Your search keyword '"Weiss, Benjamin P."' showing total 88 results

1. Magnetic Field Modeling and Visualization of the Europa Clipper Spacecraft

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Cochrane, Corey J., Murphy, Neil, Raymond, Carol A., Biersteker, John B., Dang, Katherine, Jia, Xianzhe, Korth, Haje, Narvaez, Pablo, Ream, Jodie B., Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Cochrane, Corey J., Murphy, Neil, Raymond, Carol A., Biersteker, John B., Dang, Katherine, Jia, Xianzhe, Korth, Haje, Narvaez, Pablo, Ream, Jodie B., and Weiss, Benjamin P.

Abstract

The goal of NASA’s Europa Clipper Mission is to investigate the habitability of the subsurface ocean within the Jovian moon Europa using a suite of ten investigations. The Europa Clipper Magnetometer (ECM) and Plasma Instrument for Magnetic Sounding (PIMS) investigations will be used in unison to characterize the thickness and electrical conductivity of Europa’s subsurface ocean and the thickness of the ice shell by sensing the induced magnetic field, driven by the strong time-varying magnetic field of the Jovian environment. However, these measurements will be obscured by the magnetic field originating from the Europa Clipper spacecraft. In this work, a magnetic field model of the Europa Clipper spacecraft is presented, characterized with over 260 individual magnetic sources comprising various ferromagnetic and soft-magnetic materials, compensation magnets, solenoids, and dynamic electrical currents flowing within the spacecraft. This model is used to evaluate the magnetic field at arbitrary points around the spacecraft, notably at the locations of the three fluxgate magnetometer sensors and four Faraday cups which make up ECM and PIMS, respectively. The model is also used to evaluate the magnetic field uncertainty at these locations via a Monte Carlo approach. Furthermore, both linear and non-linear gradiometry fitting methods are presented to demonstrate the ability to reliably disentangle the spacecraft field from the ambient using an array of three fluxgate magnetometer sensors mounted along an 8.5-meter (m) long boom. The method is also shown to be useful for optimizing the locations of the magnetometer sensors along the boom. Finally, we illustrate how the model can be used to visualize the magnetic field lines of the spacecraft, thus providing very insightful information for each investigation.

Published

2023

2. Direct age constraints on the magnetism of Jack Hills zircon

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Taylor, Richard JM, Reddy, Steven M, Saxey, David W, Rickard, William DA, Tang, Fengzai, Borlina, Cauê S, Fu, Roger R, Weiss, Benjamin P, Bagot, Paul, Williams, Helen M, Harrison, Richard J, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Taylor, Richard JM, Reddy, Steven M, Saxey, David W, Rickard, William DA, Tang, Fengzai, Borlina, Cauê S, Fu, Roger R, Weiss, Benjamin P, Bagot, Paul, Williams, Helen M, and Harrison, Richard J

Abstract

A potential record of Earth’s magnetic field going back 4.2 billion years (Ga) ago is carried by magnetite inclusions in zircon grains from the Jack Hills. This magnetite may be secondary in nature, however, meaning that the magnetic record is much younger than the zircon crystallization age. Here, we use atom probe tomography to show that Pb-bearing nanoclusters in magnetite-bearing Jack Hills zircons formed during two discrete events at 3.4 and <2 Ga. The older population of clusters contains no detectable Fe, whereas roughly half of the younger population of clusters is Fe bearing. This result shows that the Fe required to form secondary magnetite entered the zircon sometime after 3.4 Ga and that remobilization of Pb and Fe during an annealing event occurred more than 1 Ga after deposition of the Jack Hills sediment at 3 Ga. The ability to date Fe mobility linked to secondary magnetite formation provides new possibilities to improve our knowledge of the Archean geodynamo.

Published

2023

3. Magnetic gradiometry using frequency-domain filtering

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Ream, Jodie B, Weiss, Benjamin P, Oran, Rona, Raymond, Carol A, Polanskey, Carol A, Wenkert, Daniel D, Elkins-Tanton, Linda T, Hart, Richard A, Russell, Christopher T, Merayo, Jose MG, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Ream, Jodie B, Weiss, Benjamin P, Oran, Rona, Raymond, Carol A, Polanskey, Carol A, Wenkert, Daniel D, Elkins-Tanton, Linda T, Hart, Richard A, Russell, Christopher T, and Merayo, Jose MG

Abstract

Abstract Accurate measurements of ambient planetary and interplanetary magnetic fields using spacecraft magnetometers typically require accounting for interfering magnetic fields generated by the flight system (FS). The most common method for removing FS-generated time-variable magnetic fields is narrow-band and low-pass filtering of magnetic field data in the frequency domain. However, if fluctuations in the ambient field contain frequencies overlapping those in the FS field, it can be difficult to construct a filter that will not affect both signals. Here we present an alternate method for removing FS time-variable signatures from magnetic field measurements. For spacecraft that make use of a magnetic gradiometer (i.e. with two or more instruments on a boom at different distances from the center of the spacecraft), the dominant frequencies in the FS field can be identified using spectra of the differenced field components. The amplitudes of the FS field at those frequencies can then be suppressed without removing spectral peaks present in the ambient field. We demonstrate the successful application of this method, referred to as gradiometry peak suppression, both to modeled data sets and to 128 Hz Venus Express magnetometer data.

Published

2023

4. Paleomagnetic evidence for a disk substructure in the early solar system

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Borlina, Cauê S, Weiss, Benjamin P, Bryson, James FJ, Bai, Xue-Ning, Lima, Eduardo A, Chatterjee, Nilanjan, Mansbach, Elias N, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Borlina, Cauê S, Weiss, Benjamin P, Bryson, James FJ, Bai, Xue-Ning, Lima, Eduardo A, Chatterjee, Nilanjan, and Mansbach, Elias N

Abstract

Paleomagnetic measurements of chondrules indicate the presence of a substructure in the solar nebula.

Published

2023

5. What Can Meteorites Tell Us About the Formation of Jupiter?

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Weiss, Benjamin P, Bottke, William F, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Weiss, Benjamin P, and Bottke, William F

Published

2023

6. Distinguishing the Origin of Asteroid (16) Psyche

Author

Elkins-Tanton, Linda T., Asphaug, Erik, Bell, James F., Bierson, Carver J., Bills, Bruce G., Bottke, William F., Courville, Samuel W., Dibb, Steven D., Jun, Insoo, Lawrence, David J., Marchi, Simone, McCoy, Timothy J., Merayo, Jose M.G., Oran, Rona, O’Rourke, Joseph G., Park, Ryan S., Peplowski, Patrick N., Prettyman, Thomas H., Raymond, Carol A., Weiss, Benjamin P., Wieczorek, Mark A., Zuber, Maria T., Elkins-Tanton, Linda T., Asphaug, Erik, Bell, James F., Bierson, Carver J., Bills, Bruce G., Bottke, William F., Courville, Samuel W., Dibb, Steven D., Jun, Insoo, Lawrence, David J., Marchi, Simone, McCoy, Timothy J., Merayo, Jose M.G., Oran, Rona, O’Rourke, Joseph G., Park, Ryan S., Peplowski, Patrick N., Prettyman, Thomas H., Raymond, Carol A., Weiss, Benjamin P., Wieczorek, Mark A., and Zuber, Maria T.

Abstract

The asteroid (16) Psyche may be the metal-rich remnant of a differentiated planetesimal, or it may be a highly reduced, metal-rich asteroidal material that never differentiated. The NASA Psyche mission aims to determine Psyche’s provenance. Here we describe the possible solar system regions of origin for Psyche, prior to its likely implantation into the asteroid belt, the physical and chemical processes that can enrich metal in an asteroid, and possible meteoritic analogs. The spacecraft payload is designed to be able to discriminate among possible formation theories. The project will determine Psyche’s origin and formation by measuring any strong remanent magnetic fields, which would imply it was the core of a differentiated body; the scale of metal to silicate mixing will be determined by both the neutron spectrometers and the filtered images; the degree of disruption between metal and rock may be determined by the correlation of gravity with composition; some mineralogy (e.g., modeled silicate/metal ratio, and inferred existence of low-calcium pyroxene or olivine, for example) will be detected using filtered images; and the nickel content of Psyche’s metal phase will be measured using the GRNS.

