Discovery of a 150 day period in the Venus condensational clouds

Accepted Manuscript

Discovery of a 150 day period in the Venus condensational clouds Kevin McGouldrick, Constantine C.C. Tsang PII: DOI: Reference:

S0019-1035(16)30652-2 10.1016/j.icarus.2016.10.005 YICAR 12221

To appear in:

Icarus

Received date: Revised date: Accepted date:

11 March 2016 15 September 2016 2 October 2016

Please cite this article as: Kevin McGouldrick, Constantine C.C. Tsang, Discovery of a 150 day period in the Venus condensational clouds, Icarus (2016), doi: 10.1016/j.icarus.2016.10.005

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Highlights • We find a 150 day periodic variation in the 1.74 µm and 2.30 µm radi-

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ance.

• The oscillation is most pronounced at mid-latitudes (30◦ − 60◦ ).

• The timescales are consistent with the cloud radiative-dynamical feedback.

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• Long-term increase in radiance at mid to low latitudes is also noted.

• Additional hypotheses to guide future modelling of this phenomenon

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Discovery of a 150 day period in the Venus condensational clouds

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Kevin McGouldricka,∗, Constantine C. C. Tsangb a

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Laboratory for Atmospheric and Space Physics, University of Colorado Boulder, 3665 Discovery Dr., Boulder, CO 80303 b Southwest Research Institute, Department of Space Studies, 1050 Walnut St., Suite 300, Boulder, CO 80302

Abstract

We have analyzed the long-term regional and global variation of emitted radiance in 1.74µm and 2.30µm near infrared spectral windows in the Venus atmosphere using the medium resolution, infrared channel of the Visible and

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Infrared Thermal Imaging Spectrometer (VIRTIS-M-IR) on the Venus Express spacecraft. We find a periodic variation in the 1.74µm radiance that

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is most pronounced at mid-latitudes (30◦ − 60◦ latitude). This oscillation has a period of approximately 150 days, and is shown to be unlikely to be

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driven by variations in viewing geometry, nor by variations in instrumental characteristics such as spectrometer temperature. The oscillation has an am-

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plitude at least as large as that of the typical day-to-day variations observed. The decay and recovery timescales are consistent with response of the cloud

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vertical structure to the radiative-dynamical feedback. It remains unclear why this variation would be seen only at mid-latitudes, but some hypotheses to guide future modelling testing are suggested. ∗

Corresponding author. Email address: [email protected] (Kevin McGouldrick)

Preprint submitted to Icarus

October 7, 2016

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Keywords: Venus, Atmosphere, Clouds, Meteorology, Dynamics 1. Introduction

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Spatial and temporal inhomogeneities in the near infrared emission spec-

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trum of Venus were first discovered by Allen and Crawford (1984). It was

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soon determined that these inhomogeneities were observed as a consequence

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of the existence of narrow spectral windows in the near infrared emission

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spectrum of Venus where absorption by (primarily) CO2 and H2 O was min-

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imal. Since then, these spectral windows have been used to elucidate the

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properties of the surface of Venus (for example, Mueller et al. (2008), Kappel

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et al. (2012), Haus et al. (2014), and Shalygin et al. (2015)), atmospheric

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composition and chemistry (for example, Marcq et al. (2005) and B´ezard

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et al. (2009)), and properties of the clouds of Venus (for example, Carlson

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et al. (1993) and Wilson et al. (2008)).

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Crisp et al. (1989) and Kamp et al. (1988) showed that the variability

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of night side near infrared emission from Venus in the spectral vicinity of

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the 1.74µm and 2.30µm windows was driven primarily by variations in the

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condensational clouds of Venus. The clouds of Venus cover a range of alti-

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tudes from about 50km above the surface to about 70km above the surface.

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When viewed in emitted near infrared radiation, spatial inhomogeneities are

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driven by variations in the lower regions of the clouds, between about 50-

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55km. The bulk of the cloud mass is located also in this region, but the origin

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of the volatiles that support the entire cloud system is the photochemically

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produced sulfuric acid around 63km.

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Grinspoon et al. (1993) used the 1.74µm and 2.30µm spectral windows

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observed by the Near Infrared Mapping Spectrometer (NIMS) during the

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Galileo flyby to constrain the total infrared optical depth of the photochem-

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ical and condensational clouds and the composition of the putative Mode 3

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particles first postulated by Knollenberg and Hunten (1980). Carlson et al.

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(1993) used the same data to characterize the spatial variability of the typical

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size of the particles that comprise the condensational cloud at the time of

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the Galileo encounter.

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More recently, the infrared mapping channel of the Visible and Infrared

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Thermal Mapping Spectrometer (VIRTIS-M-IR) on the Venus Express space-

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craft (Drossart et al., 2007) has been utilized to further characterize the

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short-term evolution of the clouds of Venus (McGouldrick et al., 2012) and

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to simultaneously retrieve additional properties of the Venus clouds region,

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including cloud base altitude, sulfuric acid weight percent, and sub-cloud and

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in-cloud water vapor concentrations (Barstow et al., 2012).

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Here, we build upon the work done in those two papers to character-

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ize the long-term evolution of the clouds of Venus, as can be determined

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through analysis of 921 orbits (about two and a half years) of VIRTIS-M-IR

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observations of the night side of Venus.

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2. Observational Data

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Venus Express launched in November 2005, was placed into orbit around

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Venus in April 2006, and continued to return valuable science data until

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it exhausted the fuel for its attitude control thrusters in November 2014.

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Its polar orbit exhibited a periapsis altitude generally between 150 km and 5

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250 km above the surface of Venus at about +80◦ latitude, and an apoapsis

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altitude of about 66,000 km. The VIRTIS-M infrared channel is a medium

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spatial resolution (0.25 mrad/pxl) infrared mapping spectrometer that cov-

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ers the range of wavelengths from 1µm to 5µm with a spectral resolution

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of roughly λ/∆λ ∼ 300, or about 0.01µm. Though, in practice, the effec-

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tive resolution has been shown to be about 0.017µm (B´ezard et al., 2009).

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This is sufficient spectral resolution to resolve many details of the spectral

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windows (Drossart et al., 2007). The spatial resolution is about 30 km when

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the spacecraft is at apoapse (d ∼ 66, 000 km), improving to about 5 km at

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a distance of about 10, 000 km. The near infrared detector was a mercury-

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cadmium-telluride (HgCdTe) semiconductor cooled to 70K. The instrument

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returned data over the course of nearly four sidereal Venus days until the

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cooling system failed during orbit 921 (UTC: 2008 October 27). The cooling

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system began to show signs of wear during the nominal mission (the first 500

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orbits), so the frequency of use of the VIRTIS-M-IR instrument was signif-

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icantly reduced between orbits 500 and 921, as compared with the nominal

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mission. Previous work by McGouldrick et al. (2012) exploring the long-term

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variability of the clouds relied on data only from the first 407 orbits of the

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mission. In the present work, we utilize the entire VIRTIS-M-IR data set.

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The entire volume of data produced by the instrument can be obtained

at the European Space Agency’s (ESA’s) Planetary Science Archive (PSA) website, and is mirrored by the National Astronautical and Space Adminis-

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tration’s (NASA’s) Planetary Data System (PDS), Atmospheres Node. The

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VIRTIS instrument produced about a terabyte of data over the course of the

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Venus Express mission. In order to efficiently analyze this large volume of

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data, it is necessary to filter it according to both instrumental and geometric

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constraints. Instrumentally, we consider only observations utilizing integra-

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tion times of at least 0.3 seconds. Acquired spectral cubes having integration

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times shorter than this are intended for the much higher radiance from day

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side observations, and have very low signal to noise ratios in emitted near

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infrared light. Geometrically, we constrain the data according to distance,

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viewing angle, and solar angle considerations. To generate spectral cubes,

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VIRTIS-M-IR scans its slit across the field of view to generate spectral im-

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age cubes. The time required to do this, combined with the motion of the

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spacecraft relative to the planet, means that mapping mode spectral cubes

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generally are not created when within 10,000 km of the planet. (Drossart

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et al., 2007). Thus, we consider only data acquired at distances greater than

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10, 000 km from the planet. In doing so, we are neglecting the pericenter

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observations – mostly of northern hemisphere targets. We choose to neglect

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these data for two reasons. First, these periapse observations are necessarily

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very parochial in nature, due to the small distance to Venus and the small

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field of view of VIRTIS-M-IR. While the inclusion of these nadir-viewing,

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near-periapse observations can improve the mission-long statistics, they also

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have the potential to introduce significant errors into the time series analysis

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performed in this work that are caused by the spatial inhomogeneity. Sec-

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ond, the present work is intended to be part of a larger project in which the

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information gathered here can inform the characterization of individual fea-

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tures, including morphology, in the Venus clouds over a variety of timescales.

