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1. The Prospect of Detecting Volcanic Signatures on an ExoEarth Using Direct Imaging

Author

Ostberg, Colby M., Guzewich, Scott D., Kane, Stephen R., Kohler, Erika, Oman, Luke D., Fauchez, Thomas J., Kopparapu, Ravi K., Richardson, Jacob, and Whelley, Patrick

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

The James Webb Space Telescope (JWST) has provided the first opportunity to study the atmospheres of terrestrial exoplanets and estimate their surface conditions. Earth-sized planets around Sun-like stars are currently inaccessible with JWST however, and will have to be observed using the next generation of telescopes with direct imaging capabilities. Detecting active volcanism on an Earth-like planet would be particularly valuable as it would provide insight into its interior, and provide context for the commonality of the interior states of Earth and Venus. In this work we used a climate model to simulate four exoEarths over eight years with ongoing large igneous province eruptions with outputs ranging from 1.8-60 Gt of sulfur dioxide. The atmospheric data from the simulations were used to model direct imaging observations between 0.2-2.0 $\mu$m, producing reflectance spectra for every month of each exoEarth simulation. We calculated the amount of observation time required to detect each of the major absorption features in the spectra, and identified the most prominent effects that volcanism had on the reflectance spectra. These effects include changes in the size of the O$_3$, O$_2$, and H$_2$O absorption features, and changes in the slope of the spectrum. Of these changes, we conclude that the most detectable and least ambiguous evidence of volcanism are changes in both O$_3$ absorption and the slope of the spectrum., Comment: 13 pages, 5 figures, 4 tables, Accepted for publication in AJ (September 26, 2023)

Published
2023

3. The case for a multi-channel polarization sensitive LIDAR for investigation of insolation-driven ices and atmospheres

Author

Brown, Adrian J., Videen, Gorden, Zubko, Evgenij, Heavens, Nicholas, Schlegel, Nicole-Jeanne, Becerra, Patricio, Choi, Young-Jun, Meyer, Colin R., Harrison, Tanya N., Hayne, Paul, Obbard, Rachel W., Michaels, Tim, Wolff, Michael J., Guzewich, Scott, Hu, Yongxiang, Newman, Claire, Grund, Christian J., Sim, Chae Kyung, Buhler, Peter B., Landis, Margaret E., Stubbs, Timothy J., Spiga, Aymeric, and Jha, Devanshu

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Earth and Planetary Astrophysics
Abstract

All LIDAR instruments are not the same, and advancement of LIDAR technology requires an ongoing interest and demand from the community to foster further development of the required components. The purpose of this paper is to make the community aware of the need for further technical development, and the potential payoff of investing experimental time, money and thought into the next generation of LIDARs., Comment: 12 pages, 1 figure. arXiv admin note: substantial text overlap with arXiv:1406.0030

Published
2020

4. Terrestrial Planets Comparative Climatology (TPCC) mission concept

Author

Tamppari, Leslie K., Brecht, Amanda, Baines, Kevin, Drouin, Brian, Esposito, Larry, Guzewich, Scott, Hofer, Richard, Jessup, Kandis Lea, Kleinböhl, Armin, Kremic, Tibor, Mischna, Michael, Schneider, Nicholas, and Spiga, Aymeric

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Earth and Planetary Astrophysics
Abstract

The authors and co-signers of the Terrestrial Planets Comparative Climatology (TPCC) mission concept white paper advocate that planetary science in the next decade would greatly benefit from comparatively studying the fundamental behavior of the atmospheres of Venus and Mars, contemporaneously and with the same instrumentation, to capture atmospheric response to the same solar forcing, and with a minimum of instrument-related variability. Thus, this white paper was created for the 2023-2032 Planetary Science Decadal Survey process. It describes the science rationale for such a mission, and a mission concept that could achieve such a mission., Comment: 8 pages including cover page with one figure on cover page

Published
2020

5. Aphelion Cloud Belt Phase Function Investigations with Mars Color Imager (MARCI)

Author

Cooper, Brittney A., Moores, John E., Battalio, Joseph M., Guzewich, Scott D., Smith, Christina L., Modestino, Rachel C. N., and Tabascio, Michael V.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

This paper constrains the scattering phase function of water ice clouds (WICs) found within Mars' Aphelion Cloud Belt (ACB), determined from orbit by processing publicly available raw Mars Color Imager (MARCI) data spanning solar longitudes (Ls) 42-170 during Mars Years (MYs) 28 and 29. MARCI visible wavelength data were calibrated and then pipeline-processed to select the pixels most likely to possess clouds. Mean phase function curves for the MARCI blue filter data were derived, and for all seasons investigated, modeled aggregates, plates, solid and hollow columns, bullet rosettes, and droxtals were all found to be plausible habits. Spheres were found to be the least plausible, but still possible. Additionally, this work probed the opposition surge to examine the slope of the linear relationship between column ice water content and cloud opacity on Mars, and found a significant dependence on particle radius. The half-width-half-maxima (HWHM) of the visible 180 degree peak of five MARCI images were found to agree better with modeled HWHM for WICs than with modeled HWHM for dust., Comment: 45 pages, 12 figures, preprint for the Journal of Planetary and Space Science

Published
2020
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6. The Impact of Planetary Rotation Rate on the Reflectance and Thermal Emission Spectrum of Terrestrial Exoplanets Around Sun-like Stars

