Solar system

Seismic constraints from a Mars impact experiment using InSight and Perseverance

Nature Astronomy Springer Nature 6:1 (2021) 59-64

Authors:

Benjamin Fernando, Natalia Wojcicka, Ross Maguire, Simon C Staehler, Alexander E Stott, Savas Ceylan, Constantinos Charalambous, John Clinton, Gareth S Collins, Nikolaj Dahmen, Marouchka Froment, Matthew Golombek, Anna Horleston, Ozgur Karatekin, Taichi Kawamura, Carene Larmat, Tarje Nissen-Meyer, Manish R Patel, Matthieu Plasman, Lilya Posiolova, Lucie Rolland, Aymeric Spiga, Nicholas A Teanby, Geraldine Zenhaeusern, Domenico Giardini, Philippe Lognonne, Bruce Banerdt, Ingrid J Daubar

Abstract:

NASA’s InSight (Interior Exploration using Seismic Investigations, Geodesy and Heat Transport) mission has operated a sophisticated suite of seismology and geophysics instruments on the surface of Mars since its arrival in 2018. On 18 February 2021, we attempted to detect the seismic and acoustic waves produced by the entry, descent and landing of the Perseverance rover using the sensors onboard the InSight lander. Similar observations have been made on Earth using data from both crewed1,2 and uncrewed3,4 spacecraft, and on the Moon during the Apollo era5, but never before on Mars or another planet. This was the only seismic event to occur on Mars since InSight began operations that had an a priori known and independently constrained timing and location. It therefore had the potential to be used as a calibration for other marsquakes recorded by InSight. Here we report that no signal from Perseverance’s entry, descent and landing is identifiable in the InSight data. Nonetheless, measurements made during the landing window enable us to place constraints on the distance–amplitude relationships used to predict the amplitude of seismic waves produced by planetary impacts and place in situ constraints on Martian impact seismic efficiency (the fraction of the impactor kinetic energy converted into seismic energy).

Vertical distribution of aerosols and hazes over Jupiter's great red spot and its surroundings in 2016 from HST/WFC3 imaging

Journal of Geophysical Research: Planets American Geophysical Union 126:11 (2021) e2021JE006996

Authors:

Asier Anguiano‐Arteaga, Santiago Pérez‐Hoyos, Agustín Sánchez‐Lavega, José Francisco Sanz‐Requena, Patrick GJ Irwin

Abstract:

In this work, we have analyzed images provided by the Hubble Space Telescope's Wide Field Camera 3 (HST/WFC3) in December 2016, with a spectral coverage from the ultraviolet to the near infrared. We have obtained the spectral reflectivity of the GRS and its surroundings, with particular emphasis on selected, dynamically interesting regions. A spectral characterization of the GRS area is performed following two different procedures: (a) in terms of Altitude/Opacity and Color Indices (AOI and CI); (b) by means of automatic spectral classification. We used the NEMESIS radiative transfer suite to retrieve the main atmospheric parameters (e.g., particle vertical and size distributions, refractive indices) that are able to explain the observed spectral reflectivity. The optimal a priori model atmosphere used for the retrievals is obtained from a grid of about 12,000 different atmospheric models, and choosing the one that best fits South Tropical Zone (STrZ) spectra and its observed limb-darkening. We conclude that the spectral reflectivity of the GRS area is well reproduced with the following layout: (a) a stratospheric haze with its base near the 100 mbar level, with optical depths at 900 nm of the order of unity and particles with a size of 0.3 μm; (b) a more vertically extended tropospheric haze, with τ (900 nm) ∼10 down to 500 mbar and micron sized particles. Both haze layers show a stronger short wavelength absorption, and thus both act as chromophores. The altitude difference between clouds tops in the GRS and surrounding areas is ∼10 km.

A multispecies pseudoadiabat for simulating condensable-rich exoplanet atmospheres

Planetary Science Journal American Astronomical Society 2:5 (2021) 207

Authors:

Rj Graham, Tim Lichtenberg, Ryan Boukrouche, Raymond Pierrehumbert

Abstract:

Central stages in the evolution of rocky, potentially habitable planets may play out under atmospheric conditions with a large inventory of nondilute condensable components. Variations in condensate retention and accompanying changes in local lapse rate may substantially affect planetary climate and surface conditions, but there is currently no general theory to effectively describe such atmospheres. In this article, expanding on the work by Li et al., we generalize the single-component moist pseudoadiabat derivation in Pierrehumbert to allow for multiple condensing components of arbitrary diluteness and retained condensate fraction. The introduction of a freely tunable retained condensate fraction allows for a flexible, self-consistent treatment of atmospheres with nondilute condensable components. To test the pseudoadiabat's capabilities for simulating a diverse range of climates, we apply the formula to planetary atmospheres with compositions, surface pressures, and temperatures representing important stages with condensable-rich atmospheres in the evolution of terrestrial planets: a magma ocean planet in a runaway greenhouse state; a post-impact, late-veneer-analog planet with a complex atmospheric composition; and an Archean Earth-like planet near the outer edge of the classical circumstellar habitable zone. We find that variations in the retention of multiple nondilute condensable species can significantly affect the lapse rate and in turn outgoing radiation and the spectral signatures of planetary atmospheres. The presented formulation allows for a more comprehensive treatment of the climate evolution of rocky exoplanets and early Earth analogs.

Beyond runaway: initiation of the post-runaway greenhouse state on rocky exoplanets

Astrophysical Journal IOP Publishing 919:2 (2021) 130

Authors:

Ryan Boukrouche, Tim Lichtenberg, Raymond Pierrehumbert

Abstract:

The runaway greenhouse represents the ultimate climate catastrophe for rocky, Earth-like worlds: when the incoming stellar flux cannot be balanced by radiation to space, the oceans evaporate and exacerbate heating, turning the planet into a hot wasteland with a steam atmosphere overlying a possibly molten magma surface. The equilibrium state beyond the runaway greenhouse instellation limit depends on the radiative properties of the atmosphere and its temperature structure. Here, we use 1D radiative-convective models of steam atmospheres to explore the transition from the tropospheric radiation limit to the post-runaway climate state. To facilitate eventual simulations with 3D global circulation models, a computationally efficient band-gray model is developed, which is capable of reproducing the key features of the more comprehensive calculations. We analyze two factors that determine the equilibrated surface temperature of post-runaway planets. The infrared cooling of the planet is strongly enhanced by the penetration of the dry adiabat into the optically thin upper regions of the atmosphere. In addition, thermal emission of both shortwave and near-IR fluxes from the hot lower atmospheric layers, which can radiate through window regions of the spectrum, is quantified. Astronomical surveys of rocky exoplanets in the runaway greenhouse state may discriminate these features using multiwavelength observations.

Lucy Mission to the Trojan Asteroids: Science Goals

The Planetary Science Journal American Astronomical Society 2:5 (2021) 171

Authors:

Harold F Levison, Catherine B Olkin, Keith S Noll, Simone Marchi, James F Bell, Edward Bierhaus, Richard Binzel, William Bottke, Dan Britt, Michael Brown, Marc Buie, Phil Christensen, Joshua Emery, Will Grundy, Victoria E Hamilton, Carly Howett, Stefano Mottola, Martin Pätzold, Dennis Reuter, John Spencer, Thomas S Statler, S Alan Stern, Jessica Sunshine, Harold Weaver, Ian Wong