Published

2022

7. Compositionally and density stratified igneous terrain in Jezero crater, Mars

Author

Wiens, Roger C., Udry, Arya, Beyssac, Olivier, Quantin-Nataf, Cathy, Mangold, Nicolas, Cousin, Agnès, Mandon, Lucia, Bosak, Tanja, Forni, Olivier, McLennan, Scott M., Sautter, Violaine, Brown, Adrian, Benzerara, Karim, Johnson, Jeffrey R., Mayhew, Lisa, Maurice, Sylvestre, Anderson, Ryan B., Clegg, Samuel M., Crumpler, Larry, Gabriel, Travis S. J., Gasda, Patrick, Hall, James, Horgan, Briony H. N., Kah, Linda, Legett, Carey, Madariaga, Juan Manuel, Meslin, Pierre-Yves, Ollila, Ann M., Poulet, Francois, Royer, Clement, Sharma, Shiv K., Siljeström, Sandra, Simon, Justin I., Acosta-Maeda, Tayro E., Alvarez-Llamas, Cesar, Angel, S. Michael, Arana, Gorka, Beck, Pierre, Bernard, Sylvain, Bertrand, Tanguy, Bousquet, Bruno, Castro, Kepa, Chide, Baptiste, Clavé, Elise, Cloutis, Ed, Connell, Stephanie, Dehouck, Erwin, Dromart, Gilles, Fischer, Woodward, Fouchet, Thierry, Francis, Raymond, Frydenvang, Jens, Gasnault, Olivier, Gibbons, Erin, Gupta, Sanjeev, Hausrath, Elisabeth M., Jacob, Xavier, Kalucha, Hemani, Kelly, Evan, Knutsen, Elise, Lanza, Nina, Laserna, Javier, Lasue, Jeremie, Le Mouélic, Stéphane, Leveille, Richard, Lopez-Reyes, Guillermo, Lorenz, Ralph, Manrique, Jose Antonio, Martinez-Frias, Jesus, McConnochie, Tim, Melikechi, Noureddine, Mimoun, David, Montmessin, Franck, Moros, Javier, Murdoch, Naomi, Pilleri, Paolo, Pilorget, Cedric, Pinet, Patrick, Rapin, William, Rull, Fernando, Schröder, Susanne, Shuster, David L., Smith, Rebecca J., Stott, Alexander E., Tarnas, Jesse, Turenne, Nathalie, Veneranda, Marco, Vogt, David S., Weiss, Benjamin P., Willis, Peter, Stack, Kathryn M., Williford, Kenneth H., Farley, Kenneth A., Wiens, Roger C., Udry, Arya, Beyssac, Olivier, Quantin-Nataf, Cathy, Mangold, Nicolas, Cousin, Agnès, Mandon, Lucia, Bosak, Tanja, Forni, Olivier, McLennan, Scott M., Sautter, Violaine, Brown, Adrian, Benzerara, Karim, Johnson, Jeffrey R., Mayhew, Lisa, Maurice, Sylvestre, Anderson, Ryan B., Clegg, Samuel M., Crumpler, Larry, Gabriel, Travis S. J., Gasda, Patrick, Hall, James, Horgan, Briony H. N., Kah, Linda, Legett, Carey, Madariaga, Juan Manuel, Meslin, Pierre-Yves, Ollila, Ann M., Poulet, Francois, Royer, Clement, Sharma, Shiv K., Siljeström, Sandra, Simon, Justin I., Acosta-Maeda, Tayro E., Alvarez-Llamas, Cesar, Angel, S. Michael, Arana, Gorka, Beck, Pierre, Bernard, Sylvain, Bertrand, Tanguy, Bousquet, Bruno, Castro, Kepa, Chide, Baptiste, Clavé, Elise, Cloutis, Ed, Connell, Stephanie, Dehouck, Erwin, Dromart, Gilles, Fischer, Woodward, Fouchet, Thierry, Francis, Raymond, Frydenvang, Jens, Gasnault, Olivier, Gibbons, Erin, Gupta, Sanjeev, Hausrath, Elisabeth M., Jacob, Xavier, Kalucha, Hemani, Kelly, Evan, Knutsen, Elise, Lanza, Nina, Laserna, Javier, Lasue, Jeremie, Le Mouélic, Stéphane, Leveille, Richard, Lopez-Reyes, Guillermo, Lorenz, Ralph, Manrique, Jose Antonio, Martinez-Frias, Jesus, McConnochie, Tim, Melikechi, Noureddine, Mimoun, David, Montmessin, Franck, Moros, Javier, Murdoch, Naomi, Pilleri, Paolo, Pilorget, Cedric, Pinet, Patrick, Rapin, William, Rull, Fernando, Schröder, Susanne, Shuster, David L., Smith, Rebecca J., Stott, Alexander E., Tarnas, Jesse, Turenne, Nathalie, Veneranda, Marco, Vogt, David S., Weiss, Benjamin P., Willis, Peter, Stack, Kathryn M., Williford, Kenneth H., and Farley, Kenneth A.

Abstract

Before Perseverance, Jezero crater's floor was variably hypothesized to have a lacustrine, lava, volcanic airfall, or aeolian origin. SuperCam observations in the first 286 Mars days on Mars revealed a volcanic and intrusive terrain with compositional and density stratification. The dominant lithology along the traverse is basaltic, with plagioclase enrichment in stratigraphically higher locations. Stratigraphically lower, layered rocks are richer in normative pyroxene. The lowest observed unit has the highest inferred density and is olivine-rich with coarse (1.5 millimeters) euhedral, relatively unweathered grains, suggesting a cumulate origin. This is the first martian cumulate and shows similarities to martian meteorites, which also express olivine disequilibrium. Alteration materials including carbonates, sulfates, perchlorates, hydrated silicates, and iron oxides are pervasive but low in abundance, suggesting relatively brief lacustrine conditions. Orbital observations link the Jezero floor lithology to the broader Nili-Syrtis region, suggesting that density-driven compositional stratification is a regional characteristic.

Published

2022

8. Compositionally and density stratified igneous terrain in Jezero crater, Mars

Author

Wiens, Roger C., Udry, Arya, Beyssac, Olivier, Quantin-Nataf, Cathy, Mangold, Nicolas, Cousin, Agnès, Mandon, Lucia, Bosak, Tanja, Forni, Olivier, McLennan, Scott M., Sautter, Violaine, Brown, Adrian, Benzerara, Karim, Johnson, Jeffrey R., Mayhew, Lisa, Maurice, Sylvestre, Anderson, Ryan B., Clegg, Samuel M., Crumpler, Larry, Gabriel, Travis S. J., Gasda, Patrick, Hall, James, Horgan, Briony H. N., Kah, Linda, Legett, Carey, Madariaga, Juan Manuel, Meslin, Pierre-Yves, Ollila, Ann M., Poulet, Francois, Royer, Clement, Sharma, Shiv K., Siljeström, Sandra, Simon, Justin I., Acosta-Maeda, Tayro E., Alvarez-Llamas, Cesar, Angel, S. Michael, Arana, Gorka, Beck, Pierre, Bernard, Sylvain, Bertrand, Tanguy, Bousquet, Bruno, Castro, Kepa, Chide, Baptiste, Clavé, Elise, Cloutis, Ed, Connell, Stephanie, Dehouck, Erwin, Dromart, Gilles, Fischer, Woodward, Fouchet, Thierry, Francis, Raymond, Frydenvang, Jens, Gasnault, Olivier, Gibbons, Erin, Gupta, Sanjeev, Hausrath, Elisabeth M., Jacob, Xavier, Kalucha, Hemani, Kelly, Evan, Knutsen, Elise, Lanza, Nina, Laserna, Javier, Lasue, Jeremie, Le Mouélic, Stéphane, Leveille, Richard, Lopez-Reyes, Guillermo, Lorenz, Ralph, Manrique, Jose Antonio, Martinez-Frias, Jesus, McConnochie, Tim, Melikechi, Noureddine, Mimoun, David, Montmessin, Franck, Moros, Javier, Murdoch, Naomi, Pilleri, Paolo, Pilorget, Cedric, Pinet, Patrick, Rapin, William, Rull, Fernando, Schröder, Susanne, Shuster, David L., Smith, Rebecca J., Stott, Alexander E., Tarnas, Jesse, Turenne, Nathalie, Veneranda, Marco, Vogt, David S., Weiss, Benjamin P., Willis, Peter, Stack, Kathryn M., Williford, Kenneth H., Farley, Kenneth A., Wiens, Roger C., Udry, Arya, Beyssac, Olivier, Quantin-Nataf, Cathy, Mangold, Nicolas, Cousin, Agnès, Mandon, Lucia, Bosak, Tanja, Forni, Olivier, McLennan, Scott M., Sautter, Violaine, Brown, Adrian, Benzerara, Karim, Johnson, Jeffrey R., Mayhew, Lisa, Maurice, Sylvestre, Anderson, Ryan B., Clegg, Samuel M., Crumpler, Larry, Gabriel, Travis S. J., Gasda, Patrick, Hall, James, Horgan, Briony H. N., Kah, Linda, Legett, Carey, Madariaga, Juan Manuel, Meslin, Pierre-Yves, Ollila, Ann M., Poulet, Francois, Royer, Clement, Sharma, Shiv K., Siljeström, Sandra, Simon, Justin I., Acosta-Maeda, Tayro E., Alvarez-Llamas, Cesar, Angel, S. Michael, Arana, Gorka, Beck, Pierre, Bernard, Sylvain, Bertrand, Tanguy, Bousquet, Bruno, Castro, Kepa, Chide, Baptiste, Clavé, Elise, Cloutis, Ed, Connell, Stephanie, Dehouck, Erwin, Dromart, Gilles, Fischer, Woodward, Fouchet, Thierry, Francis, Raymond, Frydenvang, Jens, Gasnault, Olivier, Gibbons, Erin, Gupta, Sanjeev, Hausrath, Elisabeth M., Jacob, Xavier, Kalucha, Hemani, Kelly, Evan, Knutsen, Elise, Lanza, Nina, Laserna, Javier, Lasue, Jeremie, Le Mouélic, Stéphane, Leveille, Richard, Lopez-Reyes, Guillermo, Lorenz, Ralph, Manrique, Jose Antonio, Martinez-Frias, Jesus, McConnochie, Tim, Melikechi, Noureddine, Mimoun, David, Montmessin, Franck, Moros, Javier, Murdoch, Naomi, Pilleri, Paolo, Pilorget, Cedric, Pinet, Patrick, Rapin, William, Rull, Fernando, Schröder, Susanne, Shuster, David L., Smith, Rebecca J., Stott, Alexander E., Tarnas, Jesse, Turenne, Nathalie, Veneranda, Marco, Vogt, David S., Weiss, Benjamin P., Willis, Peter, Stack, Kathryn M., Williford, Kenneth H., and Farley, Kenneth A.

Abstract

Before Perseverance, Jezero crater's floor was variably hypothesized to have a lacustrine, lava, volcanic airfall, or aeolian origin. SuperCam observations in the first 286 Mars days on Mars revealed a volcanic and intrusive terrain with compositional and density stratification. The dominant lithology along the traverse is basaltic, with plagioclase enrichment in stratigraphically higher locations. Stratigraphically lower, layered rocks are richer in normative pyroxene. The lowest observed unit has the highest inferred density and is olivine-rich with coarse (1.5 millimeters) euhedral, relatively unweathered grains, suggesting a cumulate origin. This is the first martian cumulate and shows similarities to martian meteorites, which also express olivine disequilibrium. Alteration materials including carbonates, sulfates, perchlorates, hydrated silicates, and iron oxides are pervasive but low in abundance, suggesting relatively brief lacustrine conditions. Orbital observations link the Jezero floor lithology to the broader Nili-Syrtis region, suggesting that density-driven compositional stratification is a regional characteristic.

Published

2022

9. Revealing the interior structure of icy moons with a Bayesian approach to magnetic induction measurements

Author

Biersteker, John B., Weiss, Benjamin P., Cochrane, Corey J., Harris, Camilla D. K., Jia, Xianzhe, Khurana, Krishan K., Liu, Jiang, Murphy, Neil, Raymond, Carol A., Biersteker, John B., Weiss, Benjamin P., Cochrane, Corey J., Harris, Camilla D. K., Jia, Xianzhe, Khurana, Krishan K., Liu, Jiang, Murphy, Neil, and Raymond, Carol A.

