Dark Stars: a new look at the First Stars in the Universe

TL;DR

This paper explores the concept of Dark Stars powered by dark matter annihilation, proposing they are large, cool, and bright early stars that differ from standard models, potentially explaining supermassive black holes and cosmic background signals.

Contribution

It introduces the idea of Dark Stars as a new stellar phase powered by dark matter, with detailed modeling including various effects, and predicts their distinct properties and evolutionary outcomes.

Findings

Dark Stars are very large, massive, and luminous during accretion.

Dark Stars are cool and puffy, differing from standard Population III stars.

They can evolve into massive black holes, seeding supermassive black holes.

Abstract

We have proposed that the first phase of stellar evolution in the history of the Universe may be Dark Stars (DS), powered by dark matter heating rather than by nuclear fusion, and in this paper we examine the history of these DS. The power source is annihilation of Weakly Interacting Massive Particles (WIMPs) which are their own antiparticles. These WIMPs are the best motivated dark matter (DM) candidates and may be discovered by ongoing direct or indirect detection searches (e.g. FERMI /GLAST) or at the Large Hadron Collider at CERN. A new stellar phase results, powered by DM annihilation as long as there is DM fuel, from millions to billions of years. We build up the dark stars from the time DM heating becomes the dominant power source, accreting more and more matter onto them. We have included many new effects in the current study, including a variety of particle masses and accretion rates, nuclear burning, feedback mechanisms, and possible repopulation of DM density due to capture. Remarkably, we find that in all these cases, we obtain the same result: the first stars are very large, 500-1000 times as massive as the Sun; as well as puffy (radii 1-10 A.U.), bright ($10^6-10^7 L_\odot$), and cool ($T_{surf} < $10,000 K) during the accretion. These results differ markedly from the standard picture in the absence of DM heating. Hence DS should be observationally distinct from standard Pop III stars. In addition, DS avoid the (unobserved) element enrichment produced by the standard first stars. Once the dark matter fuel is exhausted, the DS becomes a heavy main sequence star; these stars eventually collapse to form massive black holes that may provide seeds for the supermassive black holes and intermediate black holes, and explain ARCADE data.