670 research outputs found
Optical Observations of the Binary Millisecond Pulsars J2145-0750 and J0034-0534
We report on optical observations of the low-mass binary millisecond pulsar
systems J0034-0534 and J2145-0750. A faint (I=23.5) object was found to be
coincident with the timing position of PSR J2145-0750. While a galaxy or
distant main-sequence star cannot be ruled out, its magnitude is consistent
with an ancient white dwarf, as expected from evolutionary models. For PSR
J0034-0534 no objects were detected to a limiting magnitude of R=25.0,
suggesting that the white dwarf in this system is cold. Using white dwarf
cooling models, the limit on the magnitude of the PSR J0034-0534 companion
suggests that at birth the pulsar in this system may have rotated with a period
as short as 0.6 ms. These observations provide further evidence that the
magnetic fields of millisecond pulsars do not decay on time scales shorter than
1 Gyr.Comment: 6 pages, uuencoded, gz -9 compressed postscript, accepted by ApJ
A Study of Giant Pulses from PSR J1824-2452A
We have searched for microsecond bursts of emission from millisecond pulsars
in the globular cluster M28 using the Parkes radio telescope. We detected a
total of 27 giant pulses from the known emitter PSR J1824-2452A. At wavelengths
around 20 cm the giant pulses are scatter-broadened to widths of around 2
microseconds and follow power-law statistics. The pulses occur in two narrow
phase-windows which correlate in phase with X-ray emission and trail the peaks
of the integrated radio pulse-components. Notably, the integrated radio
emission at these phase windows has a steeper spectral index than other
emission. The giant pulses exhibit a high degree of polarization, with many
being 100% elliptically polarized. Their position angles appear random.
Although the integrated emission of PSR J1824-2452A is relatively stable for
the frequencies and bandwidths observed, the intensities of individual giant
pulses vary considerably across our bands. Two pulses were detected at both
2700 and 3500 MHz. The narrower of the two pulses is 20 ns wide at 3500 MHz. At
2700 MHz this pulse has an inferred brightness temperature at maximum of 5 x
10^37 K. Our observations suggest the giant pulses of PSR J1824-2452A are
generated in the same part of the magnetosphere as X-ray emission through a
different emission process to that of ordinary pulses.Comment: Accepted by Ap
A New Method for Obtaining Binary Pulsar Distances and its Implications for Tests of General Relativity
We demonstrate how measuring orbital period derivatives can lead to more
accurate distance estimates and transverse velocities for some nearby binary
pulsars. In many cases this method will estimate distances more accurately than
is possible by annual parallax, as the relative error decreases as t^-5/2.
Unfortunately, distance uncertainties limit the degree to which nearby
relativistic binary pulsars can be used for testing the general relativistic
prediction of orbital period decay to a few percent. Nevertheless, the measured
orbital period derivative of PSR B1534+12 agrees within the observational
uncertainties with that predicted by general relativity if the proper-motion
contribution is accounted for.Comment: 4 pages, latex, uuencoded compressed postscript + source, no figures,
uses aaspptwo.sty and dec.sty, accepted for publication in ApJL, omitted
reference now include
Control in the technical societies: a brief history
By the time control engineering emerged as a coherent body of knowledge and practice (during and just after WW2) professional engineering societies had existed for many decades. Since control engineering is an interdisciplinary branch of the profession, new sections devoted to control were quickly established within the various existing technical societies. In addition, some new bodies devoted specifically or primarily to control were established. This article, a revised version of a paper presented at the IEEE 2009 Conference on the History of Technical Societies, describes how control engineering as a distinct branch of engineering became represented in technical societies in a number of countries
Spin-down evolution and radio disappearance of the magnetar PSR J16224950
We report on 2.4 yr of radio timing measurements of the magnetar PSR
J16224950 using the Parkes telescope, between 2011 November and 2014 March.