Author

Guzewich, Scott D., Lustig-Yaeger, Jacob, Davis, Christopher Evan, Kopparapu, Ravi Kumar, Way, Michael J., and Meadows, Victoria S.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Robust atmospheric and radiative transfer modeling will be required to properly interpret reflected light and thermal emission spectra of terrestrial exoplanets. This will help break observational degeneracies between the numerous atmospheric, planetary, and stellar factors that drive planetary climate. Here we simulate the climates of Earth-like worlds around the Sun with increasingly slow rotation periods, from Earth-like to fully Sun-synchronous, using the ROCKE-3D general circulation model. We then provide these results as input to the Spectral Planet Model (SPM), which employs the SMART radiative transfer model to simulate the spectra of a planet as it would be observed from a future space-based telescope. We find that the primary observable effects of slowing planetary rotation rate are the altered cloud distributions, altitudes, and opacities which subsequently drive many changes to the spectra by altering the absorption band depths of biologically-relevant gas species (e.g., H2O, O2, and O3). We also identify a potentially diagnostic feature of synchronously rotating worlds in mid-infrared H2O absorption/emission lines., Comment: Accepted to The Astrophysical Journal

Published
2020
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7. Visibility and Line-Of-Sight Extinction Estimates in Gale Crater during the 2018/MY34 Global Dust Storm

Author

Smith, Christina L., Moores, John E., Lemmon, Mark, Guzewich, Scott D., Moore, Casey A., Ellison, Douglas, and Khayat, Alain S. J.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Northern line-of-sight extinction within Gale Crater during the 2018 global dust storm was monitored daily using MSL's Navcam. Additional observations with Mastcam (north) and Navcam (all directions) were obtained at a lower cadence. Using feature identification and geo-referencing, extinction was estimated in all possible directions. Peak extinction of $>1.1$ km$^{-1}$ was measured between sols 2086 and 2090, an order of magnitude higher than previous maxima. Northern and western directions show an initial decrease, followed by a secondary peak in extinction, not seen in column opacity measurements. Due to foreground topography, eastern direction results are provided only as limits, and southern results were indeterminable. Mastcam red and green filter results agree well, but blue filter results show higher extinctions, likely due to low signal-to-noise. Morning results are systematically higher than afternoon results, potentially indicative of atmospheric mixing., Comment: Published in Geophysical Research Letters Special Issue: Studies of the 2018/Mars Year 34 Planet-Encircling Dust Storm, 17 pages, 4 figures

Published
2019
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8. A Statistical Comparative Planetology Approach to Maximize the Scientific Return of Future Exoplanet Characterization Efforts

Author

Checlair, Jade H., Abbot, Dorian S., Webber, Robert J., Feng, Y. Katherina, Bean, Jacob L., Schwieterman, Edward W., Stark, Christopher C., Robinson, Tyler D., Kempton, Eliza, Alcabes, Olivia D. N., Apai, Daniel, Arney, Giada, Cowan, Nicolas, Domagal-Goldman, Shawn, Dong, Chuanfei, Fleming, David P., Fujii, Yuka, Graham, R. J., Guzewich, Scott D., Hasegawa, Yasuhiro, Hayworth, Benjamin P. C., Kane, Stephen R., Kite, Edwin S., Komacek, Thaddeus D., Kopparapu, Ravi K., Mansfield, Megan, Marounina, Nadejda, Montet, Benjamin T., Olson, Stephanie L., Paradise, Adiv, Popovic, Predrag, Rackham, Benjamin V., Ramirez, Ramses M., Rau, Gioia, Reinhard, Chris, Renaud, Joe, Rogers, Leslie, Walkowicz, Lucianne M., Warren, Alexandra, and Wolf, Eric. T.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Provided that sufficient resources are deployed, we can look forward to an extraordinary future in which we will characterize potentially habitable planets. Until now, we have had to base interpretations of observations on habitability hypotheses that have remained untested. To test these theories observationally, we propose a statistical comparative planetology approach to questions of planetary habitability. The key objective of this approach will be to make quick and cheap measurements of critical planetary characteristics on a large sample of exoplanets, exploiting statistical marginalization to answer broad habitability questions. This relaxes the requirement of obtaining multiple types of data for a given planet, as it allows us to test a given hypothesis from only one type of measurement using the power of an ensemble. This approach contrasts with a "systems science" approach, where a few planets would be extensively studied with many types of measurements. A systems science approach is associated with a number of difficulties which may limit overall scientific return, including: the limited spectral coverage and noise of instruments, the diversity of exoplanets, and the extensive list of potential false negatives and false positives. A statistical approach could also be complementary to a systems science framework by providing context to interpret extensive measurements on planets of particular interest. We strongly recommend future missions with a focus on exoplanet characterization, and with the capability to study large numbers of planets in a homogenous way, rather than exclusively small, intense studies directed at a small sample of planets., Comment: White paper submitted in response to the solicitation of feedback for the "2020 Decadal Survey" by the National Academy of Sciences

Published
2019

9. The Importance of 3D General Circulation Models for Characterizing the Climate and Habitability of Terrestrial Extrasolar Planets

Author

Wolf, Eric T., Kopparapu, Ravi, Airapetian, Vladimir, Fauchez, Thomas, Guzewich, Scott D., Kane, Stephen R., Pidhorodetska, Daria, Way, Michael J., Abbot, Dorian S., Checlair, Jade H., Davis, Christopher E., Del Genio, Anthony, Dong, Chaunfei, Eggl, Siegfried, Fleming, David P., Fujii, Yuka, Haghighipour, Nader, Heavens, Nicholas, Henning, Wade G., Kiang, Nancy Y., Lopez-Morales, Mercedes, Lustig-Yaeger, Jacob, Meadows, Vikki, Reinhard, Christopher T., Rugheimer, Sarah, Schwieterman, Edward W., Shields, Aomawa L., Sohl, Linda, Turbet, Martin, and Wordsworth, Robin D.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

