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1. Artemis-enabled Stellar Imager (AeSI): A Lunar Long-Baseline UV/Optical Imaging Interferometer

Author

Rau, Gioia, Carpenter, Kenneth G., Boyajian, Tabetha, Creech-Eakman, Michelle, Foster, Julianne, Karovska, Margarita, Leisawitz, David, Morse, Jon A., Mozurkewich, David, Peacock, Sarah, Petro, Noah, Scowen, Paul, Sitarski, Breann, van Belle, Gerard, and Wilkinson, Erik

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

NASA's return to the Moon presents unparalleled opportunities to advance high-impact scientific capabilities. At the cutting edge of these possibilities are extremely high-resolution interferometric observations at visible and ultraviolet wavelengths. Such technology can resolve the surfaces of stars, explore the inner accretion disks of nascent stars and black holes, and eventually enable us to observe surface features and weather patterns on nearby exoplanets. We have been awarded Phase 1 support from NASA's Innovative Advanced Concepts (NIAC) program to explore the feasibility of constructing a high-resolution, long-baseline UV/optical imaging interferometer on the lunar surface, in conjunction with the Artemis Program. A 1996 study comparing interferometers on the Moon versus free-flyers in space concluded that, without pre-existing lunar infrastructure, free-flyers were preferable. However, with the advent of the Artemis Program, it is now crucial to revisit the potential of building lunar interferometers. Our objective is to conduct a study with the same level of rigor applied to large baseline, free-flying interferometers during the 2003-2005 NASA Vision Missions Studies. This preparation is essential for timely and effective utilization of the forthcoming lunar infrastructure. In this paper, we highlight the groundbreaking potential of a lunar surface-based interferometer. This concept study will be a huge step forward to larger arrays on both the moon and free-flying in space, over a wide variety of wavelengths and science topics. Our Phase 1 study began in April 2024, and here we present a concise overview of our vision and the progress made so far., Comment: 6 pages, 3 figures, SPIE Astronomical Telescopes + Instrumentation 2024 (Invited Paper)

Published
2024

2. The Lunar Geophysical Network Landing Sites Science Rationale

Author

Haviland, Heidi Fuqua, Weber, Renee C., Neal, Clive R., Lognonné, Philippe, Garcia, Raphaël F., Schmerr, Nicholas, Nagihara, Seiichi, Grimm, Robert, Currie, Douglas G., Dell'Agnello, Simone, Watters, Thomas R., Panning, Mark P., Johnson, Catherine L., Yamada, Ryuhei, Knapmeyer, Martin, Ostrach, Lillian R., Kawamura, Taichi, Petro, Noah, and Bremner, Paul M.

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

The Lunar Geophysical Network (LGN) mission is proposed to land on the Moon in 2030 and deploy packages at four locations to enable geophysical measurements for 6-10 years. Returning to the lunar surface with a long-lived geophysical network is a key next step to advance lunar and planetary science. LGN will greatly expand our primarily Apollo-based knowledge of the deep lunar interior by identifying and characterizing mantle melt layers, as well as core size and state. To meet the mission objectives, the instrument suite provides complementary seismic, geodetic, heat flow, and electromagnetic observations. We discuss the network landing site requirements and provide example sites that meet these requirements. Landing site selection will continue to be optimized throughout the formulation of this mission. Possible sites include the P-5 region within the Procellarum KREEP Terrane (PKT; (lat:$15^{\circ}$; long:$-35^{\circ}$), Schickard Basin (lat:$-44.3^{\circ}$; long:$-55.1^{\circ}$), Crisium Basin (lat:$18.5^{\circ}$; long:$61.8^{\circ}$), and the farside Korolev Basin (lat:$-2.4^{\circ}$; long:$-159.3^{\circ}$). Network optimization considers the best locations to observe seismic core phases, e.g., ScS and PKP. Ray path density and proximity to young fault scarps are also analyzed to provide increased opportunities for seismic observations. Geodetic constraints require the network to have at least three nearside stations at maximum limb distances. Heat flow and electromagnetic measurements should be obtained away from terrane boundaries and from magnetic anomalies at locations representative of global trends. An in-depth case study is provided for Crisium. In addition, we discuss the consequences for scientific return of less than optimal locations or number of stations., Comment: 34 pages, 12 figures, 3 tables, 1 appendix. Accepted manuscript, The Planetary Science Journal

