Effects of Bound Diprotons and Enhanced Nuclear Reaction Rates on Stellar Evolution

TL;DR

This paper investigates how stable diprotons and increased nuclear reaction rates influence stellar evolution, revealing that stars can still form and sustain life-like processes even with these altered nuclear properties.

Contribution

It demonstrates that the existence of bound diprotons and enhanced nuclear reaction rates have modest effects on stellar properties and evolution, expanding the understanding of possible universes with different nuclear physics.

Findings

Stars are somewhat brighter with stable diprotons.

Stellar lifetimes can extend to trillions of years.

Small, degenerate objects can act as stars with high luminosity.

Abstract

Deuterium represents the only bound isotope in the universe with atomic mass number $A=2$. Motivated by the possibility of other universes, where the strong force could be stronger, this paper considers the effects of bound diprotons and dineutrons on stars. We find that the existence of additional stable nuclei with $A=2$ has relatively modest effects on the universe. Previous work indicates that Big Bang Nucleosynthesis (BBN) produces more deuterium, but does not lead to catastrophic heavy element production. This paper revisits BBN considerations and confirms that the universe is left with an ample supply of hydrogen and other light nuclei for typical cosmological parameters. Using the $MESA$ numerical package, we carry out stellar evolution calculations for universes with stable diprotons, with nuclear cross sections enhanced by large factors $X$. This work focuses on $X=10^{15}-10^{18}$, but explores the wider range $X$ = $10^{-3}-10^{18}$. For a given stellar mass, the presence of stable diprotons leads to somewhat brighter stars, with the radii and photospheric temperatures roughly comparable to thoese of red giants. The central temperature decreases from the characteristic value of $T_c\approx1.5\times10^7$ K for hydrogen burning down to the value of $T_c\approx10^6$ K characteristic of deuterium burning. The stellar lifetimes are smaller for a given mass, but with the extended possible mass range, the smallest stars live for trillions of years, far longer than the current cosmic age. Finally, the enhanced cross sections allow for small, partially degenerate objects with mass $M_\ast=1-10M_J$ to produce significant steady-state luminosity and thereby function as stars.