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Since that effort will be necessarily limited to observations using the map-

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ping mode of VIRTIS-M-IR, we also constrain this preliminary work to that

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mode of observation. The pericenter observations obtained at distances less

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than 10,000 km will not be helpful in either of these contexts, so we disre-

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gard those observations for now in favor of concentrating on the southern

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hemisphere mapping data. We consider only those observations in which at

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least some of the night side is visible, discarding all data for which only the

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day side is seen. That is, we discard the data for the present analysis if the

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minimum hour angle of the Sun exceeds 5 a.m. and the maximum hour angle

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is less than 7 p.m. The 1 hour buffer from the dawn or dusk terminator is

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intended to minimize the effects of sunlight that is forward scattered from

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beyond the terminator. We also restrict the observations to those that are

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affected minimally (or not at all) by sunlight that is forward scattered from

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the day side of the planet by restricting the data in the nominal analysis to

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locations where the solar incidence angle exceeds 95◦ . In order to quantify

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the effects of this cutoff, we also compare results considering a range of inci-

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dence angle, among 100◦ , 105◦ , 110◦ , and 115◦ . Note that, due to our hour

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angle restriction, these incidence angle data filters will have their greatest ef-

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fect for observations near the pole. However, these cutoffs will have minimal

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effect on reducing the contribution by stray light sources in the data (Kappel

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et al., 2012). Finally, we restrict our analysis to the southern hemisphere.

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The highly eccentric polar orbit of Venus Express makes mapping type ob-

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servations by VIRTIS-M-IR of the southern hemisphere more favorable than

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the northern hemisphere. While portions of the northern hemisphere have

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been observed in mapping mode, the data are almost exclusively equatorial

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(|φ| < 30◦ ). If a north-south hemispheric dichotomy exists in the behavior

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of the clouds then this uneven distribution of north and south latitudinal

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observations could exacerbate the effect. Furthermore, even those north-

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ern hemisphere observations that do exist are very close to the limb, and

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hence are subject to significant foreshortening and limb darkening, resulting

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in larger uncertainties in the corrected upwelling radiance.

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Most of the time, at least some of the night side of Venus is visible to

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VIRTIS-M-IR. However, there are times when the change in the phase angle

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due to the revolution of Venus around the Sun, coupled with the telemetry

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requirements, makes it nearly impossible to observe the night side of the

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planet (which is necessary for the analysis of these near infrared emissions

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from Venus). Thus, even though VIRTIS-M-IR returned useful data over a

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window of 921 days (also 921 orbits, since the orbital period of Venus Express

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throughout this phase of the mission was 24 hours) before the failure of its

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cooling system, there are somewhat fewer than 921 orbits’ worth of data

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that will be useful for the present analysis. There are also several weeks-

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long breaks in the data during which times night side data that satisfy our

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declared criteria could not be obtained.

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Over the course of multiple orbits, significant latitudinal and longitudinal

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coverage of the clouds in the southern hemisphere was built up, which allows

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for the determination of possible latitudinal tendencies in the existence and

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optical thickness of the clouds. Furthermore, VIRTIS observations sometimes

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utilize a mosaic mode in which the entire visible hemisphere of the planet is

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observed over the course of up to nine separate cube acquisitions. Observing

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in this manner allowed a greater spatial coverage than is possible with a

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single cube, or a series of cubes over a particular location.

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Note that, due to the limited field of view of the VIRTIS-M-IR instru-

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ment, the brief lifetime of this instrument (fewer than four Venus sidereal

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days), and the existence of about a dozen unique science observation modes,

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the composite coverage of the planet is not homogeneous. In addition to

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the hemispherical observational imbalance driven by the polar and eccentric

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orbit, there may also be geographic locations that had been observed more

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frequently than others.

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The VIRTIS-M cubes demonstrate a significant amount of anomalous ra-

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diance that has been attributed to scattered sunlight, probably reflected from

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the baffle toward the detector (Mueller et al., 2008; Kappel et al., 2012). In

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order to correct for this scattered sunlight, we choose a series of wavelength

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bands in the Venus emitted near infrared spectrum for which we expect to

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see zero emitted radiance, due to the absorption of upwelling radiation by

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atmospheric constituents such as CO2 and H2 O. That is, we define a series

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of “muntins1 ” between the near infrared spectral windows with wavelengths:

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(1.05 ± 0.01 µm, 1.225 ± 0.015 µm, 1.38 ± 0.03 µm, 1.57 ± 0.03 µm). A VIR-

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TIS image cube is a three-dimensional data construct with dimensions termed

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band (wavelength), sample (pixels along the slit), and line (each new inte-

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gration by the detector). That is, a VIRTIS cube is a stack of band × sample

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images. For each band × sample image, we average over the sample (slit)

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dimension to find an average spectrum.

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Acting on the assumption that the stray light was likely scattered sun-

light, we had first attempted to fit the data in the muntins according to a

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1 A muntin is a bar or rigid supporting strip between adjacent panes of a glass window; formerly used to increase the structural integrity of a large window, today mostly used for decorative purposes.

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reflected solar Blackbody curve:

I(λ) = A

−1 2hc2  hc λkT − 1 e λ5

(1)

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where h is Planck’s Constant, c is the speed of light in vacuum, k is Boltz-

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mann’s constant, T is the temperature of the solar photosphere, and we

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choose A to be an arbitrary gray albedo that is a free parameter to be fit to

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the data along with λ. However, we found that such a spectrum could not

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match the measured muntins. If the gray albedo was chosen to fit the muntins

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near 1.5µm and 2.0µm, then the stray light radiance from the muntins at

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shorter wavelengths was underestimated. Similarly, if the curve was fitted to

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the muntins at wavelengths shorter than 1.3µm, then the stray light radiance

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from the longer wavelength muntins was overestimated. Similar to Kappel

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et al. (2012) and Longobardo et al. (2012), we found that the stray light

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radiance in the muntins closely matched a λ−4 curve. Likely interpretations

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of such a curve would mean that either the source of the stray light spectrum

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were a blackbody considerably hotter than the Sun or was produced by a

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non-gray albedo that increased strongly at shorter wavelengths. In the for-

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mer case, these near infrared wavelengths are too near the peak of the solar

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spectrum to be in the long-wavelength Rayleigh-Jeans regime of the solar

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spectrum that asymptotes to a λ−4 curve. In the latter case, Kappel et al.

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(2012) suggest that the stray light resembles λ−4 associated with scattering

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processes, but the Venus cloud particles are too large to be Rayleigh scat-

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terers at these wavelengths. Since neither of these explanations is likely, we

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chose to fit the data with an arbitrary power law or an arbitrary exponential: I(λ) = I0 λa

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I(λ) = I0 · eaλ

(2) (3)

We then fit the free parameters (I0 ) and (a) to the muntin data, finding their

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best fit values and standard deviations in each of these two cases. We found

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that the power law tended to identify best fit exponents of between λ−3 and

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λ−5 , somewhat consistent with previous suggestions by Kappel et al. (2012)

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and Longobardo et al. (2012). However, we found that the goodness of the fit

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was somewhat better when using the exponential curve in the vast majority

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of the analyzed data, so we chose to use the exponential curve as a best fit for

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the stray light correction. We then subtract this best fit stray light spectrum

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from each pixel in the slit (along the sample axis). All negative values in the

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scattered sunlight corrected spectra are treated as zeros. An example of the

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effect of this procedure for a given spectrum at one pixel (sample 100, line

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50) of one particular pure night side image cube (VIR0383 00) is shown in

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Fig. 1.

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Also shown in Fig. 1 is an example stray light spectrum obtained by av-

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eraging all valid data (i.e., pixels not exhibiting error flags) obtained from

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observations at least 200km above the limb of the planet for this same pure

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night side image cube. We see that the stray light present at 1.74µm and

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2.30µm is nearly negligible. So, even if our simple exponential stray light

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correction is invalid, it will introduce negligible error in the current analysis.

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Future analysis of the near surface windows will require us to apply a more

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Figure 1: In the left hand plot, the black curve is the uncorrected spectrum of sample 100 and line 50 of pure night side cube VIR0383 00. The red curve is the same data with the stray sunlight correction from Eq. 3 applied. In the right hand plot, an average spectrum collected from the empty space observations within the same image cube is compared with the same on-target uncorrected spectrum.

rigorous stray light correction, perhaps similar to that described by Kappel

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et al. (2012). Though the stray light has minimal effect at the wavelengths

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investigated in this paper, we include this description of our stray light cor-

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rection process in ourder to document this method and to allow reference to

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it from future work that we intend to carry out.

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Following the correction for the scattered light, in order to normalize

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the observations for long-term cross-comparisons, we apply a limb darkening

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correction to the data. In previous work, McGouldrick et al. (2008, 2012)

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utilized the corrections of Carlson et al. (1993). Here, we capitalize upon

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the efforts by Longobardo et al. (2012) to quantify the limb darkening seen

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in the VIRTIS-M-IR data in several of the near infrared spectral windows.

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Longobardo et al. (2012) found variations in the limb darkening behavior as a

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function of latitude. For the windows that Longobardo et al. (2012) analyzed

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and that we study here, we use the “average” limb darkening correction

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parameters to determine a nominal radiance at zero emission angle:

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3. Results

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3.1. Long-term global tendencies

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Iemitted = Iobserved · (αλ + βλ cos θe )−1 .

