OGLE-2013-BLG-0911Lb: A Secondary on the Brown-dwarf Planet Boundary around an M Dwarf

Shota Miyazaki; Takahiro Sumi; David P. Bennett; Andrzej Udalski; Yossi Shvartzvald; Rachel Street; Valerio Bozza; Jennifer C. Yee; Ian A. Bond; Nicholas Rattenbury; Naoki Koshimoto; Daisuke Suzuki; Akihiko Fukui; F. Abe; A. Bhattacharya; R. Barry; M. Donachie; H. Fujii; Y. Hirao; Y. Itow; Y. Kamei; I. Kondo; M. C. A. Li; C. H. Ling; Y. Matsubara; T. Matsuo; Y. Muraki; M. Nagakane; K. Ohnishi; C. Ranc; T. Saito; A. Sharan; H. Shibai; H. Suematsu; D. J. Sullivan; P. J. Tristram; T. Yamakawa; A. Yonehara; MOA Collaboration; J. Skowron; R. Poleski; P. Mróz; M. K. Szymański; I. Soszyński; P. Pietrukowicz; S. KozŁowski; K. Ulaczyk; Ł. Wyrzykowski; OGLE Collaboration; Matan Friedmann; Shai Kaspi; Dan Maoz; Wise Team; M. Albrow; G. Christie; D. L. DePoy; A. Gal-Yam; A. Gould; C. -U. Lee; I. Manulis; J. McCormick; T. Natusch; H. Ngan; R. W. Pogge; I. Porritt; μFUN Collaboration; Y. Tsapras; E. Bachelet; M. P. G. Hundertmark; M. Dominik; D. M. Bramich; A. Cassan; R. Figuera Jaimes; K. Horne; R. Schmidt; C. Snodgrass; J. Wambsganss; I. A. Steele; J. Menzies; S. Mao; RoboNet Collabofratino; U. G. Jørgensen; M. J. Burgdorf; S. Ciceri; S. Calchi Novati; G. D'Ago; D. F. Evans; T. C. Hinse; N. Kains; E. Kerins; H. Korhonen; L. Mancini; A. Popovas; M. Rabus; S. Rahvar; G. Scarpetta; J. Skottfelt; J. Southworth; G. D'Ago; N. Peixinho; P. Verma; MiNDSTEp Collaboration

doi:10.3847/1538-3881/ab64de

OGLE-2013-BLG-0911Lb: A Secondary on the Brown-dwarf Planet Boundary around an M Dwarf

Shota Miyazaki
, Takahiro Sumi
, David P. Bennett
, Andrzej Udalski
, Yossi Shvartzvald
, Rachel Street
, Valerio Bozza
, Jennifer C. Yee
, Ian A. Bond
, Nicholas Rattenbury
, Naoki Koshimoto
, Daisuke Suzuki
, Akihiko Fukui
, F. Abe
, A. Bhattacharya
, R. Barry
, M. Donachie
, H. Fujii
, Y. Hirao
, Y. Itow

Y. Kamei, I. Kondo, M. C. A. Li, C. H. Ling, Y. Matsubara, T. Matsuo, Y. Muraki, M. Nagakane, K. Ohnishi, C. Ranc, T. Saito, A. Sharan, H. Shibai, H. Suematsu, D. J. Sullivan, P. J. Tristram, T. Yamakawa, A. Yonehara, MOA Collaboration, J. Skowron, R. Poleski, P. Mróz, M. K. Szymański, I. Soszyński, P. Pietrukowicz, S. KozŁowski, K. Ulaczyk, Ł. Wyrzykowski, OGLE Collaboration, Matan Friedmann, Shai Kaspi, Dan Maoz, Wise Team, M. Albrow, G. Christie, D. L. DePoy, A. Gal-Yam, A. Gould, C. -U. Lee, I. Manulis, J. McCormick, T. Natusch, H. Ngan, R. W. Pogge, I. Porritt, μFUN Collaboration, Y. Tsapras, E. Bachelet, M. P. G. Hundertmark, M. Dominik, D. M. Bramich, A. Cassan, R. Figuera Jaimes, K. Horne, R. Schmidt, C. Snodgrass, J. Wambsganss, I. A. Steele, J. Menzies, S. Mao, RoboNet Collabofratino, U. G. Jørgensen, M. J. Burgdorf, S. Ciceri, S. Calchi Novati, G. D'Ago, D. F. Evans, T. C. Hinse, N. Kains, E. Kerins, H. Korhonen, L. Mancini, A. Popovas, M. Rabus, S. Rahvar, G. Scarpetta, J. Skottfelt, J. Southworth, G. D'Ago, N. Peixinho, P. Verma, MiNDSTEp Collaboration

