29 research outputs found
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Optical Identification of 664 Ohio Sources using Accurate Radio and Optical Positions Measured by Texas Interferometers
Astronom
Spin state and moment of inertia of Venus
Fundamental properties of the planet Venus, such as its internal mass
distribution and variations in length of day, have remained unknown. We used
Earth-based observations of radar speckles tied to the rotation of Venus
obtained in 2006-2020 to measure its spin axis orientation, spin precession
rate, moment of inertia, and length-of-day variations. Venus is tilted by
2.6392 0.0008 degrees () with respect to its orbital plane. The
spin axis precesses at a rate of 44.58 3.3 arcseconds per year
(), which gives a normalized moment of inertia of 0.337 0.024
and yields a rough estimate of the size of the core. The average sidereal day
on Venus in the 2006-2020 interval is 243.0226 0.0013 Earth days
(). The spin period of the solid planet exhibits variations of 61 ppm
(20 minutes) with a possible diurnal or semidiurnal forcing. The
length-of-day variations imply that changes in atmospheric angular momentum of
at least 4% are transferred to the solid planet.Comment: 20 pages, 7 figures, supplementary information. Submitted to Nature
Astronomy on October 14, 202
Interstellar Scintillation Observations of 146 Extragalactic Radio Sources
From 1979--1996 the Green Bank Interferometer was used by the Naval Research
Laboratory to monitor the flux density from 146 compact radio sources at
frequencies near 2 and 8 GHz. We filter the ``light curves'' to separate
intrinsic variations on times of a year or more from more rapid interstellar
scintilation (ISS) on times of 5--50 d. Whereas the intrinsic variation at 2
GHz is similar to that at 8 GHz (though diminished in amplitude), the ISS
variation is much stronger at 2 than at 8 GHz. We characterize the ISS
variation by an rms amplitude and a timescale and examine the statistics of
these parameters for the 121 sources with significant ISS at 2 GHz. We model
the scintillations using the NE2001 Galactic electron model assuming the
sources are brightness-limited.
We find the observed rms amplitude to be in general agreement with the model,
provided that the compact components of the sources have about 50% of their
flux density in a component with maximum brightness temperatures
--K. Thus our results are consistent with cm-wavelength VLBI
studies of compact AGNs, in that the maximum brightness temperatures found are
consistent with the inverse synchrotron limit at K, boosted
in jet configurations by Doppler factors up to about 20. The average of the
observed 2 GHz ISS timescales is in reasonable agreement with the model at
Galactic latitudes above about 10\de. At lower latitudes the observed
timescales are too fast, suggesting that the transverse plasma velocity
increases more than expected beyond about 1 kpc.Comment: 32 pages, 16 figures. Submitted to Ap
Measuring and Correcting Wind-Induced Pointing Errors of the Green Bank Telescope Using an Optical Quadrant Detector
Wind-induced pointing errors are a serious concern for large-aperture
high-frequency radio telescopes. In this paper, we describe the implementation
of an optical quadrant detector instrument that can detect and provide a
correction signal for wind-induced pointing errors on the 100m diameter Green
Bank Telescope (GBT). The instrument was calibrated using a combination of
astronomical measurements and metrology. We find that the main wind-induced
pointing errors on time scales of minutes are caused by the feedarm being blown
along the direction of the wind vector. We also find that wind-induced
structural excitation is virtually non-existent. We have implemented offline
software to apply pointing corrections to the data from imaging instruments
such as the MUSTANG 3.3 mm bolometer array, which can recover ~70% of
sensitivity lost due to wind-induced pointing errors. We have also performed
preliminary tests that show great promise for correcting these pointing errors
in real-time using the telescope's subreflector servo system in combination
with the quadrant detector signal.Comment: 17 pages, 11 figures; accepted for publication in PAS
Mercury's Moment of Inertia from Spin and Gravity Data
Earth-based radar observations of the spin state of Mercury at 35 epochs between 2002 and 2012 reveal that its spin axis is tilted by (2.04 plus or minus 0.08) arc min with respect to the orbit normal. The direction of the tilt suggests that Mercury is in or near a Cassini state. Observed rotation rate variations clearly exhibit an 88-day libration pattern which is due to solar gravitational torques acting on the asymmetrically shaped planet. The amplitude of the forced libration, (38.5 plus or minus 1.6) arc sec, corresponds to a longitudinal displacement of ∼450 m at the equator. Combining these measurements of the spin properties with second-degree gravitational harmonics (Smith et al., 2012) provides an estimate of the polar moment of inertia of MercuryC/MR2 = 0.346 plus or minus 0.014, where M and R are Mercury's mass and radius. The fraction of the moment that corresponds to the outer librating shell, which can be used to estimate the size of the core, is Cm/C = 0.431 plus or minus 0.025
The fading of Cassiopeia A, and improved models for the absolute spectrum of primary radio calibration sources
Based on five years of observations with the 40-foot telescope at Green Bank
Observatory (GBO), Reichart & Stephens (2000) found that the radio source
Cassiopeia A had either faded more slowly between the mid-1970s and late 1990s