Published
2021

3. In Situ Geochronology for the Next Decade: Mission Designs for the Moon, Mars, and Vesta

Author

Cohen, Barbara A., Young, Kelsey E., Zellner, Nicolle E. B., Zacny, Kris, Yingst, R. Aileen, Watkins, Ryan N., Warwick, Richard, Valencia, Sarah N., Swindle, Timothy D., Robbins, Stuart J., Petro, Noah E., Nicoletti, Anthony, Moriarty, III, Daniel P., Lynch, Richard, Indyk, Stephen J., Gross, Juliane, Grier, Jennifer A., Grant, John A., Ginyard, Amani, Fassett, Caleb I., Farley, Kenneth A., Farcy, Benjamin J., Ehlmann, Bethany L., Dyar, M. Darby, Daelemans, Gerard, Curran, Natalie M., van der Bogert, Carolyn H., Arevalo, Jr, Ricardo D., and Anderson, F. Scott

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

Geochronology, or determination of absolute ages for geologic events, underpins many inquiries into the formation and evolution of planets and our Solar System. Absolute ages of ancient and recent magmatic products provide strong constraints on the dynamics of magma oceans and crustal formation, as well as the longevity and evolution of interior heat engines and distinct mantle/crustal source regions. Absolute dating also relates habitability markers to the timescale of evolution of life on Earth. However, the number of geochronologically-significant terrains across the inner Solar System far exceeds our ability to conduct sample return from all of them. In preparation for the upcoming Decadal Survey, our team formulated a set of medium-class (New Frontiers) mission concepts to three different locations (the Moon, Mars, and Vesta) where sites that record Solar System bombardment, magmatism, and/or habitability are uniquely preserved and accessible. We developed a notional payload to directly date planetary surfaces, consisting of two instruments capable of measuring radiometric ages in situ, an imaging spectrometer, optical cameras to provide site geologic context and sample characterization, a trace element analyzer to augment sample contextualization, and a sample acquisition and handling system. Landers carrying this payload to the Moon, Mars, and Vesta would likely fit into the New Frontiers cost cap in our study (~$1B). A mission of this type would provide crucial constraints on planetary history while also enabling a broad suite of investigations such as basic geologic characterization, geomorphologic analysis, ground truth for remote sensing analyses, analyses of major, minor, trace, and volatile elements, atmospheric and other long-lived monitoring, organic molecule analyses, and soil and geotechnical properties., Comment: Submitted to the Planetary Science Journal, October 2020

Published
2021

4. Lunar Volatiles and Solar System Science

Author

Prem, Parvathy, Kereszturi, Ákos, Deutsch, Ariel N., Hibbitts, Charles A., Schmidt, Carl A., Grava, Cesare, Honniball, Casey I., Hardgrove, Craig J., Pieters, Carlé M., Goldstein, David B., Barker, Donald C., Needham, Debra H., Hurley, Dana M., Mazarico, Erwan, Dominguez, Gerardo, Patterson, G. Wesley, Kramer, Georgiana Y., Brisset, Julie, Gillis-Davis, Jeffrey J., Mitchell, Julie L., Szalay, Jamey R., Halekas, Jasper S., Keane, James T., Head, James W., Mandt, Kathleen E., Robinson, Katharine L., Luchsinger, Kristen M., Magaña, Lizeth O., Siegler, Matthew A., Landis, Margaret E., Poston, Michael J., Petro, Noah E., Lucey, Paul G., Killen, Rosemary M., Li, Shuai, Narendranath, Shyama, Shukla, Shashwat, Barrett, Thomas J., Stubbs, Timothy J., Orlando, Thomas M., and Farrell, William M.

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

Understanding the origin and evolution of the lunar volatile system is not only compelling lunar science, but also fundamental Solar System science. This white paper (submitted to the US National Academies' Decadal Survey in Planetary Science and Astrobiology 2023-2032) summarizes recent advances in our understanding of lunar volatiles, identifies outstanding questions for the next decade, and discusses key steps required to address these questions.

Published
2020

5. Was the Sun a Slow Rotator? -- Sodium and Potassium Constraints from the Lunar Regolith

Author

Saxena, Prabal, Killen, Rosemary M., Airapetian, Vladimir, Petro, Noah E., Curran, Natalie M., and Mandell, Avi M.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics
Abstract

While the Earth and Moon are generally similar in composition, a notable difference between the two is the apparent depletion in moderately volatile elements in lunar samples. This is often attributed to the formation process of the Moon and demonstrates the importance of these elements as evolutionary tracers. Here we show that paleo space weather may have driven the loss of a significant portion of moderate volatiles, such as sodium and potassium from the surface of the Moon. The remaining sodium and potassium in the regolith is dependent on the primordial rotation state of the Sun. Notably, given the joint constraints shown in the observed degree of depletion of sodium and potassium in lunar samples and the evolution of activity of solar analogues over time, the Sun is highly likely to have been a slow rotator. Since the young Sun's activity was important in affecting the evolution of planetary surfaces, atmospheres, and habitability in the early Solar System, this is an important constraint on the solar activity environment at that time. Finally, since solar activity was strongest in the first billion years of the Solar System, when the Moon was most heavily bombarded by impactors, evolution of the Sun's activity may also be recorded in lunar crust and would be an important well-preserved and relatively accessible record of past Solar System processes., Comment: Published in ApJL

