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21 results on '"Patrick Whelley"'

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

Author

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

Subjects
Exoplanet atmospheres, Exoplanet astronomy, Exoplanet detection methods, Exoplanets, Volcanism, Direct imaging, Astronomy, QB1-991
Abstract

The James Webb Space Telescope (JWST) has provided the first opportunity of studying the atmospheres of terrestrial exoplanets and estimating 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 to 60 Gt of sulfur dioxide. The atmospheric data from the simulations were used to model direct-imaging observations between 0.2 and 2.0 μ 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 we 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.

Published
2023
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2. Rhyolite lava dome growth styles at Chaitén Volcano, Chile (2008-2009): Interpretation of thermal imagery

Author

Marc Bernstein, Andrés Pavez, Nick Varley, Patrick Whelley, and Eliza S. Calder

Subjects
chaitén volcano, rhyolite, lava dome, thermal imaging., Geology, QE1-996.5
Abstract

Airborne thermal images of the Chaitén rhyolite lava dome were obtained on three occasions between January 2009 and January 2010. These images were useful for understanding the nature and pace of growth of the newly extruded lava, which formed a complex of lobes and a spine. The images also revealed contrasting growth styles affecting different parts of the lava dome complex. Observed synchronous endogenous and exogenous growth was likely the result of multiple flow paths within the lava dome. We suggest that contrasts in morphology and surface texture between various lava lobes are the result of different extrusion rates.

Published
2013
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7. Stratigraphic Evidence for Early Martian Explosive Volcanism in Arabia Terra

Author

Jacob E. Bleacher, Reagan N. Smith, Patrick Whelley, Kelsey Mach, Jacob Richardson, and Alexandra Matiella Novak

Subjects
Martian, Geophysics, Explosive material, Geochemistry, General Earth and Planetary Sciences, Mars Exploration Program, Volcanism, Geology, Volcanic ash, CRISM
Published
2021

9. Volcanic Caves as Priority Sites for Astrobiology Science

Author

Ali-akbar Agha-mohammadi, Patrick Whelley, Kyle Uckert, David A. Crown, Christopher Patterson, Jennifer G. Blank, Ernest Bell, and Benjamin Morrell

Subjects
geography, geography.geographical_feature_category, Cave, Volcano, Geology, Astrobiology
Published
2021

10. The Importance of Field Studies for Closing Key Knowledge Gaps in Planetary Science

Author

Jeffrey E. Moersch, S. D. Dibb, David A. Crown, Michael T. Thorpe, Jennifer G. Blank, Maria E. Banks, Christopher W. Hamilton, Rutu Parekh, Kevin Hubbard, J. D. Clark, Amy McAdam, Timothy A. Goudge, S. E. Kobs-Nawotniak, David A. Williams, Steven Semken, K. N. Paris, H. Bernhardt, Catherine D. Neish, Nicholas Schmerr, Amber L. Gullikson, Chuanfei Dong, Graham Lau, Lauren A. Edgar, Laura Kerber, Stephen P. Scheidt, C. I. Honniball, Rodrigo Romo, Larry S. Crumpler, Cherie N. Achilles, Ernest Bell, E. L. Patrick, Laszlo P. Kestay, Kirby Runyon, A. M. Rutledge, Paul J. van Susante, Jon Zaloumis, Jacob Richardson, Trevor G. Graff, James R. Zimbelman, Ingrid Ukstins, Alison Graettinger, Nicole Whelley, Jake W. Dean, Jessica L Swann, Janice L. Bishop, Ashly Davies, Sarah A. Fagents, Sarah S. Sutton, K. E. Young, B. Shiro, S. Czarnecki, D. M. Bower, Timothy D. Glotch, Alexandra Matiella-Novak, Shane Byrne, Emily Law, Einat Lev, A. M. Baldridge, J. R. Skok, Everett L. Shock, Gordon R. Osinski, R. Aileen Yingst, Elizabeth B. Rampe, Andrew P. de Wet, Melissa D. Lane, Patrick Whelley, and M. Elise Rumpf

Subjects
Engineering, Planetary science, business.industry, Field (Bourdieu), media_common.quotation_subject, Closing (real estate), Key (cryptography), business, Data science, media_common
Published
2021

