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Cloud clearing in the wake of Saturn’s Great Storm of 2010–2011 and suggested new constraints on Saturn’s He/H2 ratio

•The wake of Saturn’s Great Storm of 2010–2011 became uniformly bright at 5 microns.•By December 2012 the bright wake covered all longitudes and latitudes 30–39°N.•Greatly reduced cloud opacity transmitted much more thermal emission from 5-6 bar level.•The high degree of uniformity suggests complete...

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Published in:Icarus (New York, N.Y. 1962) N.Y. 1962), 2016-09, Vol.276, p.141-162
Main Authors: Sromovsky, L.A., Baines, K.H., Fry, P.M., Momary, T.W.
Format: Article
Language:English
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Summary:•The wake of Saturn’s Great Storm of 2010–2011 became uniformly bright at 5 microns.•By December 2012 the bright wake covered all longitudes and latitudes 30–39°N.•Greatly reduced cloud opacity transmitted much more thermal emission from 5-6 bar level.•The high degree of uniformity suggests complete evaporation of a deep cloud layer.•Complete deep cloud clearing is consistent with He/H2 ratios from 0.045 to 0.070. Saturn’s Great Storm of 2010–2011 produced a planet-encircling wake that slowly transitioned from a region that was mainly dark at 5 µm in February 2011 to a region that was almost entirely bright and remarkably uniform by December of 2012. The uniformity and high emission levels suggested that the entire wake region had been cleared not only of the ammonia clouds that the storm had generated and exposed, but also of any other aerosols that might provide significant blocking of the thermal emission from Saturn’s deeper and warmer atmospheric layers. Our analysis of VIMS wake spectra from December 2012 provides no evidence of ammonia ice absorption, but shows that at least one significant cloud layer remained behind: a non-absorbing layer of 3–4 optical depths (at 2 µm) extending from 150 to ∼400 mbar. A second layer of absorbing and scattering particles, with less than 1 optical depth and located near 1 bar, is also suggested, but its existence as a model requirement depends on what value of the He/H2 ratio is assumed. The observations can be fit well with just a single (upper) cloud layer for a He/H2 ratio ≈ 0.064 in combination with a PH3 deep volume mixing ratio of 5 ppm. At lower He/H2 ratios, the observed spectra can be modeled without particles in this region. At higher ratios, in order to fit the brightest wake spectrum, models must include either significant cloud opacity in this region, or significantly increased absorption by PH3, NH3, and AsH3. As the exceptional horizontal uniformity in the late wake is most easily understood as a complete removal of a deep cloud layer, and after considering independent constraints on trace gas mixing ratios, we conclude that the existence of this remarkable wake uniformity is most consistent with a He/H2 mixing ratio of 0.055−0.015+0.010, which is on the low side of the 0.038–0.135 range of previous estimates.
ISSN:0019-1035
1090-2643
DOI:10.1016/j.icarus.2016.04.031