While recently discovered exotic new planet-types have both challenged our imaginations and broadened our knowledge of planetary system workings, perhaps the most compelling objective of exoplanet science is to detect and characterize habitable and possibly inhabited worlds orbiting in other star systems. For the foreseeable future, characterizations of extrasolar planets will be made via remote sensing of planetary spectroscopic and temporal signals, along with careful fitting of this data to advanced models of planets and their atmospheres. Terrestrial planets are small and significantly more challenging to observe compared to their larger gaseous brethren; however observatories coming on-line in the coming decade will begin to allow their characterization. Still, it is not enough to invest only in observational endeavors. Comprehensive modeling of planetary atmospheres is required in order to fully understand what it is that our grand telescopes see in the night-sky. In our quest to characterize habitable, and possibly inhabited worlds, 3D general circulation models (GCMs) should be used to evaluate potential climate states and their associated temporal and spatial dependent observable signals. 3D models allow for coupled, self-consistent, multi-dimensional simulations, which can realistically simulate the climates of terrestrial extrasolar planets. A complete theoretical understanding of terrestrial exoplanetary atmospheres, gained through comprehensive 3D modeling, is critical for interpreting spectra of exoplanets taken from current and planned instruments, and is critical for designing future missions that aim to measure spectra of potentially habitable exoplanets as one of their key science goals. We recommend continued institutional support for 3D GCM modeling teams that focus on planetary and exoplanetary applications., Comment: NAS ASTRO 2020, White Paper! 2 figures, and 10 pages

Published
2019

10. Constraints on Mars Aphelion Cloud Belt Phase Function and Ice Crystal Geometries

Author

Cooper, Brittney A., Moores, John E., Ellison, Douglas J., Kloos, Jacob L., Smith, Christina L., Guzewich, Scott D., and Campbell, Charissa L.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

This study constrains the lower bound of the scattering phase function of Martian water ice clouds (WICs) through the implementation of a new observation aboard the Mars Science Laboratory (MSL). The Phase Function Sky Survey (PFSS) was a multiple pointing all-sky observation taken with the navigation cameras (Navcam) aboard MSL. The PFSS was executed 35 times during the Aphelion Cloud Belt (ACB) season of Mars Year 34 over a solar longitude range of L_s=61.4{\deg}-156.5{\deg}. Twenty observations occurred in the morning hours between 06:00 and 09:30 LTST, and 15 runs occurred in the evening hours between 14:30 and 18:00 LTST, with an operationally required 2.5 hour gap on either side of local noon due the sun being located near zenith. The resultant WIC phase function was derived over an observed scattering angle range of 18.3{\deg} to 152.61{\deg}, normalized, and compared with 9 modeled phase functions: seven ice crystal habits and two Martian WIC phase functions currently being implemented in models. Through statistical chi-squared probability tests, the five most probable ice crystal geometries observed in the ACB WICs were aggregates, hexagonal solid columns, hollow columns, plates, and bullet rosettes with p-values greater than or equal to 0.60, 0.57,0.56,0.56, and 0.55, respectively. Droxtals and spheres had p-values of 0.35, and 0.2, making them less probable components of Martian WICs, but still statistically possible ones. Having a better understanding of the ice crystal habit and phase function of Martian water ice clouds directly benefits Martian climate models which currently assume spherical and cylindrical particles., Comment: Accepted Manuscript by Planetary and Space Science

Published
2019
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11. Albedos, Equilibrium Temperatures, and Surface Temperatures of Habitable Planets

Author

Del Genio, Anthony D., Kiang, Nancy Y., Way, Michael J., Amundsen, David S., Sohl, Linda E., Fujii, Yuka, Chandler, Mark, Aleinov, Igor, Colose, Christopher M., Guzewich, Scott D., and Kelley, Maxwell

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

The potential habitability of known exoplanets is often categorized by a nominal equilibrium temperature assuming a Bond albedo of either 0.3, similar to Earth, or 0. As an indicator of habitability, this leaves much to be desired, because albedo on other planets can be very different, and because surface temperature exceeds equilibrium temperature due to the atmospheric greenhouse effect. We use an ensemble of 3-dimensional general circulation model simulations to show that for a range of habitable planets, much of the variability of Bond albedo, equilibrium temperature, and even surface temperature can be predicted with useful accuracy from incident stellar flux and stellar temperature, two known external parameters for every confirmed exoplanet., Comment: 45 pages including 8 figures, 5 tables; submitted to The Astrophysical Journal

Published
2018
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13. Highly Volcanic Exoplanets, Lava Worlds, and Magma Ocean Worlds: An Emerging Class of Dynamic Exoplanets of Significant Scientific Priority

Author

Henning, Wade G., Renaud, Joseph P., Saxena, Prabal, Whelley, Patrick L., Mandell, Avi M., Matsumura, Soko, Glaze, Lori S., Hurford, Terry A., Livengood, Timothy A., Hamilton, Christopher W., Efroimsky, Michael, Makarov, Valeri V., Berghea, Ciprian T., Guzewich, Scott D., Tsigaridis, Kostas, Arney, Giada N., Cremons, Daniel R., Kane, Stephen R., Bleacher, Jacob E., Kopparapu, Ravi K., Kohler, Erika, Lee, Yuni, Rushby, Andrew, Kuang, Weijia, Barnes, Rory, Richardson, Jacob A., Driscoll, Peter, Schmerr, Nicholas C., Del Genio, Anthony D., Davies, Ashley Gerard, Kaltenegger, Lisa, Elkins-Tanton, Linda, Fujii, Yuka, Schaefer, Laura, Ranjan, Sukrit, Quintana, Elisa, Barclay, Thomas S., Hamano, Keiko, Petro, Noah E., Kendall, Jordan D., Lopez, Eric D., and Sasselov, Dimitar D.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Physics - Atmospheric and Oceanic Physics, Physics - Geophysics
Abstract

