Superluminous super nova output

Question

I was reading about how powerful supernova were and found out there are even bigger supernovae also called hyper nova. A large explosion was discovered in 2016 I believe (or was it 2017). I would like to know on a human scale how much power that is. Suppose an inventor produced an engine technology that has the output of the largest superluminous super nova to project a space shuttle. How fast would the space ship be projected forward? That is the output pushes air to project the space ship forward. What speed would it reach. Part of me wants to say faster than light. I imagine the ship will travel so fast it would disintegrate since matter cannot exceed the speed of light.

Answer 1

This puts us in the realm of silly numbers.

A supernova has enough energy to rip a massive star apart. Putting all that energy into one small rigid body isn't going to end well.

A hypernova gives off about $10^{46}$ Joules. We will need the formula for relatavistic kinetic energy $E=mc^2(\gamma-1)$ where $\gamma$ depends on velocity. The mass of the shuttle is about $2\times 10^6$ kg, and $c^2=9\times 10^{16}$

So $10^{46} = (2\times 10^6) \times (9\times 10^{16}) (\gamma - 1)$. Rearranging, $\gamma = 5.5\times10^{22}$.

In relativity $\gamma = 1/\sqrt{1-v^2/c^2}$ So even this massive amount of energy won't make the shuttle go faster than light. It will make it go at

99.99999999999999999999999999999999999999999998%

of the speed of light.

Answer 2

This comment will not answer about the speed of a rocket, because I don't know other factors involving. But this comment will give you energy scales, which you can work on later for the speed of a rocket. I cannot put this comment in the "comment" because it will be too long.

Hypernovae (a.k.a. supernovae Ic broad line (SNe Ic-BL) and superluminous supernovae (SLSNe) are core-collapse supernovae (CCSNe).

Typical CCSNe are believed to be delayed neutrino-driven explosions, where total explosion energy is $10^{53}$ erg. For typical SNe (i.e., not SNe Ic-BL nor SLSNe), only $\sim 1$% of the total explosion energy is converted into radiation, i.e., $\sim 10^{51}$ erg.

SNe Ic-BL and SLSNe radiate $\gtrsim 10^{51} - 10^{52}$ erg, more than those of the typical SNe. Because they are more energetic than $\sim 10^{51}$ erg predicted from typical CCSNe, their explosion mechanisms or energy sources are under debate. Currently, the power from a spinning down magnetar is the most favored candidate. The magnetar spin-down can supply $\sim 10^{52}$ erg, with peak $\lesssim 10^{45}$ erg/s.

Talking in term of power, i.e., luminosity, typical SNe has peaks UV/optical/NIR outputs $\lesssim 10^{43}$ erg/s. SNe Ic-BL are about the same scale, but they are more energetic because spectral evidence implies fast moving ejecta. SLSNe are $\gtrsim 10^{44}$ erg/s.

To illustrate how powerful these SNe are, we normally compare them to solar radiation $\sim 10^{33}$ erg/s.

Note that there are even more powerful explosions predicted such as pair-instability supernovae (PISNe). PISNe can supply $\sim 10^{53}$ erg. But because of very massive ejecta, the peak luminosity is predicted to be comparable to those of SLSNe, but with very long timescale. Some slow-evolving SLSNe are candidates for PISNe.

Hope this is helpful for you to use in calculating the speed of a rocket.