12. Highs and lows: Using GPR to map cinder cones, lava flows, and lava tubes on Earth to support studies of the Moon and Mars

Author

Sanaz Esmaeili, Charles B. Connor, Soraya Alfred, Elisabeth Gallant, Kathleen Grady-Weill, E. Bell, K. E. Young, Luke Varner, Sarah Kruse, L. M. Courtland, Sajad Jazayeri, Patrick Whelley, Jacob Richardson, and Danielle Molisee

Subjects
Cinder cone, Lava, Ground-penetrating radar, Mars Exploration Program, Petrology, Earth (classical element), Geology
Published
2020

13. Lava‐Rise Plateaus and Inflation Pits in the McCartys Lava Flow Field, New Mexico: An Analog for Pāhoehoe‐Like Lava Flows on Planetary Surfaces

Author

Christopher W. Hamilton, W. Brent Garry, Stephen Self, Andrew P. de Wet, Jacob E. Bleacher, Larry S. Crumpler, James R. Zimbelman, Patrick Whelley, Michael M. Sori, Stephen P. Scheidt, and Peter J. Mouginis-Mark

Subjects
Inflation, Geophysics, Field (physics), Space and Planetary Science, Geochemistry and Petrology, Lava, media_common.quotation_subject, Earth and Planetary Sciences (miscellaneous), Mars Exploration Program, Volcanism, Petrology, Geology, media_common
Published
2020

14. Resolution of Lava Tubes With Ground Penetrating Radar: The<scp>TubeX</scp>Project

Author

Sanaz Esmaeili, Sajad Jazayeri, Patrick Whelley, K. E. Young, E. Bell, Sarah Kruse, William Brent Garry, and Jacob Richardson

Subjects
geography, geography.geographical_feature_category, Lava, Resolution (electron density), Tubex, Lava tube, Geophysics, Lidar, Space and Planetary Science, Geochemistry and Petrology, Ground-penetrating radar, Earth and Planetary Sciences (miscellaneous), Geology, Remote sensing, Planetary exploration
Published
2020

15. EXPLORING LAVA TUBES AND OTHER VOID SPACES ACROSS THE SOLAR SYSTEM WITH THE GEOPHYSICAL EVOLUTION OF THE DYNAMICS AND EVOLUTION OF THE SOLAR SYSTEM (GEODES) TEAM

Author

David L. Akin, Rebecca R. Ghent, Sanaz Esmaeili, Adam Naids, Nicholas Schmerr, Laurent G. J. Montési, Yisha Ng, Beck E. Strauss, Danielle Y. Wyrick, Wenlu Zhu, Edward Williams, Molly Wasser, David Coan, Kelsey Young, Nicole Whelley, Sajad Jazayeri, Patrick Whelley, Sarah Kruse, Matthew A. Siegler, Charles B. Connor, Ernest Bell, Debra Buczkowski, and Jacob Richardson

Subjects
Void (astronomy), Solar System, Lava, Geophysics, Geology
Published
2020

16. Spectroscopic characterization of samples from different environments in a Volcano-Glacial region in Iceland: Implications for in situ planetary exploration

Author

Shahid Aslam, Jennifer L. Eigenbrode, Feng Jin, Jennifer E. Ruliffson, John R. Kolasinski, Alan C. Samuels, Conor A. Nixon, Patrick Whelley, Tilak Hewagama, Clayton S.-C. Yang, and D. M. Bower

Subjects
Basalt, Minerals, geography, geography.geographical_feature_category, Lava, Carbonates, Iceland, Geochemistry, Sediment, Weathering, Spectrum Analysis, Raman, Atomic and Molecular Physics, and Optics, Analytical Chemistry, chemistry.chemical_compound, chemistry, Volcano, Lava field, Carbonate, Laser-induced breakdown spectroscopy, Instrumentation, Spectroscopy
Abstract