Bullock and Grinspoon (2001) and others have suggested that changes in

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SO2 in the upper atmosphere could lead to changes in overall cloud coverage,

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due to a greater availability of condensable materials. Orders of magnitude

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variations are seen in the SO2 concentrations above 70km (Esposito et al.,

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1988; Marcq et al., 2012). Although the concentrations at those altitudes

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are only at the tens to hundreds of ppbv (parts per billion by volume) level,

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the scale height of the SO2 at those altitudes has been measured to be about

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1 km, indicating that an orders of magnitude larger concentration at the

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tens to hundreds of ppmv (parts per million by volume) level exists deeper

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in the atmosphere in the cloud formation regions (near 62 km at equatorial

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latitudes). Thus, large changes in SO2 could to have significant effects on the

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total mass loading of the photochemical clouds, and potentially also effects

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on the total mass available to form the deeper condensational cloud.

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Our first goal is to determine whether a long-term global trend of Venusian

cloud cover is evident in the VIRTIS-M-IR data set by examining the long-

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term trends of the radiance in the 1.74µm and 2.30µm atmospheric windows.

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In Fig. 2, we show the hemispherically averaged radiance for each of these

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two windows as a function of orbit number. Also shown in the figure is a

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linear best fit to the data, with free parameters I0 (the radiance at orbit 14

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zero), and mI (the slope of the radiance per orbit). Finally, the five rows

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represent the five incidence angle cutoffs we considered in this analysis (95◦ ,

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100◦ , 105◦ , 110◦ , and 115◦ ).

Figure 2: Southern hemisphere radiance averaged across all cubes per orbit during the lifetime of VIRTIS-M-IR for both the 1.74µm and 2.30µm windows. From top to bottom, the rows represent data subject to differing minimum solar incidence angle restrictions of 95◦ , 100◦ , 105◦ , 110◦ , and 115◦ , respectively (0◦ is Sun at zenith).

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The linear fits to the data produce radiance at orbit 0, and the average 15

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slope of the radiance in units of W m−2 sr−1 µm−1 per orbit (or per day),

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as well as one sigma standard deviation uncertainties in those parameters.

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We overplot the best fit trend line (but not the uncertainty information) in

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Fig. 2. The unaveraged data for both windows and at most incidence angle

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restrictions shown in Fig. 2 shows a significant amount of scatter, and a

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best fit linear trend line that is essentially flat, indicating that there is no

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significant global change to the observed condensational cloud cover on Venus

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over the 2.5 year lifetime of the VIRTIS-M-IR instrument. Note also that

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as the incidence angle cutoff is made more restrictive, a hint of a periodicity

260

begins to emerge from the data. However, since the larger emission angles

261

selectively remove observational data from the polar regions, it is unclear at

262

this point whether the periodicity exists throughout the southern hemisphere

263

but has been masked by noise near the terminator, or whether is a more

264

regional phenomenon.

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Because of the high level of scatter in the data, which is partly due to the

266

small field of view of the instrument making it difficult to observe the same

267

region of the atmosphere from orbit to orbit, as well as the intrinsic variability

268

within the clouds, in Fig. 3 we have smoothed the data with a seven-day box

269

car mean window. A seven-day averaging of the data approximates extending

270

the averaging over orbit done in Fig. 2 to a global average, since the period of

271

rotation at the altitudes of these clouds is approximately seven days (Hueso

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et al., 2015).

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However, upon applying a seven day moving window average of the data,

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we notice in Fig. 3 the appearance of slight trends to the mean radiance in

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each window, and evidence of shorter-term (on the order of weeks to months)

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Figure 3: Southern hemisphere radiance averaged across all cubes per orbit during the lifetime of VIRTIS-M-IR for both the 1.74µm and 2.30µm windows, but further averaged with a seven day moving window to approximate a global average radiance. As in Fig. 2, from top to bottom, solar incidence angle restrictions of 95◦ , 100◦ , 105◦ , 110◦ , and 115◦ , are represented.

276

variations in the cloud cover from radiance changes. The overall increase in

277

radiance indicated by the mission-long linear best fit trend lines suggest that

278

the overall cloud cover of Venus may have been thinning during the course of 17

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the mission. However, visual inspection of the plots indicates that for most

280

incidence angle cutoffs this apparent trend is small compared to the overall

281

scatter in radiance that is observed on an observation-to-observation basis.

282

If the decrease in the SO2 observed is driven by a conversion into H2 SO4 and

283

thence into clouds, then the results presented here, though only of a 2.5 year

284

duration, are inconsistent with that explanation, at least on the global scale.

285

However, the highly spatially variable nature of the observed SO2 variations,

286

and of the thickness of the condensational clouds, means that a regional scale

287

relationship cannot yet be ruled out.

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The spectral registration of the VIRTIS-M-IR spectrometer varies with

289

temperature (Moinelo et al., 2010), so that the mapping from band number

290

to wavelength can vary with time. Thus, in generating the plots shown above,

291

we use the radiance within the wavelength band that is closest to the defining

292

wavelength for each particular data cube. These changes in band number

293

associated with a particular wavelength can produce small but detectable

294

variations in the measured flux. These variations are discussed at length by

295

Kappel et al. (2012), who concluded that they are the result of errors in

296

the ground calibration. Rather than reinvent the recalibration performed by

297

Kappel et al. (2012), we attempt to rule out this so called Odd-Even effect

298

as a source of the variations we see by additionally performing our analysis

299

using data that have been spectrally integrated across the entire range of

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each spectral window. This is similar to what is described by McGouldrick

301

et al. (2012), for the 1.74µm window analyzed there. Here, we integrate

302

the 1.74µm window from 1.67µm to 1.80µm; and the 2.30µm window from

303

2.15µm to 2.60µm. In this analysis of spectrally integrated data, the Even-

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Odd effect should be reduced, as overestimations of measured flux in half the

305

bands will be roughly balanced by underestimations of the flux in the other

306

half of the bands.

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Fig. 4 shows the long term trends for the seven day averaging and spec-

308

trally integrated windows. We see that both the long-term trend of increasing

309

radiance, as well as the periodic shorter-term variations appear in the inte-

310

grated data. In fact, the relative magnitude of the day-to-day variations

311

compared with the average radiance measured is slightly smaller for the inte-

312

grated case, suggesting that the contribution to the measured radiance from

313

the Odd-Even effect has been minimized by this integration, and that that

314

effect is small for the present analysis. The data in Fig. 4 are best com-

315

pared with the data in Fig. 3, since each has had the averaging extended

316

across multiple orbits. Not shown, these similarities between the single band

317

and integrated radiance for the unaveraged data are mirrored in the moving

318

window averaged data.

319

3.2. Mission-long latitudinal mean radiances

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One of our long-term goals in this project is to characterize the short-term

321

behavior and variability of the condensational clouds of Venus. Previous work

322

by McGouldrick et al. (2012) suggested that typical timescales of evolution

323

were around 30 hours, but that work only analyzed two orbits’ worth of

324

observations. Part of the difficulty in establishing patterns of variability

325

among the condensational clouds is in quantifying what level of variability can

326

be attributed to cloud variations. For example, Carlson et al. (1993) showed

327

that variations in the clouds produce roughly 20 : 1 brightness contrast

328

ratios at 2.30µm and roughly 5 : 1 brightness ratios at 1.74µm. However,

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Figure 4: Southern hemisphere radiance averaged across all cubes per orbit during the lifetime of VIRTIS-M-IR for both the 1.74µm and 2.30µm windows spectrally integrated across the entire spectral windows. The same incidence angle restrictions noted in Fig. 2 and Fig. 3 are represented.

329

those contrast ratios do not account for the large magnitude of latitudinal

330

variance in the clouds as indicated by radiance variations observed by Crisp

331

et al. (1989) and Chanover et al. (1998). Within a given latitude region, the

332

contrasts are about half of these global values. In previous analysis of short20

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term evolution of the clouds, McGouldrick et al. (2012) defined a cloud or hole

334

boundary according to closed radiance contours at a 0.02 W m−2 sr−1 µm−1

335

resolution. In order to reduce the arbitrariness of our cloud definition, we

336

here develop a latitudinal profile of radiance for each of the windows, along

337

with their one-sigma standard deviations. In future analysis of short-term

338

cloud evolution, we plan to use these latitudinally resolved estimates of long-

339

term variability to define the presence or absence of a local cloud or hole

340

phenomenon.

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In Fig. 5, we show the latitudinal profiles for each of the spectral windows.

