期刊文献+

The density and temperature dependence of the cooling timescale for fragmentation of self-gravitating disks

The density and temperature dependence of the cooling timescale for fragmentation of self-gravitating disks
下载PDF
导出
摘要 The purpose of this paper is to explore the influences of cooling timescale on fragmentation of self-gravitating protoplanetary disks. We assume the cooling timescale, expressed in terms of the dynamical timescale Ω tcool, has a power-law dependence on temperature and density, Ω toool ∝∑-aT-b, where a and b are con- stants. We use this cooling timescale in a simple prescription for the cooling rate, du/dt = -u/tcoll, where u is the internal energy. We perform our simulations using the smoothed particle hydrodynamics method. The simulations demonstrate that the disk is very sensitive to the cooling timescale, which depends on density and tem- perature. Under such a cooling timescale, the disk becomes gravitationally unstable and clumps form in the disk. This property even occurs for cooling timescales which are much longer than the critical cooling timescale, Ω toool≥ 7. We show that by adding the dependence of a cooling timescale on temperature and density, the number of clumps increases and the clumps can also form at smaller radii. The simulations im- ply that the sensitivity of a cooling timescale to density is more than to temperature, because even for a small dependence of the cooling timescale on density, clumps can still form in the disk. However, when the cooling timescale has a large dependence on temperature, clumps form in the disk. We also consider the effects of artificial viscos- ity parameters on fragmentation conditions. This consideration is performed in two cases, where Ω tcool is a constant and Ω tcool is a function of density and temperature. The simulations consider both cases, and results show the artificial viscosity param- eters have rather similar effects. For example, using too small of values for linear and quadratic terms in artificial viscosity can suppress the gravitational instability and consequently the efficiency of the clump formation process decreases. This property is consistent with recent simulations of self-gravitating disks. We perform simulations with and without the Balsara form of artificial viscosity. We find that in the cooling and self-gravitating disks without the Balsara switch, the clumps can form more easily than those with the Balsara switch. Moreover, in both cases where the Balsara switch is present or absent, the simulations show that the cooling timescale strongly depends on density and temperature. The purpose of this paper is to explore the influences of cooling timescale on fragmentation of self-gravitating protoplanetary disks. We assume the cooling timescale, expressed in terms of the dynamical timescale Ω tcool, has a power-law dependence on temperature and density, Ω toool ∝∑-aT-b, where a and b are con- stants. We use this cooling timescale in a simple prescription for the cooling rate, du/dt = -u/tcoll, where u is the internal energy. We perform our simulations using the smoothed particle hydrodynamics method. The simulations demonstrate that the disk is very sensitive to the cooling timescale, which depends on density and tem- perature. Under such a cooling timescale, the disk becomes gravitationally unstable and clumps form in the disk. This property even occurs for cooling timescales which are much longer than the critical cooling timescale, Ω toool≥ 7. We show that by adding the dependence of a cooling timescale on temperature and density, the number of clumps increases and the clumps can also form at smaller radii. The simulations im- ply that the sensitivity of a cooling timescale to density is more than to temperature, because even for a small dependence of the cooling timescale on density, clumps can still form in the disk. However, when the cooling timescale has a large dependence on temperature, clumps form in the disk. We also consider the effects of artificial viscos- ity parameters on fragmentation conditions. This consideration is performed in two cases, where Ω tcool is a constant and Ω tcool is a function of density and temperature. The simulations consider both cases, and results show the artificial viscosity param- eters have rather similar effects. For example, using too small of values for linear and quadratic terms in artificial viscosity can suppress the gravitational instability and consequently the efficiency of the clump formation process decreases. This property is consistent with recent simulations of self-gravitating disks. We perform simulations with and without the Balsara form of artificial viscosity. We find that in the cooling and self-gravitating disks without the Balsara switch, the clumps can form more easily than those with the Balsara switch. Moreover, in both cases where the Balsara switch is present or absent, the simulations show that the cooling timescale strongly depends on density and temperature.
作者 Kazem Faghei
机构地区 School of Physics
出处 《Research in Astronomy and Astrophysics》 SCIE CAS CSCD 2014年第6期648-666,共19页 天文和天体物理学研究(英文版)
基金 Financial support from the research council of Damghan University with grant number 91/phys/108/204
关键词 ACCRETION accretion disks -- planetary systems: protoplanetary disks --planetary systems: formation accretion, accretion disks -- planetary systems: protoplanetary disks --planetary systems: formation
  • 相关文献

参考文献39

  • 1Balsara, D. S. 1995, Journal of Computational Physics, 121,357.
  • 2Beltrin, M. T., Cesaroni, R., Neri, R., et al. 2004, ApJ, 601, L187.
  • 3Benz, W. 1990, in Numerical Modelling of Nonlinear Stellar Pulsations Problems and Prospects, ed. J. R. Buchler, 269 (Dordrecht: Kluwer).
  • 4Boss, A. P. 2001, ApJ, 563,367.
  • 5Chini, R., Hoffmeister, V., Kimeswenger, S., et al. 2004, Nature, 429, 155.
  • 6Cossins, P., Lodato, G., & Clarke, C. 2010, MNRAS, 401, 2587.
  • 7Durisen, R. H., Boss, A. P., Mayer, L., et al. 2007, Protostars and Planets V, eds. B. Reipurth, D. Jewitt, & K. Keil, 607 (Tucson: University of Arizona).
  • 8Faghei, K. 2012, RAA (Research in Astronomy and Astrophysics), 12, 331.
  • 9Faghei, K. 2013, RAA (Research in Astronomy and Astrophysics), 13, 170.
  • 10Gammie, C. F. 2001, ApJ, 553, 174.

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部