Your search keyword '"Lynn M. Carter"' showing total 4 results

1. The Holy Grail: A road map for unlocking the climate record stored within Mars’ polar layered deposits

Author

Thomas Navarro, Robert L. Staehle, Don Banfield, Kris Zacny, K. E. Herkenhoff, Nathaniel E. Putzig, Jeremy Emmett, Michael H. Hecht, Wendy M. Calvin, Briony Horgan, Christine S. Hvidberg, Bethany L. Ehlmann, Matthew A. Siegler, David A. Paige, Margaret E. Landis, R. W. Obbard, Isaac B. Smith, John W. Holt, S. M. Milkovich, Sylvain Piqueux, D. E. Lalich, Armin Kleinböhl, Patricio Becerra, Bryana L. Henderson, M. R. Perry, Paul O. Hayne, Shane Byrne, Candice Hansen, P. B. Buhler, Lauren A. Edgar, Mark L. Skidmore, Jennifer C. Stern, Michelle Koutnik, Lynn M. Carter, Sergio Parra, Jennifer Hanley, Nicolas Thomas, and Melinda A. Kahre

Subjects

Ground truth, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 530 Physics, Earth science, 520 Astronomy, Astronomy and Astrophysics, Mars Exploration Program, 620 Engineering, 01 natural sciences, Exoplanet, law.invention, Atmosphere, Orbiter, Space and Planetary Science, law, Planet, 0103 physical sciences, Terrestrial planet, Ice sheet, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

In its polar layered deposits (PLD), Mars possesses a record of its recent climate, analogous to terrestrial ice sheets containing climate records on Earth. Each PLD is greater than 2 ​km thick and contains thousands of layers, each containing information on the climatic and atmospheric state during its deposition, creating a climate archive. With detailed measurements of layer composition, it may be possible to extract age, accumulation rates, atmospheric conditions, and surface activity at the time of deposition, among other important parameters; gaining the information would allow us to “read” the climate record. Because Mars has fewer complicating factors than Earth (e.g. oceans, biology, and human-modified climate), the planet offers a unique opportunity to study the history of a terrestrial planet’s climate, which in turn can teach us about our own planet and the thousands of terrestrial exoplanets waiting to be discovered. During a two-part workshop, the Keck Institute for Space Studies (KISS) hosted 38 Mars scientists and engineers who focused on determining the measurements needed to extract the climate record contained in the PLD. The group converged on four fundamental questions that must be answered with the goal of interpreting the climate record and finding its history based on the climate drivers. The group then proposed numerous measurements in order to answer these questions and detailed a sequence of missions and architecture to complete the measurements. In all, several missions are required, including an orbiter that can characterize the present climate and volatile reservoirs; a static reconnaissance lander capable of characterizing near surface atmospheric processes, annual accumulation, surface properties, and layer formation mechanism in the upper 50 ​cm of the PLD; a network of SmallSat landers focused on meteorology for ground truth of the low-altitude orbiter data; and finally, a second landed platform to access ~500 ​m of layers to measure layer variability through time. This mission architecture, with two landers, would meet the science goals and is designed to save costs compared to a single very capable landed mission. The rationale for this plan is presented below. In this paper we discuss numerous aspects, including our motivation, background of polar science, the climate science that drives polar layer formation, modeling of the atmosphere and climate to create hypotheses for what the layers mean, and terrestrial analogs to climatological studies. Finally, we present a list of measurements and missions required to answer the four major questions and read the climate record. 1. What are present and past fluxes of volatiles, dust, and other materials into and out of the polar regions? 2. How do orbital forcing and exchange with other reservoirs affect those fluxes? 3. What chemical and physical processes form and modify layers? 4. What is the timespan, completeness, and temporal resolution of the climate history recorded in the PLD?

Published

2020

2. VenSAR on EnVision: taking Earth Observation radar to Venus

Author

Philippa J. Mason, Robert R. Herrick, Ed Williams, R. C. Ghail, David Hall, and Lynn M. Carter

