Near-infrared polarimetry of the GG Tauri A binary system
Near-infrared polarimetry of the GG Tauri A binary system
摘要
A high angular resolution near-infrared image that shows the intensity of polarization for the GG Tau A binary system was obtained with the Subaru Telescope. The image shows a circumbinary disk scattering the light from the central binary. The azimuthal profile of the intensity of polarization for the circumbinary disk is roughly reproduced by a simple disk model with the Henyey-Greenstein phase function and the Rayleigh function, indicating there are small dust grains at the surface of the disk. Combined with a previous observation of the circumbinary disk, our image indicates that the gap structure in the circumbinary disk orbits counterclockwise, but material in the disk orbits clockwise. We propose that there is a shadow caused by material located between the central binary and the circumbinary disk. The separations and position angles of the stellar components of the binary in the past 20 yr are consistent with the binary orbit with a = 33.4 AU and e = 0.34.
A high angular resolution near-infrared image that shows the intensity of polarization for the GG Tau A binary system was obtained with the Subaru Telescope. The image shows a circumbinary disk scattering the light from the central binary. The azimuthal profile of the intensity of polarization for the circumbinary disk is roughly reproduced by a simple disk model with the Henyey-Greenstein phase function and the Rayleigh function, indicating there are small dust grains at the surface of the disk. Combined with a previous observation of the circumbinary disk, our image indicates that the gap structure in the circumbinary disk orbits counterclockwise, but material in the disk orbits clockwise. We propose that there is a shadow caused by material located between the central binary and the circumbinary disk. The separations and position angles of the stellar components of the binary in the past 20 yr are consistent with the binary orbit with a = 33.4 AU and e = 0.34.
基金
supported by a Grant-in-Aid for Scientific Research (No. 24540231)
supported by the U.S. National Science Foundation under Award (No. 1009203)
参考文献26
-
1Artymowicz, P., & Lubow, S. H. 1996, ApJ, 467, L77.
-
2Bate, M. R? & Bonnell, I. A. 1997, MNRAS, 285, 33.
-
3Beust, H? & Dutrey, A. 2005, A&A, 439, 585.
-
4Beust, H., & Dutrey, A. 2006, A&A, 446, 137.
-
5Duchene, G., McCabe, C., Ghez, A. M., & Macintosh, B. A. 2004, ApJ, 606, 969.
-
6Fukagawa, M., Hayashi, M., Tamura, M., et al. 2004, ApJ, 605, L53.
-
7Ghez, A. M., Neugebauer, G., & Matthews, K. 1993, AJ, 106, 2005.
-
8Grinin, V., Stempels, H. C., Gahm, G. F., et al. 2008, A&A, 489, 1233.
-
9Guilloteau, S., Dutrey, A., & Simon, M. 1999, A&A, 348, 570.
-
10Hanawa, T? Ochi, Y? & Ando, K. 2010, ApJ, 708, 485.
-
1胡珊,罗建军,袁建平.惯导/双星组合系统仿真系统的开发[J].系统仿真学报,2004,16(9):1957-1960. 被引量:2
-
2李宁,贾同辉,尹义龙.一种新的指纹奇异点区增强算法[J].计算机工程,2006,32(17):71-73.
-
3刁麓弘,章森,刘磊,樊丽霞,李华.相位矩不变量[J].计算机辅助设计与图形学学报,2008,20(5):645-651. 被引量:5
-
4Song Guofeng 1 (Beijing Astronomical Observatory, The Chinese Academy of Sciences, Beijing 100012, China) 2 (National Astronomical Observatories, The Chinese Academy of Sciences, Beijing 100012, China).Near-Infrared Solar Electric Field Telescope[J].天文研究与技术,1999(S1):120-123.
-
5科技简讯[J].中国科教创新导刊,2001,0(12):37-41.
-
6李春梅,王永忠.有趣的向量旋转角度的计算[J].数学通讯(教师阅读),2008,22(9):17-18.
-
7孔捷,张保民.水下光传输中的相位函数分析[J].兵工学报,2013,34(6):792-796.
-
8Boonrucksar Soonthornthum, Sumith Niparugs, Aniwat Sooksawat, Wim Nhuerpeng (Department of Physics, Faculty of Science, Chiang Mai University, Chiang Mai 50200, Thailand).Physical Properties of an Eclipsing Binary System, YY Eridani[J].天文研究与技术,1999(S1):383-386.
-
9王爱兰.神奇的二进制系统[J].初中生学习指导(七年级博览版),2014(7):128-128.
-
10宇宙年龄为137亿岁[J].中国科技财富,2003(3):93-93.
