52 research outputs found
Neutrino emissivity under neutral kaon condensation
Neutrino emissivity from neutron star matter with neutral kaon condensate is
considered. It is shown that a new cooling channel is opened, and what is more,
all previously known channels acquire the greater emissivity reaching the level
of the direct URCA cycle in normal matter.Comment: 7 pages, 1 figure, to be published in Phys.Rev.C, revised version:
the sectioning changed and more discussion adde
Observational constraints on hyperons in neutron stars
The possibility that neutron stars may contain substantial hyperon
populations has important implications for neutron-star cooling and, through
bulk viscosity, the viability of the r-modes of accreting neutron stars as
sources of persistent gravitational waves. In conjunction with laboratory
measurements of hypernuclei, astronomical observations were used by Glendenning
and Moszkowski [Phys. Rev. Lett. 67, 2414 (1991)] to constrain the properties
of hyperonic equations of state within the framework of relativistic mean-field
theory. We revisit the problem, incorporating recent measurements of high
neutron-star masses and a gravitational redshift. We find that only the
stiffest of the relativistic hyperonic equations of state commonly used in the
literature is compatible with the redshift. However, it is possible to
construct stiffer equations of state within the same framework which produce
the observed redshift while satisfying the experimental constraints on
hypernuclei, and we do this. The stiffness parameter that most affects the
redshift is not the incompressibility but rather the hyperon coupling.
Nonrelativistic potential-based equations of state with hyperons are not
constrained by the redshift, primarily due to a smaller stellar radius.Comment: 8 pages, 5 figures; corrected error in equation three, corrected
minor typos, new tables of equations of state added; final version as
appearing in PR
Hadron Masses in Medium and Neutron Star Properties
We investigate the properties of the neutron star with relativistic mean
field models. We incorporate in the quantum hadrodynamics and in the
quark-meson coupling models a possible reduction of meson masses in nuclear
matter. The equation of state for neutron star matter is obtained and is
employed in Oppenheimer-Volkov equation to extract the maximum mass of the
stable neutron star. We find that the equation of state, the composition and
the properties of the neutron stars are sensitive to the values of the meson
masses in medium.Comment: 18 pages, 5 figures and 2 tables. To be published in EPJ
The mass of the neutron star in SMC X-1
We present new optical spectroscopy of the eclipsing binary pulsar Sk 160/SMC
X-1. From the He I absorption lines, taking heating corrections into account,
we determine the radial velocity semi-amplitude of Sk 160 to be 21.8 +/- 1.8
km/s. Assuming Sk 160 fills its Roche-lobe, the inclination angle of the system
is i=65.3 deg +/- 1.3 deg and in this case we obtain upper limits for the mass
of the neutron star as Mx = 1.21 +/- 0.10 Msolar and for Sk 160 as Mo= 16.6 +/-
0.4 Msolar. However if we assume that the inclination angle is i=90 deg, then
the ratio of the radius of Sk 160 to the radius of its Roche-lobe is beta =
0.79 +/- 0.02, and the lower limits for the masses of the two stars are Mx =
0.91 +/- 0.08 Msolar and Mo = 12.5 +/- 0.1 Msolar. We also show that the HeII
4686A emission line tracks the motion of the neutron star, but with a radial
velocity amplitude somewhat less than that of the neutron star itself. We
suggest that this emission may arise from a hotspot where material accreting
via Roche lobe overflow impacts the outer edge of an accretion disc.Comment: Accepted for publication by A&A. 4 Figures & Table 2 will only appear
in the on-line versio
Pulsations and orbital modulation of the intermediate polar 1WGA J1958.2+3232
We present optical photometry, spectroscopy and photopolarimetry, as well as
ASCA X-ray observations, of the recently discovered intermediate polar 1WGA
J1958.2+3232. Through the first detection of an optical beat frequency, we
confirm the previously tentative suggestion that the spin period of the white
dwarf is twice the X-ray and optical pulsation period, which we also confirm in
each case. We detect an orbital modulation in each of the U, B, V, R and I