Research output: Contribution to journal › Article › peer-review

Abstract

We present the analysis of the binary-lens microlensing event OGLE-2013-BLG-0911. The best-fit solutions indicate the binary mass ratio of q ≃ 0.03, which differs from that reported in Shvartzvald et al. The event suffers from the well-known close/wide degeneracy, resulting in two groups of solutions for the projected separation normalized by the Einstein radius of s ∼ 0.15 or s ∼ 7. The finite source and the parallax observations allow us to measure the lens physical parameters. The lens system is an M dwarf orbited by a massive Jupiter companion at very close ( ${M}_{\mathrm{host}}={0.30}_{-0.06}^{+0.08}{M}_{\odot }$ , ${M}_{\mathrm{comp}}={10.1}_{-2.2}^{+2.9}{M}_{\mathrm{Jup}}$ , ${a}_{\exp }={0.40}_{-0.04}^{+0.05}\,\mathrm{au}$ ) or wide ( ${M}_{\mathrm{host}}={0.28}_{-0.08}^{+0.10}{M}_{\odot }$ , ${M}_{\mathrm{comp}}={9.9}_{-3.5}^{+3.8}{M}_{\mathrm{Jup}}$ , ${a}_{\exp }={18.0}_{-3.2}^{+3.2}\,\mathrm{au}$ ) separation. Although the mass ratio is slightly above the planet-brown dwarf (BD) mass-ratio boundary of q = 0.03, which is generally used, the median physical mass of the companion is slightly below the planet-BD mass boundary of 13M_Jup. It is likely that the formation mechanisms for BDs and planets are different and the objects near the boundaries could have been formed by either mechanism. It is important to probe the distribution of such companions with masses of ∼13M_Jup in order to statistically constrain the formation theories for both BDs and massive planets. In particular, the microlensing method is able to probe the distribution around low-mass M dwarfs and even BDs, which is challenging for other exoplanet detection methods....

Original language	Undefined
Journal	The Astronomical Journal
DOIs	https://doi.org/10.3847/1538-3881/ab64de
Publication status	Published - Feb 2020

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10.3847/1538-3881/ab64de

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Miyazaki, S., Sumi, T., Bennett, D. P., Udalski, A., Shvartzvald, Y., Street, R., Bozza, V., Yee, J. C., Bond, I. A., Rattenbury, N., Koshimoto, N., Suzuki, D., Fukui, A., Abe, F., Bhattacharya, A., Barry, R., Donachie, M., Fujii, H., Hirao, Y., ... Collaboration, MDSTE. (2020). OGLE-2013-BLG-0911Lb: A Secondary on the Brown-dwarf Planet Boundary around an M Dwarf. The Astronomical Journal. https://doi.org/10.3847/1538-3881/ab64de

@article{4a8737ecf9a34675a1705c442e3654e8,

title = "OGLE-2013-BLG-0911Lb: A Secondary on the Brown-dwarf Planet Boundary around an M Dwarf",

abstract = "We present the analysis of the binary-lens microlensing event OGLE-2013-BLG-0911. The best-fit solutions indicate the binary mass ratio of q ≃ 0.03, which differs from that reported in Shvartzvald et al. The event suffers from the well-known close/wide degeneracy, resulting in two groups of solutions for the projected separation normalized by the Einstein radius of s ∼ 0.15 or s ∼ 7. The finite source and the parallax observations allow us to measure the lens physical parameters. The lens system is an M dwarf orbited by a massive Jupiter companion at very close ( \$\{M\}\_\{\textbackslash{}mathrm\{host\}\}=\{0.30\}\_\{-0.06\}\textasciicircum{}\{+0.08\}\{M\}\_\{\textbackslash{}odot \}\$ , \$\{M\}\_\{\textbackslash{}mathrm\{comp\}\}=\{10.1\}\_\{-2.2\}\textasciicircum{}\{+2.9\}\{M\}\_\{\textbackslash{}mathrm\{Jup\}\}\$ , \$\{a\}\_\{\textbackslash{}exp \}=\{0.40\}\_\{-0.04\}\textasciicircum{}\{+0.05\}\textbackslash{},\textbackslash{}mathrm\{au\}\$ ) or wide ( \$\{M\}\_\{\textbackslash{}mathrm\{host\}\}=\{0.28\}\_\{-0.08\}\textasciicircum{}\{+0.10\}\{M\}\_\{\textbackslash{}odot \}\$ , \$\{M\}\_\{\textbackslash{}mathrm\{comp\}\}=\{9.9\}\_\{-3.5\}\textasciicircum{}\{+3.8\}\{M\}\_\{\textbackslash{}mathrm\{Jup\}\}\$ , \$\{a\}\_\{\textbackslash{}exp \}=\{18.0\}\_\{-3.2\}\textasciicircum{}\{+3.2\}\textbackslash{},\textbackslash{}mathrm\{au\}\$ ) separation. Although the mass ratio is slightly above the planet-brown dwarf (BD) mass-ratio boundary of q = 0.03, which is generally used, the median physical mass of the companion is slightly below the planet-BD mass boundary of 13MJup. It is likely that the formation mechanisms for BDs and planets are different and the objects near the boundaries could have been formed by either mechanism. It is important to probe the distribution of such companions with masses of ∼13MJup in order to statistically constrain the formation theories for both BDs and massive planets. In particular, the microlensing method is able to probe the distribution around low-mass M dwarfs and even BDs, which is challenging for other exoplanet detection methods....",

