[HTML][HTML] Effects of variation in coagulation and photochemistry parameters on the particle size distributions in the Venus clouds
K McGouldrick - Earth, Planets and Space, 2017 - Springer
Earth, Planets and Space, 2017•Springer
This paper explores the effects that variation in the coalescence efficiency of the Venus
cloud particles can have on the structure of the Venus cloud. It is motivated by the
acknowledgment of uncertainties in the measured parameters—and the assumptions made
to account for them—that define our present knowledge of the particle characteristics.
Specifically, we explore the consequence of allowing the coalescence efficiency of
supercooled sulfuric acid in the upper clouds to tend to zero. This produces a cloud that …
cloud particles can have on the structure of the Venus cloud. It is motivated by the
acknowledgment of uncertainties in the measured parameters—and the assumptions made
to account for them—that define our present knowledge of the particle characteristics.
Specifically, we explore the consequence of allowing the coalescence efficiency of
supercooled sulfuric acid in the upper clouds to tend to zero. This produces a cloud that …
Abstract
This paper explores the effects that variation in the coalescence efficiency of the Venus cloud particles can have on the structure of the Venus cloud. It is motivated by the acknowledgment of uncertainties in the measured parameters—and the assumptions made to account for them—that define our present knowledge of the particle characteristics. Specifically, we explore the consequence of allowing the coalescence efficiency of supercooled sulfuric acid in the upper clouds to tend to zero. This produces a cloud that occasionally exhibits an enhancement of small particles at altitude (similar to the upper hazes observed by Pioneer Venus and subsequently shown to be somewhat transient). This simulated cloud occasionally exhibits a rapid growth of particle size near cloud base, exhibiting characteristics similar to those seen in the controversial Mode 3 particles. These results demonstrate that a subset of the variations observed as near-infrared opacity variations in the lower and middle clouds of Venus can be explained by microphysical, in addition to dynamical, variations. Furthermore, the existence of a population of particles exhibiting less efficient coalescence efficiencies would support the likelihood of conditions suitable for charge exchange, hence lightning, in the Venus clouds. We recommend future laboratory studies on the coalescence properties of sulfuric acid under the range of conditions experienced in the Venus clouds. We also recommend future in situ measurements to better characterize the properties of the cloud particles themselves, especially composition and particle habits (shapes).
Springer
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