Highly volcanic exoplanets, which can be variously characterized as 'lava worlds', 'magma ocean worlds', or 'super-Ios' are high priority targets for investigation. The term 'lava world' may refer to any planet with extensive surface lava lakes, while the term 'magma ocean world' refers to planets with global or hemispherical magma oceans at their surface. 'Highly volcanic planets', including super-Ios, may simply have large, or large numbers of, active explosive or extrusive volcanoes of any form. They are plausibly highly diverse, with magmatic processes across a wide range of compositions, temperatures, activity rates, volcanic eruption styles, and background gravitational force magnitudes. Worlds in all these classes are likely to be the most characterizable rocky exoplanets in the near future due to observational advantages that stem from their preferential occurrence in short orbital periods and their bright day-side flux in the infrared. Transit techniques should enable a level of characterization of these worlds analogous to hot Jupiters. Understanding processes on highly volcanic worlds is critical to interpret imminent observations. The physical states of these worlds are likely to inform not just geodynamic processes, but also planet formation, and phenomena crucial to habitability. Volcanic and magmatic activity uniquely allows chemical investigation of otherwise spectroscopically inaccessible interior compositions. These worlds will be vital to assess the degree to which planetary interior element abundances compare to their stellar hosts, and may also offer pathways to study both the very young Earth, and the very early form of many silicate planets where magma oceans and surface lava lakes are expected to be more prevalent. We suggest that highly volcanic worlds may become second only to habitable worlds in terms of both scientific and public long-term interest., Comment: A white paper submitted in response to the National Academy of Sciences 2018 Exoplanet Science Strategy solicitation, from the NASA Sellers Exoplanet Environments Collaboration (SEEC) of the Goddard Space Flight Center. 6 pages, 0 figures

Published
2018

14. Exoplanet Diversity in the Era of Space-based Direct Imaging Missions

Author

Kopparapu, Ravi, Hebrard, Eric, Belikov, Rus, Batalha, Natalie M., Mulders, Gijs D., Stark, Chris, Teal, Dillon, Domagal-Goldman, Shawn, Gelino, Dawn, Mandell, Avi, Roberge, Aki, Rinehart, Stephen, Kane, Stephen R., Hasegawa, Yasuhiro, Henning, Wade, Hicks, Brian, Adibekyan, Vardan, Schwieterman, Edward W., Kohler, Erika, Teske, Johanna, Hinkel, Natalie, Nixon, Conor, France, Kevin, Danchi, William, Haqq-Misra, Jacob, Wolf, Eric T., Guzewich, Scott D., Charnay, Benjamin, Arney, Giada, Hartnett, Hilairy E., Lopez, Eric D., Minniti, Dante, Renaud, Joe, Airapetian, Vladimir, Dong, Chuanfei, Del Genio, Anthony D., Trainer, Melissa, Rau, Gioia, Jensen, Adam, Way, Michael, Lisse, Carey M., Lyra, Wladimir, Marchis, Franck, Jontof-Hutter, Daniel, Young, Patrick, Pierrehumbert, Ray, Harman, Chester E., Fortney, Jonathan, Moore, Bill, Beckwith, Steven, Shock, Everett, Desch, Steve, Mandt, Kathleen E., Izenberg, Noam, Ford, Eric B., Curry, Shannon, Scharf, Caleb, and Anbar, Ariel

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

This whitepaper discusses the diversity of exoplanets that could be detected by future observations, so that comparative exoplanetology can be performed in the upcoming era of large space-based flagship missions. The primary focus will be on characterizing Earth-like worlds around Sun-like stars. However, we will also be able to characterize companion planets in the system simultaneously. This will not only provide a contextual picture with regards to our Solar system, but also presents a unique opportunity to observe size dependent planetary atmospheres at different orbital distances. We propose a preliminary scheme based on chemical behavior of gases and condensates in a planet's atmosphere that classifies them with respect to planetary radius and incident stellar flux., Comment: A white paper submitted to the National Academy of Sciences Exoplanet Science Strategy

Published
2018

15. Penitentes as the origin of the bladed terrain of Tartarus Dorsa, Pluto

Author

Moores, John E., Smith, Christina L., Toigo, Anthony, and Guzewich, Scott

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Penitentes are ablative features observed in snow and ice that, on Earth, are characterized by regular cm to tens of cm spaced bowl-shaped depressions whose edges grade into tall spires up to several meters tall (Nichols et al. 1939, Lliboutry et al. 1954, Claudin et al. 2015). While penitentes have been suggested as an explanation for anomalous radar data on Europa (Hobley et al. 2013), hitherto no penitentes have been identified conclusively on other planetary bodies. Regular ridges with spacing of 3000 m to 5000 m and a depth of $\sim500$ m with morphologies that resemble penitentes (Fig. 1) have been observed by the New Horizons spacecraft (Moore et al. 2016, Stern et al. 2015, Gladstone et al. 2016, Moore et al. 2017) in the Tartarus Dorsa (TD) region of Pluto (approximately 220-250$^\circ$ E, 0-20$^\circ$ N). Here we report simulations, based upon a recent model (Claudinet al. 2015) adapted to conditions on Pluto (Gladstone et al. 2016, Toigo et al. 2015), that reproduce both the tri-modal orientation and the spacing of these features by deepening penitentes. These penitentes deepen by of order 1 cm per orbital cycle in the present era and grow only during periods of relatively high atmospheric pressure, suggesting a formation timescale of several tens of millions of years, consistent with cratering ages and the current atmospheric loss rate of methane. This time scale, in turn, implies that the penitentes formed from initial topographic variations of no more than a few 10s of meters, consistent with Pluto's youngest terrains., Comment: 12 pages, 5 figures, 1 table, authors' accepted version of the manuscript submitted as a letter to Nature and published 12th Jan 2017. V2 uploaded to correct a typographical error

Published
2017
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18. Martian Dust

Author

Newman, Claire E., primary, Bertrand, Tanguy, additional, Fenton, Lori K., additional, Guzewich, Scott D., additional, Jackson, Brian, additional, Lewis, Stephen R., additional, Mischna, Michael A., additional, Montabone, Luca, additional, and Wellington, Danika F., additional

Published
2022
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19. A Potential Surface Warming Regime for Volcanic Super‐Eruptions Through Stratospheric Water Vapor Increases.