Abstract

Some icy moons and small bodies in the solar system are believed to host subsurface liquid water oceans. The interaction of these saline, electrically conductive oceans with time-varying external magnetic fields generates induced magnetic fields. Magnetometry observations of these induced fields in turn enable the detection and characterization of these oceans. We present a framework for characterizing the interiors of icy moons using multi-frequency induction and Bayesian inference applied to magnetometry measurements anticipated from the upcoming Europa Clipper mission. Using simulated data from the Europa Clipper Magnetometer (ECM), our approach can accurately retrieve a wide range of plausible internal structures for Europa. In particular, the ocean conductivity is recovered to within ${\pm}50\%$ for all internal structure scenarios considered and the ocean thickness can be retrieved to within ${\pm}25~\mathrm{km}$ for five out of seven scenarios. Characterization of the ice shell thickness to ${\pm}50\%$ is possible for six of seven scenarios. Our recovery of the ice shell thickness is highly contingent on accurate modeling of magnetic fields arising from the interaction of Europa with the ambient magnetospheric plasma, while the ocean thickness is more modestly affected and the ocean conductivity retrieval is largely unchanged. Furthermore, we find that the addition of a priori constraints (e.g., static gravity measurements) can yield improved ocean characterization compared to magnetometry alone, suggesting that multi-instrument techniques can play a key role in revealing the interiors of Europa and other ocean worlds., Comment: 18 pages, 16 figures, submitted to Planetary Science Journal

Published

2022

10. Was the moon magnetized by impact plasmas?

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Oran, Rona, Weiss, Benjamin P, Shprits, Yuri, Miljković, Katarina, Tóth, Gábor, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Oran, Rona, Weiss, Benjamin P, Shprits, Yuri, Miljković, Katarina, and Tóth, Gábor

Abstract

© 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC). The crusts of the Moon, Mercury, and many meteorite parent bodies are magnetized. Although the magnetizing field is commonly attributed to that of an ancient core dynamo, a longstanding hypothesized alternative is amplification of the interplanetary magnetic field and induced crustal field by plasmas generated by meteoroid impacts. Here, we use magnetohydrodynamic and impact simulations and analytic relationships to demonstrate that although impact plasmas can transiently enhance the field inside the Moon, the resulting fields are at least three orders of magnitude too weak to explain lunar crustal magnetic anomalies. This leaves a core dynamo as the only plausible source of most magnetization on the Moon.

Published

2022

11. Meteorite evidence for partial differentiation and protracted accretion of planetesimals

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Maurel, Clara, Bryson, James FJ, Lyons, Richard J, Ball, Matthew R, Chopdekar, Rajesh V, Scholl, Andreas, Ciesla, Fred J, Bottke, William F, Weiss, Benjamin P, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Maurel, Clara, Bryson, James FJ, Lyons, Richard J, Ball, Matthew R, Chopdekar, Rajesh V, Scholl, Andreas, Ciesla, Fred J, Bottke, William F, and Weiss, Benjamin P

Abstract

© 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC). Modern meteorite classification schemes assume that no single planetary body could be source of both unmelted (chondritic) and melted (achondritic) meteorites. This dichotomy is a natural outcome of formation models assuming that planetesimal accretion occurred nearly instantaneously. However, it has recently been proposed that the accretion of many planetesimals lasted over ≳1 million years (Ma). This could have resulted in partially differentiated internal structures, with individual bodies containing iron cores, achondritic silicate mantles, and chondritic crusts. This proposal can be tested by searching for a meteorite group containing evidence for these three layers. We combine synchrotron paleomagnetic analyses with thermal, impact, and collisional evolution models to show that the parent body of the enigmatic IIE iron meteorites was such a partially differentiated planetesimal. This implies that some chondrites and achondrites simultaneously coexisted on the same planetesimal, indicating that accretion was protracted and that apparently undifferentiated asteroids may contain melted interiors.

Published

2022

12. History of the solar nebula from meteorite paleomagnetism

Author

Weiss, Benjamin P., Bai, Xue-Ning, Fu, Roger R., Weiss, Benjamin P., Bai, Xue-Ning, and Fu, Roger R.

Abstract

Copyright © 2021 The Authors, some rights reserved. We review recent advances in our understanding of magnetism in the solar nebula and protoplanetary disks (PPDs). We discuss the implications of theory, meteorite measurements, and astronomical observations for planetary formation and nebular evolution. Paleomagnetic measurements indicate the presence of fields of 0.54 ± 0.21 G at ~1 to 3 astronomical units (AU) from the Sun and ≳0.06 G at 3 to 7 AU until >1.22 and >2.51 million years (Ma) after solar system formation, respectively. These intensities are consistent with those predicted to enable typical astronomically observed protostellar accretion rates of ~10−8 M☉year−1, suggesting that magnetism played a central role in mass transport in PPDs. Paleomagnetic studies also indicate fields <0.006 G and <0.003 G in the inner and outer solar system by 3.94 and 4.89 Ma, respectively, consistent with the nebular gas having dispersed by this time. This is similar to the observed lifetimes of extrasolar protoplanetary disks.

Published

2022

13. Searching for Subsurface Oceans on the Moons of Uranus Using Magnetic Induction

Author

Weiss, Benjamin P., Biersteker, John B., Colicci, Vittorio, Goode, Allison, Castillo‐Rogez, Julie C., Petropoulos, Anastassios E., Balint, Tibor S., Weiss, Benjamin P., Biersteker, John B., Colicci, Vittorio, Goode, Allison, Castillo‐Rogez, Julie C., Petropoulos, Anastassios E., and Balint, Tibor S.

Abstract

The icy moons of Uranus may contain subsurface oceans. Such oceans could be detected and characterized using measurements of magnetic fields induced by Uranus' time-varying magnetospheric field. Here we explore this possibility for Uranus's five major moons, with a focus on Ariel. We find that the magnetic field at each moon is dominated by the synodic frequency with amplitudes ranging from ∼4 nT at Oberon up to ∼300 nT at Miranda. If these bodies contain oceans with sufficient thicknesses (>∼3–40 km) and conductivities (>2 S m−1) even underlying relatively thick (∼50 km) ice shells, the induced surface fields should have amplitudes exceeding the typical ∼1 nT sensitivity of spacecraft magnetometry investigations. Furthermore, the magnetic field variations at the moons span periods ranging from 1 to 103 h. These could enable long-term measurements to separately constrain ocean and ice thicknesses and ocean salinity.

Published

2022

14. Deciphering Redox State for a Metal-Rich World

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, McCoy, Timothy J., Dibb, Steven D., Peplowski, Patrick N., Maurel, Clara, Bercovici, Hannah L., Corrigan, Catherine M., Bell, James F., Weiss, Benjamin P., Lawrence, David J., Wenkert, Daniel D., Prettyman, Thomas H., Elkins-Tanton, Lindy T., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, McCoy, Timothy J., Dibb, Steven D., Peplowski, Patrick N., Maurel, Clara, Bercovici, Hannah L., Corrigan, Catherine M., Bell, James F., Weiss, Benjamin P., Lawrence, David J., Wenkert, Daniel D., Prettyman, Thomas H., and Elkins-Tanton, Lindy T.

Abstract

The Psyche mission’s Oxidation-Reduction Working Group is focused on understanding, determining, and applying the redox state of (16) Psyche to understand the origin of a metal-rich world. The oxidation-reduction state of an asteroid, along with its temperature, parent body size, and composition, is a key parameter in determining the history of an asteroid. Determining the redox state from spacecraft data is most easily done by examining potential metal-oxide buffer pairs. The occurrence of Ni, Fe, C, Cr, P and Si, in that order, in the metal or sulfide phase of an asteroidal body indicates increasingly reduced conditions. Key observations by the Imager and Gamma-Ray and Neutron Spectrometer (GRNS) of Psyche can bracket the redox state using metal-oxide buffers. The presence of Fe,Ni metal can be confirmed by the ratios of Fe/O or Fe/Si and the concentration of Ni variability in metal across the asteroid can be determined by GRNS. The FeO concentration of silicates is complementary to the Ni concentration of metal and can be constrained using filters on the Imager. The presence of FeO in silicates from ground-based observations is one of the few measurements we already have of redox state, although available data permit a wide range of silicate compositions and mineralogies. The presence of C, P or Si concentrated in the metallic, Fe-rich portion of the asteroid, as measured by GRNS, or Ca-sulfide, determined by imaging, would indicate increasingly reducing conditions. Linkage to known types of meteorites, whether metal-rich chondrites, stony-irons or irons, expands the mineralogical, chemical and isotopic data not available from remote observations alone. Redox also controls both silicate and metal mineralogy, influencing differentiation, solidification, and subsolidus cooling, including the relative abundance of sulfur in the core and possible magnetic signatures. The redox state of Psyche, if a fully-differentiated metallic core, might constrain the loca

Published

2022

15. Magnetic Properties of Asteroid (162173) Ryugu

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Hercik, David, Auster, Hans-Ulrich, Constantinescu, Dragos, Blum, Jürgen, Fornaçon, Karl-Heinz, Fujimoto, Masaki, Gebauer, Kathrin, Grundmann, Jan-Thimo, Güttler, Carsten, Hillenmaier, Olaf, Ho, Tra-Mi, Hördt, Andreas, Krause, Christian, Kührt, Ekkehard, Lorda, Laurence, Matsuoka, Ayako, Motschmann, Uwe, Moussi-Soffys, Aurélie, Richter, Ingo, Sasaki, Kaname, Scholten, Frank, Stoll, Bernd, Weiss, Benjamin P., Wolff, Friederike, Glassmeier, Karl-Heinz, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Hercik, David, Auster, Hans-Ulrich, Constantinescu, Dragos, Blum, Jürgen, Fornaçon, Karl-Heinz, Fujimoto, Masaki, Gebauer, Kathrin, Grundmann, Jan-Thimo, Güttler, Carsten, Hillenmaier, Olaf, Ho, Tra-Mi, Hördt, Andreas, Krause, Christian, Kührt, Ekkehard, Lorda, Laurence, Matsuoka, Ayako, Motschmann, Uwe, Moussi-Soffys, Aurélie, Richter, Ingo, Sasaki, Kaname, Scholten, Frank, Stoll, Bernd, Weiss, Benjamin P., Wolff, Friederike, and Glassmeier, Karl-Heinz

Abstract

©2020. The Authors. Observations of the magnetization state of asteroids indicate diverse properties. Values between 1.9 × 10 -6Am2/kg (Eros) and 10-2 Am2/kg (Braille) have been reported. A more detailed understanding of asteroidal magnetic properties allows far-reaching conclusions of the magnetization mechanism as well as the strength of the magnetic field of the solar system regions the asteroid formed in. The Hayabusa2 mission with its lander Mobile Asteroid Surface Scout is equipped with a magnetometer experiment, MasMag. MasMag is a state-of-the-art three-axis fluxgate magnetometer, successfully operated also on Philae, the Rosetta mission lander. MasMag has enabled, after Eros for the second time ever, to determine the magnetic field of an asteroid during descent and on-surface operations. The new observations show that Ryugu, a low-albedo C-type asteroid, has no detectable global magnetization, and any local magnetization is either small (< 10−6 Am2/kg) or on very small (subcentimeter) scales. This implies, for example, that energetic solar wind particles could reach and alter the surface unimpeded by strong asteroidal magnetic fields, such as minimagnetospheres in case of the Moon.