Published
2019
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7. 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

8. Exoplanet Science Priorities from the Perspective of Internal and Surface Processes for Silicate and Ice Dominated Worlds

Author

Henning, Wade G., Renaud, Joseph P., Mandell, Avi M., Saxena, Prabal, Hurford, Terry A., Matsumura, Soko, Glaze, Lori S., Livengood, Timothy A., Airapetian, Vladimir, Asphaug, Erik, Teske, Johanna K., Schwieterman, Edward, Efroimsky, Michael, Makarov, Valeri V., Berghea, Ciprian T., Bleacher, Jacob, Rushby, Andrew, Lee, Yuni, Kuang, Weijia, Barnes, Rory, Dong, Chuanfei, Driscoll, Peter, Domagal-Goldman, Shawn D., Schmerr, Nicholas C., Del Genio, Anthony D., Jensen, Adam G., Kaltenegger, Lisa, Elkins-Tanton, Linda, Shock, Everett L., Sohl, Linda E., Quintana, Elisa, Schaefer, Laura, Barclay, Thomas S., Fujii, Yuka, Hamano, Keiko, Petro, Noah E., Lopez, Eric D., and Sasselov, Dimitar D.

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

The geophysics of extrasolar planets is a scientific topic often regarded as standing largely beyond the reach of near-term observations. This reality in no way diminishes the central role of geophysical phenomena in shaping planetary outcomes, from formation, to thermal and chemical evolution, to numerous issues of surface and near-surface habitability. We emphasize that for a balanced understanding of extrasolar planets, it is important to look beyond the natural biases of current observing tools, and actively seek unique pathways to understand exoplanet interiors as best as possible during the long interim prior to a time when internal components are more directly accessible. Such pathways include but are not limited to: (a) enhanced theoretical and numerical modeling, (b) laboratory research on critical material properties, (c) measurement of geophysical properties by indirect inference from imprints left on atmospheric and orbital properties, and (d) the purpose-driven use of Solar System object exploration expressly for its value in comparative planetology toward exoplanet-analogs. Breaking down barriers that envision local Solar System exploration, including the study of Earth's own deep interior, as separate from and in financial competition with extrasolar planet research, may greatly improve the rate of needed scientific progress for exoplanet geophysics. As the number of known rocky and icy exoplanets grows in the years ahead, we expect demand for expertise in 'exogeoscience' will expand at a commensurately intense pace. We highlight key topics, including: how water oceans below ice shells may dominate the total habitability of our galaxy by volume, how free-floating nomad planets may often attain habitable subsurface oceans supported by radionuclide decay, and how deep interiors may critically interact with atmospheric mass loss via dynamo-driven magnetic fields., Comment: A white paper submitted in response to the National Academy of Sciences 2018 Exoplanet Science Strategy solicitation, from the NASA Nexus for Exoplanetary System Science (NExSS). 6 pages, 0 figures

Published
2018

9. Volatile interactions with the lunar surface

Author

Lucey, Paul G., Petro, Noah, Hurley, Dana M., Farrell, William M., Prem, Parvathy, Costello, Emily S., Cable, Morgan L., Barker, Michael K., Benna, Mehdi, Dyar, M. Darby, Fisher, Elizabeth A., Green, Robert O., Hayne, Paul O., Hibbitts, Karl, Honniball, Casey, Li, Shuai, Malaret, Erick, Mandt, Kathy, Mazarico, Erwan, McCanta, Molly, Pieters, Carle, Sun, Xiaoli, Thompson, David, and Orlando, Thomas

Published
2022
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10. A Model of the Primordial Lunar Atmosphere

Author

Saxena, Prabal, Elkins-Tanton, Lindy, Petro, Noah, and Mandell, Avi

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

We create the first quantitative model for the early lunar atmosphere, coupled with a magma ocean crystallization model. Immediately after formation, the moon's surface was subject to a radiative environment that included contributions from the early Sun, a post-impact Earth that radiated like a mid-type M dwarf star, and a cooling global magma ocean. This radiative environment resulted in a largely Earth-side atmosphere on the Moon, ranging from $\sim$10$^4$ to $\sim$10$^2$ pascals, composed of heavy volatiles (Na and SiO). This atmosphere persisted through lid formation and was additionally characterized by supersonic winds that transported significant quantities of moderate volatiles and likely generated magma ocean waves. The existence of this atmosphere may have influenced the distribution of some moderate volatiles and created temperature asymmetries which influenced ocean flow and cooling. Such asymmetries may characterize young, tidally locked rocky bodies with global magma oceans and subject to intense irradiation., Comment: In press at EPSL

