http://arxiv.org/abs/2002.05310
We report a strong candidate multiplanetary system found by analyzing a very high-magnification ($A\sim 900$) microlensing event KMT-2019-BLG-1953. A single-lens single-source (1L1S) model appears to approximately delineate the observed light curve, but the residuals from the model exhibit small but obvious deviations in the peak region. Although models with a binary lens (2L1S) and binary source (1L2S) improve the fit, there still remain small residuals from the models, and these residuals can be explained by either triple-lens (3L1S) or binary-lens binary-source (2L2S) models. Among the two models, we judge that the 3L1S model provides a more plausible interpretation first because the signature of the second planet according to the 3L1S solution appears in the region where it is expected, i.e., around the peak of a very high-magnification event, and second because the 2L2S model is physically implausible. From the 3L1S modeling, we find four sets of solutions caused by the close/wide degeneracies in the planet separations from the host, $s_2$ and $s_3$. From Bayesian analysis, we estimate that the host of the planets has a mass of $M_{\rm host}=0.31^{+0.37}{-0.17}~M\odot$ and that the planetary system is located at a distance of $D_{\rm L}=7.04^{+1.10}{-1.33}~{\rm kpc}$ toward the Galactic center. The mass of the first planet, $M_2$, is in the range of $0.42 \lesssim M_2/M{\rm J}\lesssim 0.62$ and that of the second planet, $M_3$, is in the ranges of $0.27 \lesssim M_3/M_{\rm J}\lesssim 0.48$ for solutions with $s_3<1.0$ and $2.1 \lesssim M_3/M_{\rm J} \lesssim 2.8$ for solutions with $s_3>1.0$.
C. Han, D. Kim, Y. Jung, et. al.
Fri, 14 Feb 20
30/51
Comments: 9 pages, 7 figures
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