Published

2022

16. A Portable Magnetometer for Magnetic Measurements of Meter‐Sized Meteorites

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Clavé, Elise, Maurel, Clara, Lima, Eduardo A, Shah, Jay, Mansbach, Elias N, Uehara, Minoru, Weiss, Benjamin P, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Clavé, Elise, Maurel, Clara, Lima, Eduardo A, Shah, Jay, Mansbach, Elias N, Uehara, Minoru, and Weiss, Benjamin P

Abstract

Meteorites contain records of past magnetic fields in the form of natural remanent magnetization (NRM). A key property of meteorite magnetization that provides information about its origin is its dependence on spatial scale. In particular, understanding how the mean remanent magnetization varies from the scale of meteorites to the global scale of their parent bodies would aid in the interpretation of spacecraft magnetometry data. However, the vast majority of meteorite samples whose remanent magnetization have been measured have sizes <10 cm due to the limited size range accommodated by laboratory magnetometers. To address this limitation, we developed a portable magnetometer array that enables remanence measurements of meter-size meteorites in a non-magnetically shielded environment. The instrument measures both NRM and induced magnetization using two orthogonal square Helmholtz coil pairs that compensate the vertical and horizontal components of the background magnetic field. An array of four magnetometers mounted on a movable aluminum rail measures the magnetic field at multiple locations around the sample. The instrument is transportable and can be adapted to different sample sizes. After distinguishing the induced component from the remanent component of a sample's total field, the remanence can be estimated from a multipole field inversion combined with nonlinear least squares method. We validated the instrument and data processing on a magnet of known magnetic moment and measured the NRM of a meter-sized iron meteorite.

Published

2022

17. Maximum Energies of Trapped Particles Around Magnetized Planets and Small Bodies

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Oran, Rona, Weiss, Benjamin P, De Soria Santacruz‐Pich, Maria, Jun, Insoo, Lawrence, David J, Polanskey, Carol A, Ratliff, J Martin, Raymond, Carol A, Ream, Jodie B, Russell, Christopher T, Shprits, Yuri Y, Zuber, Maria T, Elkins‐Tanton, Linda T, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Oran, Rona, Weiss, Benjamin P, De Soria Santacruz‐Pich, Maria, Jun, Insoo, Lawrence, David J, Polanskey, Carol A, Ratliff, J Martin, Raymond, Carol A, Ream, Jodie B, Russell, Christopher T, Shprits, Yuri Y, Zuber, Maria T, and Elkins‐Tanton, Linda T

Published

2022

18. A Long‐Lived Planetesimal Dynamo Powered by Core Crystallization

Author

Maurel, Clara, Bryson, James F. J., Shah, Jay, Chopdekar, Rajesh V., T. Elkins‐Tanton, Linda, A. Raymond, Carol, Weiss, Benjamin P., Maurel, Clara, Bryson, James F. J., Shah, Jay, Chopdekar, Rajesh V., T. Elkins‐Tanton, Linda, A. Raymond, Carol, and Weiss, Benjamin P.

Abstract

The existence of numerous iron meteorite groups indicates that some planetesimals underwent melting that led to metal-silicate segregation, sometimes producing metallic cores. Meteorite paleomagnetic records suggest that crystallization of these cores generated dynamo magnetic fields. Here we describe the magnetic history of the partially differentiated IIE iron meteorite parent body. This is the first planetesimal for which we have a time-resolved paleomagnetic record constrained by 40Ar/39Ar chronometry spanning several tens of million years (Ma). We find that the core of the IIE parent body generated a dynamo, likely powered by core crystallization, starting before 78 ± 13 Ma after solar system formation and lasting at least 80 Ma. Such extended core crystallization suggests that the core composed a substantial fraction of the body ( urn:x-wiley:00948276:media:grl61991:grl61991-math-0001 13%–19% core-to-body radius ratio depending on the body’s radius), indicating efficient core formation within some partially differentiated planetesimals.

Published

2022

19. Lifetime of the Outer Solar System Nebula From Carbonaceous Chondrites

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Borlina, Cauê S, Weiss, Benjamin P, Bryson, James FJ, Armitage, Philip J, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Borlina, Cauê S, Weiss, Benjamin P, Bryson, James FJ, and Armitage, Philip J

Published

2022

20. Deciphering Redox State for a Metal-Rich World

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, McCoy, Timothy J., Dibb, Steven D., Peplowski, Patrick N., Maurel, Clara, Bercovici, Hannah L., Corrigan, Catherine M., Bell, James F., Weiss, Benjamin P., Lawrence, David J., Wenkert, Daniel D., Prettyman, Thomas H., Elkins-Tanton, Lindy T., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, McCoy, Timothy J., Dibb, Steven D., Peplowski, Patrick N., Maurel, Clara, Bercovici, Hannah L., Corrigan, Catherine M., Bell, James F., Weiss, Benjamin P., Lawrence, David J., Wenkert, Daniel D., Prettyman, Thomas H., and Elkins-Tanton, Lindy T.

Abstract

The Psyche mission’s Oxidation-Reduction Working Group is focused on understanding, determining, and applying the redox state of (16) Psyche to understand the origin of a metal-rich world. The oxidation-reduction state of an asteroid, along with its temperature, parent body size, and composition, is a key parameter in determining the history of an asteroid. Determining the redox state from spacecraft data is most easily done by examining potential metal-oxide buffer pairs. The occurrence of Ni, Fe, C, Cr, P and Si, in that order, in the metal or sulfide phase of an asteroidal body indicates increasingly reduced conditions. Key observations by the Imager and Gamma-Ray and Neutron Spectrometer (GRNS) of Psyche can bracket the redox state using metal-oxide buffers. The presence of Fe,Ni metal can be confirmed by the ratios of Fe/O or Fe/Si and the concentration of Ni variability in metal across the asteroid can be determined by GRNS. The FeO concentration of silicates is complementary to the Ni concentration of metal and can be constrained using filters on the Imager. The presence of FeO in silicates from ground-based observations is one of the few measurements we already have of redox state, although available data permit a wide range of silicate compositions and mineralogies. The presence of C, P or Si concentrated in the metallic, Fe-rich portion of the asteroid, as measured by GRNS, or Ca-sulfide, determined by imaging, would indicate increasingly reducing conditions. Linkage to known types of meteorites, whether metal-rich chondrites, stony-irons or irons, expands the mineralogical, chemical and isotopic data not available from remote observations alone. Redox also controls both silicate and metal mineralogy, influencing differentiation, solidification, and subsolidus cooling, including the relative abundance of sulfur in the core and possible magnetic signatures. The redox state of Psyche, if a fully-differentiated metallic core, might constrain the loca

Published

2022

21. The Psyche Gravity Investigation

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Zuber, Maria T., Park, Ryan S., Elkins-Tanton, Linda T., Bell, J. F., Bruvold, Kristoffer N., Bercovici, David, Bills, Bruce G., Binzel, Richard P., Jaumann, R., Marchi, Simone, Raymond, Carol A., Roatsch, T., Wang, Charles C., Weiss, Benjamin P., Wenkert, Daniel, Wieczorek, Mark A., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Zuber, Maria T., Park, Ryan S., Elkins-Tanton, Linda T., Bell, J. F., Bruvold, Kristoffer N., Bercovici, David, Bills, Bruce G., Binzel, Richard P., Jaumann, R., Marchi, Simone, Raymond, Carol A., Roatsch, T., Wang, Charles C., Weiss, Benjamin P., Wenkert, Daniel, and Wieczorek, Mark A.

Abstract

The objective of the NASA Psyche mission gravity science investigation is to map the mass distribution within asteroid (16) Psyche to elucidate interior structure and to resolve the question of whether this metal-rich asteroid represents a remnant metal core or whether it is a primordial body that never melted. Measurements of gravity will be obtained via the X-band telecommunication system on the Psyche spacecraft, collected from progressively lower mapping altitudes. Orbital gravity will allow an estimate of G M $GM$ to better than 0.001 km3 s−2. A spherical harmonic model of gravity to degree and order 10 will be achievable and, in concert with spherical harmonic data sets from topography and magnetometry, as well as surface composition data, will provide information regarding the spatial and radial distribution of mass that will be used to constrain the origin and evolution of (16) Psyche.

Published

2022

22. Ilmenite and magnetite microfabrics in shocked gneisses from the Vredefort impact structure, South Africa

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Dellefant, Fabian, Trepmann, Claudia A., Gilder, Stuart A., Sleptsova, Iuliia V., Kaliwoda, Melanie, Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Dellefant, Fabian, Trepmann, Claudia A., Gilder, Stuart A., Sleptsova, Iuliia V., Kaliwoda, Melanie, and Weiss, Benjamin P.

Abstract

We investigated microfabrics of shocked Archean gneisses from two, 10 m-deep drill cores located near the center of the Vredefort impact structure in an area that is characterized by a prominent, long-wavelength negative magnetic anomaly (< − 3000 nT) together with short-wavelength, high-amplitude anomalies attributed to lightning strikes. Planar fractures and feather features in quartz, which can be partially recrystallized, indicate shock conditions less than 20 GPa. Micrometer-sized magnetite and ilmenite along shock-related shear fractures in quartz and feldspar emanate from adjacent deformed coarse (> 100 µm) ilmenite and magnetite host grains. These fine-scaled veins suggest mobilization of magnetite and ilmenite during shear deformation of host Fe-phases and adjacent silicates, probably associated with frictional heating. Coarse ilmenite has fine-lamellar mechanical twins parallel to {10 $$\overline{1}$$ 1 ¯ 1} and single (0001) twins, indicative of dislocation-glide-controlled deformation under non-isostatic stresses related to shock. A few µm-wide magnetite lamellae parallel to {10 $$\overline{1}$$ 1 ¯ 1} and spheroidal magnetite (diameter ≈10 µm) within coarse ilmenite document exsolution after shock. Dauphiné twins associated with planar features in quartz imply cooling from 650 to 725 °C after shock, which accords with estimates of pre-impact basement temperatures from petrographic studies. The Curie temperature of magnetite is 580 °C; therefore, the central negative magnetic anomaly was produced as a thermoremanent magnetization acquired during cooling of the initially hot crust. The long-wavelength anomaly was likely amplified by the newly created magnetite that also acquired a thermal remanence. Although the magnetic properties of surface samples are often influenced by lightning strikes, we found no microstructural evidence for lightning-related processes.