Published
2017
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11. Exoplanet Science Priorities from the Perspective of Internal and Surface Processes for Silicate and Ice Dominated Worlds

Author

Henning, Wade G, Renaud, Joseph P, Mandell, Avi M, Saxena, Prabal, Hurford, Terry A, Matsumura, Soko, Glaze, Lori S, Livengood, Timothy A, Airapetian, Vladimir, Asphaug, Erik, Teske, Johanna K, Schwieterman, Edward, Efroimsky, Michael, Makarov, Valeri V, Berghea, Ciprian T, Bleacher, Jacob, Rushby, Andrew, Lee, Yuni, Kuang, Weijia, Barnes, Rory, Dong, Chuanfei, Driscoll, Peter, Domagal-Goldman, Shawn D, Schmerr, Nicholas C, Genio, Anthony D Del, Jensen, Adam G, Kaltenegger, Lisa, Elkins-Tanton, Linda, Shock, Everett L, Sohl, Linda E, Quintana, Elisa, Schaefer, Laura, Barclay, Thomas S, Fujii, Yuka, Hamano, Keiko, Petro, Noah E, Lopez, Eric D, and Sasselov, Dimitar D

Subjects
astro-ph.EP, physics.geo-ph
Abstract

The geophysics of extrasolar planets is a scientific topic often regarded asstanding largely beyond the reach of near-term observations. This reality in noway diminishes the central role of geophysical phenomena in shaping planetaryoutcomes, from formation, to thermal and chemical evolution, to numerous issuesof surface and near-surface habitability. We emphasize that for a balancedunderstanding of extrasolar planets, it is important to look beyond the naturalbiases of current observing tools, and actively seek unique pathways tounderstand exoplanet interiors as best as possible during the long interimprior to a time when internal components are more directly accessible. Suchpathways include but are not limited to: (a) enhanced theoretical and numericalmodeling, (b) laboratory research on critical material properties, (c)measurement of geophysical properties by indirect inference from imprints lefton atmospheric and orbital properties, and (d) the purpose-driven use of SolarSystem object exploration expressly for its value in comparative planetologytoward exoplanet-analogs. Breaking down barriers that envision local SolarSystem exploration, including the study of Earth's own deep interior, asseparate from and in financial competition with extrasolar planet research, maygreatly improve the rate of needed scientific progress for exoplanetgeophysics. As the number of known rocky and icy exoplanets grows in the yearsahead, we expect demand for expertise in 'exogeoscience' will expand at acommensurately intense pace. We highlight key topics, including: how wateroceans below ice shells may dominate the total habitability of our galaxy byvolume, how free-floating nomad planets may often attain habitable subsurfaceoceans supported by radionuclide decay, and how deep interiors may criticallyinteract with atmospheric mass loss via dynamo-driven magnetic fields.

Published
2018

13. Building Lunar Maps for Terrain Relative Navigation and Hazard Detection Applications

Author

Beyer, Ross A, Iwashita, Yumi, Morgan, Zachary, Cheng, Yang, Ansar, Adnan I, Richardson, Jacob, Scheidt, Stephen, Gnam, Christopher, Liounis, Andrew, Mazarico, Erwan, Barker, Michael K, Petro, Noah E, and Restrepo, Carolina I

Abstract

Terrain Relative Navigation (TRN) systems that localize a spacecraft with respect to a map of the surface by comparing descent imagery to that reference map can only be as accurate as the reference map itself. Accurate map products that are based on orbital reconnaissance data must be validated for navigation applications to ensure that all relevant error sources are minimized. Currently available map products have been generated for scientific applications, so the need for accurate TRN maps remains a gap to be filled for upcoming lunar lander missions, in particular missions to the South Pole region. Additionally, representative high-resolution maps that contain lander-scale features are needed for successful development and testing of Hazard Detection (HD) systems. This paper describes one of NASA’s current efforts to develop benchmark data sets that can be used for developing and testing TRN and HD algorithms as well as suggested processes and metrics for generating and validating lunar maps that can be used for navigation and hazard detection.

Published
2022

26. Advancing Science of the Moon: Progress Toward Achieving the Goals of the Scientific Context for Exploration of the Moon Report

Author

Denevi, Brett W, Lawrence, Samuel J, Burns, Jack O, Cohen, BarBara A, Fagan, Amy F, Farrell, William M, Gaddis, Lisa R, Hamilton, Joseph A, John, Kristen K, Kramer, Georgiana Y, Lawrence, David J, Lucey, Paul G, McCubbin, Francis M, Neal, Clive R, Ostrach, Lillian R, Petro, Noah E, Pieters, Carle M, Robinson, Mark S, Shearer, Charles K, Taylor, G. Jeffrey, and Weber, Renee C

