* Astronomy

Title: Primordial black holes from monopoles connected by strings
Authors: Tomohiro Matsuda
(Version v5)

Primordial black holes (PBHs) are known to be produced from collapsing cosmic defects such as domain walls and strings. In this paper we show how PBHs are produced in monopole-string networks.

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Black holes have been aggravating physicists for some time.
The mere suggestion that stars could gravitationally collapse triggered one of the most bitter physics feuds of the last century. Eventual Nobel-Prize winner Subrahmanyan Chandrasekhar held that they could, but the United Kingdom's then-eminent Arthur Eddington so strongly disagreed that Chandrasekhar changed his area of research to escape the dispute.
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A team of astronomers using the Canada-France-Hawaii Telescope on Mauna Kea has found the most distant -- and therefore oldest -- black hole so far discovered in the universe.
The team announced their find yesterday at the annual conference of the Canadian Astronomical Society in Ontario.

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In a study of more than 1,000 void galaxies, using data from the Sloan Digital Sky Survey, astronomers from Drexel and Widener Universities found that the growth of monster black holes with masses millions to hundreds of millions times that of our sun are found where galaxies are sparse and interact very little with each other.
These findings shed light on the black hole formation and evolution process by showing that the environment does affect how quickly galaxies proceed through their evolutionary cycle.
The simple presence of growing supermassive black holes in the rural outposts of the universe challenges the current theoretical models of galaxy and structure formation and evolution, explained Anca Constantin of Drexel University, lead author of the paper delivered today at the American Astronomical Society meeting in Honolulu.

Interestingly, we see actively accreting galactic black holes in all phases of evolution in these sparse regions. This means that the black hole growth process is quite similar in what could be compared to the most reclusive countrysides and in the crowded urban regions of the universe - Anca Constantin.

The void regions, nearly empty, three-dimensional fields hundreds of millions of light-years across, fill half of the universe. Only five percent of all galaxies live in these bubble-like regions. The other 95 percent of galaxies live together in communities, crowded into clusters, filaments, and walls: the cities and suburbs of the universe.
Studying a 700-million light year wide slice of the universe, the researchers found that spectra of the centres of void galaxies show hot gases ionised by light emitted from matter swirling around supermassive black holes.

 The more isolated accreting black holes are however not as active as the ones in more populous environs, and the fuel seems less available for accretion in voids than in urban galaxies - Anca Constantin.

 This is strange given that these reclusive galaxies are forming stars at higher rates than their counterparts in denser regions; this means there is plenty of fuel, but it is not efficiently channelled toward the central engine - Astronomer Fiona Hoyle, a member of the discovery team from Widener University

Star formation requires the presence of large amounts of gas and so there must be more than enough gas in the void galaxies if their star forming rates are high. The smaller accretion rate observed in void galaxies means that this gas is just not getting down to the nuclear region where accretion happens. Interactions with other galaxies are thought to disturb the gravitational potential, which drives some gas into the nuclear region.

These interactions are not as frequent in voids, so the 'feeding' of the black hole is slower.

These rugged individuals in voids do not need to compete with their neighbours for fuel, and their life cycle is rarely bothered. In contrast, life is more hectic in crowded regions where galaxy interactions are frequent. As a consequence, galaxies are either stripped of their gas or more material is funnelled toward the central engine. This means that there are many more chances the accretion onto black holes is enhanced or turned off in more 'urban environments.'

On the other hand, the void galaxy black holes might take longer to reach the mature, low accretion rate phase, which might explain why the most massive, lazy black holes are less frequent in voids - Anca Constantin.

The data studied by Constantin may also show that active black holes appear to be more common in voids but only among small (less massive) galaxies, while less common among massive galaxies. This is also a clue that the life cycle of black hole growth in voids is delayed or slower compared to that in denser regions.
Discovery team member Michael Vogeley of Drexel said that it's particularly puzzling that the few most massive and sluggishly accreting void systems live within the most secluded sub-regions, while their "urban" counterparts are found in the most populated neighbourhoods.

Perhaps because massive objects are prone to accreting material around them, such a 'cleaning' process would contribute to emptying the already rarefied neighbouring space in voids. This would leave little or insufficient material for future formation of other nearby massive, bright galaxies  - Michael Vogeley.

In contrast, within galaxy clusters where there is plenty of stuff around, accretion of surrounding material would make a small difference.
These results have been possible only because of the sheer number of void regions and void galaxies found in the SDSS-II data, the most ambitious survey of the universe ever undertaken, the researchers said. The sample used in the analysis announced today comprises more than 1,000 void galaxies. Previously, the black hole accretion in centres of void galaxies had been studied in only a handful of objects contained in only one void region, the Bootes Void.

The results are described in the paper "Active Galactic Nuclei in Void Regions" submitted for publication in The Astrophysical Journal.

Source: Drexel University