2023
DOI: 10.1051/0004-6361/202243751
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Framework for the architecture of exoplanetary systems

Abstract: We present a novel, model-independent framework for studying the architecture of an exoplanetary system at the system level. This framework allows us to characterise, quantify, and classify the architecture of an individual planetary system. Our aim in this endeavour is to generate a systematic method to study the arrangement and distribution of various planetary quantities within a single planetary system. We propose that the space of planetary system architectures be partitioned into four classes: similar, m… Show more

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Cited by 26 publications
(16 citation statements)
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“…The existence of intra-system similar Jupiter pairs and the diverse architecture that can be produced by their instability does not seem to be recovered by existing population syntheses (which do not include the effect of pressure bumps). For example, in Mishra et al (2023), it seems uncommon for synthesized systems (their Figure 6, right panel) to have giant planets in very similar masses (mass ratio 0.8, corresponding to the peak in Figure 4). Their synthesized systems also do not show any significant mass inversion (large-small-large configuration, as opposed to the more typical monotonic or smalllarge-small configuration), which has been observed in a few systems and might be explained by the instability of Jupiter pairs.…”
Section: Comparison With Previous Studiesmentioning
confidence: 99%
See 1 more Smart Citation
“…The existence of intra-system similar Jupiter pairs and the diverse architecture that can be produced by their instability does not seem to be recovered by existing population syntheses (which do not include the effect of pressure bumps). For example, in Mishra et al (2023), it seems uncommon for synthesized systems (their Figure 6, right panel) to have giant planets in very similar masses (mass ratio 0.8, corresponding to the peak in Figure 4). Their synthesized systems also do not show any significant mass inversion (large-small-large configuration, as opposed to the more typical monotonic or smalllarge-small configuration), which has been observed in a few systems and might be explained by the instability of Jupiter pairs.…”
Section: Comparison With Previous Studiesmentioning
confidence: 99%
“…This diagram is for illustration only, and the samples shown here may not be statistically representative of the whole planet population. All systems are chosen from a catalog of known systems with four planets compiled inMishra et al (2023), with the exception of HD 37124, which serves as an example of a Jupiter triplet. Generally, a system can contain multiple classes of planets; we highlight the planets that belong to the relevant class with filled markers, and other planets are indicated by open markers.…”
mentioning
confidence: 99%
“…From the plethora of exoplanet discoveries, a vast array of system architectures have been revealed, many of which differ significantly from the solar system (Ford 2014;Winn & Fabrycky 2015;Horner et al 2020;Kane et al 2021;Mishra et al 2023aMishra et al , 2023b. The majority of these exoplanet discoveries have occurred through the use of the transit or radial velocity (RV) methods.…”
Section: Introductionmentioning
confidence: 99%
“…The origin and evolution of planetary architectures are key areas of study within exoplanetary science. The large number of discovered planets allows a statistical analysis of these architectures and a direct comparison with the solar system (Ford 2014;Winn & Fabrycky 2015;Horner et al 2020;Kane et al 2021a;Mishra et al 2023aMishra et al , 2023b. In particular, we are beginning to understand the prevalence of Jupiter analogs (Wittenmyer et al 2011(Wittenmyer et al , 2020Fulton et al 2021;Rosenthal et al 2021), largely from the long baseline of radial velocity (RV) observations (Kane et al 2007;Ford 2008;Wittenmyer et al 2013).…”
Section: Introductionmentioning
confidence: 99%