Subjects
Lunar And Planetary Science And Exploration
Published
2018

27. CubeX: A Compact X-Ray Telescope Enables Both X-Ray Fluorescence Imaging Spectroscopy and Pulsar Timing Based Navigation

Author

Stupl, Jan, Ebert, Monica, Mauro, David, Hong, JaeSub, Romaine, Suzanne, Kenter, Almus, Evans, Janet, Kraft, Ralph, Nittler, Larry, Crawford, Ian, Kring, David, Petro, Noah, Gendreau, Keith, Mitchell, Jason, Winternitz, Luke, Masterson, Rebecca, Prigozhin, Gregory, Wickizer, Brittany, Bonner, Kellen, Clark, Ashley, Dave, Arwen, Dono-Perez, Andres, Kashani, Ali, Larrabee, Daniel, Montez, Samuel, Ronzano, Karolyn, Snyder, Tim, Mueting, Joel, Plice, Laura, Shen, Yueh-Liang, and Nguyen, Duy

Subjects
Spacecraft Instrumentation And Astrionics
Abstract

This paper describes the miniaturized X-ray telescope payload, CubeX, in the context of a lunar mission. The first part describes the payload in detail, the second part summarizes a small satellite mission concept that utilizes its compact form factor and performance. This instrument can be used for both X-ray fluorescence (XRF) imaging spectroscopy and X-ray pulsar timing-based navigation (XNAV). It combines high angular resolution (<1 arcminutes) Miniature Wolter-I X-ray optics (MiXO) with a common focal plane consisting of high spectral resolution (<150 eV at 1 keV) CMOS X-ray sensors and a high timing resolution (< 1 μsec) SDD X-ray sensor. This novel combination of the instruments enables both XRF measurements and XNAV operations without moving parts, in a small form factor (~1×1×6U, <6 kg). In this paper we illustrate one potential application for a lunar mission concept: The elemental composition of the Moon holds keys to understanding the origin and evolution of both the Moon and the Earth. X-ray fluorescence (XRF), induced either by solar X-ray flux or energetic ions, carries decisive signatures of surface elemental composition. In between XRF observations, CubeX also leverages the technology of high resolution X-ray imaging and time series measurements to conduct XNAV operations and evaluate their performance.

Published
2018

29. BIRCHES and Lunarcubes: Building the First Deep Space Cubesat Broadband IR Spectrometer

Author

Chapin, Peter, Brandon, Carl, Brown, Kevin, Malphrus, Benjamin, Petro, Noah, Folta, David, Banks, Stuart, Patel, Deepak, Mentzell, Eric, Reuter, Dennis, Hurford, Terry, Brambora, Cliff, Farrell, William, MacDowall, Robert, and Clark, Pamela

Abstract

The Broadband InfraRed Compact High-resolution Exploration Spectrometer (BIRCHES), which will be described in detail here, is the compact broadband IR spectrometer of the Lunar Ice Cube mission. Lunar Ice Cube is one of 13 6U cubesats that will be deployed by EM1 in cislunar space, qualifying as lunarcubes. The LunarCube paradigm is a proposed approach for extending the affordable CubeSat standard to support access to deep space via cis-lunar/lunar missions. Because the lunar environment contains analogs of most solar system environments, the Moon is an ideal target for both testing critical deep space capabilities and understanding solar system formation and processes. Effectively, as developments are occurring in parallel, 13 prototype deep space cubesats are being flown for EM1. One useful outcome of this ‘experiment’ will be to determine to what extent it is possible to develop a lunarcube ‘bus’ with standardized interfaces to all subsystems using reasonable protocols for a variety of payloads. The lunar ice cube mission was developed as the test case in a GSFC R&D study to determine whether the cubesat paradigm could be applied to deep space, science requirements driven missions, and BIRCHES was its payload. Here, we present the design and describe the ongoing development, and testing, in the context of the challenges of using the cubesat paradigm to fly a broadband IR spectrometer in a 6U platform, including minimal funding and extensive need for leveraging existing assets and relationships on development, the foreshortened schedule for payload delivery on testing, and minimum bandwidth translating into simplified or canned operation.

