Modeling Exoplanet Interiors from Host Star Elemental Abundances

Hamilton, Brandi B.

January 2019

No description available.

Geological

Geophysics

exoplanet modeling

terrestrial exoplanet

geophysics

elemental abundances

planetary geology

Dry Oxidation of Ferrous and Mixed-valence Smectites and Its Implications for the Oxidative History of Mars

Araneda Noboa, Paula, 0000-0002-7727-0231

January 2021

Phyllosilicates are widespread on Noachian to Early Hesperian terrains on Mars and can help constrain the planet’s geologic and environmental history, particularly its aqueous and redox history, which in turn can provide clues about past habitability. A range of ferrous and mixed-valence smectites were synthesized and then exposed to varying O2 fluxes under dry conditions to determine if Fe/Mg trioctahedral smectites can be oxidized without an aqueous medium to form dioctahedral smectites like those observed on the surface of Mars. The appearance of a secondary peak in some unaltered samples indicates a separate phase formed during synthesis, which remained throughout the oxidation process. Partial oxidation was achieved by all samples, but only those with the highest starting Fe3+ content reached almost complete oxidation. Rapid initial oxidation was observed for all samples, but seemed to subside before oxidation was complete, indicating the process becomes unfavorable after a certain point. All three O2 fluxes used in this study were successful in partially oxidizing the smectite samples but no correlation was observed between O2 flux and actual amount of oxidation, i.e., a higher O2 flux does not necessarily result in higher production of ferric iron. The process of oxidation did cause octahedral sheet contraction in some cases; however, in some samples octahedral sheet expansion was observed with oxidation. No additional phases were formed upon oxidation and no Fe ejection was observed. Overall, the amount of oxidation observed for all samples indicates that O2 alteration of trioctahedral smectites into dioctahedral smectites can proceed under dry conditions, meaning oxidation could have continued on Mars after surface water dried up. / Geology

Geochemistry

Mineralogy

Geology

Clay minerals

Fe/Mg smectites

Martian geochemistry

Martian mineralogy

Planetary geology

Smectites

The Dynamical Evolution of the Inner Solar System

Carlisle April Wishard (16641123)

25 July 2023

<p>The solar system that we live in today bears only a passing resemblance to the solar system that existed 4.5 billion years ago. As our young star shed the gas nebula from which it was born, a disk of dust and rocky bodies emerged in the space between the Sun and Jupiter. Over the next hundred million years, this planetary disk evolved and gave rise to the terrestrial planets of the inner solar system. Clues left behind during this early stage of evolution can be seen in the orbital architecture of the modern planets, the cratering records of rocky bodies, and the signatures of the solar system's secular modes. </p> <p><br></p> <p>Past works in the fields of terrestrial planet accretion and solar system evolution typically do not include collisional fragmentation. While the mechanics of collisional fragmentation are well studied, the incorporation of this processes into simulations of terrestrial planet formation is computationally expensive via traditional methods. For this reason, many works elect to exclude collisional fragmentation entirely, improving computational performance but neglecting a known process that could have played a significant role in the formation of the solar system. In this dissertation, I develop a collisional fragmentation algorithm, called Fraggle, and incorporate it into the n-body symplectic integrator Swiftest SyMBA. Along with performance enhancements and modern programming practices, Swiftest SyMBA with Fraggle is a powerful tool for simulating the formation and evolution of the inner solar system. </p> <p><br></p> <p>In this dissertation, I use Swiftest SyMBA} with Fraggle to study the effect of collisional fragmentation on the accretion and orbital architecture of the terrestrial planets, as well as the cratering record of early Mars. I show that collisional fragmentation is a significant process in the early solar system that creates a spatially heterogeneous and time-dependent population of collisional debris that fluctuates as the solar system evolves. This ever-changing population results in cratering records that are unique across the inner solar system. The work presented in this dissertation highlights the need for independent cratering chronologies to be established for all rocky bodies in the solar system, as well as the need for future models of solar system accretion to include the effects of collisional fragmentation. </p> <p><br></p> <p>While the cratering records and orbits of the terrestrial planets are two means by which to study the solar system's ancient past, analysis of the evolution of the secular modes of the solar system offers a third method. A secular mode arises due to the precession of the orbit of a planet over time. Each body's orbit precesses at a specific fundamental frequency, or mode, that has the power to shape the orbital architecture of the solar system. I show that jumps in the eccentricity of Mars can trigger short-lived power sharing relationships between secular modes, resulting in periods in which the strength and fundamental frequencies of modes fluctuates. While evidence of these past jumps in Mars' eccentricity would likely not be visible today in the secular modes of the inner solar system, the work presented in this dissertation poses additional questions. In particular, questions related to other possible triggers of power sharing relationships, as well as the effects of power sharing relationships on the stability of small bodies during these periods of fluctuation, are particularly compelling.</p> <p><br></p> <p>The work presented in this dissertation contributes to the fields of numerical modeling, solar system evolution, collisional fragmentation, martian cratering, and secular modes and resonances. As a whole, it explores avenues by which we can understand the very earliest period of our solar system's history and develops a model that will allow for continued research in this field. </p>