Author

Guzewich, Scott D., Oman, Luke D., Colarco, Peter R., Richardson, Jacob A., Whelley, Patrick L., Fauchez, Thomas J., Kopparapu, Ravi K., and Bastelberger, Sandra T.

Subjects
VOLCANIC eruptions, WATER vapor, STRATOSPHERIC aerosols, GLOBAL warming, SURFACE potential, FLOOD basalts
Abstract

Large volcanic eruptions are known to influence the climate through a variety of mechanisms including aerosol‐forced cooling and warming via emitted CO2. The January 2022 Hunga shallow underwater eruption caused an increase in stratospheric water vapor, and demonstrated how the associated positive radiative forcing can be an important component of an eruption's climate forcing. We present interactive stratospheric aerosol model simulations of super‐volcanic eruptions with a range of SO2 emissions that can produce climate warming through feedback effects produced by a large igneous province (or "flood basalt") mid‐latitude super‐eruption using Goddard Earth Observing System Chemistry Climate Model climate model simulations. The model experiments suggest total SO2 emissions ≳4,000 Tg/4 Gt generate a multi‐year period of sustained aerosol absorptive local‐heating of the upper troposphere and lower stratosphere and hence produce net climate warming after strong initial cooling. The eruptions produce stratospheric water vapor increases of factors of 8–600. The initiation of these feedbacks within the simulations suggest they could occur for individual stratovolcano eruptions of the scale of the Toba or Tambora eruptions. We note the sensitivity of our results to volcanic sulfate aerosol microphysics and model chemistry. Plain Language Summary: Volcanic eruptions are important drivers of climate change throughout Earth's history. Using climate model experiments, we examine how massive volcanic eruptions can produce warmer climate conditions through an increase in stratospheric water vapor. We find that there is a range of volcanic sulfur dioxide emissions that can produce climate warming, but that the stratospheric water vapor increase occurs in all of our model experiments. Key Points: Stratospheric water vapor increases by a factor of 8–600 for volcanic SO2 emissions of 1,875–60,000 TgVolcanic SO2 emissions ≳4,000 Tg can produce net climate warming through feedbacksAbsorptive‐heating driven increases to stratospheric water vapor likely becomes the dominant forcing for volcanic super‐eruptions [ABSTRACT FROM AUTHOR]

Published
2024
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24. 'Winter is coming'

Author

Kostov, Veselin, Allan, Daniel, Hartman, Nikolaus, Guzewich, Scott, and Rogers, Justin

Subjects
Physics - Popular Physics, Astrophysics - Earth and Planetary Astrophysics
Abstract

Those that do not sow care little about such mundane things as equinoxes or planting seasons, or even crop rotation for that matter. Wherever and whenever the reavers reave, the mood is always foul and the nights are never warm or pleasant. For the rest of the good folks of Westeros, however, a decent grasp of the long-term weather forecast is a necessity. Many a maester have tried to play the Game of Weather Patterns and foretell when to plant those last turnip seeds, hoping for a few more years of balmy respite. Tried and failed. For other than the somewhat vague (if not outright meaningless) omens of "Winter is Coming", their meteorological efforts have been worse than useless. To right that appalling wrong, here we attempt to explain the apparently erratic seasonal changes in the world of G.R.R.M. A natural explanation for such phenomena is the unique behavior of a circumbinary planet. Thus, by speculating that the planet under scrutiny is orbiting a pair of stars, we utilize the power of numerical three-body dynamics to predict that, unfortunately, it is not possible to predict either the length, or the severity of any coming winter. We conclude that, alas, the Maesters were right -- one can only throw their hands in the air in frustration and, defeated by non-analytic solutions, mumble "Coming winter? May be long and nasty (~850 days, T<268K) or may be short and sweet (~600 days, T~273K). Who knows...", Comment: 6 pages, 2 figures, 1 table. Submitted for publication in the Oldtown Journal of Evil Omens

Published
2013

25. Mission to the Trojan Asteroids: lessons learned during a JPL Planetary Science Summer School mission design exercise

Author

Diniega, Serina, Sayanagi, Kunio M., Balcerski, Jeffrey, Carande, Bryce, Diaz-Silva, Ricardo A., Fraeman, Abigail A., Guzewich, Scott D., Hudson, Jennifer, Nahm, Amanda L., Potter-McIntyre, Sally, Route, Matthew, Urban, Kevin D., Vasisht, Soumya, Benneke, Bjoern, Gil, Stephanie, Livi, Roberto, Williams, Brian, Budney, Charles J., and Lowes, Leslie L.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