Published
2017

31. The Moon Mineralogy Mapper (M³) on Chandrayaan-1

Author

Pieters, Carle M., Boardman, Joseph, Buratti, Bonnie, Chatterjee, Alok, Clark, Roger, Glavich, Tom, Green, Robert, Head, James, Isaacson, Peter, Malaret, Erick, McCord, Thomas, Mustard, John, Petro, Noah, Runyon, Cassandra, Staid, Matthew, Sunshine, Jessica, Taylor, Lawrence, Tompkins, Stefanie, Varanasi, Padma, and White, Mary

Published
2009

32. Editorial Introduction: Lunar Reconnaissance Orbiter, Part II

Author

Petro, Noah E, Keller, John W, and Gaddis, Lisa R

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Lunar Reconnaissance Orbiter (LRO) mission has shifted our understanding of the history of the Moon. The seven instruments on LRO each have contributed to creating new paradigms for the evolution of the Moon by providing unprecedented measurements of the surface, subsurface, and lunar environment. In this second volume of the LRO Special Issue, we present 21 papers from a broad range of the areas of investigation from LRO, from the volatile inventory, to the shape of the Moon's surface, to its rich volcanic history, and the interactions between the lunar surface and the space environment. These themes provide rich science for the instrument teams, as well as for the broader science com- munity who continue to use the LRO data in their research. Each paper uses publicly available data from one or more instruments on LRO, illustrating the value of a robust spacecraft. For example, the production of high-resolution topographic data products from the LRO Camera Narrow Angle Camera (Henriksen et al., pp. 122-137, this issue) rely on the accurate geodetic grid produced by the LOLA instrument (Mao et al., pp. 55-69, this issue; Smith et al., pp. 70-91, this issue). Additionally, analysis of LRO data coupled with other spacecraft data, such as LADEE (Hurley et al., pp. 31-37, this issue) and GRAIL (e.g., Jozwiak et al., pp. 224-231, this issue) illustrate the utility of merging not only data from multiple instruments, but also multiple orbital platforms. These synergistic studies show the value of the inter-team approach adopted by the LRO mission. This second volume represents the culmination of an extensive effort to highlight the high-quality science still being produced by the LRO instrument teams, even after more than seven years in orbit at the Moon.

Published
2016
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33. Global Variations in Regolith Properties on Asteroid Vesta from Dawn's Low-Altitude Mapping Orbit

Author

Denevi, Brett W, Beck, Andrew W, Coman, Ecaterina, Thomson, Bradley J, Ammannito, Eleonora, Blewett, David T, Sunshine, Jessica M, De Sanctis, Maria Cristina, Li, Jian-Yang, Marchi, Simone, Mittlefehldt, David W, Petro, Noah E, Raymond, Carol A, and Russell, Christopher T

Subjects
Lunar And Planetary Science And Exploration
Abstract

We investigate the depth, variability, and history of regolith on asteroid Vesta using data from the Dawn spacecraft. High-resolution (15-20 m pixel(sup -1)) Framing Cameraimages are used to assess the presence of morphologic indicators of a shallow regolith,including the presence of blocks in crater ejecta, spur-and-gully-type features in crater walls,and the retention of small (less than 300 m) impact craters. Such features reveal that the broad,regional heterogeneities observed on Vesta in terms of albedo and surface composition extend to the physical properties of the upper approx. 1 km of the surface. Regions of thin regolithare found within the Rheasilvia basin and at equatorial latitudes from approx. 0-90 deg. E and approx.260-360 deg. E. Craters in these areas that appear to excavate material from beneath the regolithhave more diogenitic (Rheasilvia, 090 deg. E) and cumulate eucrite (260-360 deg. E) compositions.A region of especially thick regolith, where depths generally exceed 1 km, is found from approx.100-240 deg. E and corresponds to heavily cratered, low-albedo surface with a basaltic eucritecomposition enriched in carbonaceous chondrite material. The presence of a thick regolithin this area supports the idea that this is an ancient terrain that has accumulated a larger component of exogenic debris. We find evidence for the gardening of crater ejecta towardmore howarditic compositions, consistent with regolith mixing being the dominant form of "weathering" on Vesta.

Published
2016
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34. The Lunar Geophysical Network Landing Sites Science Rationale

Author

Fuqua Haviland, Heidi, primary, Weber, Renee C., additional, Neal, Clive R., additional, Lognonné, Philippe, additional, Garcia, Raphaël F., additional, Schmerr, Nicholas, additional, Nagihara, Seiichi, additional, Grimm, Robert, additional, Currie, Douglas G., additional, Dell’Agnello, Simone, additional, Watters, Thomas R., additional, Panning, Mark P., additional, Johnson, Catherine L., additional, Yamada, Ryuhei, additional, Knapmeyer, Martin, additional, Ostrach, Lillian R., additional, Kawamura, Taichi, additional, Petro, Noah, additional, and Bremner, Paul M., additional

Published
2022
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35. Building Lunar Maps for Terrain Relative Navigation and Hazard Detection Applications

Author

Restrepo, Carolina I., primary, Petro, Noah, additional, Barker, Michael, additional, Mazarico, Erwan, additional, Liounis, Andrew, additional, Gnam, Chris, additional, Jacob, Richardson, additional, Scheidt, Stephen, additional, Ansar, Adnan I., additional, Cheng, Yang, additional, Morgan, Zachary, additional, Iwashita, Yumi, additional, and Beyer, Ross, additional

