Abstract
Abstract Based on recent Hubble Space Telescope (HST) observations in the far-UV and ground-based observations in optical bands, Pavlov and colleagues have revealed a thermal component in the spectrum of the old pulsar B0950+08 (spin-down age 17.5 Myr) and estimated a neutron star (NS) surface temperature of (1–3) × 105 K. Our new HST observations in the optical have allowed us to resolve the pulsar from a close-by galaxy and measure the optical fluxes more accurately. Using the newly measured fluxes and a new calibration of the HST’s far-UV detector, we fit the optical-UV pulsar’s spectrum with a model that consists of a nonthermal power law (f ν ∝ ν α ) and thermal blackbody components. We obtained the spectral slope α = −0.3 ± 0.3, considerably flatter than found from ground-based observations, and the best-fit temperature in the range of (6–12) × 104 K (as seen by a distant observer), depending on interstellar extinction and NS radius. The temperature is lower than reported previously, but still much higher than predicted by NS passive cooling scenarios for such an old pulsar. This means that some heating mechanisms operate in NSs, e.g., caused by the interaction of the faster-rotating neutron superfluid with the slower-rotating normal matter in the inner crust of the NS.
Highlights
Born very hot, neutron stars (NSs) lose their thermal energy via neutrino and photon emission
Based on recent Hubble Space Telescope (HST) observations in far-UV and groundbased observations in optical bands, Pavlov and colleagues have revealed a thermal component in the spectrum of the old pulsar B0950+08 and estimated a neutron star (NS) surface temperature of (1–3) × 105 K
Since FUV emission is unobservable from the ground, observational studies of heating mechanisms and thermal evolution of NSs can only be done with the Hubble Space Telescope (HST; Pavlov 1992)
Summary
Neutron stars (NSs) lose their thermal energy via neutrino and photon emission. Interaction of vortex lines of the faster rotating neutron superfluid with the slower rotating normal matter in the inner NS crust can heat the NS surface up to temperatures of a few times 105 K at an age of ∼ 10–100 Myr (Alpar et al 1984; Shibazaki & Lamb 1989; Larson & Link 1999; Gonzalez & Reisenegger 2010) This “frictional heating” mechanism can be explored in observations of thermal emission from old NSs. An optimal range for such observation is far-UV (FUV) because the thermal flux is higher there at the expected temperatures and because optical spectrum can be dominated by magnetospheric emission if the NS is a rotation-powered pulsar. Results of these observations and a new fit of the optical-FUV spectrum of B0950 are presented below
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