342

These figures assimilate the entire VIRTIS-M-IR dataset that fit our criteria

343

detailed in Section 2 above. Note the local maximum in radiance evident

344

near 50◦ latitude in both the 2.30µm and 1.74µm data. This has been seen

345

since the NIR observations began in the 1980’s, and has been explained as

346

evidence of the interaction between the photochemical cloud production, the

347

condensational cloud production, and the near-global meridional Hadley-like

348

circulation by Imamura and Hashimoto (1998). The optically thick cloud

349

near the polar collar is also evident as the strong decrease in radiance pole-

350

ward of that radiance maximum. The slight but sharp increase in radiance

351

very near to the pole in the 1.74µm profile is possibly due to sunlight in the

352

atmosphere scattered across the polar terminator, or is due to the deep emis-

353

sion from the polar vortex. In the 1.74µm and 2.30µm profiles, we also see

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a significant but smaller increase in the variability of the clouds (evidenced

355

by an increase in the standard deviation about the mean) in the equatorial

356

region. However, since the orbit of Venus Express limited the number of

357

observations in this region that could match our criteria, and since these

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359

to potential errors or uncertainties in the limb darkening correction – the

360

variation seen at equatorial latitudes should be taken cum grano salis. It is

361

hoped that observations by JAXA’s Akatsuki spacecraft (Nakamura et al.,

362

2007), having begun science operations from a more equatorial orbit in April

363

of 2016, will help to resolve the level of variability seen here by VIRTIS-M-IR

364

on Venus Express in the equatorial clouds of Venus.

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0.15

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observations tend also to be very close to the limb – hence more susceptible

latitude

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Figure 5: Zonally and temporally averaged mean radiance with their standard deviations as functions of latitude for the 1.74µm window, the 2.30µm window, and the Carlson et al. (1993) size parameter, in addition to geometrical data such as incidence and emission angles, surface elevation, and local solar time. The data here are subject to a minimum incidence angle of 95◦ .

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Also shown in Fig. 5 is the Carlson et al. (1993) size parameter: I1.74µm . (I2.30µm )0.53

(5)

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m=

Carlson et al. (1993) showed that this weighted ratio of the 1.74µm and

367

2.30µm emitted radiance can be used to estimate typical particle sizes in the

368

Venus atmosphere, due to the relative Mie scattering properties of Mode 2

369

and Mode 3 particles at these wavelengths. Wilson et al. (2008) applied

370

this technique to a handful of early orbits of Venus Express, and found a

371

significant increase in size parameter in the polar regions, when applying a

372

zonal average, similar to what we have done here, but for individual orbits.

373

Similarly, Barstow et al. (2012) found that the ratio of the Mode 3:Mode 20

374

particle numbers increased toward the pole. This increase is likely the result

375

of the deeper altitude in which the condensational clouds exist at polar lat-

376

itudes. We reproduce this strong increase in size parameter (hence, particle

377

size) poleward of about 50◦ . We also see a slight increase in size parame-

378

ter seen with a local miximum near 20◦ was not reported by Barstow et al.

379

(2012). However, a reanalysis of the Barstow et al. (2012) work, presented

380

in the Barstow (2012) doctoral thesis, does report a similar phenomenon

381

with regard to the relative Mode 20 :Mode 3 particle number ratio. As can

382

be seen in Fig. 5, the standard deviation about the mean is increasing at

383

these latitudes, due to the paucity of data and large emission angle of the

384

observations. Because we calculate the size parameter for a single band (we

385

do not use the spectrally integrated calculations), the size parameter calcu-

386

lation is probably also still somewhat affected by the Odd-Even effect. If

387

real, this increase could represent a slight increase in the relative population

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of Mode 3:Mode 20 particles at these latitudes, followed by a reversal of the

389

trend (i.e., to an increase in Mode 20 relative to Mode 3) from about 20◦ to

390

about 50◦ latitude. Such a trend would be consistent with cloud formation

391

altered by the meridional circulation modelled by Imamura and Hashimoto

392

(1998). That is, the Mode 3 population would be driven by convection in the

393

condensational clouds maximized near the equator, while the Mode 2 popu-

394

lation would steadily increase as the parcels are carried from the equator to-

395

ward the poles. Since the gravitational sedimentation velocity of the Mode 2

396

particles is so slow, they simply accumulate in the observable cloud, slowly

397

skewing the population from larger to smaller particles, until the downwelling

398

branch takes over near 50◦ latitude. However, this slight increase in the size

399

parameter should also be taken with a grain of salt, since the large emission

400

angle, low observation frequency, and possible calibration artifacts may still

401

be playing significant roles in this calculation. Furthermore, the retrievals

402

by Haus et al. (2014) did not find an increase in particles size at equatorial

403

latitudes. It is anticipated that JAXA’s Akatsuki spacecraft, observing from

404

a more equatorial vantage point, will soon be able to resolve the veracity of

405

this observation.

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The average surface elevation observed in the data that satisfy our cri-

407

teria shows that lower elevations are slightly favored in the polar regions

408

compared with the elevations observed near the equatorial regions. How-

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ever, the total range of average surface elevations observed is less than one

410

kilometer. The emission and incidence angle profiles are as expected from a

411

spacecraft imaging mostly the night side of a planet from a highly eccentric

412

and polar orbit. Namely, low emission angle near the pole, while the equator

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is imaged mostly near the limb; and near-terminator (low incidence angles)

414

near the poles, with gradually larger incidence angles at lower latitudes. The

415

effect of the incidence angle on the measured parameters is negligible. The

416

primary effect being a reduction in how far into the polar regions the analysis

417

can obtain data that fit the incidence angle criterion. Therefore, we do not

418

reproduce the latitudinal profiles for all incidence angle cutoffs.

419

3.3. Regional Temporal Behavior

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Note again from Fig. 5 the significant changes in radiance as a func-

421

tion of latitude within all of the near infrared spectral windows. This large

422

amount of variability, and the differing frequency of observation as a func-

423

tion of latitude suggests that we ought to consider geographic sub-regions

424

when investigating possible existence of long term trends. Hence, we pro-

425

duce also zonally averaged radiance that have been averaged across 30◦ wide

426

latitude bands, in addition to the hemisphere-wide calculations we showed

427

in Section 3.1. We chose 30◦ wide regions for simplicity, and to ensure that

428

we do not subsample the data to a point where the signal begins to be lost

429

in the noise. We divide the southern hemisphere observations into polar

430

(60◦ − 90◦ ), mid-latitude (30◦ − 60◦ ) and equatorial (0◦ − 30◦ ) regions. Plots

431

of these regionally averaged data are shown in Fig. 6 for the 1.74µm and

432

2.30µm radiance, and the Carlson et al. (1993) size parameter. The best fit

433

linear trend parameters (I0 , mI ) and their uncertainties (δI0 , δmI ) for each

434

of these regions and spectral windows are shown in Table 1. In addition to

435

this, we calculate the total change in radiance expected from the beginning

436

to the end of the 921-orbit VIRTIS lifetime, if the best fit trends were to per-

437

sist throughout, and the total mission-long variability (standard deviation)

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of the radiance in each window and region. equ:w174

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Figure 6: Regionally segregated time series data for (L−R) 1.74µm radiance, 2.30µm radiance, and Carlson et al. (1993) size parameter, with seven-day averaging applied. The regions are: hemispheric (‘hem’: 0◦ − 90◦ ), equatorial (‘equ’: 0◦ − 30◦ ), mid-latitude (‘mid’:30◦ − 60◦ ), and polar (‘pol’: 60◦ − 90◦ ). Also shown is the best fit trend line to the observed data.

Our strictest criterion for considering a best fit trend (slope) to be sig-

440

nificant requires that the total change in radiance predicted from the slope

441

of the fit (i.e., Norbit × mI ) exceeds the overall variability in (i.e., the stan-

442

dard deviation of) the measured emitted radiance (σI (φ)). That is, the trend

443

is significant only if the long term trend exceeds the per-observation varia-

444

tions. Note that, as expected from the hemispherical averages, the majority

445

of the windows and regions exhibit best fit trends that are consistent with

446

a null result; that is, no change in overall cloud coverage. In fact, only the

447

mid-latitude 1.74µm radiance indicates a significant long-term trend by this

448

criterion. However, the mid-latitude region at 1.74µm and 2.30µm, and the

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449

size parameter, all exhibit overall tendencies in that are suggestive of long-

450

term trends in cloud thickness or particle size population. But, even these

451

long-term variations require several years at their currently measured rates

452

to effect a significant difference in the overall emitted radiance, hence cloud 26