Published
2022
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38. In Situ Geochronology for the Next Decade: Mission Designs for the Moon, Mars, and Vesta

Author

Cohen, Barbara A., primary, Young, Kelsey E., additional, Zellner, Nicolle E. B., additional, Zacny, Kris, additional, Yingst, R. Aileen, additional, Watkins, Ryan N., additional, Warwick, Richard, additional, Valencia, Sarah N., additional, Swindle, Timothy D., additional, Robbins, Stuart J., additional, Petro, Noah E., additional, Nicoletti, Anthony, additional, Moriarty, Dan P., additional, Lynch, Richard, additional, Indyk, Stephen J., additional, Gross, Juliane, additional, Grier, Jennifer A., additional, Grant, John A., additional, Ginyard, Amani, additional, Fassett, Caleb I., additional, Farley, Kenneth A., additional, Farcy, Benjamin J., additional, Ehlmann, Bethany L., additional, Dyar, M. Darby, additional, Daelemans, Gerard, additional, Curran, Natalie M., additional, van der Bogert, Carolyn H., additional, Arevalo, Ricardo D., additional, and Scott Anderson, F., additional

Published
2021
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39. Low-Latency Science Exploration of Planetary Bodies: How ISS Might Be Used as Part of a Low-Latency Analog Campaign for Human Exploration

Author

Thronson, Harley, Valinia, Azita, Bleacher, Jacob, Eigenbrode, Jennifer, Garvin, Jim, and Petro, Noah

Subjects
Cybernetics, Artificial Intelligence And Robotics, Lunar And Planetary Science And Exploration
Abstract

We suggest that the International Space Station be used to examine the application and validation of low-latency telepresence for surface exploration from space as an alternative, precursor, or potentially as an adjunct to astronaut "boots on the ground." To this end, controlled experiments that build upon and complement ground-based analog field studies will be critical for assessing the effects of different latencies (0 to 500 milliseconds), task complexity, and alternate forms of feedback to the operator. These experiments serve as an example of a pathfinder for NASA's roadmap of missions to Mars with low-latency telerobotic exploration as a precursor to astronaut's landing on the surface to conduct geological tasks.

Published
2014

40. Low-latency Science Exploration of Planetary Bodies: a Demonstration Using ISS in Support of Mars Human Exploration

Author

Thronson, Harley A, Valinia, Azita, Bleacher, Jacob, Eigenbrode, Jennifer, Garvin, Jim, and Petro, Noah

Subjects
Administration And Management, Lunar And Planetary Science And Exploration, Cybernetics, Artificial Intelligence And Robotics
Abstract

We summarize a proposed experiment to use the International Space Station to formally examine the application and validation of low-latency telepresence for surface exploration from space as an alternative, precursor, or potentially as an adjunct to astronaut "boots on the ground." The approach is to develop and propose controlled experiments, which build upon previous field studies and which will assess the effects of different latencies (0 to 500 msec), task complexity, and alternate forms of feedback to the operator. These experiments serve as an example of a pathfinder for NASA's roadmap of missions to Mars with low-latency telerobotic exploration as a precursor to astronaut's landing on the surface to conduct geological tasks.

Published
2014

42. Compositional analyses of lunar pyroclastic deposits

Author

Gaddis, Lisa R., Staid, Matthew I., Tyburczy, James A., Hawke, B. Ray, and Petro, Noah E.

Subjects
Lunar mineralogy -- Research, Lunar petrology -- Research, Moon -- Composition, Volcanism -- Research, Astronomy, Earth sciences
Abstract

The 5-band Clementine UVVIS data at ~100 m/pixel were used to examine the compositions of 75 large and small lunar pyroclastic deposits (LPDs), and these were compared to representative lunar maria and highlands deposits. Results show that the albedo, spectral color, and inferred composition of most LPDs are similar to those of low-titanium, mature lunar maria. These LPDs may have consisted largely of fragmented basalt, with substantial components of iron-beating mafic minerals (pyroxenes, olivine) and smaller amounts (if any) of volcanic glass. Several smaller LPDs also show substantial highland components. Three classes of very large deposits can be distinguished from most LPDs and from each other on the basis of crystallinity and possible titanium content of their pyroclastic components. One class has spectral properties that are dominated by high-titanium, crystallized 'black beads' (e.g., Taurus-Littrow), a second consists of a mixture of high-titanium glasses and beads with a higher glass/bead ratio (Sulpicius Gallus) than that of Taurus-Littrow, and a third has a significant component of quenched iron-bearing volcanic glasses (Aristarchus) with possible moderate titanium contents. Although areally extensive, these three classes of very large pyroclastic deposits compose only 20 of the 75 deposits studied (~27%), and eruption of such materials was thus likely to have been less frequent on the Moon. Keywords: Moon; Moon surface; Volcanism; Spectroscopy

