Kojima-1Lb Is a Mildly Cold Neptune around the Brightest Microlensing Host Star

Fukui, A.; Suzuki, D.; Koshimoto, Naoki; Bachelet, E.; Vanmunster, Tonny; Storey, D.; Maehara, Hiroyuki; Yanagisawa, K.; Yamada, Tōru; Yonehara, A.; Hirano, T.; Bennett, D. P.; Bozza, V.; Mawet, Dimitri; Penny, Matthew T.; Awiphan, S.; Oksanen, A.; Heintz, Tyler M.; Oberst, Thomas E.; Béjar, V. J. S.; Casasayas-Barris, N.; Chen, G.; Crouzet, Nicolas; Hidalgo, D.; Klagyivik, P.; Murgas, F.; Narita, Norio; Πάλλη, Ε.; Parviainen, H.; Watanabe, Noriharu; Kusakabe, Nobuhiko; Mori, M.; Terada, Yuka; Leon, Jerome de; Hernández, Anthony; Luque, R.; Monelli, M.; Montañes-Rodríguez, P.; Murata, Katsuhiro L.; Shugarov, S. Yu.; Kubota, Yuriko; Otsuki, C.; Shionoya, A.; Nishiumi, Taku; Nishide, A.; Fukagawa, Misato; Onodera, Keisuke; Villanueva, Steven; Street, R. A.; Tsapras, Y.; Hundertmark, M.; Kuzuhara, Masayuki; Fujita, M.; Beichman, Charles; Beaulieu, J. P.; Alonso, R.; Reichart, D. E.; Kawai, N.; Tamura, Motohide

doi:10.3847/1538-3881/ab487f

Cited by 26 publications

(25 citation statements)

References 65 publications

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“…Finding microlensing events requires frequent monitoring of a large Table 3 Microlensing Optical Depth and Average Timescales in EROS Fields (Rahal et al 2009) Region area along the Galactic plane. This is why the first Galactic plane events were detected mostly serendipitously (e.g., Fukui et al 2007Fukui et al , 2019Gaudi et al 2008;Nucita et al 2018;Zang et al 2019). Only the recent few years have brought about more detections of microlensing events in the Galactic plane, mostly thanks to efforts by the Gaia and ZTF groups.…”

Section: Discussionmentioning

confidence: 99%

“…Fukui et al (2007) and Gaudi et al (2008) presented the discovery of a bright microlensing event in the constellation Cassiopeia (l=117°). Nucita et al (2018), Fukui et al (2019), and Zang et al (2019) reported the characterization of a planetary-mass companion in microlensing event TCP J05074264+2447555 that was located toward the Galactic anticenter (l=179°). This was the first event, in which the two images generated by microlensing were resolved thanks to the use of the Very Large Telescope Interferometer GRAVITY (Dong et al 2019).…”

Section: Introductionmentioning

confidence: 99%

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Microlensing Optical Depth and Event Rate in the OGLE-IV Galactic Plane Fields

Mróz

Udalski

Szymański

et al. 2020

ApJS

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Searches for gravitational microlensing events are traditionally concentrated on the central regions of the Galactic bulge but many microlensing events are expected to occur in the Galactic plane, far from the Galactic Center. Owing to the difficulty in conducting high-cadence observations of the Galactic plane over its vast area, which are necessary for the detection of microlensing events, their global properties were hitherto unknown. Here, we present results of the first comprehensive search for microlensing events in the Galactic plane. We searched an area of almost 3000 square degrees along the Galactic plane (<  b 7 | | , 0°<l<50°, 190°<l<360°) observed by the Optical Gravitational Lensing Experiment (OGLE) during 2013-2019 and detected 630 events. We demonstrate that the mean Einstein timescales of Galactic plane microlensing events are on average three times longer than those of Galactic bulge events, with little dependence on the Galactic longitude. We also measure the microlensing optical depth and event rate as a function of Galactic longitude and demonstrate that they exponentially decrease with the angular distance from the Galactic Center (with the characteristic angular scale length of 32°). The average optical depth decreases from 0.5×10 −6 at l=10°to 1.5×10 −8 in the Galactic anticenter. We also find that the optical depth in the longitude range 240°<l<330°is asymmetric about the Galactic equator, which we interpret as a signature of the Galactic warp.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Microlensing Optical Depth and Event Rate in the OGLE-IV Galactic Plane Fields

Mróz

Udalski

Szymański

et al. 2020

ApJS

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“…Thus, the blended light basically all comes from the lens. Fukui et al (2019) detected no contamination at the position of the microlens on their Keck AO images, and using priors of an upper limit of p E and q E measured by Dong et al (2019), they found that the majority of the blend is most likely from the lens star rather than an ambient star or a companion to the source or the lens star. Our analysis directly measures the lens mass and distance using measured p E and q E , thus it is a direct demonstration that the blend mostly comes from the lens.…”

Section: Klmentioning

confidence: 96%

“…To estimate the lens apparent brightness, we use the angular Einstein radius q =  1.891 0.014 E mas and p =  0.469 0.060 E of the "luminous lens" model, and follow the procedure in Section 4.1. For extinction, we adopt the extinction law of Cardelli et al (1989) and estimate the extinction of the lens using the function of Fukui et al (2019). The predicted lens apparent magnitude is shown in Table 3.…”

Section: Klmentioning

confidence: 99%

“…Nucita et al (2018) discovered short-lived planetary features due to a super-Earth planet in this event. Fukui et al (2019) followed it up with Keck AO imaging, and combining it with an upper limit of p E and q E measurements from Dong et al (2019), they found that the blend was most likely due to the lens star with mass M L =0.581±0.033 M e .…”

Section: Introductionmentioning

confidence: 99%

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Spitzer + VLTI-GRAVITY Measure the Lens Mass of a Nearby Microlensing Event

Zang¹,

Dong²,

Gould

et al. 2020

ApJ

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We report the lens mass and distance measurements of the nearby microlensing event TCP J05074264+2447555 (Kojima-1). We measure the microlens parallax vector p E using Spitzer and ground-based light curves with constraints on the direction of lens-source relative proper motion derived from Very Large Telescope Interferometer (VLTI) GRAVITY observations. Combining this p E determination with the angular Einstein radius q E measured by VLTI-GRAVITY observations, we find that the lens is a star with mass = M L  M 0.495 0.063  at a distance D L =429±21 pc. We find that the blended light basically all comes from the lens. The lens-source proper motion is m = -26.55 0.36 mas yr rel,hel 1 , so with currently available adaptiveoptics instruments, the lens and source can be resolved in 2021. This is the first microlensing event whose lens mass is unambiguously measured by interferometry + satellite-parallax observations, which opens a new window for mass measurements of isolated objects such as stellar-mass black holes.

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Exoplanet Occurrence Rates from Microlensing Surveys

Mróz,

Poleski

2024

Handbook of Exoplanets

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Kojima-1Lb Is a Mildly Cold Neptune around the Brightest Microlensing Host Star

Cited by 26 publications

References 65 publications

Microlensing Optical Depth and Event Rate in the OGLE-IV Galactic Plane Fields

Microlensing Optical Depth and Event Rate in the OGLE-IV Galactic Plane Fields

Spitzer + VLTI-GRAVITY Measure the Lens Mass of a Nearby Microlensing Event

Exoplanet Occurrence Rates from Microlensing Surveys

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