bands for the first time, and suggest that the true orbital period is the -1d
alias of that previously suggested. We also confirm the presence of circular
polarization in this system, detecting a variable polarization which has
opposite signs in each of the B and R bands. The double peaked pulse profile
and oppositely signed polarization pulses suggest that 1WGA J1958.2+3232
accretes onto both magnetic poles via a disc which is truncated relatively
close to the white dwarf.Comment: All figures now included as postscrip
The radial velocity curve of HD153919 (4U1700-37) revisited
We have re-analysed all available high-resolution ultraviolet IUE spectra of
the high-mass X-ray binary HD153919/4U1700-37. The radial velocity
semi-amplitude of 20.6 +/- 1.0 km/s and orbital eccentricity of 0.22 +/- 0.04
agree very well with the values obtained earlier from optical spectra. They
disagree with earlier conclusions for the same data reduced by Heap & Corcoran
(1992) and by Stickland & Lloyd (1993).Comment: 6 pages, latex, figure included, Astronomy & Astrophysics, in pres
Neutron star properties and the equation of state of neutron-rich matter
We calculate total masses and radii of neutron stars (NS) for pure neutron
matter and nuclear matter in beta-equilibrium. We apply a relativistic nuclear
matter equation of state (EOS) derived from Dirac-Brueckner-Hartree-Fock (DBHF)
calculations. We use realistic nucleon-nucleon (NN) interactions defined in the
framework of the meson exchange potential models. Our results are compared with
other theoretical predictions and recent observational data. Suggestions for
further study are discussed.Comment: 13 pages, 9 figures, 1 table; Revised version, accepted for
publication in Physical Review
The mass of the neutron star in Vela X-1 and tidally induced non-radial oscillations in GP Vel
We report new radial velocity observations of GP Vel/HD77581, the optical
companion to the eclipsing X-ray pulsar Vela X-1. Using data spanning more than
two complete orbits of the system, we detect evidence for tidally induced
non-radial oscillations on the surface of GP Vel, apparent as peaks in the
power spectrum of the residuals to the radial velocity curve fit. By removing
the effect of these oscillations (to first order) and binning the radial
velocities, we have determined the semi-amplitude of the radial velocity curve
of GP Vel to be K_o=22.6+/-1.5 km/s. Given the accurately measured
semi-amplitude of the pulsar's orbit, the mass ratio of the system is
0.081+/-0.005. We are able to set upper and lower limits on the masses of the
component stars as follows. Assuming GP Vel fills its Roche lobe then the
inclination angle of the system, i=70.1+/-2.6 deg. In this case we obtain the
masses of the two stars as M_x=2.27 +/-0.17 M_sun for the neutron star and
M_o=27.9+/-1.3 M_sun for GP Vel. Conversely, assuming the inclination angle is
i=90 deg, the ratio of the radius of GP Vel to the radius of its Roche lobe is
beta=0.89+/-0.03 and the masses of the two stars are M_x=1.88+/-0.13 M_sun and
M_o=23.1+/-0.2 M_sun. A range of solutions between these two sets of limits is
also possible, corresponding to other combinations of i and beta. In addition,
we note that if the zero phase of the radial velocity curve is allowed as a
free parameter, rather than constrained by the X-ray ephemeris, a significantly
improved fit is obtained with an amplitude of 21.2+/-0.7 km/s and a phase shift
of 0.033+/-0.007 in true anomaly. The apparent shift in the zero phase of the
radial velocity curve may indicate the presence of an additional radial
velocity component at the orbital period.Comment: Accepted for publication in Astronomy & Astrophysic
Neutron star matter equation of state and gravitational wave emission
The EOS of strongly interacting matter at densities ten to fifteen orders of
magnitude larger than the typical density of terrestrial macroscopic objects
determines a number of neutron star properties, including the pattern of
gravitational waves emitted following the excitation of nonradial oscillation
modes. This paper reviews some of the approaches employed to model neutron star
matter, as well as the prospects for obtaining new insights from the
experimental study of gravitational waves emitted by neutron stars.Comment: 15 pages, 8 figures. To be published as a Brief Review in Modern
Physics Letters
- …