2008.01080
Synergies between ground-based and space-based observations in the solar system and beyond
Kofman, et al
Telescope and detector developments continuously enable deeper and more detailed studies of astronomical objects. Larger collecting areas, improvement in dispersion and detector techniques, and higher sensitivities allow detection of more molecules in a single observation, at lower abundances, resulting in better constraints of the targets physical and chemical conditions. Improvements on current telescopes, and not to mention future observatories, both in space and on the ground, will continue this trend, ever improving our understanding of the Universe. Planetary exploration missions carry instrumentation to unexplored areas, and reveal details impossible to observe from the Earth by performing in-situ measurements. Space based observatories allow observations of object at wavelength ranges absorbed by the Earths atmosphere. The depth of understanding from all of these studies can be greatly enhanced by combining observations: ground-based and space-based, low-resolution and high-resolution, local and global-scale, similar observations over a broader or different spectra range, or by providing temporal information through follow-ups. Combined observations provide context and a broader scope of the studied object, and in this white paper, we outline a number of studies where observations are synergistically applied to increase the scientific value of both datasets. Examples include atmospheric studies of Venus, Mars, Titan, comets, Jupiter, as well as more specific cases describing synergistic studies in the Juno mission, and ground-based radar studies for near Earth objects. The examples aim to serve as inspiration for future synergistic observations, and recommendations are made based on the lessons learned from these examples.
2008.01082
Fundamental Physics using the temporal gravitational wave background
Mukhurjee, Silk
We propose a novel probe of fundamental physics by the exploitation of the temporal correlations between the multi-frequency electromagnetic (EM) signal and the stochastic gravitational wave background (SGWB) originating from coalescing binaries. This method will be useful for detection of EM counterparts associated with SGWB sources. Measurement of the inevitable time-domain correlations between different frequencies of gravitational and EM waves will test several aspects of fundamental physics and theory of gravity, and explore a new pathway for studying the universal nature of binary compact objects up to high redshifts. Exploiting the time delay between concomitant emission of the gravitational wave and EM signals enables inference of the redshifts of the contributing sources by studying the time delay dilation due to cosmological expansion, if the time-lag between the emission of gravitational wave signal and EM signal acts like a standard clock. Exploration of the time-domain correlations between multi-messenger probes will bring new research directions to the understanding of transient sources, in a way that is accessible with current and future gravitational wave observatories.
2008.01107
Characterizing galaxy clusters by their gravitational potential: systematic of cluster potential reconstruction
Tchernin, et al
Context. Biases in mass measurements of galaxy clusters are one of the major limiting systematics in constraining cosmology with clusters. Aims. We aim to demonstrate that the systematics associated with cluster gravitational potentials are smaller than the hydrostatic mass bias and that cluster potentials could therefore be a good alternative to cluster masses in cosmological studies. Methods. Using cosmological simulations of galaxy clusters, we compute the biases in the hydrostatic mass (HE mass) and those in the gravitational potential, reconstructed from measurements at X-ray and millimeter wavelengths. In particular, we investigate the effects of the presence of substructures and of non-thermal pressure support on both the HE mass and the reconstructed potential. Results. We find that the bias in the reconstructed potential (6%) is less than that of the HE mass (13%), and that the scatter in the reconstructed potential decreases by about 35% with respect to that in the HE mass. Conclusions. This study shows that characterizing galaxy clusters by their gravitational potential is a promising alternative to using cluster masses in cluster cosmology.
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