During this period the torque on the neutron star (inferred from the rotational
frequency derivative) varied greatly, though much less erratically than in the
2 yr following its discovery in 2009. During the last year of our measurements
the frequency derivative decreased in magnitude monotonically by 20\%, to a
value of s, a factor of 8 smaller than when
discovered. The flux density continued to vary greatly during our monitoring
through 2014 March, reaching a relatively steady low level after late 2012. The
pulse profile varied secularly on a similar timescale as the flux density and
torque. A relatively rapid transition in all three properties is evident in
early 2013. After PSR J16224950 was detected in all of our 87 observations
up to 2014 March, we did not detect the magnetar in our resumed monitoring
starting in 2015 January and have not detected it in any of the 30 observations
done through 2016 September.Comment: 8 pages, 5 figures, submitted to Ap
Implications of a VLBI Distance to the Double Pulsar J0737-3039A/B
The double pulsar J0737-3039A/B is a unique system with which to test
gravitational theories in the strong-field regime. However, the accuracy of
such tests will be limited by knowledge of the distance and relative motion of
the system. Here we present very long baseline interferometry observations
which reveal that the distance to PSR J0737-3039A/B is 1150+220-160 pc, more
than double previous estimates, and confirm its low transverse velocity (~9
km/s). Combined with a decade of pulsar timing, these results will allow tests
of gravitational radiation emission theories at the 0.01% level, putting
stringent constraints on theories which predict dipolar gravitational
radiation. They also allow insight into the system's formation and the source
of its high-energy emission.Comment: 14 pages including supplementary online material, 1 figure. Accepted
by Science, published online in Science Express on February 5
(10.1126/science.1167969
On the Eccentricities and Merger Rates of Double Neutron Star Binaries and the Creation of "Double Supernovae"
We demonstrate that a natural consequence of an asymmetric kick imparted to
neutron stars at birth is that the majority of double neutron star binaries
should possess highly eccentric orbits. This leads to greatly accelerated
orbital decay, due to the enormous increase in the emission of gravitational
radiation at periastron as originally demonstrated by Peters (1964). A uniform
distribution of kick velocities constrained to the orbital plane would result
in ~24% of surviving binaries coalescing at least 10,000 times faster than an
unperturbed circular system. Even if the planar kick constraint is lifted, ~6%
of bound systems still coalesce this rapidly. In a non-negligible fraction of
cases it may even be possible that the system could coalesce within 10 years of
the final supernova, resulting in what we might term a "double supernova''. For
systems resembling the progenitor of PSR J0737-3039A, this number is as high as
\~9% (in the planar kick model). Whether the kick velocity distribution extends
to the range required to achieve this is still unclear. We do know that the
observed population of binary pulsars has a deficit of highly eccentric systems
at small orbital periods. In contrast, the long-period systems favour large
eccentricities, as expected. We argue that this is because the short-period
highly eccentric systems have already coalesced and are thus selected against
by pulsar surveys. This effect needs to be taken into account when using the
scale-factor method to estimate the coalescence rate of double neutron star
binaries. We therefore assert that the coalesence rate of such binaries is
underestimated by a factor of several.Comment: 7 pages, 6 figures, submitted to Ap
Millisecond Pulsar Velocities
We present improved timing parameters for 13 millisecond pulsars (MSPs)
including 9 new proper motion measurements. These new proper motions bring to
23 the number of MSPs with measured transverse velocities. In light of these
new results we present and compare the kinematic properties of MSPs with those
of ordinary pulsars. The mean transverse velocity of MSPs was found to be
85+/-13 km/s; a value consistent with most models for the origin and evolution
of MSPs and approximately a factor of four lower than that of ordinary pulsars.
We also find that, in contrast to young ordinary pulsars, the vast majority of
which are moving away from the Galactic plane, almost half of the MSPs are
moving towards the plane. This near isotropy would be expected of a population
that has reached dynamic equilibrium. Accurate measurements of MSP velocities
have allowed us to correct their measured spin-down rates for Doppler
acceleration effects, and thereby derive their intrinsic magnetic field
strengths and characteristic ages. We find that close to half of our sample of
MSPs have a characteristic age comparable to or greater than the age of the
Galaxy.Comment: 10 pages LaTeX including 2 LaTeX tables and 3 postscript figures;
submitted to MNRA
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