than Baars et al. (1977) had found it to be fading between the late 1940s and
mid-1970s, or that it had rebrightened and then resumed fading sometime between
the mid-1970s and mid-1990s, in L band (1.4 GHz). Here, we present 15
additional years of observations of Cas A and Cyg A with the 40-foot in L band,
and three and a half additional years of observations of Cas A, Cyg A, Tau A,
and Vir A with GBO's recently refurbished 20-meter telescope in L and X (9 GHz)
bands. We also present a more sophisticated analysis of the 40-foot data, and a
reanalysis of the Baars et al. (1977) data, which reveals small, but
non-negligible differences. We find that overall, between the late 1950s and
late 2010s, Cas A faded at an average rate of %/yr in L band,
consistent with Reichart & Stephens (2000). However, we also find, at the
6.3 credible level, that it did not fade at a constant rate. Rather,
Cas A faded at a faster rate through at least the late 1960s, rebrightened (or
at least faded at a much slower rate), and then resumed fading at a similarly
fast rate by, at most, the late 1990s. Given these differences from the
original Baars et al. (1977) analysis, and given the importance of their fitted
spectral and temporal models for flux-density calibration in radio astronomy,
we update and improve on these models for all four of these radio sources. In
doing so, we additionally find that Tau A is fading at a rate of
%/yr in L band.Comment: 17 pages, 12 figures, accepted to MNRA
Holographic Measurement and Improvement of the Green Bank Telescope Surface
We describe the successful design, implementation, and operation of a 12 GHz
holography system installed on the Robert C. Byrd Green Bank Telescope (GBT).
We have used a geostationary satellite beacon to construct high-resolution
holographic images of the telescope mirror surface irregularities. These images
have allowed us to infer and apply improved position offsets for the 2209
actuators which control the active surface of the primary mirror, thereby
achieving a dramatic reduction in the total surface error (from 390 microns to
~240 microns, rms). We have also performed manual adjustments of the corner
offsets for a few panels. The expected improvement in the radiometric aperture
efficiency has been rigorously modeled and confirmed at 43 GHz and 90 GHz. The
improvement in the telescope beam pattern has also been measured at 11.7 GHz
with greater than 60 dB of dynamic range. Symmetric features in the beam
pattern have emerged which are consistent with a repetitive pattern in the
aperture due to systematic panel distortions. By computing average images for
each tier of panels from the holography images, we confirm that the magnitude
and direction of the panel distortions, in response to the combination of
gravity and thermal gradients, are in general agreement with finite-element
model predictions. The holography system is now fully integrated into the GBT
control system, and by enabling the telescope staff to monitor the health of
the individual actuators, it continues to be an essential tool to support
high-frequency observations.Comment: Accepted for publication in PASP. Contains 28 pages with 2 tables and
9 figures (several at reduced quality). The full resolution version is
available at http://wwwlocal.gb.nrao.edu/ptcs/papers/Hunter2011/gbtholo.ps.gz
(34MB gzip file unpacks to 134MB postscript
Overview of the coordinated ground-based observations of Titan during the Huygens mission
Coordinated ground-based observations of Titan were performed around or during the Huygens atmospheric probe mission at Titan on 14 January 2005, connecting the momentary in situ observations by the probe with the synoptic coverage provided by continuing ground-based programs. These observations consisted of three different categories: (1) radio telescope tracking of the Huygens signal at 2040 MHz, (2) observations of the atmosphere and surface of Titan, and (3) attempts to observe radiation emitted during the Huygens Probe entry into Titan's atmosphere. The Probe radio signal was successfully acquired by a network of terrestrial telescopes, recovering a vertical profile of wind speed in Titan's atmosphere from 140 km altitude down to the surface. Ground-based observations brought new information on atmosphere and surface properties of the largest Satumian moon. No positive detection of phenomena associated with the Probe entry was reported. This paper reviews all these measurements and highlights the achieved results. The ground-based observations, both radio and optical, are of fundamental imnortance for the interpretatinn of results from the Huygens mission
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Spin state and moment of inertia of Venus
Fundamental properties of the planet Venus, such as its internal mass
distribution and variations in length of day, have remained unknown. We used
Earth-based observations of radar speckles tied to the rotation of Venus
obtained in 2006-2020 to measure its spin axis orientation, spin precession
rate, moment of inertia, and length-of-day variations. Venus is tilted by
2.6392 0.0008 degrees () with respect to its orbital plane. The
spin axis precesses at a rate of 44.58 3.3 arcseconds per year
(), which gives a normalized moment of inertia of 0.337 0.024
and yields a rough estimate of the size of the core. The average sidereal day
on Venus in the 2006-2020 interval is 243.0226 0.0013 Earth days
(). The spin period of the solid planet exhibits variations of 61 ppm
(20 minutes) with a possible diurnal or semidiurnal forcing. The
length-of-day variations imply that changes in atmospheric angular momentum of
at least 4% are transferred to the solid planet