author = "Shota Miyazaki and Takahiro Sumi and Bennett, \{David P.\} and Andrzej Udalski and Yossi Shvartzvald and Rachel Street and Valerio Bozza and Yee, \{Jennifer C.\} and Bond, \{Ian A.\} and Nicholas Rattenbury and Naoki Koshimoto and Daisuke Suzuki and Akihiko Fukui and F. Abe and A. Bhattacharya and R. Barry and M. Donachie and H. Fujii and Y. Hirao and Y. Itow and Y. Kamei and I. Kondo and Li, \{M. C. A.\} and Ling, \{C. H.\} and Y. Matsubara and T. Matsuo and Y. Muraki and M. Nagakane and K. Ohnishi and C. Ranc and T. Saito and A. Sharan and H. Shibai and H. Suematsu and Sullivan, \{D. J.\} and Tristram, \{P. J.\} and T. Yamakawa and A. Yonehara and MOA Collaboration and J. Skowron and R. Poleski and P. Mr{\'o}z and Szyma{\'n}ski, \{M. K.\} and I. Soszy{\'n}ski and P. Pietrukowicz and S. Koz{\L}owski and K. Ulaczyk and {\L}. Wyrzykowski and OGLE Collaboration and Matan Friedmann and Shai Kaspi and Dan Maoz and Wise Team and M. Albrow and G. Christie and DePoy, \{D. L.\} and A. Gal-Yam and A. Gould and Lee, \{C. -U.\} and I. Manulis and J. McCormick and T. Natusch and H. Ngan and Pogge, \{R. W.\} and I. Porritt and μFUN Collaboration and Y. Tsapras and E. Bachelet and Hundertmark, \{M. P. G.\} and M. Dominik and Bramich, \{D. M.\} and A. Cassan and Jaimes, \{R. Figuera\} and K. Horne and R. Schmidt and C. Snodgrass and J. Wambsganss and Steele, \{I. A.\} and J. Menzies and S. Mao and RoboNet Collabofratino and J{\o}rgensen, \{U. G.\} and Burgdorf, \{M. J.\} and S. Ciceri and Novati, \{S. Calchi\} and G. D'Ago and Evans, \{D. F.\} and Hinse, \{T. C.\} and N. Kains and E. Kerins and H. Korhonen and L. Mancini and A. Popovas and M. Rabus and S. Rahvar and G. Scarpetta and J. Skottfelt and J. Southworth and G. D'Ago and N. Peixinho and P. Verma and MiNDSTEp Collaboration",