Subjects

Synthetic aperture radar, Global and Planetary Change, Earth observation, 010504 meteorology & atmospheric sciences, biology, Venus, Management, Monitoring, Policy and Law, biology.organism_classification, 01 natural sciences, Exoplanet, Astrobiology, law.invention, Planet, law, 0103 physical sciences, Interferometric synthetic aperture radar, Terrestrial planet, Computers in Earth Sciences, Radar, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Venus should be the most Earth-like of all our planetary neighbours: its size, bulk composition and distance from the Sun are very similar to those of Earth. How and why did it all go wrong for Venus? What lessons can be learned about the life story of terrestrial planets in general, in this era of discovery of Earth-like exoplanets? Were the radically different evolutionary paths of Earth and Venus driven solely by distance from the Sun, or do internal dynamics, geological activity, volcanic outgassing and weathering also play an important part? EnVision is a proposed ESA Medium class mission designed to take Earth Observation technology to Venus to measure its current rate of geological activity, determine its geological history, and the origin and maintenance of its hostile atmosphere, to understand how Venus and Earth could have evolved so differently. EnVision will carry three instruments: the Venus Emission Mapper (VEM); the Subsurface Radar Sounder (SRS); and VenSAR, a world-leading European phased array synthetic aperture radar that is the subject of this article. VenSAR will obtain images at a range of spatial resolutions from 30 m regional coverage to 1 m images of selected areas; an improvement of two orders of magnitude on Magellan images; measure topography at 15 m resolution vertical and 60 m spatially from stereo and InSAR data; detect cm-scale change through differential InSAR, to characterise volcanic and tectonic activity, and estimate rates of weathering and surface alteration; and characterise of surface mechanical properties and weathering through multi-polar radar data. These data will be directly comparable with Earth Observation radar data, giving geoscientists unique access to an Earth-sized planet that has evolved on a radically different path to our own, offering new insights on the Earth-sized exoplanets across the galaxy.

Published

2017

3. Contributors

Author

Mahesh Anand, Markus J. Aschwanden, Fran Bagenal, W. Bruce Banerdt, James F. Bell, Anil Bhardwaj, Richard P. Binzel, John C. Brandt, Doris Breuer, Daniel T. Britt, Bonnie J. Buratti, James D. Burke, Michael H. Carr, Lynn M. Carter, David C. Catling, John E. Chambers, Geoffrey Collins, Athena Coustenis, Ian A. Crawford, Wanda L. Davis, Véronique Dehant, Konrad Dennerl, Imke de Pater, Deborah L. Domingue, Luke Dones, Timothy E. Dowling, Line Drube, Adam M. Dziewonski, Michael Endl, Carolyn M. Ernst, Berndt Feuerbacher, Jonathan J. Fortney, Matthew P. Golombek, J.T. Gosling, Richard A.F. Grieve, Robert Grimm, Matthias Grott, Eberhard Grün, S.J. Guy Consolmagno, Klaus Gwinner, Alex N. Halliday, Alan W. Harris, Matthew M. Hedman, Amanda R. Hendrix, Harald Hiesinger, Bernhard Hufenbach, Donald M. Hunten, Ralf Jaumann, Torrence V. Johnson, Katherine H. Joy, Randolph L. Kirk, Margaret Galland Kivelson, Harald Krüger, William S. Kurth, Larry Lebofsky, David Leverington, Harold F. Levison, Michael E. Lipschutz, Jack J. Lissauer, Carey M. Lisse, Philippe Lognonné, Rosaly M.C. Lopes, J.G. Luhmann, Mark S. Marley, Lucy A. McFadden, Christopher P. McKay, William B. McKinnon, Harry Y. McSween, Alessandro Morbidelli, Nils Mueller, Scott L. Murchie, Carl D. Murray, Catherine D. Neish, Robert M. Nelson, Francis Nimmo, Jürgen Oberst, Gordon R. Osinski, Robert T. Pappalardo, David C. Pieri, Carolyn Porco, Thomas H. Prettyman, Frank Preusker, Louise M. Prockter, Attilio Rivoldini, Ludolf Schultz, Adam P. Showman, Suzanne E. Smrekar, Sue Smrekar, S.C. Solomon, Tilman Spohn, Sabine Stanley, S. Alan Stern, Ellen R. Stofan, Robert G. Strom, Mark V. Sykes, Fredric W. Taylor, Stephen C. Tegler, Peter C. Thomas, Matthew S. Tiscareno, Alan T. Tokunaga, Livio L. Tornabene, Nicola Tosi, Tim Van Hoolst, Ronald J. Vervack, Renee C. Weber, Paul R. Weissman, Robert A. West, and Lionel Wilson

Published

2014

4. Planetary Radar

Author

Catherine D. Neish and Lynn M. Carter

Subjects

Synthetic aperture radar, Solar System, business.industry, Planetary geology, Radar systems, law.invention, Planetary science, law, Remote sensing (archaeology), Saturn, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, Radar, business, Physics::Atmospheric and Oceanic Physics, Geology

Abstract

This chapter describes the principles of planetary radar, and the primary scientific discoveries that have been made using this technique. The chapter starts by describing the different types of radar systems and how they are used to acquire images and accurate topography of planetary surfaces and probe their subsurface structure. It then explains how these products can be used to understand the properties of the target being investigated. Several examples of discoveries made with planetary radar are then summarized, covering solar system objects from Mercury to Saturn. Finally, opportunities for future discoveries in planetary radar are outlined and discussed.

Published

2014