Published

2022

23. Paleomagnetic evidence for a disk substructure in the early solar system

Author

Borlina, Cauê S., Weiss, Benjamin P., Bryson, James F. J., Bai, Xue-Ning, Lima, Eduardo A., Chatterjee, Nilanjan, Mansbach, Elias N., Borlina, Cauê S., Weiss, Benjamin P., Bryson, James F. J., Bai, Xue-Ning, Lima, Eduardo A., Chatterjee, Nilanjan, and Mansbach, Elias N.

Abstract

Astronomical observations and isotopic measurements of meteorites suggest that substructures are common in protoplanetary disks and may even have existed in the solar nebula. Here, we conduct paleomagnetic measurements of chondrules in CO carbonaceous chondrites to investigate the existence and nature of these disk sub-structures. We show that the paleomagnetism of chondrules in CO carbonaceous chondrites indicates the presence of a 101 $\pm$ 48 $\mu$T field in the solar nebula in the outer solar system ($\sim$3 to 7 AU from the Sun). The high intensity of this field relative to that inferred from inner solar system ($\lesssim$3 AU) meteorites indicates a factor of $\sim$5 to 150 mismatch in nebular accretion between the two reservoirs. This suggests substantial mass loss from the disk associated with a major disk substructure, possibly due to a magnetized disk wind., Comment: 16 pages, 3 figures, published in Science Advances

Published

2021

24. Perseverance rover notional caches for Mars Sample Return

Author

Hickman-Lewis, Keyron, Herd, Christopher D.K., Bosak, Tanja, Stack, Kathryn M., Sun, Vivian Z., Benison, Kathleen C., Cohen, Barbara A., Czaja, Andrew D., Debaille, Vinciane, Hausrath, Elisabeth M., Mayhew, Lisa E., Moynier, Frederic, Sephton, Mark A., Shuster, David L., Siljeström, Sandra, Simon, Justin I., Weiss, Benjamin P., Smith, Caroline L., Steele, Andrew, Flannery, David, Goreva, Yulia S., Gupta, Sanjeev, Kah, Linda C., Minitti, Michelle E., McLennan, Scott M., Madariaga, Juan Manuel, Brown, Adrian J., Williford, Kenneth H., Farley, Kenneth A., Hickman-Lewis, Keyron, Herd, Christopher D.K., Bosak, Tanja, Stack, Kathryn M., Sun, Vivian Z., Benison, Kathleen C., Cohen, Barbara A., Czaja, Andrew D., Debaille, Vinciane, Hausrath, Elisabeth M., Mayhew, Lisa E., Moynier, Frederic, Sephton, Mark A., Shuster, David L., Siljeström, Sandra, Simon, Justin I., Weiss, Benjamin P., Smith, Caroline L., Steele, Andrew, Flannery, David, Goreva, Yulia S., Gupta, Sanjeev, Kah, Linda C., Minitti, Michelle E., McLennan, Scott M., Madariaga, Juan Manuel, Brown, Adrian J., Williford, Kenneth H., and Farley, Kenneth A.

Abstract

The NASA Mars 2020 Perseverance rover plans to collect a suite of scientifically compelling samples for return to Earth [1–3]. Strategic planning by the Mars 2020 Science Team has identified notional sample caches within the framework of the geology of Jezero crater and its surroundings [2]. Locations of interest were identified by considering remotely sensed data and traversability constraints [1]. Notional sample caches have been defined for the prime mission within Jezero crater, and an extended mission outside Jezero crater. Prime mission notional cache. Samples of interest include: deltaic, crater floor, crater rim, and regolith materials. Lithologies with high habitability and biosignature preservation potential, such as carbonates and/or chemical deposits, will also be targeted. Such samples would address several questions: What habitable niches were present at Jezero? Are biosignatures and/or prebiotic organics preserved? What was the timing of fluviolacustrine activity? How can Jezero lithologies facilitate absolute crater chronology calibration? What insights do these lithologies provide into Mars climate evolution? What is the origin and alteration history of regional Noachian crust? Extended mission notional cache. Nili Planum is geologically distinct from Jezero, containing diverse Early or Pre-Noachian rocks [4]. Samples of interest include: basement rocks; megabreccias; fractures cross-cutting basement; olivine- and carbonate-bearing rocks; and mafic cap rock. These samples could answer questions 1, 4 and 5 above, together with: What characteristics defined the early planetary evolution and habitability of Mars? How long did the Martian dynamo persist? How do outside-Jezero surfaces, including bedrock and ejecta enable crater chronology calibration? What were the local and regional effects of the Isidis impact? The samples to be collected by Perseverance align with community prio

Published

2021

25. Sampling Mars: Notional Caches from Mars 2020 Strategic Planning

Author

Herd, Chris, Bosak, T., Stack, K. M., Sun, V. Z., Benison, Kathleen C., Cohen, Barbara A., Czaja, Andrew D., Debaille, V., Hausrath, Elisabeth M., Hickman-Lewis, K., Mayhew, L. E., Moynier, Frederic, Sephton, Mark A., Shuster, David L., Siljeström, Sandra, Simon, J. I., Weiss, Benjamin P., Flannery, David, Goreva, Y. S., Gupta, S., Kah, L. C., Minitti, Michelle, McLennan, S. M., Madariaga, J. M., Brown, A. J., Williford, K. H., Farley, K. A., Herd, Chris, Bosak, T., Stack, K. M., Sun, V. Z., Benison, Kathleen C., Cohen, Barbara A., Czaja, Andrew D., Debaille, V., Hausrath, Elisabeth M., Hickman-Lewis, K., Mayhew, L. E., Moynier, Frederic, Sephton, Mark A., Shuster, David L., Siljeström, Sandra, Simon, J. I., Weiss, Benjamin P., Flannery, David, Goreva, Y. S., Gupta, S., Kah, L. C., Minitti, Michelle, McLennan, S. M., Madariaga, J. M., Brown, A. J., Williford, K. H., and Farley, K. A.

Abstract

A central objective of the NASA Mars 2020 Perseverance rover mission is to collect and document a suite of scientifically compelling samples for possible return to Earth by a subsequent mission [1]. Strategic planning by the Mars 2020 Science Team has thus far identified a set of notional sample caches. These arose from integrating the testable hypotheses that could be addressed by Mars 2020 within the framework of the geology of Jezero crater and its surroundings [2], identifying specific locations of high scientific interest by analysis of remotely sensed data, and traversability considerations [1]. Here we describe the general characteristics of the identified notional caches and compare them to the types of samples previously prioritized by the wider Mars science community [3]. While strategic planning will guide and streamline the decision-making processes once the rover lands at Jezero crater, the actual samples collected will depend on the landing location, the traverse taken, and decisions made by the Mars 2020 Science Team.

Published

2021

26. Paleocene latitude of the Kohistan–Ladakh arc indicates multistage India–Eurasia collision

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Martin, Craig R, Jagoutz, Oliver E, Upadhyay, Rajeev, Royden, Leigh H, Eddy, Michael P, Bailey, Elizabeth, Nichols, Claire, Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Martin, Craig R, Jagoutz, Oliver E, Upadhyay, Rajeev, Royden, Leigh H, Eddy, Michael P, Bailey, Elizabeth, Nichols, Claire, and Weiss, Benjamin P.

Abstract

© 2020 National Academy of Sciences. All rights reserved. We report paleomagnetic data showing that an intraoceanic Trans- Tethyan subduction zone existed south of the Eurasian continent and north of the Indian subcontinent until at least Paleocene time. This system was active between 66 and 62 Ma at a paleolatitude of 8.1 ± 5.6 °N, placing it 600-2,300 km south of the contemporaneous Eurasian margin. The first ophiolite obductions onto the northern Indian margin also occurred at this time, demonstrating that collision was a multistage process involving at least two subduction systems. Collisional events began with collision of India and the Trans-Tethyan subduction zone in Late Cretaceous to Early Paleocene time, followed by the collision of India (plus Trans-Tethyan ophiolites) with Eurasia in mid-Eocene time. These data constrain the total postcollisional convergence across the India-Eurasia convergent zone to 1,350-2,150 km and limit the north-south extent of northwestern Greater India to <900 km. These results have broad implications for how collisional processes may affect plate reconfigurations, global climate, and biodiversity.

Published

2021

27. The potential science and engineering value of samples delivered to Earth by Mars sample return

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, and Weiss, Benjamin P.

Abstract

© 2019 The Authors. Meteoritics & Planetary Science published by Wiley Periodicals, Inc. on behalf of The Meteoritical Society (MET) Executive summary provided in lieu of abstract.

Published

2021

28. Paleomagnetic evidence for a disk substructure in the early solar system

Author

Borlina, Cauê S., Weiss, Benjamin P., Bryson, James F. J., Bai, Xue-Ning, Lima, Eduardo A., Chatterjee, Nilanjan, Mansbach, Elias N., Borlina, Cauê S., Weiss, Benjamin P., Bryson, James F. J., Bai, Xue-Ning, Lima, Eduardo A., Chatterjee, Nilanjan, and Mansbach, Elias N.

Abstract

Astronomical observations and isotopic measurements of meteorites suggest that substructures are common in protoplanetary disks and may even have existed in the solar nebula. Here, we conduct paleomagnetic measurements of chondrules in CO carbonaceous chondrites to investigate the existence and nature of these disk sub-structures. We show that the paleomagnetism of chondrules in CO carbonaceous chondrites indicates the presence of a 101 $\pm$ 48 $\mu$T field in the solar nebula in the outer solar system ($\sim$3 to 7 AU from the Sun). The high intensity of this field relative to that inferred from inner solar system ($\lesssim$3 AU) meteorites indicates a factor of $\sim$5 to 150 mismatch in nebular accretion between the two reservoirs. This suggests substantial mass loss from the disk associated with a major disk substructure, possibly due to a magnetized disk wind., Comment: 16 pages, 3 figures, published in Science Advances

Published

2021

29. History of the Solar Nebula from Meteorite Paleomagnetism

Author

Weiss, Benjamin P., Bai, Xue-Ning, Fu, Roger R., Weiss, Benjamin P., Bai, Xue-Ning, and Fu, Roger R.

