What kind of energy is released in a nuclear fusion reaction?

  • #1
freddie_mclair
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2
Hi, I have a fundamental (and maybe silly question) but I couldn't find a proper answer anywhere yet:

For example, for a nuclear fusion reaction of Tritium (T) and Deuterium (D), we get an alpha particle (##\alpha##) a neutron (n) and energy release due to the mass difference ##\Delta m=m_D+m_T-m_n-m_{\alpha}##, which means that: ##D + T \rightarrow \alpha + n + \mbox{ 17.6 MeV}## where ##\mbox{ 17.6 MeV}= \Delta m c^2 ##. These 17.6MeV get split by the neutron (14.1MeV) and the alpha particle (3.5MeV).

Now, my question is: what does it mean, to release energy? What kind of energy is this?
Thanks!
 
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  • #2
AFAIK, kinetic energy of the products and gamma rays.
 
  • #3
I agree with the kinetic energy of the products, but where are the gamma rays? What I understand is that the 17.6MeV are just split into the kinetic energy of the neutron by ##KE_n=\Delta m c^2 \frac{m_{\alpha}}{m_{\alpha}+m_n} ## and the rest to the alpha particle ##KE_{\alpha} = \Delta m c^2 - T_n ##.
 
  • #4
freddie_mclair said:
but where are the gamma rays
You posited a reaction without them.
 
  • #5
Vanadium 50 said:
You posited a reaction without them.
what would be the correct formulation then? and what amount of radiation would that be in terms of energy?
 
  • #6
I can't tell you what reaction you are thinking of. Just that A+B → C+D and A+B → C+D+γ are not the same process.
 
  • #7
For this specific reaction I mentioned it is just Deuterium + Tritium, there are no gamma rays, just an alpha particle and a neutron. But in several places it is indicated that, apart from the reaction products, there is also an energy release, like for example here.
 
  • #8
freddie_mclair said:
here are no gamma rays
freddie_mclair said:
but where are the gamma rays?

Do you see why people are confused?
 
  • #9
No, why? I asked Hill where are the gamma rays in the reaction I described.
 
  • #10
The reaction without gamma rays is the most common outcome, all the released energy becomes kinetic energy of the reaction products:
##D + T \rightarrow \alpha + n##

This is possible, too:
##D + T \rightarrow \alpha + n + \gamma##
Here the photon energy is variable and the rest will be kinetic energy of the alpha and n.
 
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  • #11
freddie_mclair said:
For this specific reaction I mentioned it is just Deuterium + Tritium, there are no gamma rays, just an alpha particle and a neutron. But in several places it is indicated that, apart from the reaction products, there is also an energy release, like for example here.
That's not a sufficiently detailed source for discussion. In this reaction, most of the energy is kinetic energy of the neutron. Hyperphysics has a little more detail:

http://hyperphysics.phy-astr.gsu.edu/hbase/NucEne/fusion.html
 
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  • #12
Thanks mfb, and PeroK.
To conclude: energy release in this specific fusion reaction can be totally kinetic (shared the n and ) or kinetic + EM radiation.
 
  • #13
The deuterium tritium reaction produces an alpha particle and a neutron. The energy of the reaction becomes the kinetic energy of the products. Gamma rays do not seem to be produced.
 
  • #14
sharmast said:
Gamma rays do not seem to be produced.
It's possible, as discussed, it's just rare. It even has a 16.75 MeV photon line corresponding to He-5 decaying to its ground state before emitting a neutron.
 
  • #15
When neutrons are emitted, nuclei of the surrounding material could capture a neutron and emit gamma rays. So even though the reaction itself may not emit gammas, you will get gamma rays "in real life" from any reaction with neutrons as a product.
 

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