An observational program was carried out to investigate the spectrum of Pluto at various points on its lightcurve. Spectrophotometry of Pluto in the wavelength range of 5600 to 10500 Å was obtained on four nights covering lightcurve phases of 0.18, 0.35, 0.49, and 0.98. The four phases included minimum light (0.98) and one near maximum light (0.49). The spectra reveal variations in the adsorption depths of the methane bands at 6200, 7200, 7900, 8400, 8600, 8900, and 10000 Å. The minimum amount of adsorption was found to occur at minimum light. A model for the surface and atmosphere of Pluto was constructed in an attempt to explain the phase variation observed. The model is based upon a previous photometric two-spot model which was constructed to explain the variations in the lightcurve from 1950 to 1982. Two dark circular spots (46° and 28° in radius, both at latitude -23°, separated by 134° in longitude) were used to constrain the surface distribution of methane frost on the surface of Pluto. The reflectance properties of the two terrains were modelled with a theory by B. Hapke (J.G.R., v. 86, p. 3039, 1981) which includes the effects of multiple scattering in the surface frost. The particle size and continuum optical depth of the frost particles were allowed to vary between the dark regions inside the spot boundaries and the brighter regions surrounding the spots. The transmission of the atmosphere was calculated using the Mayer-Goody band model. The model fit to the spectrum required the presence of a frost with particle sizes on the order of 1-20 mm in order to explain the observed phase dependence of the methane bands. Using only the atmosphere and no surface frost implies a variation in column abundance of 30% within three days. From energy balance considerations this variation in column abundance is not possible. By including the absorption of methane frost on the surface a range of model solutions was obtained. This range yields an approximate limit of 5.5 m-amagats to the amount of gas that can be present and still achieve a good fit to the phase variation of the 7200 Å band. If the atmosphere is removed from the model an equally good fit to the 7200 Å band is obtained. A major problem with the model is its failure to reproduce the relative absorption band depths. The gaseous atmospheric calculation on the other hand can fit the spectrum quite well. Possible explanations include a particle size distribution within a given terrain.
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机译:进行了一个观测程序,以研究冥王星在其光曲线上各个点的光谱。在四个晚上,涵盖了0.18、0.35、0.49和0.98的光曲线相位,获得了5600至10500Å波长范围内的冥王星的分光光度法。四个阶段包括最小光(0.98)和一个接近最大光(0.49)。光谱揭示了甲烷带在6200、7200、7900、8400、8600、8900和10000Å处的吸附深度的变化。发现最小量的吸附发生在最小的光下。为了解释所观察到的相位变化,构造了冥王星表面和大气的模型。该模型基于以前的光度学两点模型,该模型被构造为解释1950年至1982年光曲线的变化。两个暗圆形点(半径分别为46°和28°,都在纬度-23°处,由134隔开)用经度(°)约束甲烷霜在冥王星表面的分布。 B. Hapke(J.G.R.,v。86,p。3039,1981)运用理论对两个地形的反射特性进行了建模,其中包括表面霜冻中多次散射的影响。允许霜颗粒的粒径和连续光学深度在斑点边界内的暗区域和斑点周围的较亮区域之间变化。使用Mayer-Goody能带模型计算大气的透射率。该模型适合光谱,需要存在粒径在1-20毫米左右的霜,以解释甲烷带的相依性。仅使用大气且没有表面霜冻意味着三天内色谱柱丰度变化30%。从能量平衡的角度考虑,这种色谱柱丰度的变化是不可能的。通过包括吸收甲烷霜在表面上,可获得一系列模型溶液。此范围产生的气体数量大约限制为5.5 m-amagass,并且仍然非常适合7200Å波段的相位变化。如果将空气从模型中移开,则可以获得与7200Å波段同样良好的拟合度。该模型的主要问题是其无法再现相对吸收带深度。另一方面,气态大气计算可以很好地拟合光谱。可能的解释包括给定地形内的粒度分布。
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