8 research outputs found
An Extremely Elongated Cloud over Arsia Mons Volcano on Mars: I. Life Cycle
We report a previously unnoticed annually repeating phenomenon consisting of
the daily formation of an extremely elongated cloud extending as far as 1800 km
westward from Arsia Mons. It takes place in the Solar Longitude (Ls) range of
~220-320, around the Southern solstice. We study this Arsia Mons Elongated
Cloud (AMEC) using images from different orbiters, including ESA Mars Express,
NASA MAVEN, Viking 2, MRO, and ISRO Mars Orbiter Mission (MOM). We study the
AMEC in detail in Martian Year (MY) 34 in terms of Local Time and Ls and find
that it exhibits a very rapid daily cycle: the cloud growth starts before
sunrise on the western slope of the volcano, followed by a westward expansion
that lasts 2.5 hours with a velocity of around 170 m/s in the mesosphere (~45
km over the areoid). The cloud formation then ceases, it detaches from its
formation point, and continues moving westward until it evaporates before the
afternoon, when most sun-synchronous orbiters observe. Moreover we
comparatively study observations from different years (i.e. MYs 29-34) in
search of interannual variations and find that in MY33 the cloud exhibits lower
activity, whilst in MY34 the beginning of its formation was delayed compared to
other years, most likely due to the Global Dust Storm. This phenomenon takes
place in a season known for the general lack of clouds on Mars. In this paper
we focus on observations, and a theoretical interpretation will be the subject
of a separate paper
The Surface Energy Budget at Gale Crater During the First 2500 Sols of the Mars Science Laboratory Mission
We use in situ environmental measurements by the Mars Science Laboratory (MSL) mission to obtain the surface energy budget (SEB) across Curiosity's traverse during the first 2500 sols of the mission. This includes values of the downwelling shortwave solar radiation, the upwelling solar radiation reflected by the surface, the downwelling longwave radiation from the atmosphere, the upwelling longwave radiation emitted by the surface, the sensible heat flux associated with turbulent motions, and the latent heat flux associated with water phase changes. We then analyze their temporal variation on different timescales and relate this to the mechanisms causing these variations. Through its Rover Environmental Monitoring Station, MSL allows for a more accurate determination of the SEB than its predecessors on Mars. Moreover, the unprecedented duration, cadence, and frequency of MSL environmental observations allow for analyses of the SEB from diurnal to interannual timescales. The results presented in this article can be used to evaluate the consistency with predictions from atmospheric numerical models, to validate aerosol radiative properties under a range of dust conditions, to understand the energy available for solar-powered missions, and to enable comparisons with measurements of the SEB by the Perseverance rover at Jezero crater.Peer reviewe
Thick discs in galaxies were most likely not accreted
The origin of thick discs in galaxies remains shrouded in mystery. A variety of formation scenarios has been proposed. Here we aim to test one such scenario where the thick disc stars are proposed to be accreted from satellite galaxies. In this scenario, in at least some galaxies a fraction of thick disc stars would rotate in a retrograde way, which would cause a large thick disc velocity lag. Here, we compare the rotation curves of the thin and the thick discs of eight edge-on galaxies observed with MUSE at the VLT. We find that the velocity lags of the thick discs are compatible with those expected from asymmetric drift. If we consider the galaxies with thick disc rotation curves in the literature, only one in about fifteen shows clear signs of an accreted thick disc. Based on simulations in the literature we estimate that if thick discs were accreted, at least one in six would show clear signs of retrograde material. Thus, there is a growing tension between the observations and the hypothesis that thick discs are made of accreted stars