year = "2020",

month = feb,

doi = "10.3847/1538-3881/ab64de",

language = "Undefined",

journal = "The Astronomical Journal",

issn = "0004-6256",

publisher = "American Astronomical Society",

}

Miyazaki, S, Sumi, T, Bennett, DP, Udalski, A, Shvartzvald, Y, Street, R, Bozza, V, Yee, JC, Bond, IA, Rattenbury, N, Koshimoto, N, Suzuki, D, Fukui, A, Abe, F, Bhattacharya, A, Barry, R, Donachie, M, Fujii, H, Hirao, Y, Itow, Y, Kamei, Y, Kondo, I, Li, MCA, Ling, CH, Matsubara, Y, Matsuo, T, Muraki, Y, Nagakane, M, Ohnishi, K, Ranc, C, Saito, T, Sharan, A, Shibai, H, Suematsu, H, Sullivan, DJ, Tristram, PJ, Yamakawa, T, Yonehara, A, Collaboration, MOA, Skowron, J, Poleski, R, Mróz, P, Szymański, MK, Soszyński, I, Pietrukowicz, P, KozŁowski, S, Ulaczyk, K, Wyrzykowski, Ł, Collaboration, OGLE, Friedmann, M, Kaspi, S, Maoz, D, Team, W, Albrow, M, Christie, G, DePoy, DL, Gal-Yam, A, Gould, A, Lee, C-U, Manulis, I, McCormick, J, Natusch, T, Ngan, H, Pogge, RW, Porritt, I, Collaboration, ΜFUN, Tsapras, Y, Bachelet, E, Hundertmark, MPG, Dominik, M, Bramich, DM, Cassan, A, Jaimes, RF, Horne, K, Schmidt, R, Snodgrass, C, Wambsganss, J, Steele, IA, Menzies, J, Mao, S, Collabofratino, R, Jørgensen, UG, Burgdorf, MJ, Ciceri, S, Novati, SC, D'Ago, G, Evans, DF, Hinse, TC, Kains, N, Kerins, E, Korhonen, H, Mancini, L, Popovas, A, Rabus, M, Rahvar, S, Scarpetta, G, Skottfelt, J, Southworth, J, D'Ago, G, Peixinho, N, Verma, P & Collaboration, MDSTE 2020, 'OGLE-2013-BLG-0911Lb: A Secondary on the Brown-dwarf Planet Boundary around an M Dwarf', The Astronomical Journal. https://doi.org/10.3847/1538-3881/ab64de

TY - JOUR

T1 - OGLE-2013-BLG-0911Lb: A Secondary on the Brown-dwarf Planet Boundary around an M Dwarf

AU - Miyazaki, Shota

AU - Sumi, Takahiro

AU - Bennett, David P.

AU - Udalski, Andrzej

AU - Shvartzvald, Yossi

AU - Street, Rachel

AU - Bozza, Valerio

AU - Yee, Jennifer C.

AU - Bond, Ian A.

AU - Rattenbury, Nicholas

AU - Koshimoto, Naoki

AU - Suzuki, Daisuke

AU - Fukui, Akihiko

AU - Abe, F.

AU - Bhattacharya, A.

AU - Barry, R.

AU - Donachie, M.

AU - Fujii, H.

AU - Hirao, Y.

AU - Itow, Y.

AU - Kamei, Y.

AU - Kondo, I.

AU - Li, M. C. A.

AU - Ling, C. H.

AU - Matsubara, Y.

AU - Matsuo, T.

AU - Muraki, Y.

AU - Nagakane, M.

AU - Ohnishi, K.

AU - Ranc, C.

AU - Saito, T.

AU - Sharan, A.

AU - Shibai, H.

AU - Suematsu, H.

AU - Sullivan, D. J.

AU - Tristram, P. J.

AU - Yamakawa, T.

AU - Yonehara, A.

AU - Collaboration, MOA

AU - Skowron, J.

AU - Poleski, R.

AU - Mróz, P.

AU - Szymański, M. K.

AU - Soszyński, I.

AU - Pietrukowicz, P.

AU - KozŁowski, S.

AU - Ulaczyk, K.

AU - Wyrzykowski, Ł.

AU - Collaboration, OGLE

AU - Friedmann, Matan

AU - Kaspi, Shai

AU - Maoz, Dan

AU - Team, Wise

AU - Albrow, M.

AU - Christie, G.

AU - DePoy, D. L.

AU - Gal-Yam, A.

AU - Gould, A.

AU - Lee, C. -U.

AU - Manulis, I.

AU - McCormick, J.

AU - Natusch, T.

AU - Ngan, H.

AU - Pogge, R. W.

AU - Porritt, I.

AU - Collaboration, μFUN

AU - Tsapras, Y.

AU - Bachelet, E.

AU - Hundertmark, M. P. G.

AU - Dominik, M.

AU - Bramich, D. M.

AU - Cassan, A.

AU - Jaimes, R. Figuera

AU - Horne, K.

AU - Schmidt, R.

AU - Snodgrass, C.

AU - Wambsganss, J.

AU - Steele, I. A.

AU - Menzies, J.

AU - Mao, S.

AU - Collabofratino, RoboNet

AU - Jørgensen, U. G.

AU - Burgdorf, M. J.

AU - Ciceri, S.