solar system dynamics

Solar System Formation and Evolution

INVESTIGATING THE ROLE OF SULFIDES AND FE-OXIDES IN THE SPACE WEATHERING OF ASTEROIDAL REGOLITHS

Laura Camila Chaves (17065729)

29 September 2023

<p dir="ltr">This work focuses on understanding the response of sulfides and Fe-oxides to space weathering through the analysis of returned samples and laboratory simulations </p>

Mineralogy and crystallography

Planetary geology

Space weathering

Asteroids

Mineralogy

Itokawa

Bennu

Ryugu

Remote sensing

Writing and Designing a Chapter on Mercury and Pluto for the Textbook Exploring the Planets (explanet.info)

Spilker, Braxton Clark

01 November 2018

Exploring the Planets (http://explanet.info) is a free online college textbook covering thebasic concepts of planetary science emphasizing the character and evolution of the planetarybodies in the Solar System. The latest edition (3rd edition) was published online in 2007 by EricH Christiansen. Since the release of the third edition, two important planetary missions havebeen completed: MESSENGER (to Mercury) and New Horizons (to Pluto). These missionsprovided new information and fundamental insights into these planetary bodies, which have notyet been included in Exploring the Planets. The modern results based on recent investigations ofMercury and Pluto are critical for our understanding of the nature and history of these bodies andthe Solar System and build upon the previous information on Mercury and Pluto gained fromMariner 10 (1974-1975) and the Hubble Space Telescope, respectively. These two planetarybodies are end members in a spectrum of objects in the Solar System. Mercury is small, hot,dense, and a silicate metal rich end member of the planets, helping scientists understand thethermal and accretionary evolution of the terrestrial planets. Pluto is cold, icy, distant from theSun, and a representative object of the vast Kuiper Belt, and is thus another end member amongplanetary bodies. These two bodies refine models of how different planets will evolve over time,and how our Solar System has evolved. For these reasons, it is important to update Exploring thePlanets to summarize the current understanding of the geology of Mercury and Pluto. This way,students can better understand their formation and evolution and the implications for theevolution of our Solar System.

Mercury

Pluto

planetary geology

Exploring the Planets

Astrophysics and Astronomy

Geology

Physical Sciences and Mathematics

Mapping the Outer Margin of the Serpent Mound Impact Structure to Assess the Outer Limit of Deformation: Adams, Highland, and Pike Counties, Ohio

Vanadia, David S.

January 2017

No description available.

Geology

impact structure

cratering

rim diameter

complex crater

planetary geology

geology

Serpent Mound

Exploring the Polar Layered Deposits of Mars through spectroscopy and rover-based analog studies

Prakhar Sinha (13956780)

