Earth and Planetary Astrophysics (astro-ph.EP)

Abstract: Extensive numerical experiments on the long-term dynamics of planetesimals near the orbits of planets around single stars with debris disks have been carried out. The radial sizes of planetesimal clusters and the planetary chaotic zone as a function of mass parameter $\mu$ (planet-star mass ratio) have been determined numerically with a high accuracy separately for the outer and inner parts of the chaotic zone. The results obtained have been analyzed and interpreted in light of existing analytical theories (based on the planet-planetesimal mean motion resonance overlap criterion) and in comparison with previous numerical experiment approaches to the problem. We show and explain how the stepwise dependence of the chaotic zone sizes on $\mu$ is determined by the marginal resonances.

Abstract: The ever changing transparency of the Martian atmosphere hinders the determination of absolute surface colour from spacecraft images. While individual high resolution images from low orbit reveal numerous striking colour details of the geology, the colour variation between images caused by scattering off atmospheric dust can easily be of greater magni-tude. The construction of contiguous large-scale mosaics has thus required a strategy to suppress the influence of scatter-ing, most often a form of high-pass filtering, which limits their ability to convey colour variation information over distanc-es greater than the dimensions of single images. Here we make use of a dedicated high altitude observation campaign with the Mars Express High Resolution Stereo Camera1,2 (HRSC), applying a novel iterative method to construct a globally self-consistent colour model. We demonstrate that the model can be used to colour-reference a high-altitude mosaic in-corporating long-range colour variation information, and show that this mosaic, in turn, can be used to colour-reference high resolution images from low orbit. By using only the relative colour information internal to individual images, the in-fluence of absolute colour changes brought about by scattering is minimised, while the model iteration enables variations across image boundaries to be self-consistently reconstructed. The resulting mosaic reveals a previously unseen diversity and detail of colour, closely related to composition, over the whole of the martian surface.

Abstract: We present an analysis of microlensing event OGLE-2019-BLG-0825. This event was identified as a planetary candidate by preliminary modeling. We find that significant residuals from the best-fit static binary-lens model exist and a xallarap effect can fit the residuals very well and significantly improves $\chi^2$ values. On the other hand, by including the xallarap effect in our models, we find that binary-lens parameters like mass-ratio, $q$, and separation, $s$, cannot be constrained well. However, we also find that the parameters for the source system like the orbital period and semi major axis are consistent between all the models we analyzed. We therefore constrain the properties of the source system better than the properties of the lens system. The source system comprises a G-type main-sequence star orbited by a brown dwarf with a period of $P\sim5$ days. This analysis is the first to demonstrate that the xallarap effect does affect binary-lens parameters in planetary events. It would not be common for the presence or absence of the xallarap effect to affect lens parameters in events with long orbital periods of the source system or events with transits to caustics, but in other cases, such as this event, the xallarap effect can affect binary-lens parameters.

Abstract: Compact systems of multiple close-in super-Earths/sub-Neptunes ("compact multis") are a ubiquitous outcome of planet formation. It was recently discovered that the outer edges of compact multis are located at smaller orbital periods than expected from geometric and detection biases alone, suggesting some truncation or transition in the outer architectures. Here we test whether this "edge-of-the-multis" might be explained in any part by distant giant planets in the outer regions ($\gtrsim 1$ AU) of the systems. We investigate the dynamical stability of observed compact multis in the presence of hypothetical giant ($\gtrsim 0.5 \ M_{\mathrm{Jup}}$) perturbing planets. We identify what parameters would be required for hypothetical perturbing planets if they were responsible for dynamically sculpting the outer edges of compact multis. "Edge-sculpting" perturbers are generally in the range $P\sim100-500$ days for the average compact multi, with most between $P\sim200-300$ days. Given the relatively close separation, we explore the detectability of the hypothetical edge-sculpting perturbing planets, finding that they would be readily detectable in transit and radial velocity data. We compare to observational constraints and find it unlikely that dynamical sculpting from distant giant planets contributes significantly to the edge-of-the-multis. However, this conclusion could be strengthened in future work by a more thorough analysis of the detection yields of the perturbing planets.