Santiago Torres scite author profile

NGC 6791 is a well studied open cluster that it is so close to us that can be imaged down to very faint luminosities. The main-sequence turn-off age ( approximately 8 Gyr) and the age derived from the termination of the white dwarf cooling sequence ( approximately 6 Gyr) are very different. One possible explanation is that as white dwarfs cool, one of the ashes of helium burning, (22)Ne, sinks in the deep interior of these stars. At lower temperatures, white dwarfs are expected to crystallize and phase separation of the main constituents of the core of a typical white dwarf ((12)C and (16)O) is expected to occur. This sequence of events is expected to introduce long delays in the cooling times, but has not hitherto been proven. Here we report that, as theoretically anticipated, physical separation processes occur in the cores of white dwarfs, resolving the age discrepancy for NGC 6791.

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Axions and the Cooling of White Dwarf Stars

Isern

Garcı́a–Berro

Torres

et al. 2008

ApJ

169

176

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White dwarfs are the end product of the lives of intermediate-and low-mass stars and their evolution is described as a simple cooling process. Recently, it has been possible to determine with an unprecedented precision their luminosity function, that is, the number of stars per unit volume and luminosity interval. We show here that the shape of the bright branch of this function is only sensitive to the averaged cooling rate of white dwarfs and we propose to use this property to check the possible existence of axions, a proposed but not yet detected weakly interacting particle. Our results indicate that the inclusion of the emission of axions in the evolutionary models of white dwarfs noticeably improves the agreement between the theoretical calculations and the observational white dwarf luminosity function. The best fit is obtained for meV, where is the massof the axion and is a free parameter. We also show that values larger than 10 meV are clearly excluded.2 cos b The existing theoretical and observational uncertainties do not yet allow the confirmation of the existence of axions, but our results clearly show that if their mass is of the order of a few meV, the white dwarf luminosity function is sensitive enough to detect their existence.

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Double Degenerate Mergers as Progenitors of High-Field Magnetic White Dwarfs

Garcı́a–Berro

Lorén–Aguilar

Aznar–Siguán

et al. 2012

ApJ

168

155

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High-field magnetic white dwarfs have been long suspected to be the result of stellar mergers. However, the nature of the coalescing stars and the precise mechanism that produces the magnetic field are still unknown. Here we show that the hot, convective, differentially rotating corona present in the outer layers of the remnant of the merger of two degenerate cores is able to produce magnetic fields of the required strength that do not decay for long timescales. We also show, using an state-of-the-art Monte Carlo simulator, that the expected number of high-field magnetic white dwarfs produced in this way is consistent with that found in the Solar neighborhood.

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Santiago Torres

A white dwarf cooling age of 8 Gyr for NGC 6791 from physical separation processes

Axions and the Cooling of White Dwarf Stars

Double Degenerate Mergers as Progenitors of High-Field Magnetic White Dwarfs

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