OGLE-2015-BLG-1670Lb: A Cold Neptune beyond the Snow Line in the Provisional WFIRST Microlensing Survey Field

Cl\'ement Ranc (1 , 4) , David P. Bennett (1 , 4 , 5) , Yuki Hirao (1 , 6) , Andrzej Udalski (2

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7) Cheongho Han (3 8) Ian A. Bond (1 9) Jennifer C. Yee (3 10) The KMTNet Collaboration: Michael D. Albrow (11) Sun-Ju Chung (12 13) Andrew Gould (12 14 15) Kyu-Ha Hwang (12) Youn-Kil Jung (12) Yoon-Hyun Ryu (12) In-Gu Shin (10) Yossi Shvartzvald (16) Weicheng Zang (17) Wei Zhu (14) Sang-Mok Cha (12 18) Dong-Jin Kim (12) Hyoun-Woo Kim (12) Seung-Lee Kim (12 Chung-Uk Lee (12 Dong-Joo Lee (12) Yong-Seok Lee (12 Byeong-Gon Park (12 Richard W. Pogge (15) The MOA Collaboration: Fumio Abe (19) Richard K. Barry (4) Aparna Bhattacharya (4 Martin Donachie (20) Akihiko Fukui (21 22) Yoshitaka Itow (19) Kohei Kawasaki (6) Iona Kondo (6) Naoki Koshimoto (23 24) Man Cheung Alex Li (20) Yutaka Matsubara (19) Shota Miyazaki (6) Yasushi Muraki (19) Masayuki Nagakane (6) Nicholas J. Rattenbury (20) Haruno Suematsu (6) Denis J. Sullivan (25) Takahiro Sumi (6) Daisuke Suzuki (26) Paul J. Tristram (27) Atsunori Yonehara (28) The OGLE Collaboration: Rados{\l}aw Poleski (14 Przemek Mr\'oz (7) Jan Skowron (7) Micha{\l} K. Szyma\'nski (7) Igor Soszy\'nski (7) Szymon Koz{\l}owski (7) Pawe{\l} Pietrukowicz (7 29) Krzysztof Ulaczyk (7) ((1) The MOA Collaboration (2) The OGLE Collaboration (3) The KMTNet Collaboration (4) Astrophysics Science Division NASA/Goddard Space Flight Center Greenbelt USA (5) Department of Astronomy University of Maryland College Park (6) Department of Earth Space Science Graduate School of Science Osaka University Toyonaka Japan (7) Warsaw University Observatory Warszawa Poland (8) Department of Physics Chungbuk National University Cheongju Republic of Korea (9) Institute of Natural Mathematical Sciences Massey University Auckland New Zealand (10) Harvard-Smithsonian Center for Astrophysics Cambridge (11) University of Canterbury Department of Physics Astronomy Christchurch (12) Korea Astronomy Space Science Institute Daejon (13) Korea University of Science Technology Daejeon (14) Department of Astronomy Ohio State University Columbus (15) Max-Planck-Institute for Astronomy Heidelberg Germany (16) IPAC Caltech Pasadena (17) Physics Department Tsinghua Centre for Astrophysics Tsinghua University Beijing People's Republic of China (18) School of Space Research Kyung Hee University Yongin (19) Institute for Space-Earth Environmental Research Nagoya University Nagoya (20) Department of Physics University of Auckland (21) Subaru Telescope Okayama Branch Office National Astronomical Observatory of Japan Asakuchi (22) Instituto de Astrof\'isica de Canarias La Laguna Spain (23) Department of Astronomy The University of Tokyo Bunkyo-ku (24) National Astronomical Observatory of Japan Mitaka (25) School of Chemical Physical Sciences Victoria University Wellington (26) Institute of Space Astronautical Science Japan Aerospace Exploration Agency Sagamihara (27) University of Canterbury Mt. John Observatory Lake Tekapo (28) Department of Physics Faculty of Science Kyoto Sangyo University Kyoto (29) Department of Physics University of Warwick Coventry UK)

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classification 🌌 astro-ph.EP

keywords mathrmmicrolensingeventplanetclosefieldgalacticlight-curve

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We present the analysis of the microlensing event OGLE-2015-BLG-1670, detected in a high-extinction field, very close to the Galactic plane. Due to the dust extinction along the line of sight, this event was too faint to be detected before it reached the peak of magnification. The microlensing light-curve models indicate a high-magnification event with a maximum of $A_\mathrm{max}\gtrsim200$, very sensitive to planetary deviations. An anomaly in the light curve has been densely observed by the microlensing surveys MOA, KMTNet, and OGLE. From the light-curve modeling, we find a planetary anomaly characterized by a planet-to-host mass ratio, $q=\left(1.00^{+0.18}_{-0.16}\right)\times 10^{-4}$, at the peak recently identified in the mass-ratio function of microlensing planets. Thus, this event is interesting to include in future statistical studies about planet demography. We have explored the possible degeneracies and find two competing planetary models resulting from the $s\leftrightarrow1/s$ degeneracy. However, because the projected separation is very close to $s=1$, the physical implications for the planet for the two solutions are quite similar, except for the value of $s$. By combining the light-curve parameters with a Galactic model, we have estimated the planet mass $M_2=17.9^{+9.6}_{-8.8}\,\mathrm{M}_\oplus$ and the lens distance $D_\mathrm{L}=6.7^{+1.0}_{-1.3}\,\mathrm{kpc}$, corresponding to a Neptune-mass planet close to the Galactic bulge. Such events with a low absolute latitude ($|b|\approx 1.1\,\mathrm{deg}$) are subject to both high extinction and more uncertain source distances, two factors that may affect the mass measurements in the provisional Wide Field Infrared Survey Telescope fields. More events are needed to investigate the potential trade-off between the higher lensing rate and the difficulty in measuring masses in these low-latitude fields.

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OGLE-2015-BLG-1670Lb: A Cold Neptune beyond the Snow Line in the Provisional WFIRST Microlensing Survey Field

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