AU - Novati, S. Calchi

AU - D'Ago, G.

AU - Evans, D. F.

AU - Hinse, T. C.

AU - Kains, N.

AU - Kerins, E.

AU - Korhonen, H.

AU - Mancini, L.

AU - Popovas, A.

AU - Rabus, M.

AU - Rahvar, S.

AU - Scarpetta, G.

AU - Skottfelt, J.

AU - Southworth, J.

AU - D'Ago, G.

AU - Peixinho, N.

AU - Verma, P.

AU - Collaboration, MiNDSTEp

PY - 2020/2

Y1 - 2020/2

N2 - We present the analysis of the binary-lens microlensing event OGLE-2013-BLG-0911. The best-fit solutions indicate the binary mass ratio of q ≃ 0.03, which differs from that reported in Shvartzvald et al. The event suffers from the well-known close/wide degeneracy, resulting in two groups of solutions for the projected separation normalized by the Einstein radius of s ∼ 0.15 or s ∼ 7. The finite source and the parallax observations allow us to measure the lens physical parameters. The lens system is an M dwarf orbited by a massive Jupiter companion at very close ( ${M}_{\mathrm{host}}={0.30}_{-0.06}^{+0.08}{M}_{\odot }$ , ${M}_{\mathrm{comp}}={10.1}_{-2.2}^{+2.9}{M}_{\mathrm{Jup}}$ , ${a}_{\exp }={0.40}_{-0.04}^{+0.05}\,\mathrm{au}$ ) or wide ( ${M}_{\mathrm{host}}={0.28}_{-0.08}^{+0.10}{M}_{\odot }$ , ${M}_{\mathrm{comp}}={9.9}_{-3.5}^{+3.8}{M}_{\mathrm{Jup}}$ , ${a}_{\exp }={18.0}_{-3.2}^{+3.2}\,\mathrm{au}$ ) separation. Although the mass ratio is slightly above the planet-brown dwarf (BD) mass-ratio boundary of q = 0.03, which is generally used, the median physical mass of the companion is slightly below the planet-BD mass boundary of 13MJup. It is likely that the formation mechanisms for BDs and planets are different and the objects near the boundaries could have been formed by either mechanism. It is important to probe the distribution of such companions with masses of ∼13MJup in order to statistically constrain the formation theories for both BDs and massive planets. In particular, the microlensing method is able to probe the distribution around low-mass M dwarfs and even BDs, which is challenging for other exoplanet detection methods....

AB - We present the analysis of the binary-lens microlensing event OGLE-2013-BLG-0911. The best-fit solutions indicate the binary mass ratio of q ≃ 0.03, which differs from that reported in Shvartzvald et al. The event suffers from the well-known close/wide degeneracy, resulting in two groups of solutions for the projected separation normalized by the Einstein radius of s ∼ 0.15 or s ∼ 7. The finite source and the parallax observations allow us to measure the lens physical parameters. The lens system is an M dwarf orbited by a massive Jupiter companion at very close ( ${M}_{\mathrm{host}}={0.30}_{-0.06}^{+0.08}{M}_{\odot }$ , ${M}_{\mathrm{comp}}={10.1}_{-2.2}^{+2.9}{M}_{\mathrm{Jup}}$ , ${a}_{\exp }={0.40}_{-0.04}^{+0.05}\,\mathrm{au}$ ) or wide ( ${M}_{\mathrm{host}}={0.28}_{-0.08}^{+0.10}{M}_{\odot }$ , ${M}_{\mathrm{comp}}={9.9}_{-3.5}^{+3.8}{M}_{\mathrm{Jup}}$ , ${a}_{\exp }={18.0}_{-3.2}^{+3.2}\,\mathrm{au}$ ) separation. Although the mass ratio is slightly above the planet-brown dwarf (BD) mass-ratio boundary of q = 0.03, which is generally used, the median physical mass of the companion is slightly below the planet-BD mass boundary of 13MJup. It is likely that the formation mechanisms for BDs and planets are different and the objects near the boundaries could have been formed by either mechanism. It is important to probe the distribution of such companions with masses of ∼13MJup in order to statistically constrain the formation theories for both BDs and massive planets. In particular, the microlensing method is able to probe the distribution around low-mass M dwarfs and even BDs, which is challenging for other exoplanet detection methods....

U2 - 10.3847/1538-3881/ab64de

DO - 10.3847/1538-3881/ab64de

M3 - Article

SN - 0004-6256

JO - The Astronomical Journal

JF - The Astronomical Journal

ER -