Raman spectroscopy and laser induced breakdown spectroscopy (LIBS) are complementary techniques that together can provide a comprehensive characterization of geologic environments. For landed missions with constrained access to target materials on other planetary bodies, discerning signatures of life and habitability can be daunting, particularly where the preservation of organic compounds that contain the building blocks of life is limited. The main challenge facing any spectroscopy measurements of natural samples is the complicated spectra that often contain signatures for multiple components, particularly in rocks that are composed of several minerals with surfaces colonized by microbes. The goal of this study was to use the combination of Raman spectroscopy and LIBS to discern different environmental regimes based on the identification of minerals and biomolecules in rocks and sediments. Iceland is a terrestrial volcano-glacial location that offers a range of planetary analog environments, including volcanically active regions, extensive lava fields, geothermal springs, and large swaths of ice-covered terrain that are relevant to both rocky and icy planetary bodies. We combined portable VIS (532 nm) and NIR (785 nm) Raman spectroscopy, VIS micro-Raman spectroscopic mapping, and UV/VIS/NIR (200 – 1000 nm) and Mid-IR (5.6 – 10 μm, 1785 – 1000 cm−1) laser induced breakdown spectroscopy (LIBS) to characterize the mineral assemblages, hydrated components, and biomolecules in rock and sediment samples collected from three main sites in the volcanically active Kverkfjoll-Vatnajokull region of Iceland: basalt and basalt-hosted carbonate rind from Hveragil geothermal stream, volcanic sediments from the base of Vatnajokull glacier at Kverkfjoll, and lava from the nearby Holuhraun lava field. With our combination of techniques, we were able to identify major mineral polytypes typical for each sample set, as well as a large diversity of biomolecules typical for lichen communities across all samples. The anatase we observed using micro-Raman spectroscopic mapping of the lava compared with the volcanic sediment suggested different formation pathways: lava anatase formed authigenically, sediment anatase could have formed in association with microbial weathering. Mn-oxide, only detected in the carbonate samples, seems to have two possible formation pathways, either by fluvial or microbial weathering or both. Even with our ability to detect a wide diversity of biomolecules and minerals in all of the samples, there was not enough variation between each set to distinguish different environments based on the limited measurements done for this study.

Published
2021

18. LiDAR-derived surface roughness signatures of basaltic lava types at the Muliwai a Pele Lava Channel, Mauna Ulu, Hawai‘i

Author

Christopher W. Hamilton, Jacob E. Bleacher, Patrick Whelley, and W. Brent Garry

Subjects
Basalt, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Lava, Mineralogy, Surface finish, 010502 geochemistry & geophysics, 01 natural sciences, Lava channel, Lidar, Flow velocity, Volcano, Geochemistry and Petrology, Surface roughness, Geology, 0105 earth and related environmental sciences
Abstract

We used light detection and ranging (LiDAR) data to calculate roughness patterns (homogeneity, mean-roughness, and entropy) for five lava types at two different resolutions (1.5 and 0.1 m/pixel). We found that end-member types (ʻaʻā and pāhoehoe) are separable (with 95% confidence) at both scales, indicating that roughness patterns are well suited for analyzing types of lava. Intermediate lavas were also explored, and we found that slabby-pāhoehoe is separable from the other end-members using 1.5 m/pixel data, but not in the 0.1 m/pixel analysis. This suggests that the conversion from pāhoehoe to slabby-pāhoehoe is a meter-scale process, and the finer roughness characteristics of pāhoehoe, such as ropes and toes, are not significantly affected. Furthermore, we introduce the ratio $$ \frac{ENT}{HOM} $$ (derived from lava roughness) as a proxy for assessing local lava flow rate from topographic data. High entropy and low homogeneity regions correlate with high flow rate while low entropy and high homogeneity regions correlate with low flow rate. We suggest that this relationship is not directional, rather it is apparent through roughness differences of the associated lava type emplaced at the high and low rates, respectively.

Published
2017

20. Dust Devil Tracks

Author

Dennis Reiss, Lori Fenton, Lynn Neakrase, Michael Zimmerman, Thiago Statella, Patrick Whelley, Angelo Pio Rossi, and Matthew Balme

Subjects
010504 meteorology & atmospheric sciences, 0103 physical sciences, 010303 astronomy & astrophysics, 01 natural sciences, 0105 earth and related environmental sciences
Published
2017

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