Microlenses with typical stellar masses (a few M⊙) have traditionally been disregarded as potential sources of gravitational lensing effects at LIGO/Virgo frequencies, since the time delays are often ...much smaller than the inverse of the frequencies probed by LIGO/Virgo, resulting in negligible interference effects at LIGO/Virgo frequencies. While this is true for isolated microlenses in this mass regime, we show how, under certain circumstances and for realistic scenarios, a population of microlenses (for instance stars and remnants from a galaxy halo or from the intracluster medium) embedded in a macromodel potential (galaxy or cluster) can conspire together to produce time delays of order one millisecond, which would produce significant interference distortions in the observed strains. At sufficiently large magnification factors (of several hundred), microlensing effects should be common in gravitationally lensed gravitational waves. We explored the regime where the predicted signal falls in the frequency range probed by LIGO/Virgo. We find that stellar mass microlenses, permeating the lens plane, and near critical curves, can introduce interference distortions in strongly lensed gravitational waves. Lensed events with negative parity, or saddle points (which have never before been studied in the context of gravitational waves), and that take place near caustics of macromodels, are more likely to produce measurable interference effects at LIGO/Virgo frequencies. This is the first study that explores the effect of a realistic population of microlenses, including a macromodel, on strongly lensed gravitational waves.
Abstract
Microwave kinetic inductance detectors (MKIDs) are typically readout using custom high-speed electronics and firmware, a challenging and time-intensive undertaking. We have developed a ...readout system for these devices using a software defined radio (SDR), a software implementation of radiofrequency signal processing. The SDR allows use of pre-existing software libraries and minimizes specialized firmware coding, a significant reduction in effort. We customized our SDR to readout mm and optical band MKIDs with resonant frequencies of 1.8-2 GHz and 2-2.2 GHz respectively. We used this readout system to measure the sensitivity of our MKIDs devices to visible light. We show that SDRs are a good candidate for small pixel count MKIDs readout systems, and make recommendations for readout systems for larger Pixel count arrays.
We have searched the first-year Wilkinson Microwave Anisotropy Probe (WMAP) W-band CMB anisotropy map for evidence of cosmic strings. We set a limit on the dimensionless string parameter d of d = ...8pGkgb < 2.9 x 10 super(-5) for the statistical search for a significant number of strings in the map. We also set a limit using the uniform-distribution-of-strings model in the WMAP data with d = 8pGkgb < 7.3 x 10 super(-5) at the 95% confidence level (CL). The pattern search technique we developed in this paper set a limit d = 8pGkgb < 1.5 x 10 super(-5) at the 95% CL, which corresponds to a limit on the symmetry-breaking energy scale of 10 super(16) GeV/ .
Observations in all electromagnetic bands show that many supernova remnants (SNRs) have a very aspherical shape. This can be the result of asymmetries in the supernova explosion or a clumpy ...circumstellar medium. We study the generation of inhomogeneities and the mixing of elements arising from these two sources in multidimensional hydrodynamic simulations of the propagation of a supernova blast wave into a cloudy environment. We model a specific SNR, Vela Jr (RX J0852.0−4622). By comparing our results with recent observations, we can constrain the properties of the explosion. We find that a very energetic explosion of several 1051 erg occurring roughly about 800 years ago is consistent with the shape and emission of the SNR, as well as a supernova with an energy closer to the canonical value of 1051 erg a few thousand years ago.