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Table 1: Parameters and their uncertainties to linear best fit to shown wavelength and region. Also included is the overall standard deviation. ‘hem’ represents the hemispheric average (0◦ − 90◦ ); ‘pol’, ‘mid’, ‘equ’ represent 60◦ − 90◦ , 30◦ − 60◦ , and 0◦ − 30◦ , respectively). region I0 δ I0 mI δmI Norb × mI σI p-value 1.74µm W m−2 sr−1 µm−1 W m−2 sr−1 µm−1 d−1 W m−2 sr−1 µm−1 hem 1.094e-01 1.886e-03 1.821e-06 4.569e-06 1.677e-03 6.182e-02 0.0017 pol 9.083e-02 6.720e-04 -3.584e-05 2.160e-06 -3.301e-02 4.052e-02 < 0.0001 mid 1.240e-01 3.896e-04 5.744e-05 8.338e-07 5.290e-02 5.212e-02 < 0.0001 equ 9.923e-02 7.656e-04 5.622e-05 3.114e-06 5.178e-02 6.793e-02 < 0.0001 2.30µm W m−2 sr−1 µm−1 W m−2 sr−1 µm−1 d−1 W m−2 sr−1 µm−1 hem 3.555e-02 5.508e-04 9.752e-06 1.157e-06 8.982e-03 4.055e-02 < 0.0001 pol 2.331e-02 2.925e-04 -1.256e-05 7.176e-07 -1.157e-02 1.720e-02 < 0.0001 mid 4.497e-02 3.554e-05 3.652e-05 7.472e-08 3.363e-02 3.741e-02 < 0.0001 equ 3.456e-02 1.203e-04 3.619e-05 8.334e-07 3.333e-02 5.063e-02 < 0.0001 Size < unitless > < unitless > d−1 < unitless > hem 7.115e-01 3.750e-03 1.270e-05 9.594e-06 1.170e-02 2.053e-01 0.3720 pol 7.479e-01 2.588e-03 1.662e-05 7.172e-06 1.530e-02 2.687e-01 0.3087 mid 6.588e-01 1.266e-03 7.154e-05 3.374e-06 6.589e-02 8.933e-02 < 0.0001 equ 6.448e-01 1.946e-03 5.195e-05 4.824e-06 4.784e-02 2.761e-01 < 0.0001 Elev km km d−1 km hem -1.799e-01 2.484e-02 9.167e-05 5.749e-05 8.443e-02 6.038e-01 0.0827 pol -2.170e-01 1.840e-02 2.911e-05 4.502e-05 2.681e-02 6.287e-01 0.2742 mid -2.342e-01 7.573e-03 1.260e-04 1.144e-05 1.160e-01 5.580e-01 0.2853 equ 2.358e-01 1.702e-02 -4.717e-06 4.029e-05 -4.345e-03 5.888e-01 0.5364 Emis < deg > < deg > d−1 < deg > hem 3.045e+01 7.891e-02 4.124e-03 2.425e-04 3.798e+00 1.692e+01 0.0585 pol 2.017e+01 1.628e-01 9.252e-04 5.886e-04 8.521e-01 9.383e+00 0.0139 mid 3.225e+01 5.829e-02 6.935e-03 1.004e-04 6.387e+00 1.289e+01 0.0394 equ 5.436e+01 7.993e-02 1.103e-02 1.597e-04 1.016e+01 1.181e+01 0.0024 Inc < deg > < deg > d−1 < deg > hem 1.147e+02 1.132e-02 -4.852e-03 1.465e-04 -4.469e+00 1.537e+01 0.1937 pol 1.059e+02 5.452e-02 -3.563e-03 1.294e-04 -3.281e+00 5.886e+00 < 0.0001 mid 1.173e+02 1.240e-02 -4.885e-03 6.183e-05 -4.499e+00 1.174e+01 0.0262 equ 1.272e+02 8.688e-02 -2.186e-03 1.595e-04 -2.013e+00 1.862e+01 0.0843 LST hr hr d−1 hr hem -8.239e-01 8.726e-05 1.467e-03 1.703e-07 1.351e+00 2.458e+00 0.0017 pol -5.108e-01 9.058e-05 5.384e-04 1.833e-07 4.959e-01 1.661e+00 0.2154 mid -7.590e-01 4.815e-05 1.492e-03 1.020e-07 1.374e+00 2.682e+00 0.0056 equ -1.506e+00 1.205e-04 3.028e-03 5.436e-07 2.789e+00 2.920e+00 < 0.0001

453

cover, based on this criterion. A longer time baseline as might be provided

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454

by the Akatsuki mission could elucidate the persistence or transience of these

455

long-term trends and their significance. Another method of testing the significance of the linear trend is to apply

457

a linear regression analysis to evaluate the correlation between the estimated

458

trend line and the data, compared with the null hypothesis. We calculate

459

the p-value, which is a measure of the probability that random variations

460

can explain the observed distribution as well as the modelled trend. Hence,

461

a p-value of 0.01 indicated that there is a 1% likelihood that the observed

462

data are better fit with random perturbations, and a 99% likelihood that the

463

best fit trend is a better predictor of the observed behavior. While a small

464

value of the p-value can be interpreted to mean the null hypothesis is highly

465

unlikely, it cannot confirm the existence of the posited trend. However, a

466

large p-value can be used to rule out a linear trend in the data. Here, we

467

will assume that a p-value of less than 0.0001 (a 99.99% likelihood that the

468

best fit trend line is a better predictor of the observed changes than random

469

variations) indicates that the trend based on the best fit parameters is likely

470

to be real. The rightmost column in Table 1 shows the calculated p-value

471

for each of the parameters and regions analyzed in this paper. We find that

472

the p-value for the 1.74µm and 2.30µm radiance data in all regions is less

473

than 0.002, and is less than 0.0001 in all but the 1.74µm hemispherical data.

474

We find p-values for the size parameter to be less than 0.0001 in the mid-

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latitude and equatorial data; but larger than 0.3 for the hemispherical and

476

polar data, suggesting that the trends a lower latitudes are more reliable

477

than those at high latitude or planet-wide. However, the calculated trend

478

in the hemispheric and polar size parameter data is very shallow, so there

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is very little difference between the linear best fit and the null hypothesis,

480

once the overall average has been corrected for. Finally, among the geometric

481

parameters analyzed (emission angle, incidence angle, surface elevation, and

482

local solar time), all but a few of the quantities demonstrate relatively large

483

p-values, indicating at least that the linear best fit trends to these quantities

484

are less statistically significant than those discussed above. Furthermore, the

485

absence of significant linear trends found in these parameters suggests that

486

it is unlikely that variations in these geometric parameters are responsible

487

for the long-term trends observed in the radiance data.

488

3.4. 150 day oscillation in the mid-latitudes

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In addition to these long-term trends, a months-long periodic variation

490

can be seen in the mid-latitude region for the 1.74µm and 2.30µm data. Such

491

a periodicity is most noticeable for larger incidence angle restrictions and at

492

mid-latitudes, and was previously suggested by McGouldrick et al. (2012)

493

using a somewhat smaller subset of this data; it is reinforced here with the

494

full dataset. This periodicity is not seen at the shorter wavelengths that

495

are less cloud dominated and more surface dominated. However, this may

496

be a function of our stray light removal technique. Further analysis of the

497

variability of these surface dominated windows is underway. McGouldrick

498

et al. (2012) qualitatively estimated a period of about 140 days. Here, in

499

order to quantitatively determine the periodicity, we applied a least squares

500

sinusoidal fit analysis (LSSA) (Lomb, 1976; Scargle, 1982) to produce a fre-

501

quency spectrum of the 1.74µm radiance, shown in Fig. 7. We perform the

502

LSSA calculation by starting with the time series data shown in Fig. 3, and

503

subtracting the linear trend for the 1.74µm mid-latitude data shown in Ta-

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504

ble 1, in order to achieve a data set with a mean of zero. We then apply the

505

LSSA calculation to this adjusted radiance data. Fig. 7 shows the LSSA frequency analysis for the mid-latitude (30◦ − 60◦ )

507

data at 1.74µm, 2.30µm, the Carlson et al. (1993) size parameter, and several

508

geometric parameters, with the seven-day averaging applied (i.e., the data

509

shown in Fig. 3). As discussed previously, the seven-day moving average is

510

designed to minimize the regionalism that results from the limited field of

511

view of the VIRTIS-M instrument. By thus averaging the data, we arrive

512

more closely at a measure of the zonally averaged behavior. However, as we

513

will show later, this averaging to ensure a zonally averaged radiance does not

514

appear to affect the values of the measured periods significantly. One period

515

stands clear above all others in each of the 1.74µm and the 2.30µm radiance

516

data periodograms. At 1.74µm, this period is found to be 150.3 days, while

517

at 2.30µm it is found to be 150.5 days. This peak is rather broad, with

518

a half-width of about 20 days, indicating either that this is a quasi-period,

519

whose frequency varies with time, or we have too short a baseline of data

520

for a more precise measurement of the frequency spectrum. It is possible

521

that wavelet analysis (Bravo et al., 2014) of this dataset may resolve this

522

discrepancy; but it is subject to the same difficulties of the sporadic nature

523

and somewhat brief temporal duration of the observations.

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506

Also shown in Fig. 7 is the periodogram for the Carlson et al. (1993)

size parameter. There are no dominant peaks with significant power in the

526

frequency spectrum. Since our calculation of the size parameter involves a

527

comparison of radiance at two separate bands, it is likely that the odd-even

528

effect discussed by Kappel et al. (2012) may have more of an effect here. Not

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0.45 0.40 0.35 0.30 0.25 0.20 0.15 0.10 0.05 0.00

PT

Figure 7: Frequency spectrum for the mid-latitude 1.74µm and 2.30µm radiance, Carlson et al. (1993) size parameter, emission and incidence angles, surface elevation, local solar time, and spectrometer temperature.

only might the radiance in one of the bands fall into an enhanced or a reduced

530

sensitivity pixel of the detector, but since the wavelength registration is non-

531

linear, it is possible that the odd versus even location of each band might

532

not occur in parallel. That is, one band might be enhanced while the other

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533

is reduced. This is possibly also the reason for the larger and more variable

534

standard deviation found in the latitudinal profile of the size parameter data

535

compared with the radiances themselves, as seen in Fig. 5. The lack of a

536

significant peak in the size parameter periodogram around 150 days indicates 31

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that changes in the relative populations of Mode 20 and Mode 3 particles in

538

the clouds of Venus are not likely to be driving the observed periodicity at

539

1.74µm and 2.30µm.