The 2013 Planetary Science Decadal Survey identified a detailed investigation of the Trojan asteroids occupying Jupiter's L4 and L5 Lagrange points as a priority for future NASA missions. Observing these asteroids and measuring their physical characteristics and composition would aid in identification of their source and provide answers about their likely impact history and evolution, thus yielding information about the makeup and dynamics of the early Solar System. We present a conceptual design for a mission to the Jovian Trojan asteroids: the Trojan ASteroid Tour, Exploration, and Rendezvous (TASTER) mission, that is consistent with the NASA New Frontiers candidate mission recommended by the Decadal Survey and the final result of the 2011 NASA-JPL Planetary Science Summer School. Our proposed mission includes visits to two Trojans in the L4 population: a 500 km altitude fly-by of 1999 XS143, followed by a rendezvous with and detailed observations of 911 Agamemnon at orbital altitudes of 1000 - 100 km over a 12 month nominal science data capture period. Our proposed instrument payload - wide- and narrow-angle cameras, a visual and infrared mapping spectrometer, and a neutron/gamma ray spectrometer - would provide unprecedented high-resolution, regional-to-global datasets for the target bodies, yielding fundamental information about the early history and evolution of the Solar System. Although our mission design was completed as part of an academic exercise, this study serves as a useful starting point for future Trojan mission design studies. In particular, we identify and discuss key issues that can make large differences in the complex trade-offs required when designing a mission to the Trojan asteroids., Comment: 38 pages, 8 tables, 4 figures. Accepted for publication in Planetary and Space Science

Published
2013
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28. Formation and Stability of Salty Soil Seals in Mars‐Like Conditions. Implications for Methane Variability on Mars.

Author

Pavlov, Alexander A., Johnson, James, Garcia‐Sanchez, Raul, Siguelnitzky, Ariel, Johnson, Chris, Davis, Jeffrey, Guzewich, Scott, and Misra, Prabhakar

Subjects
SOIL crusting, GALE Crater (Mars), REGOLITH, MARTIAN atmosphere, SOIL salinity, SOIL air
Abstract

Methane spikes observed in the Martian atmosphere require the abrupt release of large amounts of methane from the Martian subsurface. The mechanism for such release has not been identified. We tested whether gas traps can form under Mars‐like conditions in the shallow Martian regolith due to salt migration in the icy soil. Experiments were performed on various soil samples in a Mars Simulation Chamber comprising different perchlorate salts and water concentrations mixed with JSC Mars‐1A. Inside the chamber, the samples were exposed to a range of temperatures from −20°C to 10°C and maintained CO2 gaseous pressure between 8 and 10 mbars. As a methane analog, Neon was injected periodically underneath the soil sample. It was found that over a wide range of Mars‐like soil parameters, a gas impermeable soil seal can form over a relatively short period (3–13 days) but requires 5%–10% of perchlorate salt content in the soil. It was determined that such a seal could sustain several mbars of neon above the Martian atmospheric pressure in the soil. Based on our experiments, substantial amounts of gaseous methane may accumulate under the soil seal and get released abruptly into the atmosphere upon seal cracking. An abrupt release of methane from the shallow subsurface may help explain methane variability at the Martian surface, as the Mars Science Laboratory detected. Plain Language Summary: Spikes of atmospheric methane on Mars, recently observed by the Mars Science Laboratory mission, are puzzling. To explain rapid variations in methane abundance in the Martian atmosphere, methane has to be released abruptly. Our experiments in the Mars simulation chamber demonstrated that perchlorate salts can be transported toward the surface regolith via water migration and subsequent sublimation. We showed that under Mars‐like conditions, the soil with migrated salts can become cemented and form a solid gas impermeable seal. Methane and other volatiles can accumulate under the soil seal. Methane seasonal variability and occasional methane spikes in the Gale crater on Mars can be due to a sudden release of methane from the soil gas pockets when the Curiosity rover breaks soil seals by moving or drilling. Key Points: Gas impermeable seals can form in Mars‐like conditions in the soil with 5%–10% perchlorate salts by mass and a shallow permafrost layerMethane could accumulate under the seal in the shallow subsurface and be released abruptly into the atmosphere when the seal breaks [ABSTRACT FROM AUTHOR]

Published
2024
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33. Dust Lifting Observations with the Mars Science Laboratory Navigation Cameras

Author

Guzewich, Scott, Mason, Emily, Lemmon, Mark, Newman, Claire, and Lewis, Kevin

Abstract

CSV files containing information on Mars Science Laboratory Navigation Camera observations of dust lifting events. Including dates, sequence identifiers, dust lifting detection statistics, locations of some dust lifting events, and their implied directions of motion. &nbsp

Published
2023
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34. Design of a Direct-Detection Wind and Aerosol Lidar for Mars Orbit

Author

Cremons, Daniel R, Abshire, James B, Sun, Xiaoli, Allan, Graham R, Haris Riris, Smith, Michael D, Guzewich, Scott D, Yu, Anthony W, and Floyd Hovis

Subjects
Earth Resources And Remote Sensing
Abstract

The present knowledge of the Mars atmosphere is greatly limited by a lack of global measurements of winds and aerosols. Hence, measurements of height-resolved wind and aerosol profiles are a priority for new Mars orbiting missions. We have designed a direct-detection lidar (MARLI) to provide global measurements of dust, winds and water ice profiles from Mars orbit. From a 400-km polar orbit, the instrument is designed to provide wind and backscatter measurements with a vertical resolution of 2 km and with resolution of 2° in latitude along track. The instrument uses a single-frequency, seeded Nd:YAG laser that emits 4 mJ pulses at 1064 nm at a 250 Hz pulse rate. The receiver utilizes a 50-cm diameter telescope and a double edge Fabry-Pérot etalon as a frequency discriminator to measure the Doppler shift of the aerosol-backscatter profiles. The receiver also includes a polarization-sensitive channel to detect the cross-polarized backscatter profiles from water ice. The receiver uses a sensitive 4 × 4 pixel HgCdTe avalanche photodiode array as a detector for all signals. Here we describe the measurement concept, instrument design, and calculate its performance for several cases of Mars atmospheric conditions. The calculations show that under a range of atmospheric conditions MARLI is capable of measuring wind speed profiles with random error of 2–4 m/s within the first three scale heights, enabling vertically resolved mapping of transport processes in this important region of the atmosphere.