Published
2003

43. Terrestrial Analog Field Investigations to Enable Science and Exploration Studies of Impacts and Volcanism on the Moon, NEAs, and Moons of Mars

Author

Heldmann, Jennifer Lynne, Colaprete, Anthony, Cohen, Barbara, Elphic, Richard, Garry, William, Hodges, Kip, Hughes, Scott, Kim, Kyeon, Lim, Darlene, McKay, Chris, Osinski, Gordon R, Petro, Noah, Sears, Derek, Squyres, Steve, and Tornabene, Livio

Subjects
Astronomy
Abstract

Terrestrial analog studies are a critical component for furthering our understanding of geologic processes on the Moon, near-Earth asteroids (NEAs), and the moons of Mars. Carefully chosen analog sites provide a unique natural laboratory with high relevance to the associated science on these solar system target bodies. Volcanism and impact cratering are fundamental processes on the Moon, NEAs, and Phobos and Deimos. The terrestrial volcanic and impact records remain invaluable for our understanding of these processes throughout our solar system, since these are our primary source of firsthand knowledge on volcanic landform formation and modification as well as the three-dimensional structural and lithological character of impact craters. Regarding impact cratering, terrestrial fieldwork can help us to understand the origin and emplacement of impactites, the history of impact bombardment in the inner Solar System, the formation of complex impact craters, and the effects of shock on planetary materials. Volcanism is another dominant geologic process that has significantly shaped the surface of planetary bodies and many asteroids. Through terrestrial field investigations we can study the processes, geomorphic features and rock types related to fissure eruptions, volcanic constructs, lava tubes, flows and pyroclastic deposits. Also, terrestrial analog studies have the advantage of enabling simultaneous robotic and/or human exploration testing in a low cost, low risk, high fidelity environment to test technologies and concepts of operations for future missions to the target bodies. Of particular interest is the importance and role of robotic precursor missions prior to human operations for which there is little to no actual mission experience to draw upon. Also critical to understanding new worlds is sample return, and analog studies enable us to develop the appropriate procedures for collecting samples in a manner that will best achieve the science objectives.

Published
2013

44. High Priority Returned Lunar Samples

Author

Valencia, Sarah, primary, Curran, Natalie, additional, Flahaut, Jessica, additional, Gross, Juliane, additional, Mercer, Cameron M., additional, III, Daniel P. Moriarty,, additional, Neal, Clive R., additional, Petro, Noah E., additional, Prissel, Tabb C., additional, Watkins, Ryan N., additional, and Iqbal, Wajiha, additional

Published
2021
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46. Lunar Volatiles Orbiters

Author

Lucey, Paul G., primary, Prem, Parvathy, additional, Cable, Morgan L., additional, Hibbitts, Charles A., additional, Honniball, Casey I., additional, Pieters, Carlé M., additional, Barker, Michael, additional, Benna, Mehdi, additional, Dyar, Darby, additional, Fisher, Elizabeth, additional, Hayne, Paul, additional, Li, Shuai, additional, McCanta, Molly, additional, Hurley, Dana M., additional, Mazarico, Erwan, additional, Mandt, Kathleen E., additional, Petro, Noah E., additional, Orlando, Thomas M., additional, and Farrell, William M., additional

Published
2021
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50. Lunar Volatiles and Solar System Science

Author

Prem, Parvathy, primary, Kereszturi, Ákos, additional, Deutsch, Ariel N., additional, Hibbitts, Charles A., additional, Schmidt, Carl A., additional, Grava, Cesare, additional, Honniball, Casey I., additional, Hardgrove, Craig J., additional, Pieters, Carlé M., additional, Goldstein, David B., additional, Barker, Donald C., additional, Needham, Debra H., additional, Hurley, Dana M., additional, Mazarico, Erwan, additional, Dominguez, Gerardo, additional, Patterson, G. Wesley, additional, Kramer, Georgiana Y., additional, Brisset, Julie, additional, Gillis-Davis, Jeffrey J., additional, Mitchell, Julie L., additional, Szalay, Jamey R., additional, Halekas, Jasper S., additional, Keane, James T., additional, Head, James W., additional, Mandt, Kathleen E., additional, Robinson, Katharine L., additional, Luchsinger, Kristen M., additional, Magaña, Lizeth O., additional, Siegler, Matthew A., additional, Landis, Margaret E., additional, Poston, Michael J., additional, Petro, Noah E., additional, Lucey, Paul G., additional, Killen, Rosemary M., additional, Li, Shuai, additional, Narendranath, Shyama, additional, Shukla, Shashwat, additional, Barrett, Thomas J., additional, Stubbs, Timothy J., additional, Orlando, Thomas M., additional, and Farrell, William M., additional

Published
2021
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