Long-term Variations of Venus’s 365 nm Albedo Observed by Venus Express, Akatsuki, MESSENGER, and the Hubble Space Telescope

Yeon Joo Lee,Takeshi Horinouchi,Manabu Yamada,Sebastien Lebonnois,Shigeto Watanabe,William M Mcclintock,Anthony Roman,Dmitrij V Titov,Masahiro Takagi,Shin-Ya Murakami,Takeshi Imamura,Sanjay Limaye,Atsushi Yamazaki,Kandis-Lea Jessup,Kazunori Ogohara,Javier Peralta,Emmanuel Marcq,Gregory Holsclaw,Santiago Perez-Hoyos

doi:10.3847/1538-3881/ab3120

Abstract

Abstract An unknown absorber near the cloud-top level of Venus generates a broad absorption feature from the ultraviolet (UV) to visible, peaking around 360 nm, and therefore plays a critical role in the solar energy absorption. We present a quantitative study of the variability of the cloud albedo at 365 nm and its impact on Venus’s solar heating rates based on an analysis of Venus Express and Akatsuki UV images and Hubble Space Telescope and MESSENGER UV spectral data; in this analysis, the calibration correction factor of the UV images of Venus Express (Venus Monitoring Camera) is updated relative to the Hubble and MESSENGER albedo measurements. Our results indicate that the 365 nm albedo varied by a factor of 2 from 2006 to 2017 over the entire planet, producing a 25%–40% change in the low-latitude solar heating rate according to our radiative transfer calculations. Thus, the cloud-top level atmosphere should have experienced considerable solar heating variations over this period. Our global circulation model calculations show that this variable solar heating rate may explain the observed variations of zonal wind from 2006 to 2017. Overlaps in the timescale of the long-term UV albedo and the solar activity variations make it plausible that solar extreme UV intensity and cosmic-ray variations influenced the observed albedo trends. The albedo variations might also be linked with temporal variations of the upper cloud SO2 gas abundance, which affects the H2SO4–H2O aerosol formation.

Highlights

The solar radiance is the principal energy source for the atmosphere of terrestrial planets, such as Earth, Venus, and Mars
We report that the long-term variations of the UV reflectivity are a real phenomenon through a comparison of four space-based instruments: imagers on board Venus Express and Akatsuki and spectrometers on board the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) and the Hubble Space Telescope (HST; Section 2)
This trend is consistent among four independent UV instruments, Venus Monitoring Camera (VMC) and Mercury Atmospheric and Surface Composition Spectrometer (MASCS) in 2007 and VMC, Space Telescope Imaging Spectrograph (STIS), and UV Imager (UVI) in 2011, using either disk-resolved or disk-integrated data

Summary

Introduction

The solar radiance is the principal energy source for the atmosphere of terrestrial planets, such as Earth, Venus, and Mars. Inhomogeneous solar radiance absorption drives atmospheric motions, from small-scale convection to large-scale global circulation. These motions distribute excess energy and transport mass and momentum in the atmosphere. Temporal variation of absorbed solar radiance is an important indication of possible changes in the atmosphere. The longterm monitoring of solar energy absorption is .

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