Published
2020
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35. Mars 2020 Perseverance Rover Studies of the Martian Atmosphere Over Jezero From Pressure Measurements

Author

Física aplicada I, Fisika aplikatua I, Sánchez Lavega, Agustín María, Del Río Gaztelurrutia, María Teresa, Hueso Alonso, Ricardo, de la Torre Juárez, Manuel, Martínez, Germán M., Harri, Ari Matti, Genzer, Maria, Hieta, Maria, Polkko, J., Rodríguez Manfredi, José Antonio, Lemmon, Mark T., Plá García, Jorge, Toledo, Daniel, Vicente Retortillo, Álvaro, Viúdez Moreiras, Daniel, Munguira Ruiz, Asier, Tamppari, Leslie, Newman, Claire E., Gómez Elvira, Javier, Guzewich, Scott, Bertrand, Tanguy, Apestigue, Victor, Arruego, Ignacio, Wolff, Michael J., Banfield, Don, Jaakonaho, I., Makinen, T., Física aplicada I, Fisika aplikatua I, Sánchez Lavega, Agustín María, Del Río Gaztelurrutia, María Teresa, Hueso Alonso, Ricardo, de la Torre Juárez, Manuel, Martínez, Germán M., Harri, Ari Matti, Genzer, Maria, Hieta, Maria, Polkko, J., Rodríguez Manfredi, José Antonio, Lemmon, Mark T., Plá García, Jorge, Toledo, Daniel, Vicente Retortillo, Álvaro, Viúdez Moreiras, Daniel, Munguira Ruiz, Asier, Tamppari, Leslie, Newman, Claire E., Gómez Elvira, Javier, Guzewich, Scott, Bertrand, Tanguy, Apestigue, Victor, Arruego, Ignacio, Wolff, Michael J., Banfield, Don, Jaakonaho, I., and Makinen, T.

Abstract

The pressure sensors on Mars rover Perseverance measure the pressure field in the Jezero crater on regular hourly basis starting in sol 15 after landing. The present study extends up to sol 460 encompassing the range of solar longitudes from Ls ∼ 13°–241° (Martian Year (MY) 36). The data show the changing daily pressure cycle, the sol-to-sol seasonal evolution of the mean pressure field driven by the CO2 sublimation and deposition cycle at the poles, the characterization of up to six components of the atmospheric tides and their relationship to dust content in the atmosphere. They also show the presence of wave disturbances with periods 2–5 sols, exploring their baroclinic nature, short period oscillations (mainly at night-time) in the range 8–24 min that we interpret as internal gravity waves, transient pressure drops with duration ∼1–150 s produced by vortices, and rapid turbulent fluctuations. We also analyze the effects on pressure measurements produced by a regional dust storm over Jezero at Ls ∼ 155°.

Published
2023

39. Dust Lifting Observations With the Mars Science Laboratory Navigation Cameras.

Author

Guzewich, Scott D., Mason, Emily L., Lemmon, Mark T., Newman, Claire E., and Lewis, Kevin W.

Subjects
DUST, GALE Crater (Mars), LABORATORIES, MARS rovers, MARS (Planet), WIND pressure
Abstract

Martian dust lifting is believed to occur through two primary mechanisms: dust devils and wind stress forced dust lifting. Gale Crater's varied terrain and meteorology provide a unique in situ perspective on Martian dust lifting, with the Mars Science Laboratory Curiosity rover passing through both conditions and locations detrimental to dust lifting (e.g., the crater floor) and those with active sand motion and frequent dust lifting (e.g., the Bagnold Dunes). Between Ls = 248° in Mars Year 33 and Ls = 51° in Mars Year 37, over ∼3.5 Mars years and 2,300 sols, the rover's Navigation Cameras took 1,260 dedicated image sequences to search for dust lifting. Approximately 42.7% of all sequences, and 9.5% of the total images have shown active dust lifting, both dust devils and linear/straight‐line wind stress dust lifting. 79% of dust lifting events are classified as dust devils, while ∼16% are linear wind stress dust lifting and the remainder are of an indeterminate type. We analyze this large catalog of dust lifting events to provide ground truth on theoretical and model expectations of dust lifting and show that dust lifting in Gale Crater occurs throughout the Martian year, is strongly peaked in frequency near solar noon (even after accounting for observational biases), and that dust lifting shows an affinity for sand‐covered surfaces which highlights the importance of saltating sand grains for Martian dust lifting in both dust devils and wind stress forced lifting. Plain Language Summary: Airborne dust is an important control on the modern Martian climate. Dust is lifted into the air by two primary mechanisms: dust devils (rotating columns of air that are also common in dry areas on Earth) and the force of straight‐line winds acting on dust‐covered surfaces. The Mars Science Laboratory Curiosity rover Navigation Cameras have taken regular movies to search for dust lifting in the Gale Crater. Approximately 42.7% of all sequences, and 9.5% of the total images have shown active dust lifting and we analyze this large catalog of events to better understand the mechanisms and conditions that lift dust into the air on Mars. We find that dust lifting in Gale Crater is more strongly clustered near solar noon than previously expected from analyses of air pressure and that dust lifting often occurs on sand‐covered terrains, suggesting that the motion of sand grains across the surface supports dust lifting. Key Points: The Mars Science Laboratory Navigation Cameras have taken 1,260 dedicated image sequences searching for dust liftingApproximately 42.7% of all sequences and 9.5% of all images show active dust liftingDust lifting in the Gale Crater most frequently occurs on sand‐covered surfaces [ABSTRACT FROM AUTHOR]

Published
2023
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46. Estimating the Altitudes of Martian Water-Ice Clouds Above the Mars Science Laboratory Rover Landing Site

Author

Campbell, Charissa L, Kling, Alexandre M, Guzewich, Scott D, Smith, Christina L, Kloos, Jacob L, Lemmon, Mark T, Moore, Casey A, Cooper, Brittney A, Haberle, Robert M, and Moores, John E

Subjects
Space Sciences (General)
Abstract

This study retrieved estimated altitudes of Martian water-ice clouds through a comparison of observations taken by the Mars Science Laboratory (MSL, Curiosity) rover and the Mars Regional Atmospheric Modelling System (MRAMS). The vertical pointing of a Zenith Movie (ZM) allows many wind velocities and directions to be measured when clouds are observed, however without a lidar onboard the altitude of these clouds cannot be directly determined. By simulating conditions at Gale Crater with MRAMS, wind properties found in ZMs can be correlated with model outputs to estimate cloud altitudes at Gale Crater from the surface for the first time. These results are evaluated to assess any diurnal and seasonal cloud altitude patterns above Gale crater.