14 October 2022

<p>Mars’ Polar layered Deposits (PLD) accumulated over the last few millions of years due to seasonal buildup of frost trapping atmospheric gasses and incoming sediments, thereby preserving the history of Mars' recent climate in the form of an ice-rich geologic record. The PLD includes both the North Polar Layered Deposits (NPLD) and the South Polar Layered Deposits (SPLD) which are estimated to be up to 5 Mya and 100 Mya old respectively. Characterizing the contents of these deposits is essential to understand the role of geologic and climatic processes recently active on Mars. The Mars scientific community recommends robotic exploration of these icy NPLD to sample the ice and extract recent climate records; however, linking the geologic record to the climatic history will require quantitative dating of the NPLD. The SPLD is thought to be older than the north polar deposits, so the stratigraphic records of the SPLD are a window to look deeper into the climatic history of Amazonian Mars. Deciphering the paleoenvironment at the PLD requires characterization of the ice-rich deposits, however, the origin, composition, transport histories, and alteration environment of sediments within the deposits are not well constrained.</p> <p>In this study we use orbital reflectance spectroscopy to show for the first time that dateable mafic lithics are present throughout the PLD. We find significant glass as well as diverse crystalline minerals, which suggests that surface processes like impacts and volcanism were active during the late Amazonian and transported sand-sized and finer sediments from across the planet to the poles. In situ investigation of the PLD will thus provide critical quantitative age constraint on both the recent geologic and climatic histories of Mars. Previous studies have confirmed widespread detection of sulfates at the NPLD and here we show that sulfates dominate the alteration mineralogy at the SPLD suggesting acidic, oxidizing, and evaporitic conditions. Based on this more extensive survey, previously reported rare detection of smectites and hydrated silica in the SPLD is likely due to ballistic emplacement by impacts from targets on surrounding smectite-bearing Noachian terrains.</p> <p>Detrital ice-rich sediments within the PLD are a complex mixture of mafic minerals and weathering products from multiple sources and are continuously reworked. In order to investigate the material and grain-size dependent effects of chemical and physical weathering in a cold and wet basaltic environment, a rover-based Mars analog study is conducted in the glacio-fluvial-aeolian landscapes of Iceland. A DCS-based color analysis technique is employed in tandem with VNIR spectroscopy and XRF analysis to develop a strategy for conducting sediment provenance. We observe that DCS-based color analysis is a powerful tool for identifying spectral diversity, and that it has the capability to differentiate primary minerals from alteration minerals. Because color analysis can aid in identifying diverse targets for sampling within the rover’s workspace, tactically, DCS colors can be used during operations to link detrital sediments within the rover’s vicinity to surrounding bedrock sources. DCS images enhance our ability to correlate observation of surface features from orbit, extend local mineralogical interpretation to surrounding regions, optimize rover’s traverse and select science targets. </p>

Planetary geology

Mars

Polar Science

Impacts

Volcanism

VNIR Spectroscopy

Rovers

Color analysis

XRF

Earth Analogs

Iceland

Meteoroid and ejecta modeling with KFIX

Michael A Carlson (18309073)

04 April 2024

<p dir="ltr">Here we present two studies of different aspects of meteoritic impacts. The first study is about the behavior of ejecta plumes after a hypervelocity impact onto a body with an atmosphere. The second study looks at the effect vaporization has on meteoroids as they descend through Earth's atmosphere, specifically the effect permeability and meteor size have on the vaporization during their explosive fragmentation.</p><p dir="ltr">Atmospheres play an important role in ejecta deposition after an impact event. Many impact experiments and simulations neglect the effect of atmospheres. In the first study, we simulate ejecta plumes created by craters with transient diameters of 2 km and 20 km on Mars and Earth to show the difference atmospheric density and crater size have on the strength of the interaction. The interaction of ejecta with an atmosphere is explored in this study using a two-fluid hydrocode that simultaneously simulates ejecta and atmospheres as coupled, continuum fields to correctly capture the transfer of mass, energy, and momentum between the two. Here we study the effect of vaporization of plume material as well as the effect of the bow shock. We find that only the fastest ejecta is vaporized with a peak vaporized mass of 2.5x10⁵ kg, 3.5 s after the impact in our 2 km diameter Terrestrial crater. Terrestrial meteorites are preferentially formed from the fastest ejecta. However, that fastest ejecta is mostly vaporized in our simulations, so to form a Terrestrial meteorite there must be a sufficiently large impact for solid material to be ejected and not vaporize. Thus, we place a lower limit of 33 km on the size of crater needed to generate terrestrial meteorites, but the crater size needed could be substantially larger. The bow shocks in our simulations result in lofting of ejecta, especially vaporized material, in the wake of the impactor. We find that Mars' thin atmosphere slows the ejecta but does not significantly change the trajectory of the plume. Earth's atmosphere can stop and entrain ejecta particles to suspend heated material long after the majority of material has already been deposited, resulting in 4x10¹⁰ kg of material being suspended in the atmosphere 100 seconds after the impact for a 2 km diameter crater. For larger craters, we find that Earth's atmosphere has a more limited effect and ejecta more closely follows a ballistic trajectory.</p><p dir="ltr">The 1908 Tunguska bolide event and the 2013 Chelyabinsk bolide event underscore the potential damage posed by relatively small meteoroids as compared to the dinosaur-killing Chicxulub meteoroid. In this study, we model Tunguska- and Chelyabinsk-sized bolide events, extending the work of Tabetah and Melosh (2018) by exploring a larger parameter space and introducing the novel feature of material vaporization. Building upon their findings that the porosity and permeability of a meteoroid significantly influence fragmentation, we investigate additional factors such as meteoroid size, entry speed, and entry angle. Furthermore, we demonstrate that vaporization plays a crucial role, lowering the fragmentation height by extracting energy through latent heat. We find that a larger meteoroid size or higher entry speed increases the amount of vaporization that occurs while lowering the altitude of disruption of the meteoroid, and that a shallower entry angle decreases the amount of vaporization and increases the altitude of disruption. Our study not only refines the understanding of bolide events but also introduces a novel perspective with potential implications for planetary science and impact risk assessment.</p>