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537

We compare also the periodograms of various geometrical parameters of

541

the observations, including incidence angle, emission angle, surface elevation,

542

and local solar time. None of these show a significant peak near 150 days,

543

suggesting that changes in the viewing geometry are not responsible for the

544

periodicity seen at 1.74µm and 2.30µm. Notably, the LSSA periodogram

545

does find strong evidence for periodicity in several of the geometric parame-

546

ters, For example, the emission angle and the local solar time show a strong

547

period at about 220 days and 216 days, very close to the 225 day sidereal

548

orbital period of Venus. This is not surprising, since these are both tied to

549

the the viewed phase of Venus by VIRTIS-M-IR, which evolves in parallel

550

with the orbit of Venus around the Sun. In addition, the solar incidence

551

angle and the surface elevation shows a significant peak at 115 days and

552

116 days, almost exactly the Venusian synodic (or solar) day of 116.75 days,

553

as expected. Since the observations in the present analysis are restricted to

554

the night side, and the view of the surface of Venus from VIRTIS will vary

555

along with the orbit of Venus around the Sun, then the surface data that fit

556

our criteria should be seen on a periodicity very closely tied to the synodic

557

period of Venus, or the solar day. That the LSSA finds these periodicities

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540

in the geometry data that match what would be expected a priori, from the

559

known orbital and observational parameters and criteria, lends further cre-

560

dence to the veracity of the periods measured in the analysis of the radiance

561

data and their absence in the size parameter data.

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Finally, we also compare the periodogram of the spectrometer tempera-

563

ture to the observed radiance variations. Since the wavelength registration

564

of the spectrometer is temperature dependent, and there is evidence for re-

565

maining imperfections in the calibration of the detector (Moinelo et al., 2010;

566

Kappel et al., 2012), changes in the spectrometer temperature might produce

567

spurious changes in measured radiance. However, Fig. 7 shows that the LSSA

568

found no dominant period in the spectrometer temperature. Other relevant

569

instrumental temperatures are measured and reported by the VIRTIS house-

570

keeping, including the focal plane temperature, telescope temperature, and

571

cooling point temperature. We do not reproduce those analyses here because

572

each shows nearly identical periodogram spectra, even as the magnitudes of

573

the temperatures are significantly different.

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562

We have run the LSSA analysis for a number of different averaging win-

575

dow sizes, incidence angle cutoffs, and frequency space resolutions. Although

576

the specific values of the periods change slightly in response to changes in the

577

incidence angle criterion and the size of the averaging window, the salient

578

points mentioned in the discussion of Fig. 7 remain unchanged through each

579

of these. That is, an oscillation is found in the 1.74µm and 2.30µm radiance

580

with a period of about 150 days. None of the other measured or calculated

581

quantities exhibit a dominant periodicity with a similar frequency. The emis-

582

sion angle and local solar time show periodicities of approximately the Venus

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sidereal orbital period. And the surface elevation and solar incidence angles

584

show periodicities of approximately the Venus synodic period, or solar day.

585

The results of these calculations are summarized in Table 2.

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In order to further quantify and characterize the observed variability, in 33

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Table 2: Summary of most prominant period found for each parameter for each tested incidence angle restriction, and each size of the moving window averaging. All units of periods are in days. window min(θinc ) I1.74 I2.30 size θemi θinc elevation LST 95◦ 147.4 146.9 109.2 216.7 116.8 116.8 215.9 100◦ 147.3 146.8 109.6 215.8 117.0 116.6 215.5 1 105◦ 146.7 146.4 41.7 212.7 118.8 116.8 215.5 110◦ 146.6 146.2 253.5 213.8 119.6 116.7 212.1 115◦ 144.6 145.3 247.9 211.4 145.2 119.6 232.1 95◦ 150.3 150.5 245.9 219.0 114.9 116.3 215.2 100◦ 149.9 150.3 108.9 218.5 115.7 116.0 215.1 7 105◦ 149.7 150.0 108.8 218.0 147.4 116.0 214.7 110◦ 149.7 149.9 109.0 217.6 148.7 116.0 214.4 115◦ 146.6 148.8 258.4 217.4 76.8 117.2 227.1 95◦ 150.7 151.0 254.0 218.8 113.6 116.2 215.9 100◦ 150.4 150.8 262.1 219.2 145.4 116.2 215.8 14 105◦ 150.3 150.8 109.1 219.6 146.1 116.0 215.6 110◦ 150.3 150.7 259.3 219.2 147.1 115.9 215.3 115◦ 145.8 148.8 265.9 218.8 76.7 117.1 226.5

Fig. 8, we produce period-folded plots of the parameters analyzed in Fig. 7.

588

Here, we see that the amplitude of the periodic behavior is approximately

589

as large as the the magnitude of the per-observation variability seen in the

590

data. By phase-shifting the period-folded 1.74µm radiance by about 45 days,

591

we can see that the variation can be well matched with a sinusoid with

592

an amplitude that is half of the maximum radiance measured. The phase

593

folded data suggest that the sinusoids describing the near infrared radiance

594

variations may not be quite symmetric. That is, the comparison suggests

595

that the decrease in radiance might occur slightly more quickly than the

596

corresponding increase. In Section 4, we consider potential drivers of the

597

observed variations, and a difference in the rate of increase or decrease in

598

radiance can help to discriminate among the possibilities. However, since the

599

difference between a standard and a skewed sinusoid is so slight, compared

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with the data, we do not make any conclusions based on the shape of the

601

curve at this time.

602

4. Discussion

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600

Here we explore some various drivers of the observed variations and con-

604

sider their likelihood, based on the analyzed data set and other constraints.

605

We report a possible long-term increase in 1.74µm and 2.30µm radiance

606

at mid-latitudes, that would indicate an overall reduction in total cloud opac-

607

ity in this region. This increase in mid-latitude radiances is accompanied by

608

a decrease in polar radiances. On a hemisphere-wide averaging, there is little

609

change seen in these radiances over the course of the VIRTIS-M-IR instru-

610

mental lifetime. These trends are not consistent with a scenario in which the

611

observed decrease in SO2 at higher altitudes reported by Marcq et al. (2012)

612

is coupled with a conversion of SO2 into H2 SO4 and thence into clouds. Hence

613

some other sink for the SO2 loss observed must be found. However, as the

614

observed trends are barely larger than the overall variance in the data, more

615

detailed analysis of this and future data (including the Akatsuki mission) will

616

be required for more definitive conclusions.

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Previous investigations have reported increases in wind speeds in the

618

Venus atmosphere over time (Khatuntsev et al., 2013; Kouyama et al., 2013).

619

These investigations interpret motions of high contrast features in the re-

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flected sunlight at ultraviolet wavelengths as indicators of local wind speeds

621

at an altitude of the cloud tops, around 70km above the surface of the planet.

622

There remains some ambiguity as to whether these measured winds are in-

623

dicative of the true wind speeds of the features themselves, or of the large 35

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Figure 8: Phase-folded data for the mid-latitude data, for each of the parameters shown in the previous figures, with seven-day averaging applied, assuming the period found by LSSA having the greatest spectral power for each parameter. The radiance curves are phase shifted by 45 days to align with the baseline sinusoid. Phase shifts of −75 days, 25 days, 30 days, −50 days, and 45 days have been added to the plots of size parameter, emission angle, incidence, angle, surface elevation, local solar time, and spectrometer temperature, respectively.

36

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scale dynamics (similar to the “steering winds” at 500mb on Earth that

625

transport tropical and extratropical cyclones), or of morphological or com-

626

positional changes. However, if we accept that the measured wind speeds

627

are representative of the overall dynamics of the Venus atmosphere, then the

628

increase in the mean zonal wind speeds reported by both Khatuntsev et al.

629

(2013) and Kouyama et al. (2013) would imply that some mechanism is act-

630

ing that either adds momentum to the atmosphere as a whole, or transports

631

momentum from another atmospheric region to the level of the cloud tops

632

seen in ultraviolet wavelengths. If momentum is being transported to this

633

region of the atmosphere, then so too must energy be transported. Such a

634

transport of energy could manifest itself as an increase in local temperature

635

at regions where the clouds have been accelerated by the deposition of mo-

636

mentum. Another possibility is that the energy could be trasnported in the

637

form of latent heat, but the very small mass of the Venus clouds tends to pre-

638

clude latent heat as an efficient means of energy transport. Because the vapor

639

pressure of the sulfuric acid cloud particles is so small, small changes in tem-

640

perature tend to have rapid and significant effects on the mass and opacity

641

of the Venus clouds (McGouldrick and Toon, 2007). This increase in radi-

642

ance emitted from the cloud-dominated spectral windows at equatorial and

643

mid-latitudes, coupled with the decrease in radiance at polar latitudes could

644

indicate a net transport of energy from high to low latitude over the course

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624

of these observations. Such an energy transport would be consistent with

646

the increase in momentum seen by Khatuntsev et al. (2013) and Kouyama

647

et al. (2013). It is beyond the scope of this paper to thoroughly compare

648

the variation in the previously measured wind speeds at the cloud tops using

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VMC ultraviolet data with the emitted radiance through the condensational

650

(and photochemical) clouds of Venus using VIRTIS infrared data, but we

651

note that the apprearance of a correlation suggests fertile ground for future

652

comparison.