Abstract

We review recent advances in our understanding of magnetism in the solar nebular and protoplanetary disks (PPDs). We discuss the implications of theory, meteorite measurements, and astronomical observations for planetary formation and nebular evolution. Paleomagnetic measurements indicate the presence of fields of 0.54$\pm$0.21 G at $\sim$1 to 3 astronomical units (AU) from the Sun and $\gtrsim$0.06 G at 3 to 7 AU until >1.22 and >2.51 million years (Ma) after solar system formation, respectively. These intensities are consistent with those predicted to enable typical astronomically-observed protostellar accretion rates of $\sim$10$^{-8}$ M$_\odot$ yr$^{-1}$, suggesting that magnetism played a central role in mass and angular momentum transport in PPDs. Paleomagnetic studies also indicate fields <0.006 G and <0.003 G in the inner and outer solar system by 3.94 and 4.89 Ma, respectively, consistent with the nebular gas having dispersed by this time. This is similar to the observed lifetimes of extrasolar protoplanetary disks., Comment: Revised version published in Science Advances

Published

2021

30. Magnetic Properties of Asteroid (162173) Ryugu

Author

Hercik, David, Auster, Hans-Ulrich, Constantinescu, Dragos, Blum, Jürgen, Fornaçon, Karl-Heinz, Fujimoto, Masaki, Gebauer, Kathrin, Grundmann, Jan-Thimo, Güttler, Carsten, Hillenmaier, Olaf, Ho, Tra-Mi, Hördt, Andreas, Krause, Christian, Kührt, Ekkehard, Lorda, Laurence, Matsuoka, Ayako, Motschmann, Uwe, Moussi-Soffys, Aurélie, Richter, Ingo, Sasaki, Kaname, Scholten, Frank, Stoll, Bernd, Weiss, Benjamin P, Wolff, Friederike, Glassmeier, Karl-Heinz, Hercik, David, Auster, Hans-Ulrich, Constantinescu, Dragos, Blum, Jürgen, Fornaçon, Karl-Heinz, Fujimoto, Masaki, Gebauer, Kathrin, Grundmann, Jan-Thimo, Güttler, Carsten, Hillenmaier, Olaf, Ho, Tra-Mi, Hördt, Andreas, Krause, Christian, Kührt, Ekkehard, Lorda, Laurence, Matsuoka, Ayako, Motschmann, Uwe, Moussi-Soffys, Aurélie, Richter, Ingo, Sasaki, Kaname, Scholten, Frank, Stoll, Bernd, Weiss, Benjamin P, Wolff, Friederike, and Glassmeier, Karl-Heinz

Abstract

©2020. The Authors. Observations of the magnetization state of asteroids indicate diverse properties. Values between 1.9 × 10 -6Am2/kg (Eros) and 10-2 Am2/kg (Braille) have been reported. A more detailed understanding of asteroidal magnetic properties allows far-reaching conclusions of the magnetization mechanism as well as the strength of the magnetic field of the solar system regions the asteroid formed in. The Hayabusa2 mission with its lander Mobile Asteroid Surface Scout is equipped with a magnetometer experiment, MasMag. MasMag is a state-of-the-art three-axis fluxgate magnetometer, successfully operated also on Philae, the Rosetta mission lander. MasMag has enabled, after Eros for the second time ever, to determine the magnetic field of an asteroid during descent and on-surface operations. The new observations show that Ryugu, a low-albedo C-type asteroid, has no detectable global magnetization, and any local magnetization is either small (< 10−6 Am2/kg) or on very small (subcentimeter) scales. This implies, for example, that energetic solar wind particles could reach and alter the surface unimpeded by strong asteroidal magnetic fields, such as minimagnetospheres in case of the Moon.

Published

2021

31. History of the solar nebula from meteorite paleomagnetism

Author

Weiss, Benjamin P, Bai, Xue-Ning, Fu, Roger R, Weiss, Benjamin P, Bai, Xue-Ning, and Fu, Roger R

Abstract

Copyright © 2021 The Authors, some rights reserved. We review recent advances in our understanding of magnetism in the solar nebula and protoplanetary disks (PPDs). We discuss the implications of theory, meteorite measurements, and astronomical observations for planetary formation and nebular evolution. Paleomagnetic measurements indicate the presence of fields of 0.54 ± 0.21 G at ~1 to 3 astronomical units (AU) from the Sun and ≳0.06 G at 3 to 7 AU until >1.22 and >2.51 million years (Ma) after solar system formation, respectively. These intensities are consistent with those predicted to enable typical astronomically observed protostellar accretion rates of ~10−8 M☉year−1, suggesting that magnetism played a central role in mass transport in PPDs. Paleomagnetic studies also indicate fields <0.006 G and <0.003 G in the inner and outer solar system by 3.94 and 4.89 Ma, respectively, consistent with the nebular gas having dispersed by this time. This is similar to the observed lifetimes of extrasolar protoplanetary disks.

Published

2021

32. Reevaluating the evidence for a Hadean-Eoarchean dynamo

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Borlina, Cauê S, Weiss, Benjamin P, Lima, Eduardo A, Tang, Fengzai, Taylor, Richard JM, Einsle, Joshua F, Harrison, Richard J, Fu, Roger R, Bell, Elizabeth A, Alexander, Ellen W, Kirkpatrick, Heather M, Wielicki, Matthew M, Harrison, T Mark, Ramezani, Jahandar, Maloof, Adam C, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Borlina, Cauê S, Weiss, Benjamin P, Lima, Eduardo A, Tang, Fengzai, Taylor, Richard JM, Einsle, Joshua F, Harrison, Richard J, Fu, Roger R, Bell, Elizabeth A, Alexander, Ellen W, Kirkpatrick, Heather M, Wielicki, Matthew M, Harrison, T Mark, Ramezani, Jahandar, and Maloof, Adam C

Abstract

Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC). The time of origin of the geodynamo has important implications for the thermal evolution of the planetary interior and the habitability of early Earth. It has been proposed that detrital zircon grains from Jack Hills, Western Australia, provide evidence for an active geodynamo as early as 4.2 billion years (Ga) ago. However, our combined paleomagnetic, geochemical, and mineralogical studies on Jack Hills zircons indicate that most have poor magnetic recording properties and secondary magnetization carriers that postdate the formation of the zircons. Therefore, the existence of the geodynamo before 3.5 Ga ago remains unknown.

Published

2021

33. Was the moon magnetized by impact plasmas?

Author

Oran, Rona, Weiss, Benjamin P, Shprits, Yuri, Miljković, Katarina, Tóth, Gábor, Oran, Rona, Weiss, Benjamin P, Shprits, Yuri, Miljković, Katarina, and Tóth, Gábor

Abstract

© 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC). The crusts of the Moon, Mercury, and many meteorite parent bodies are magnetized. Although the magnetizing field is commonly attributed to that of an ancient core dynamo, a longstanding hypothesized alternative is amplification of the interplanetary magnetic field and induced crustal field by plasmas generated by meteoroid impacts. Here, we use magnetohydrodynamic and impact simulations and analytic relationships to demonstrate that although impact plasmas can transiently enhance the field inside the Moon, the resulting fields are at least three orders of magnitude too weak to explain lunar crustal magnetic anomalies. This leaves a core dynamo as the only plausible source of most magnetization on the Moon.

Published

2021

34. Paleocene latitude of the Kohistan–Ladakh arc indicates multistage India–Eurasia collision

Author

Martin, Craig R, Jagoutz, Oliver, Upadhyay, Rajeev, Royden, Leigh H, Eddy, Michael P, Bailey, Elizabeth, Nichols, Claire IO, Weiss, Benjamin P, Martin, Craig R, Jagoutz, Oliver, Upadhyay, Rajeev, Royden, Leigh H, Eddy, Michael P, Bailey, Elizabeth, Nichols, Claire IO, and Weiss, Benjamin P

Abstract

© 2020 National Academy of Sciences. All rights reserved. We report paleomagnetic data showing that an intraoceanic Trans- Tethyan subduction zone existed south of the Eurasian continent and north of the Indian subcontinent until at least Paleocene time. This system was active between 66 and 62 Ma at a paleolatitude of 8.1 ± 5.6 °N, placing it 600-2,300 km south of the contemporaneous Eurasian margin. The first ophiolite obductions onto the northern Indian margin also occurred at this time, demonstrating that collision was a multistage process involving at least two subduction systems. Collisional events began with collision of India and the Trans-Tethyan subduction zone in Late Cretaceous to Early Paleocene time, followed by the collision of India (plus Trans-Tethyan ophiolites) with Eurasia in mid-Eocene time. These data constrain the total postcollisional convergence across the India-Eurasia convergent zone to 1,350-2,150 km and limit the north-south extent of northwestern Greater India to <900 km. These results have broad implications for how collisional processes may affect plate reconfigurations, global climate, and biodiversity.

Published

2021

35. A Portable Magnetometer for Magnetic Measurements of Meter‐Sized Meteorites

Author

Clavé, Elise, Maurel, Clara, Lima, Eduardo A, Shah, Jay, Mansbach, Elias N, Uehara, Minoru, Weiss, Benjamin P, Clavé, Elise, Maurel, Clara, Lima, Eduardo A, Shah, Jay, Mansbach, Elias N, Uehara, Minoru, and Weiss, Benjamin P

Abstract

Meteorites contain records of past magnetic fields in the form of natural remanent magnetization (NRM). A key property of meteorite magnetization that provides information about its origin is its dependence on spatial scale. In particular, understanding how the mean remanent magnetization varies from the scale of meteorites to the global scale of their parent bodies would aid in the interpretation of spacecraft magnetometry data. However, the vast majority of meteorite samples whose remanent magnetization have been measured have sizes <10 cm due to the limited size range accommodated by laboratory magnetometers. To address this limitation, we developed a portable magnetometer array that enables remanence measurements of meter-size meteorites in a non-magnetically shielded environment. The instrument measures both NRM and induced magnetization using two orthogonal square Helmholtz coil pairs that compensate the vertical and horizontal components of the background magnetic field. An array of four magnetometers mounted on a movable aluminum rail measures the magnetic field at multiple locations around the sample. The instrument is transportable and can be adapted to different sample sizes. After distinguishing the induced component from the remanent component of a sample's total field, the remanence can be estimated from a multipole field inversion combined with nonlinear least squares method. We validated the instrument and data processing on a magnet of known magnetic moment and measured the NRM of a meter-sized iron meteorite.