Meteoroids

hypervelocity entry

Hypervelocity impact

Ejecta deposition

bolide

Unraveling the Formation and Evolution of Mercury's Caloris Basin

Gregory John Gosselin (19203778)

26 July 2024

<p dir="ltr">Impact cratering is the most pervasive geologic process to have shaped our Solar System. At the largest scales, impact basins provide a window into the primordial structure of the impacted body as the mechanics governing their formation and evolution are dependent on the planet's surface structure at the time the basin was formed and for several tens of millions of years thereafter. This dissertation focuses on Mercury's Caloris basin, its largest best-preserved impact basin, to aide in characterizing the internal and surgical structure of a young Mercury.</p><p dir="ltr">Mercury has been visited by two spacecraft over the past several decades, providing us with a wealth of information about its surface morphology, its unique internal structure, and chemical makeup. Views of Caloris basin show that it preserves evidence of Mercury's early volcanic history both within its interior and in an annulus surrounding the basin, though they mask our ability to determine whether Caloris formed as a culturing basin. The plains units within the basin record the evolution of the regional stress field and its interplay with Mercury's persistent global contraction in the form of brittle deformation features and linear long-wavelength topographic undulations. </p><p dir="ltr">This dissertation attempts to unravel the sequence of events that led to Caloris basin's present-day configuration to aide in characterizing Mercury's thermomechanical structure and how it has evolved over geologic time. Impact simulations are used to reproduce Caloris basin's crustal structure which is indicative of Mercury's thermal state at the time of its formation. Results from these models are used as initial conditions in subsequent finite element models that explore how the basin evolved over geologic time. Here, it will be shown that Mercury's thermal structure and the large impact velocities experienced on the planet inhibit its formation as a multiring basin. Further, Mercury's thin silicate shell causes Caloris to undergo a unique postimpact evolution compared to other large impact basins, potentially resulting in its formation as a mascon basin without the need for the emplacement of its interior volcanic plains.</p>

Planetary geology

Geophysics not elsewhere classified

Mercury

Impact cratering

Impact basins

Quantifying Exoplanet Habitable Lifetime for a Diverse Range of Orbital Configurations

Angela Rose Burke (19199392)

24 July 2024

<p dir="ltr">The climate and habitable potential of a planet is controlled in part by its orbital configuration, including its obliquity, eccentricity, rotation period, and separation from the host star. Recent studies have suggested the exoplanets with higher eccentricity or obliquity than Earth might be able to produce larger biospheres, potentially leading to "super-habitable" worlds. However, high-obliquity and high-eccentricity planets have also been shown to be susceptible to increased water loss, which would decrease the habitable lifetime.</p><p dir="ltr">I use ExoPlaSim, a 3D General Climate Model, to investigate the habitable lifetimes of a diverse range of possible orbital configurations by varying the planetary obliquity (0-90^o), eccentricity (0-0.4), rotation period (6-96 hr), and stellar constant (1350-1650 W/m²). I study each orbital parameter independently while also co-varying obliquity with eccentricity and rotation period for the entire range of stellar constants. I find that stellar constant is the primary control on atmospheric water vapor, but also that the planetary obliquity, eccentricity and rotation period can determine the escape regime. Increasing the obliquity or eccentricity can push the climate into the significant escape regime at lower stellar constants relative to low-obliquity or low-eccentricity planets. Increasing the rotation period at high obliquities maximizes the habitable lifetime of an exoplanet.</p>

Astrobiology

Habitability

Exoplanet

Atmospheric escape