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649

We might consider that this 150-day oscillation is a manifestation of a

654

Hadley-like meridional circulation in the clouds. If we consider a meridional

655

circulation cell that runs from the equator to about 50◦ latitude, consistent

656

with previous models by Imamura and Hashimoto (1998), then we calculate

657

an average meridional wind speed of only 0.9 m/s. Hueso et al. (2012, 2015),

658

using VIRTIS-M-Vis ultraviolet observations, and Khatuntsev et al. (2013),

659

using VMC ultraviolet observations, report meridional wind speeds peaking

660

at about 10 m/s in the poleward direction at a latitude of around 50◦ -55◦ ,

661

and decreasing to 0 m/s at the pole and equator. They each interpret this as

662

a manifestation of a hemispherical-scale Hadley-like meridional circulation

663

cell. If we assume a sinusoidal shape to the meridional wind speed as a func-

664

tion of latitude, then we can estimate the average flow speed over the entire

665

cell to be about 6 m/s. Hence, the timescale for the Hadley-like meridional

666

circulation would then be about 35 days, much shorter than the periodicity

667

measured here. Note that Hueso et al. (2015) report measured meridional

668

wind speeds of a few m/s in infrared wavelengths (corresponding to similar

669

altitudes to those inhabited by the clouds that drive the radiance variations

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653

anlayzed here). However, they also point out that their measured wind speed

671

is significantly smaller than their measured standard deviations, indicating

672

that the meridional circulation likely has its return branch at a deeper alti-

673

tude than that occupied by the clouds. Hence, for the meridional circulation

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to directly affect the properties of the condensational clouds between about

675

50 km and 57 km that are analyzed here, there would need to be a verti-

676

cal wander of the mean circulation. Similar wanderings of the meridional

677

circulation were found in VenusCAM General Circulation Model simulations

678

by Parish et al. (2011). However, subsequent analysis showed that a later

679

version of VenusCAM that addressed a number of angular momentum errors

680

did not show as significant a variation (Lebonnois et al., 2012).

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674

The 150 day oscillation is closer in magnitude to the time scale for the

682

meridional circulation assumed in the models of Imamura and Hashimoto

683

(1998). Imamura and Hashimoto (1998) prescribed a meridional Hadley-like

684

circulation with a cycle timescale of 90 days. This would correspond to a

685

maximum mid-latitude merdional cloud top wind speed of a few m/s, or a

686

factor of three or so smaller than the wind speed reported from the Venus

687

Express observations described above. Based on the results of Imamura and

688

Hashimoto (1998), who considered the effect of a variation in the magnitude

689

of the meridional circulation, a meridional Hadley-like circulation with a

690

150 day timescale would produce smaller latitudinal contrasts in cloud opac-

691

ity than those that are observed. This occurs because for slower circulations,

692

particle sedimentation timescales become moree important to the cloud par-

693

ticle lifetimes than the meridional transportation timescales. Note that the

694

Imamura and Hashimoto (1998) models did not consider effects of the zonal

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681

circulation, having treated a 2D (latitude-altitude) model. The 2D cloud

696

structure found by Imamura and Hashimoto (1998) was consistent with lat-

697

itudinal opacity variations derived from the observations of Venus by Crisp

698

et al. (1989) and Chanover et al. (1998), indicating that the magnitude of

AC 695

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ACCEPTED MANUSCRIPT

the meridional circulation that Imamura and Hashimoto (1998) proposed is

700

consistent with observations. Our long-term average latitudinal profiles also

701

are consistent with the previous work by Crisp et al. (1989) and Chanover

702

et al. (1998), suggesting that the meridional circulation remains similar to

703

that postulated by Imamura and Hashimoto (1998). However, our analysis

704

does not investigate potential temporal variations in the latitudinal profile,

705

which might indicate variations in the magnitude of the meridional circu-

706

lation. It is difficult to achieve a high level of confidence in the temporal

707

variations in latitudinal profiles using VIRTIS-M-IR data, because the spa-

708

tial coverage is so limited. Perhaps the Akatsuki mission (Nakamura et al.,

709

2016), with its more equatorially-inclined orbit, and frequent high spatial

710

resolution full-disk imaging capability, might address this issue.

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In addition to the long-term trend in the measured wind speeds, previous

712

investigators such as Khatuntsev et al. (2013) and Kouyama et al. (2013)

713

have indicated periodic variations in the wind speeds. Kouyama et al. (2013)

714

reported a 255 day period in their measured wind speeds; but this does not

715

seem to be related to the 150 day period found here. Furthermore, their

716

analysis does not find a comparable periodicity near 150 days. Khatuntsev

717

et al. (2013) reports on a number of short-period (4 − 5 days) oscillations

718

in their measured wind speeds, and also some weaker 238 day and 117 day

719

periods; but these are probably related to Venus orbital characteristics, and

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711

in any case, are not very close to the 150 day period presented in this paper.

721

We note that the 150 day period is approximately 2/3 of the Venus sidereal

722

orbital period. Perhaps the periodic variations seen in the clouds are an

723

indication of a 3:2 resonance between the meridional Hadley-like circulation

AC 720

40

ACCEPTED MANUSCRIPT

724

and solar influences (such as solar tides). Looking toward microphysical phenomena, we compare the observed pe-

726

riodicity to the sedimentation and eddy diffusion (or, effectively, convective)

727

timescales in the clouds. We noted previously that the Carlson et al. (1993)

728

size parameter does not indicate an oscillation at the period exhibited by

729

the 1.74µm and 2.30µm radiances, consistent with the findings of Barstow

730

(2012). This behavior suggests that large scale changes in the ratio of the

731

number of Mode 3 particles to the number of Mode 20 particles are not re-

732

sponsible for the radiance variations observed. Now, there is sufficient vari-

733

ation in the calculated size parameter over the course of the observations

734

reported here that we cannot say with certainty that the size parameter does

735

not change at all during the course of the oscillation in the radiances. But

736

we can say that if changes in the size parameter were driving the radiance

737

changes seen, then a 150 day period should have appeared in the size param-

738

eter periodogram.

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725

That it does not can only mean that either 1) only Mode 3 particles

740

are growing larger (and smaller) to drive the oscillation, or 2) both Mode 20

741

and Mode 3 are increasing (and decreasing) in total number concentration

742

at similar rates. For the remainder of the discussion in this paragraph, we

743

invite the reader to please consult Figure 1a of Grinspoon et al. (1993).

744

That figure shows the extinction coefficients of the four traditional modes

CE

PT

739

of cloud particles generally used in radiative transfer analysis of the Venus

746

atmosphere. Note that the extinction coefficient of the Mode 3 particles is

747

essentially flat between 1.74µm and 2.30µm, while the extinction coefficient

748

for each of the Mode 2 and Mode 20 particle modes exhibits a strong gradient

AC 745

41

ACCEPTED MANUSCRIPT

with increasing wavelength between these two spectral windows. Hence, the

750

size parameter is most strongly affected by changes in the size of the Mode 2

751

(or Mode 20 ) particles, or by changes in the relative numbers of the Mode 3

752

and Mode 2 (or Mode 20 ) particles. But, it is less strongly affected by changes

753

in the size of the Mode 3 particles. In the 2.30µm radiance (cloud opacity)

754

and the 1.74µm radiance (cloud opacity), we observe parallel variations, while

755

noting an absence of a parallel variation in the size parameter. A change in

756

Mode 3 particle size alone will increase the opacity of the clouds, but will have

757

minimal effect on the size parameter, since the effect of the change in opacity

758

will be comparable at the two wavelengths. Thus, an increase in Mode 3

759

particle size, while the number remains constant, and while the Mode 20

760

number and size remain constant would be consistent with the observations

761

reported here. Similarly, if the numbers of Mode 20 and Mode 3 particles

762

increase in a comparable manner (the more traditional interpretation of the

763

size parameter), then we would expect an increase in opacity with a relatively

764

unchanged size parameter.

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749

If both modes of particles are considered to be sulfuric acid, then simple

766

growth and evaporation mechanisms would suffice to explain changes in total

767

particle number (option 2). But for one mode to increase in size while the

768

other mode does not (option 1) would require either that the two modes have

769

distinct compositions or that they are a single modal size distribution with a

CE

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765

consistent composition that has been mistaken for two distinct populations,

771

as Toon et al. (1984) have suggested. Furthermore, this would rule out

772

coagulation processes as driving the observed variations, since this would

773

preferentially increase the number of larger particles at the expense of the

AC 770

42

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smaller particles. Of course, since coalescence time scales are so slow for

775

the conditions in the condensational cloud (McGouldrick, 2007), it would be

776

difficult to imagine them driving such variations.