Published

2021

36. A time‐resolved paleomagnetic record of Main Group pallasites: Evidence for a large‐cored, thin‐mantled parent body

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Nichols, Claire IO, Bryson, James FJ, Cottrell, Rory D, Fu, Roger R, Harrison, Richard J, Herrero-Albillos, Julia, Kronast, Florian, Tarduno, John A, Weiss, Benjamin P, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Nichols, Claire IO, Bryson, James FJ, Cottrell, Rory D, Fu, Roger R, Harrison, Richard J, Herrero-Albillos, Julia, Kronast, Florian, Tarduno, John A, and Weiss, Benjamin P

Published

2021

37. Meteorite evidence for partial differentiation and protracted accretion of planetesimals

Author

Maurel, Clara, Bryson, James FJ, Lyons, Richard J, Ball, Matthew R, Chopdekar, Rajesh V, Scholl, Andreas, Ciesla, Fred J, Bottke, William F, Weiss, Benjamin P, Maurel, Clara, Bryson, James FJ, Lyons, Richard J, Ball, Matthew R, Chopdekar, Rajesh V, Scholl, Andreas, Ciesla, Fred J, Bottke, William F, and Weiss, Benjamin P

Abstract

© 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC). Modern meteorite classification schemes assume that no single planetary body could be source of both unmelted (chondritic) and melted (achondritic) meteorites. This dichotomy is a natural outcome of formation models assuming that planetesimal accretion occurred nearly instantaneously. However, it has recently been proposed that the accretion of many planetesimals lasted over ≳1 million years (Ma). This could have resulted in partially differentiated internal structures, with individual bodies containing iron cores, achondritic silicate mantles, and chondritic crusts. This proposal can be tested by searching for a meteorite group containing evidence for these three layers. We combine synchrotron paleomagnetic analyses with thermal, impact, and collisional evolution models to show that the parent body of the enigmatic IIE iron meteorites was such a partially differentiated planetesimal. This implies that some chondrites and achondrites simultaneously coexisted on the same planetesimal, indicating that accretion was protracted and that apparently undifferentiated asteroids may contain melted interiors.

Published

2021

38. Magnetic gradiometry using frequency-domain filtering

Author

Ream, Jodie B., Weiss, Benjamin P., Oran, Rona, Raymond, Carol A., Polanskey, Carol A., Wenkert, Daniel D., Elkins-Tanton, Linda T, Hart, Richard A, Russell, Christopher T, Merayo, Jose M G, Ream, Jodie B., Weiss, Benjamin P., Oran, Rona, Raymond, Carol A., Polanskey, Carol A., Wenkert, Daniel D., Elkins-Tanton, Linda T, Hart, Richard A, Russell, Christopher T, and Merayo, Jose M G

Abstract

Accurate measurements of ambient planetary and interplanetary magnetic fields using spacecraft magnetometers typically require accounting for interfering magnetic fields generated by the flight system (FS). The most common method for removing FS-generated time-variable magnetic fields is narrow-band and low-pass filtering of magnetic field data in the frequency domain. However, if fluctuations in the ambient field contain frequencies overlapping those in the FS field, it can be difficult to construct a filter that will not affect both signals. Here we present an alternate method for removing FS time-variable signatures from magnetic field measurements. For spacecraft that make use of a magnetic gradiometer (i.e. with two or more instruments on a boom at different distances from the center of the spacecraft), the dominant frequencies in the FS field can be identified using spectra of the differenced field components. The amplitudes of the FS field at those frequencies can then be suppressed without removing spectral peaks present in the ambient field. We demonstrate the successful application of this method, referred to as gradiometry peak suppression, both to modeled data sets and to 128 Hz Venus Express magnetometer data.

Published

2021

39. The sustainability of habitability on terrestrial planets: Insights, questions, and needed measurements from Mars for understanding the evolution of Earth-like worlds

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Weiss, Benjamin P, Ehlmann, B. L., Anderson, F. S., Andrews-Hanna, J., Catling, D. C., Christensen, P. R., Cohen, B. A., Dressing, C. D., Edwards, C. S., Elkins-Tanton, L. T., Farley, K. A., Fassett, C. I., Fischer, W. W., Fraeman, A. A., Golombek, M. P., Hamilton, V. E., Hayes, A. G., Herd, C. D. K., Horgan, B., Hu, R., Jakosky, B. M., Johnson, J. R., Kasting, J. F., Kerber, L., Kinch, K. M., Kite, E. S., Knutson, H. A., Lunine, J. I., Mahaffy, P. R., Mangold, N., McCubbin, F. M., Mustard, J. F., Niles, P. B., Quantin-Nataf, C., Rice, M. S., Stack, K. M., Stevenson, D. J., Stewart, S. T., Toplis, M. J., Usui, T., Werner, S. C., Wordsworth, R. D., Wray, J. J., Yingst, R. A., Yung, Y. L., Zahnle, K. J., Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Weiss, Benjamin P, Ehlmann, B. L., Anderson, F. S., Andrews-Hanna, J., Catling, D. C., Christensen, P. R., Cohen, B. A., Dressing, C. D., Edwards, C. S., Elkins-Tanton, L. T., Farley, K. A., Fassett, C. I., Fischer, W. W., Fraeman, A. A., Golombek, M. P., Hamilton, V. E., Hayes, A. G., Herd, C. D. K., Horgan, B., Hu, R., Jakosky, B. M., Johnson, J. R., Kasting, J. F., Kerber, L., Kinch, K. M., Kite, E. S., Knutson, H. A., Lunine, J. I., Mahaffy, P. R., Mangold, N., McCubbin, F. M., Mustard, J. F., Niles, P. B., Quantin-Nataf, C., Rice, M. S., Stack, K. M., Stevenson, D. J., Stewart, S. T., Toplis, M. J., Usui, T., Werner, S. C., Wordsworth, R. D., Wray, J. J., Yingst, R. A., Yung, Y. L., Zahnle, K. J., and Weiss, Benjamin P.

Abstract

What allows a planet to be both within a potentially habitable zone and sustain habitability over long geologic time? With the advent of exoplanetary astronomy and the ongoing discovery of terrestrial-type planets around other stars, our own solar system becomes a key testing ground for ideas about what factors control planetary evolution. Mars provides the solar system's longest record of the interplay of the physical and chemical processes relevant to habitability on an accessible rocky planet with an atmosphere and hydrosphere. Here we review current understanding and update the timeline of key processes in early Mars history. We then draw on knowledge of exoplanets and the other solar system terrestrial planets to identify six broad questions of high importance to the development and sustaining of habitability (unprioritized): (1) Is small planetary size fatal? (2) How do magnetic fields influence atmospheric evolution? (3) To what extent does starting composition dictate subsequent evolution, including redox processes and the availability of water and organics? (4) Does early impact bombardment have a net deleterious or beneficial influence? (5) How do planetary climates respond to stellar evolution, e.g., sustaining early liquid water in spite of a faint young Sun? (6) How important are the timescales of climate forcing and their dynamical drivers? Finally, we suggest crucial types of Mars measurements (unprioritized) to address these questions: (1) in situ petrology at multiple units/sites; (2) continued quantification of volatile reservoirs and new isotopic measurements of H, C, N, O, S, Cl, and noble gases in rocks that sample multiple stratigraphic sections; (3) radiometric age dating of units in stratigraphic sections and from key volcanic and impact units; (4) higher-resolution measurements of heat flux, subsurface structure, and magnetic field anomalies coupled with absolute age dating. Understanding the evolution of early Mars will feed forward to unde

Published

2018

40. A re-assessesment of the shallow paleomagnetic inclinations of the Western Cyclades, Greece

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Bradley, Kyle Edward, Weiss, Benjamin P, Royden, Leigh H, Vassilakis, E., Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Bradley, Kyle Edward, Weiss, Benjamin P, Royden, Leigh H, Vassilakis, E., and Weiss, Benjamin P.

Abstract

Consistently shallow paleomagnetic inclinations measured in Early to Middle Miocene lacustrine and dacitic volcanic rocks of the Kymi-Aliveri basin have been cited as evidence for an anomalous geomagnetic field geometry or northward drift of the Aegean Sea region. We present new paleomagnetic data from the lacustrine beds that are instead not anomalously shallow and consistent with deposition near their present-day latitude as predicted by global apparent polar wander paths. Anomalously shallow inclinations and easterly declinations reported from the Oxylithos volcanics are an artifact of an inappropriate tilt correction. The excessively shallow paleomagnetic inclinations reported from the deformed Middle Miocene plutons on Mykonos and Naxos are consistent with reorientation of an original thermoremanent magnetization acquired during cooling below 580°C by subsequent ductile strain at temperatures of 400-500°C. Magnetization overprints observed in these rocks may reflect the acquisition of a stable chemical remanent magnetization lying parallel to the transposed high-temperature magnetization as the result of low-temperature (<350°C) maghemitization. We therefore find no convincing evidence for an anomalous Middle Miocene field geometry, northward drift of the Aegean, or back-tilting of the low-angle normal faults that constitute the North Cycladic Detachment System. Keyword: Tectonics; paleomagnetism; detachment; paleolatitude; Kymi-Aliveri basin, National Science Foundation (U.S.) (Grant EAR-0409373)

Published

2018

41. Multi-scale magnetic mapping of serpentinite carbonation

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Lima, Eduardo A., Weiss, Benjamin P, Tominaga, Masako, Beinlich, Andreas, Tivey, Maurice A., Hampton, Brian A., Harigane, Yumiko, Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Lima, Eduardo A., Weiss, Benjamin P, Tominaga, Masako, Beinlich, Andreas, Tivey, Maurice A., Hampton, Brian A., Harigane, Yumiko, and Weiss, Benjamin P.

Abstract

Peridotite carbonation represents a critical step within the long-term carbon cycle by sequestering volatile CO₂ in solid carbonate. This has been proposed as one potential pathway to mitigate the effects of greenhouse gas release. Most of our current understanding of reaction mechanisms is based on hand specimen and laboratory-scale analyses. Linking laboratory-scale observations to fi eld scale processes remains challenging. Here we present the fi rst geophysical characterization of serpentinite carbonation across scales ranging from km to sub-mm by combining aeromagnetic observations, outcrop- and thin section-scale magnetic mapping. At all scales, magnetic anomalies coherently change across reaction fronts separating assemblages indicative of incipient, intermittent, and fi nal reaction progress. The abundance of magnetic minerals correlates with reaction progress, causing amplitude and wavelength variations in associated magnetic anomalies. This correlation represents a foundation for characterizing the extent and degree of in sity ultramafic rock carbonation in space and time., National Science Foundation (U.S.) (grant DMS-1521765), Thomas F. Peterson, Jr (generous support)

Published

2018

42. Micrometer-scale magnetic imaging of geological samples using a quantum diamond microscope

Author

Lincoln Laboratory, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Fu, Roger Rennan, Le Sage, David A, Lima, E. A., Weiss, Benjamin P, Glenn, D. R., Kehayias, P., Walsworth, R. L., Weiss, Benjamin P., Lincoln Laboratory, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Fu, Roger Rennan, Le Sage, David A, Lima, E. A., Weiss, Benjamin P, Glenn, D. R., Kehayias, P., Walsworth, R. L., and Weiss, Benjamin P.

