Is there a way to compare input and output energy of solar fusion to the input and output energy of man made fusion?

Question

The Livermore fusion experiment was said to be 2 megajoules of energy in and 3 megajoules of energy out. However upon closer inspection the facility used 300 megajoules of energy. So man made uses 300 megajoules and we get 3 megajoules. Can we say Input = 300, output =3.

Now the question is if it is possible to compare the sun to this process. We may need the sum of gravitational potential energy and we know the power output at the core is about 300 watts per cubic meter The gravitational potential binding energy is ≈3GM2/5R≈2.3×10^41 joules. The other problem is I don't know the average power output. The 300 watts is the core. The other assumption I make is to use the gravitational binding energy to be the activation energy for the proton-proton fusion.

I am wondering if the sun does better than our 300 to 3 megajoules.

Answer 1

Roughly $25,000$% for main sequence nuclear fusion.

The internal energy of the Sun is roughly $$U \sim \frac{3M_\odot k_B T}{m_p}\ , $$ where $T \sim 10^7$ K is an average interior temperature and $2M_\odot/m_p$ is the number of protons and electrons in the Sun, assuming it is ionised hydrogen.

If we take that as the "initial state" that we have to reach to maintain sustained fusion, then we know that the Sun will produce a solar luminosity of power for $\tau \sim 10^{10}$ years, almost entirely produced by nuclear fusion.

Thus in your terms, the efficiency of main sequence nuclear fusion is $$ E \sim \frac{L_\odot \tau m_p}{3M_\odot k_B T}\ .$$ Putting the numbers in, I get $E \sim 250$ or $25,000$%. This would be reduced by a factor of two if you consider the heat radiated during its initial gravitational contraction as "wasted".

Of course you then have a shorter giant phase that produces much more luminosity that would increase this by another order of magnitude at least.