777

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774

Since the clouds that are the primary drivers of opacity differences at

1.74µm are located between about 50 km and 57 km, we consider the timescales

779

for particles to fall through such a 7 km distance. Furthermore, since the

780

sedimentation can only remove particles from the clouds, we need another

781

mechanism to re-supply the cloud mass. So, we consider half the period to

782

be the relevant timescale to compare to sedimentation processes. Thus, for

783

a particle falling through the Venus atmosphere from an altitude of about

784

57 km to an altitude of about 50 km in a time of about 75 days, requires

785

a sedimentation velocity of 0.11 cm/s. The gravitational sedimentation ve-

786

locity of a droplet falling through a medium is given by Seinfeld and Pandis

787

(1998) as:

M

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778

ED

vsed =

2 rp2 ρp gCc 9 µ

(6)

where rp is the radius of the particle, ρp is its mass density (about 1.75 g/cm3 ),

789

g µ is the viscosity of the medium (about 2 × 10−4 cm·s for this region of the

790

Venus atmopshere), and Cc is the unitless “Cunningham slip-correction fac-

791

tor,” which for a 0.1µm particles is about 3, is about 1.2 for a 1µm radius

792

particle, and asymptotes to 1.0 for particles with radius larger than ∼ 3µm.

793

The sedimentation velocity for a typical Mode 3 particle (3.65µm) under

AC

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PT

788

794

these consitions is 0.23 cm/s, while that of a Mode 20 particle having a

795

1.4µm radius is 0.041 cm/s, and of a Mode 2 particle with a 1.0µmradius

796

is 0.021 cm/s. For a gravitational sedimentation velocity of 0.11 cm/s, and

797

expecting a particle radius near 1µm, consistent with previous in situ and 43

ACCEPTED MANUSCRIPT

remote measurements of the Venus clouds (Knollenberg and Hunten, 1980;

799

Grinspoon et al., 1993), Eq. 6 can be solved to find a particle size, rp = 2.2µm.

800

If instead, we allow for very large particles (typical of Mode 3 and larger)

801

by using a slip correction factor of 1.0, then we find a typical particle size

802

of rp = 2.4µm. This is located between the sizes of the Mode 20 and the

803

Mode 3 particles generally considered to exist in the Venus condensational

804

clouds. Hence, it is plausible that the clearing of the clouds (the increase in

805

radiance) is consistent with rainout of the typically 1 − 3 µm-sized droplets

806

in the Venus condensational clouds. If we consider instead a 10 km thick

807

layer through which the particles must fall – which is plausible since a 47 km

808

cloud base is not unreasonable, based on other analyses (Barstow et al.,

809

2012) – then we find a typical particle size of 2.6 − 2.8µm, which is even

810

closer to the Mode 3 population. However, if the Mode 3 particles are sim-

811

ply a large-radius tail of the Knollenberg and Hunten (1980) Mode 2, as

812

suggested by Toon et al. (1984), then the typical modal radius of Mode 20

813

would be pulled to larger values, possibly consistent with these calculations.

814

In fact, these calculated modal radii would equate to effective radii (i.e.,

815

area-averaged radii) of between 2.8µm and 3.7µm, a range that includes

816

the effective radii found in microphysics simulations of the condensational

817

cloud driven by radiative-dynamical feedback (McGouldrick and Toon, 2007;

818

McGouldrick, 2016). Note also that changes in the typical radius of cloud

CE

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798

particles in the range from 2.2µm to 2.8µm will have minimal effect on the

820

Carlson et al. (1993) size parameter in most cases, since the Mie scattering

821

spectrum would more closely resemble Mode 3 than Mode 20 at these radii,

822

and hence would lie in a relatively flat part of the Mie scattering spectrum,

AC 819

44

ACCEPTED MANUSCRIPT

823

according to previous work by Grinspoon et al. (1993), cf. their Figure 1a. If we next consider the particle lifetime being driven by the eddy diffusion

825

time scale, (∆z)2 /κdif f , then we find that a typical eddy diffusion coefficient

826

of κdif f = 8 m2 /s is required to fully mix a 10 km thick region within the

827

75 day observed timescale, while an eddy diffusion coefficient of 15 m2 /s is

828

required to fully mix a 7 km layer. Each of these also are consistent with

829

the time-averaged eddy diffusion coefficients that were obtained from the

830

radiative-dynamical simulations by McGouldrick and Toon (2007).

832

AN US

831

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824

Finally, the radiative time constant for cooling from the altitude of the condensational clouds of Venus can be calculated as

F

,

(7)

M

τrad =

cp Pg Tmean

where P/g is the total atmospheric column mass above the altitude in ques-

834

tion (in this case, the condensational cloud tops at about 50 kPa), cp ∼

835

800 J/kg/K is the specific heat capacity of the Venus atmosphere averaged

836

across that layer, Tmean ∼ 230 K is the mean temperature above the cloud

ED

833

tops, and F = 157 W/m2 is the emitted flux. The values of the atmospheric

838

values listed above are calculated from the standard Venus International

839

Reference Atmosphere (Seiff et al., 1985). The emitted flux is calculated by

840

assuming that Venus has a Bond albedo of 0.76 (Moroz et al., 1985) and that

841

the globally averaged emitted flux exactly balances the globally averaged

842

incident solar flux. Performing this calculation, we find a radiative cooling

843

time scale of about 76 days, almost exactly half the observed periodicity.

844

Combining this with the eddy diffusional time scale above (which was driven

845

by radiative heating of cloud base and cooling from the condensational cloud

AC

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837

45

ACCEPTED MANUSCRIPT

tops), we suggest that the 150 day period we see in the 1.74µm mid-latitude

847

radiance measured by VIRTIS-M on Venus Express is sustained by an inter-

848

action between radiative cooling and microphysical cloud processes, similar

849

to those demonstrated by McGouldrick and Toon (2007).

CR IP T

846

Please note that, since the tendencies plotted here are averaged over large

851

areas and times, and since the known spatial and temporal variability in the

852

Venus condensational clouds is very large, it will be necessary to explore

853

these relationships on shorter timescales; work that we are preparing for a

854

future paper.

855

5. Conclusions

AN US

850

We have presented analysis of the complete Venus Express VIRTIS-M-IR

857

data set for night side thermal emission in the near infrared spectral win-

858

dows for all southern hemisphere observations made before the failure of the

859

instrument’s cooling system after orbit 921 (2008 October 27). We find no

860

clear evidence of global long-term increase or decrease in the overall radiance

861

(hence overall cloud coverage and thickness) from analysis of just the 1.74µm

862

and 2.30µm spectral windows that are most sensitive to the cloud variations.

863

However, at mid-latitudes, the radiance steadily increases through the dura-

864

tion of the VIRTIS-M-IR lifetime, while steadily decreasing with time near

865

the poles. This may be an indication of a transfer of cloud mass poleward,

AC

CE

PT

ED

M

856

866

an inhibiting of heat transfer by the meridional circulation, or subtle vertical

867

or meridional wanderings of the meridional circualtion cell. This long-term

868

radiance trend might represent a manifestation of heat energy transport in

869

parallel with the momentum transport indicated by the variations in zonal 46

ACCEPTED MANUSCRIPT

870

wind speeds previously inferred from cloud tracking studies. Our global analysis of the Carlson et al. (1993) size parameter demon-

872

strates an overall increase in size parameter, hence particle size, from equator

873

to pole, consistent with previous particular analysis by Wilson et al. (2008).

874

We also note a subtle increase in the size parameter peaking at about −20◦

875

latitude; but it is difficult to state its existence with certainty, due to the

876

increasing magnitude of the standard deviation of the calculated size param-

877

eter in the equatorial latitudes observed by VIRTIS-M-IR, possibly amplified

878

by instrumental artifacts.

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871

We observe in the VIRTIS-M-IR data that the 1.74µm and 2.30µm win-

880

dows demonstrate local maxima in radiance peaking around 50◦ latitude,

881

consistent with previous observations of these spectral windows, dating to

882

the time of their discovery in the 1980’s. We also measure a large amount of

883

variability to the typical cloud coverage as at latitudes between 0◦ and 60◦ ,

884

as evidenced by the very large standard deviations about the mean in the

885

cloud-dominated windows at those latitudes.

ED

M

879

Finally, we report the existence of a roughly 150-day periodic variation

887

in the cloud coverage, seen most prominently at mid-latitudes in the 1.74µm

888

radiance data. A least squares frequency analysis quantifies this period that

889

was suggested in earlier work by McGouldrick et al. (2012). The timescale

890

is consistent with a cloud formation and evolution cycle that is driven by

CE

PT

886

the radiative dynamical feedback and gravitational settling of particles with

892

sizes typical of the condensational clouds. Further modeling investigations

893

will be necessary to elucidate the drivers of this periodicity in the clouds.

AC 891

47

ACCEPTED MANUSCRIPT

894

6. Acknowledgments This work was supported through NASA Planetary Mission Data Analysis

896

Program Grant Number NNX14AP94G, and greatly benefitted from discus-

897

sions sponsored by the International Space Sciences Institute (ISSI). This

898

manuscript was much improved thanks to thoughtful and helpful reviews by

899

Nils Mueller and Jo Barstow.

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900

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