Toon O B, McKay C P, Griffith C A, Turco R P
NASA Ames Research Center, Moffett Field, California 94035, USA.
Icarus. 1992 Jan;95(1):24-53. doi: 10.1016/0019-1035(92)90188-d.
Microphysical simulations of Titan's stratospheric haze show that aerosol microphysics is linked to organized dynamical processes. The detached haze layer may be a manifestation of 1 cm sec-1 vertical velocities at altitudes above 300 km. The hemispherical asymmetry in the visible albedo may be caused by 0.05 cm sec-1 vertical velocities at altitudes of 150 to 200 km, we predict contrast reversal beyond 0.6 micrometer. Tomasko and Smith's (1982, Icarus 51, 65-95) model, in which a layer of large particles above 220 km altitude is responsible for the high forward scattering observed by Rages and Pollack (1983, Icarus 55, 50-62), is a natural outcome of the detached haze layer being produced by rising motions if aerosol mass production occurs primarily below the detached haze layer. The aerosol's electrical charge is critical for the particle size and optical depth of the haze. The geometric albedo, particularly in the ultraviolet and near infrared, requires that the particle size be near 0.15 micrometer down to altitudes below 100 km, which is consistent with polarization observations (Tomasko and Smith 1982, West and Smith 1991, Icarus 90, 330-333). Above about 400 km and below about 150 km Yung et al.'s (1984, Astrophys. J. Suppl. Ser. 55, 465-506) diffusion coefficients are too small. Dynamical processes control the haze particles below about 150 km. The relatively large eddy diffusion coefficients in the lower stratosphere result in a vertically extensive region with nonuniform mixing ratios of condensable gases, so that most hydrocarbons may condense very near the tropopause rather than tens of kilometers above it. The optical depths of hydrocarbon clouds are probably less than one, requiring that abundant gases such as ethane condense on a subset of the haze particles to create relatively large, rapidly removed particles. The wavelength dependence of the optical radius is calculated for use in analyzing observations of the geometric albedo. The lower atmosphere and surface should be visible outside of regions of methane absorption in the near infrared. Limb scans at 2.0 micrometers wavelength should be possible down to about 75 km altitude.
对土卫六平流层霾的微物理模拟表明,气溶胶微物理与有组织的动力学过程相关联。分离的霾层可能是300千米以上高度处1厘米/秒垂直速度的一种表现。可见光反照率的半球不对称性可能是由150至200千米高度处0.05厘米/秒的垂直速度引起的,我们预测在0.6微米以上会出现对比度反转。托马斯科和史密斯(1982年,《伊卡鲁斯》51卷,65 - 95页)的模型中,220千米以上高度的一层大颗粒导致了拉热斯和波拉克(1983年,《伊卡鲁斯》55卷,50 - 62页)观测到的高前向散射,如果气溶胶质量产生主要发生在分离的霾层下方,那么分离的霾层是由上升运动产生的自然结果。气溶胶的电荷对于霾的颗粒大小和光学厚度至关重要。几何反照率,特别是在紫外和近红外波段,要求颗粒大小在100千米以下高度接近0.15微米,这与偏振观测结果一致(托马斯科和史密斯1982年,韦斯特和史密斯1991年,《伊卡鲁斯》90卷,330 - 333页)。在大约400千米以上和150千米以下,杨等人(1984年,《天体物理学杂志增刊》55卷,465 - 506页)的扩散系数太小。动力学过程控制着150千米以下的霾颗粒。平流层下部相对较大的涡动扩散系数导致了一个垂直范围广泛的区域,其中可凝结气体的混合比不均匀,因此大多数碳氢化合物可能在对流层顶附近凝结,而不是在其上方几十千米处。碳氢化合物云的光学厚度可能小于1,这要求诸如乙烷等丰富的气体在一部分霾颗粒上凝结,以形成相对较大、能快速去除的颗粒。计算了光学半径的波长依赖性,用于分析几何反照率的观测结果。在近红外波段甲烷吸收区域之外,应该可以看到下层大气和表面。在2.0微米波长处的临边扫描应该可以进行到大约75千米的高度。
