is it photons can move through space?
Answer one: that's just to accelerate; things that are already moving keep moving without doing anything.
Answer two: they just do. Photons are one of those things that it's best not to ask many questions about. Until you are ready to learn quantum mechanics, and are used to being constantly confused, that is. :)
 
  • #17
It does! There is helium-helium fusion, and later the CNO cycle that go on. It just so happens that these reactions don't kick in until the star is very old and very compressed. Once you get to iron, fusion is no longer favorable: proton-proton repulsion (like charges and all that) stops the process. Some old stars have huge shells of iron because of this.

If both possibilites 1&2 happen, then won't the stars also have small amounts of elements like
Lithium, Beryllium, Boron, Fluorine, Neon, Sodium, Magnesium, Aluminium, Silicon, Phosphorus, Sulphur, Chlorine, Argon, Potassium, Calcium, Scandium, Titanium, Vanadium and Manganese?
(Basically all the elements from proton number 1 - 26)

Why does the cycle involve carbon, nitrogen and oxygen, why not any consecutive xyz element below iron? eg. silicon, phosphorus and sulphur.

Why does the cycle not involve more then 3 elements, wxyz? eg. boron, carbon, nitrogen and oxygen.

Answer two: they just do. Photons are one of those things that it's best not to ask many questions about. Until you are ready to learn quantum mechanics, and are used to being constantly confused, that is. :)

Try me. If you don't, then i will never be able to know if i am or am not ready.:smile:

For PP chains, nearing the end of the chain, why won't the 2 Helium-3s just fuse to form a Beryllium atom with 2 neutrons? Why must it form a Helium-4 and give out 2 Hydrogen atoms?

When will gamma rays be released? When will beta-rays be released? When will alpha-particles be released?

If Carbon-12 can just capture a proton and release gamma-rays, can other elements do so too? eg. Vanadium-51 capturing a proton and releasing gamma-rays.

In the CNO cycle, when
The mass-12 isotope of Carbon captures a proton and emits a gamma-ray, producing the mass-13 isotope of Nitrogen.
Why isn't the isotope called a mass-13 isotope of Carbon, why a mass-13 isotope of Nitrogen? What is the difference between a mass-13 isotope of Carbon and a mass-13 isotope of Nitrogen?

If there is a PP chain, proton-proton chain, why not a EE chain, electron-electron chain? Or a NN chain, neutron-neutron chain?

How does a catalyst work?
 
  • #18
The "heavy element" shells in a large star can be seen at:

http://csep10.phys.utk.edu/guidry/violence/supernovae.html

And heavy element formation has some info at:

http://aether.lbl.gov/www/tour/elements/stellar/stellar_a.html

Why isn't the isotope called a mass-13 isotope of Carbon, why a mass-13 isotope of Nitrogen? What is the difference between a mass-13 isotope of Carbon and a mass-13 isotope of Nitrogen?
Because Carbon has atomic number of 6 (protons), and the capture of another proton means it isn't Carbon anymore. Nitrogen has 7 protons, and an isotope of any element with 7 protons is a Nitrogen isotope, not Carbon. It is not the mass that defines the element, it is the number of protons. Each sucsessive reaction needed to create (fuse) to heavier elements requires a higher temperature, hence more mass and compression by gravity.
 
  • #19
Why does the cycle involve carbon, nitrogen and oxygen, why not any consecutive xyz element below iron? eg. silicon, phosphorus and sulphur...
Beats me exactly. Complicated reasons. Certain fusion processes are energetically more favorable than others. Some will occur often at stellar temperatures and pressures, some will not. Because of details of atomic structure, certain reactions will be easier than others, certain cycles are self-catalyzing. It's basically chemistry stuff. I'm sure there is some tome on stellar processes or chemistry with detailed explanations as to why those cycles are favored, but I don't know 'em. :)
Try me. If you don't, then i will never be able to know if i am or am not ready.:smile:
That was more a general statement on light... nothin specific here. You could also justify it by thinking of light as a wave; waves always travels at the propagation speed through some material.
How does a catalyst work?
Ask a chemist! :) Depends on the type of catalyst. The basic idea is that for a reaction you often need multiple particles to interact; a catalyst can kind of "stick" to the necessary particles and help bring them into close enough proximity to react. Or it may promote the formation of some intermediate compound/atom necessary for the reaction, and then get released at the end.
 
  • #20
Ask a chemist! :)

Well, it's in my syllabus, but the textbook gave a rather vague and unsatisfactory answer. So i tried asking my Chemistry teacher and he also said roughly the same stuff as the textbook, so i decided to ask this here, 'cause maybe someone here might be able to answer my question.
 
  • #21
If both possibilites 1&2 happen, then won't the stars also have small amounts of elements like
They do eventually - but very small amounts and long into the star's life. Hydrogen fusion is by far the 'best' so most of the fusion going on is of hydrogen.
How does a catalyst work?
A catalyst is a chemical that provides an intermediate reaction having the net effect of reducing the activation energy for the reaction you are trying to create. This speeds up the reaction and makes it more efficient.

Correct answer: "Sun" is the the proper name of one and only one star in the universe. Ours. No other star can properly be called "the Sun." That's it's name. Many stars have their own name, too, like Rigel, and Alpha Centauri.
No. www.dictionary.com definition 2: "A star that is the center of a planetary system." There is only one Sun, but there are many suns.
 
Last edited:
  • #22
A catalyst is a chemical that provides an intermediate reaction having the net effect of reducing the activation energy for the reaction you are trying to create. This speeds up the reaction and makes it more efficient.

Could you be more specific? What intermediate reaction?
 
  • #23
For example, in the dehydration of Ethanol (C2H5OH), Sulphuric Acid is added which first reacts to remove the OH to form C2H5(+) + H2O + HSO4(-), and then reacts again to recover the catalyst: C2H4 + H2O + H2SO4. The catalyst itself, though involved in the reaction, is not itself affected.
 

1. What is the current understanding of fire in space?

The current understanding of fire in space is still limited and constantly evolving. It is known that fire requires three elements to exist: fuel, oxygen, and heat. However, in the microgravity environment of space, these elements behave differently, making fire behavior unpredictable and difficult to control.

2. Can fire spread in space?

Yes, fire can spread in space, however, it does so differently than on Earth. In a microgravity environment, flames burn in a spherical shape rather than the typical teardrop shape seen on Earth. This makes the spread of fire harder to predict and control.

3. How do astronauts handle fire emergencies in space?

Astronauts are trained to handle fire emergencies in space by following strict safety protocols. These protocols include isolating the fire, cutting off its oxygen supply, and using fire extinguishers specifically designed for use in space. Astronauts also have access to emergency evacuation procedures if necessary.

4. What are the potential dangers of fire in space?

The potential dangers of fire in space include damage to equipment and spacecraft, as well as harm to astronauts. In a confined space environment, fire can spread quickly and produce toxic gases, which can be hazardous to astronauts' health. Fire can also disrupt critical systems, such as oxygen and communication, which are necessary for survival in space.

5. How are scientists working to understand and mitigate the risks of fire in space?

Scientists are conducting research and experiments in simulated microgravity environments to better understand how fire behaves in space. They are also developing new technologies, such as flame-retardant materials and advanced fire detection and suppression systems, to reduce the risk of fires in space. Additionally, strict safety protocols and extensive training for astronauts are in place to minimize the potential dangers of fire in space.

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