RX J1856.5-3754: Bare Quark Star or Naked Neutron Star ?
Abstract
Recent Chandra observations have shown that the soft X-ray spectrum from the isolated neutron star RX J1856.5-3754 is featureless and best fitted by a blackbody, in contrast with the predictions of current neutron star atmospheric models. The star distance (~120-140 pc) implies a radiation radius of at most \~5-6 km, too small for any neutron star equation of state. Proposed explanations for such a small radius include a reduced X-ray emitting region (as a polar cap), or the presence of a more compact object, as a bare quark/strange star. However, both interpretations rely on the presumption that the quark star or the cap radiates a pure blackbody spectrum, and no justification for this assumption has been presented yet. Here we discuss an alternative possibility. Cool neutron stars (T < 106 K) endowed with high magnetic field (B > 1013 G) may suffer a phase transition in the outermost layers. The neutron star is then left bare of the gaseous atmosphere. We computed spectra from naked neutron stars with a surface Fe composition. Depending on B, we found that the 0.1-2 keV emission can be featureless and indistinguishable from a blackbody. Owing to the reduced surface emissivity, the star only radiates ~30-50 % of the blackbody power, thus that the size of the emitting region is larger than for a perfect planckian emitter. When applied to RX J1856.5-3754 our model accounts for the observed X-ray properties and solves the paradox of the small radius. The apparent star radius is ~10-12 km, consistent with equations of state of a neutron star. The optical emission of RX J1856.5-3754 may be explained by the presence a thin gaseous shell on the top of the Fe condensate.
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