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Searching here for "mass gap" yields nothing yet. Penn State's Black hole or neutron star? LIGO-Virgo scientists find mystery object in 'mass gap' begins:

When the most massive stars die, they collapse under their own gravity and leave behind black holes; when stars that are a bit less massive than this die, they explode and leave behind dense, dead remnants of stars called neutron stars. For decades, astronomers have been puzzled by a gap in mass that lies between neutron stars and black holes: the heaviest known neutron star is no more than 2.5 times the mass of our sun, or 2.5 solar masses, and the lightest known black hole is about 5 solar masses. The question remained: Does anything lie in this so-called mass gap?

and later says:

"This is going to change how scientists talk about neutron stars and black holes," said co-author Patrick Brady, a professor at the University of Wisconsin, Milwaukee, and the LIGO Scientific Collaboration spokesperson. "The mass gap may in fact not exist at all but may have been due to limitations in observational capabilities. Time and more observations will tell."

The paper is the 23-June-2020 ApJ Letter GW190814: Gravitational Waves from the Coalescence of a 23 Solar Mass Black Hole with a 2.6 Solar Mass Compact Object which says:

GW190814's secondary mass lies in the hypothesized lower mass gap of 2.5–5 M (Bailyn et al. 1998; Özel et al. 2010; Farr et al. 2011; Özel et al. 2012) between known NSs and BHs.

Question: I'm curious about the use of the word "hypothesized" here. Is said hypothesis that there is a mass gap at all (versus there not being a mass gap) or is it that the should be a mass gap? In other words, is the observed lower mass gap strictly an observation, or is it something that at least some predict should be there?

there's another mass gap starting at about 45 M related to the upper limit of stellar-mass black holes

In the popular press for example, Forbes published Is LIGO About To Destroy The Theory Of A 'Mass Gap' Between Neutron Stars And Black Holes? but the word "theory" does not appear anywhere else in the article, so I assume there are no such theories.

However it does contain a really interesting statement:

The most recent microlensing studies take advantage of data from the ESA's Gaia mission, and find no evidence at all for this purported mass gap. Instead, they have uncovered a number of interesting microlensing candidates with exactly the masses you'd need to fill in this so-called gap.

Interesting that we go from "The Theory of a Mass Gap" in the beginning, to "this so-called gap" at the end.

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  • $\begingroup$ Though the question is long, it's quite possible that it can be answered in one or two sentences. $\endgroup$
    – uhoh
    Commented Jun 29, 2020 at 23:54
  • $\begingroup$ I've just asked How goes GAIA measure the mass of free microlensing black holes? $\endgroup$
    – uhoh
    Commented Jun 30, 2020 at 0:19
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    $\begingroup$ FWIW, the theorised upper mass gap is due to pair-instability supernovae totally disrupting the star. This diagram shows the various types of supernova remnants, but it only gives the mass of the progenitor star, not the remnant. $\endgroup$
    – PM 2Ring
    Commented Jun 30, 2020 at 18:40

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The "mass gap" is an observed deficit in the number of compact objects with mass between 2.5 and 5 solar masses.

The "mass gap" is/was not understood. Such objects may be rare because they are difficult to detect or because something about the supernova process leads to a bifurcation between the most massive neutron stars and the least massive black holes.

The Ozel et al. references in your question fill in the details. Also see https://astronomy.stackexchange.com/a/8280/2531

Update: There are now about a dozen candidate objects that might populate the mass gap. These objects are a mix of candidates where the masses have been estimated from gravitational wave observations, radial velocity and ellipsoidal mapping of binary companions or, in one case, a mass estimated from microlensing. These candidates are examined statistically by Da Sa et al. (2022), who conclude that the mass gap is unlikely to be an unfilled "desert" but is more likely to just represent a relative dearth of objects in this mass range.

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Perhaps neutron stars cant get beyond 2.5 solar masses because an inner shell of electrons or up and down quarks keeps radiation at the core from escaping and so causes expansion of the neutron ball. In stars with high metallicity metal atoms do this and expand and cool the star . It is interesting to note that above 40 solar masses (their maybe another mass gap at 45 ) low metal stars collapse directly to black holes but high metal stars form type 1b/c supernovae that can leave a neutron star. Metal could be limiting the mass of neutron star formed .

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  • $\begingroup$ As a ball of neutrons starts to form a neutron star it may be the case that while new neutrons flow into the ball electrons and protons are prevented from forming a shell that traps radiation and creates outward pressure. But in highly metallic supernovae the metals could be providing extra protons and electrons that assist shell formation and prevent large mass neutron star formation. $\endgroup$
    – user52394
    Commented Oct 3, 2023 at 8:59

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