Published
2019
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47. The Mars Global Dust Storm of 2018

Author

Smith, Michael D and Guzewich, Scott D

Subjects
Lunar And Planetary Science And Exploration
Abstract

Mars is a dusty planet. Wind often lifts dust from the surface into the air forming clouds of dust at different locations across Mars. These dust storms typically last up to a couple days and grow to a few hundred km in size. However, once in a long while when conditions are just right, localized dust storms can interact in a way that optically thick suspended dust covers nearly the entire planet remaining aloft for weeks to months. These global-scale dust storms are the most dramatic of all weather phenomena on Mars, greatly altering the thermal structure and dynamics of the Martian atmosphere and significantly changing the global distribution of surface dust. Such a global-scale dust storm occurred during the summer of 2018, the first such event since 2007. The global dust storm was observed by an international fleet of spacecraft in Mars orbit and on the surface of Mars providing an unprecedented view of the initiation, growth, and decay of the storm as well as the physical properties of the dust during the storm's evolution. The 2018 global-scale dust storm was observed to grow from several localized dust-lifting centers with wind-blown dust suspended in the atmosphere encircling Mars after about two weeks of activity. Dust column optical depths recorded by the Opportunity and Curiosity rovers on the surface were the highest ever recorded on Mars. Peak global intensity of the dust storm was reached in early July 2018. Over the next couple months, the dust settled out and the atmosphere returned to its climatological average. Only a small number of global-scale dust storms have been observed on Mars, and so detailed analysis of the observations of this storm will provide important new insight into how these events occur and their effect on the current Mars climate.

Published
2019

48. Mars Science Laboratory Observations of the 2018/Mars Year 34 Global Dust Storm

Author

Guzewich, Scott D, Lemmon, M, Smith, C. L, Martinez, G, de Vicente-Retortillo, A, Newman, C. E, Baker, M, Campbell, C, Cooper, B, Gomez-Elvira, J, Harri, A.-M, Hassler, D, Martin-Torres, F. J, McConnochie, T, Moores, J. E, Kahanpaa, H, Khayat, A, Richardson, M. I, Smith, M. D, Sullivan, R, de la Torre Juarez, M, Vasavada, A. R, Viudez-Moreiras, D, Zeitlin, C, and Zorzano Mier, Maria-Paz

Subjects
Lunar And Planetary Science And Exploration
Abstract

Mars Science Laboratory Curiosity rover observations of the 2018/Mars year 34 global/planet-encircling dust storm represent the first in situ measurements of a global dust storm with dedicated meteorological sensors since the Viking Landers. The Mars Science Laboratory team planned and executed a science campaign lasting approximately 100 Martian sols to study the storm involving an enhanced cadence of environmental monitoring using the rover's meteorological sensors, cameras, and spectrometers. Mast Camera 880-nanometer optical depth reached 8.5, and Rover Environmental Monitoring Station measurements indicated a 97 percent reduction in incident total ultraviolet solar radiation at the surface, 30 degrees Kelvin reduction in diurnal range of air temperature, and an increase in the semidiurnal pressure tide amplitude to 40 pascals. No active dust-lifting sites were detected within Gale Crater, and global and local atmospheric dynamics were drastically altered during the storm. This work presents an overview of the mission's storm observations and initial results.

Published
2019
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49. Understanding the Water Cycle Above the North Polar Cap on Mars Using MRO CRISM Retrievals of Water Vapor

Author

Khayat, Alain S. J, Smith, Michael D, and Guzewich, Scott D

Subjects
Lunar And Planetary Science And Exploration
Abstract

The north polar cap (NPC) on Mars is the major reservoir of atmospheric water (H2O) currently on Mars. The retrieval and monitoring of atmospheric water vapor abundance are crucial for tracking the cycle of water above the NPC. The Compact Reconnaissance Imaging Spectrometer for Mars (CRISM) aboard the Mars Reconnaissance Orbiter (MRO) has provided a wealth of data that extend over 5 + Martian years, covering the time period between 2006 and 2016. CRISM is ideally suited for spring and summer observations of the north polar region (latitudes poleward of 60 °N). The retrievals of water vapor column abundances over this extended period of time were performed over both ice-free and water ice covered surfaces, extending the coverage of the water vapor maps to include the permanent cap, where a maximum value of 90 precipitable micrometers (pr–µm) is retrieved, as compared to 60 pr–µm over ice-free regions in the North Polar Region. Away from summertime maximum, modest interannual variability in the water vapor abundance is observed. Zonal averages over all the observed Martian years combined show a developing water front that shifts northward towards summer, before dissipating over the permanent cap during mid-summer. A prominent feature at latitudes around 75 °N shows large abundances of water vapor, indicating a water vapor annulus encircling the retreating edge of the seasonal polar cap during late spring. Meridional transport of water modeled here show that the annulus may be a result of the convergence of water vapor from both south and north along the retreating edge of the NPC.

Published
2018
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