Abstract

Remanent magnetization in geological samples may record the past intensity and direction of planetary magnetic fields. Traditionally, this magnetization is analyzed through measurements of the net magnetic moment of bulk millimeter to centimeter sized samples. However, geological samples are often mineralogically and texturally heterogeneous at submillimeter scales, with only a fraction of the ferromagnetic grains carrying the remanent magnetization of interest. Therefore, characterizing this magnetization in such cases requires a technique capable of imaging magnetic fields at fine spatial scales and with high sensitivity. To address this challenge, we developed a new instrument, based on nitrogen-vacancy centers in diamond, which enables direct imaging of magnetic fields due to both remanent and induced magnetization, as well as optical imaging, of room-temperature geological samples with spatial resolution approaching the optical diffraction limit. We describe the operating principles of this device, which we call the quantum diamond microscope (QDM), and report its optimized image-area-normalized magnetic field sensitivity (20 µT⋅µm/Hz1/2), spatial resolution (5 µm), and field of view (4 mm), as well as trade-offs between these parameters. We also perform an absolute magnetic field calibration for the device in different modes of operation, including three-axis (vector) and single-axis (projective) magnetic field imaging. Finally, we use the QDM to obtain magnetic images of several terrestrial and meteoritic rock samples, demonstrating its ability to resolve spatially distinct populations of ferromagnetic carriers., United States. National Aeronautics and Space Administration. Planetary Major Equipment Program (NNX15AH72G), United States. National Aeronautics and Space Administration. Emerging Worlds Program, National Science Foundation (U.S.). Integrated Support Promoting Interdisciplinary Research and Education (INSPIRE) Program (grant EAR 1647504), National Science Foundation (U.S.). Electronics, Photonics and Magnetic Devices Program (grant 1408075), United States. Defense Advanced Research Projects Agency. Quantum Assisted Sensing And Readout Program (contract HR0011‐11‐C‐0073), Thomas F. Peterson Jr. (generous gift)

Published

2018

43. The Mars 2020 Candidate Landing Sites: A Magnetic Field Perspective

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Weiss, Benjamin P, Mittelholz, Anna, Morschhauser, Achim, Johnson, Catherine L., Langlais, Benoit, Lillis, Robert J., Vervelidou, Foteini, Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Weiss, Benjamin P, Mittelholz, Anna, Morschhauser, Achim, Johnson, Catherine L., Langlais, Benoit, Lillis, Robert J., Vervelidou, Foteini, and Weiss, Benjamin P.

Abstract

We present an analysis of the remaining three candidate landing sites for Mars 2020, Columbia Hills (CH), Northeast Syrtis (NES) and Jezero (JE) from the perspective of understanding Mars' crustal magnetic field. We identify how the different sites can address each of six community-defined paleomagnetic science objectives for Mars return samples. These objectives include understanding the early dynamo field and its variability, identification of magnetic minerals that carry magnetization in the samples, and characterization of any thermal and chemical alteration of samples. Satellite data have provided global and regional constraints on crustal magnetization, indicating strong magnetizations at CH and weak to no magnetization at JE and NES. However, the primary paleomagnetic interest—understanding the early dynamo—requires ground truth from a landing site at which pre-Noachian and Early Noachian deposits are accessible. This requirement is most likely met by the site NES, which contains meggabreccia deposits, and it is therefore the highest priority landing site for magnetic field investigations. Importantly, a sample return mission has never been done, and so any of the three landing sites will provide critical, new data that will contribute to understanding the history of Mars' magnetic field and crustal mineralogy and, in turn, yield constraints on the planet's evolution. Keywords: Mars 2020; paleomagnetism; Mars; magnetic field

Published

2018

44. Magnetic Fields Recorded by Chondrules Formed in Nebular Shocks

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Weiss, Benjamin P, Mai, Chuhong, Desch, Steven J., Boley, Aaron C., Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Weiss, Benjamin P, Mai, Chuhong, Desch, Steven J., Boley, Aaron C., and Weiss, Benjamin P.

Abstract

Recent laboratory efforts have constrained the remanent magnetizations of chondrules and the magnetic field strengths to which the chondrules were exposed as they cooled below their Curie points. An outstanding question is whether the inferred paleofields represent the background magnetic field of the solar nebula or were unique to the chondrule-forming environment. We investigate the amplification of the magnetic field above background values for two proposed chondrule formation mechanisms, large-scale nebular shocks and planetary bow shocks. Behind large-scale shocks, the magnetic field parallel to the shock front is amplified by factors of ∼10-30, regardless of the magnetic diffusivity. Therefore, chondrules melted in these shocks probably recorded an amplified magnetic field. Behind planetary bow shocks, the field amplification is sensitive to the magnetic diffusivity. We compute the gas properties behind a bow shock around a 3000 km radius planetary embryo, with and without atmospheres, using hydrodynamics models. We calculate the ionization state of the hot, shocked gas, including thermionic emission from dust, thermal ionization of gas-phase potassium atoms, and the magnetic diffusivity due to Ohmic dissipation and ambipolar diffusion. We find that the diffusivity is sufficiently large that magnetic fields have already relaxed to background values in the shock downstream where chondrules acquire magnetizations, and that these locations are sufficiently far from the planetary embryos that chondrules should not have recorded a significant putative dynamo field generated on these bodies. We conclude that, if melted in planetary bow shocks, chondrules probably recorded the background nebular field. Key words: magnetic fields, meteorites, meteors, meteoroids, protoplanetary disks, shock waves, United States. National Aeronautics and Space Administration (NNX15AH72G)

Published

2018

45. Meteorite evidence for partial differentiation and protracted accretion of planetesimals.

Author

Maurel, Clara, Maurel, Clara, Bryson, James FJ, Lyons, Richard J, Ball, Matthew R, Chopdekar, Rajesh V, Scholl, Andreas, Ciesla, Fred J, Bottke, William F, Weiss, Benjamin P, Maurel, Clara, Maurel, Clara, Bryson, James FJ, Lyons, Richard J, Ball, Matthew R, Chopdekar, Rajesh V, Scholl, Andreas, Ciesla, Fred J, Bottke, William F, and Weiss, Benjamin P

Abstract

Modern meteorite classification schemes assume that no single planetary body could be source of both unmelted (chondritic) and melted (achondritic) meteorites. This dichotomy is a natural outcome of formation models assuming that planetesimal accretion occurred nearly instantaneously. However, it has recently been proposed that the accretion of many planetesimals lasted over ≳1 million years (Ma). This could have resulted in partially differentiated internal structures, with individual bodies containing iron cores, achondritic silicate mantles, and chondritic crusts. This proposal can be tested by searching for a meteorite group containing evidence for these three layers. We combine synchrotron paleomagnetic analyses with thermal, impact, and collisional evolution models to show that the parent body of the enigmatic IIE iron meteorites was such a partially differentiated planetesimal. This implies that some chondrites and achondrites simultaneously coexisted on the same planetesimal, indicating that accretion was protracted and that apparently undifferentiated asteroids may contain melted interiors.

Published

2020

46. Meteorite evidence for partial differentiation and protracted accretion of planetesimals.

Author

Maurel, Clara, Maurel, Clara, Bryson, James FJ, Lyons, Richard J, Ball, Matthew R, Chopdekar, Rajesh V, Scholl, Andreas, Ciesla, Fred J, Bottke, William F, Weiss, Benjamin P, Maurel, Clara, Maurel, Clara, Bryson, James FJ, Lyons, Richard J, Ball, Matthew R, Chopdekar, Rajesh V, Scholl, Andreas, Ciesla, Fred J, Bottke, William F, and Weiss, Benjamin P

Abstract

Modern meteorite classification schemes assume that no single planetary body could be source of both unmelted (chondritic) and melted (achondritic) meteorites. This dichotomy is a natural outcome of formation models assuming that planetesimal accretion occurred nearly instantaneously. However, it has recently been proposed that the accretion of many planetesimals lasted over ≳1 million years (Ma). This could have resulted in partially differentiated internal structures, with individual bodies containing iron cores, achondritic silicate mantles, and chondritic crusts. This proposal can be tested by searching for a meteorite group containing evidence for these three layers. We combine synchrotron paleomagnetic analyses with thermal, impact, and collisional evolution models to show that the parent body of the enigmatic IIE iron meteorites was such a partially differentiated planetesimal. This implies that some chondrites and achondrites simultaneously coexisted on the same planetesimal, indicating that accretion was protracted and that apparently undifferentiated asteroids may contain melted interiors.

Published

2020

47. Was the moon magnetized by impact plasmas?

Author

Oran, Rona, Oran, Rona, Weiss, Benjamin P, Shprits, Yuri, Miljković, Katarina, Tóth, Gábor, Oran, Rona, Oran, Rona, Weiss, Benjamin P, Shprits, Yuri, Miljković, Katarina, and Tóth, Gábor

Abstract

The crusts of the Moon, Mercury, and many meteorite parent bodies are magnetized. Although the magnetizing field is commonly attributed to that of an ancient core dynamo, a longstanding hypothesized alternative is amplification of the interplanetary magnetic field and induced crustal field by plasmas generated by meteoroid impacts. Here, we use magnetohydrodynamic and impact simulations and analytic relationships to demonstrate that although impact plasmas can transiently enhance the field inside the Moon, the resulting fields are at least three orders of magnitude too weak to explain lunar crustal magnetic anomalies. This leaves a core dynamo as the only plausible source of most magnetization on the Moon.

Published

2020

48. Constraining the Evolutionary History of the Moon and the Inner Solar System: A Case for New Returned Lunar Samples

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Tartèse, Romain, Anand, Mahesh, Gattacceca, Jérôme, Joy, Katherine H., Mortimer, James I., Pernet-Fisher, John F., Russell, Sara, Snape, Joshua F., Weiss, Benjamin P., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Tartèse, Romain, Anand, Mahesh, Gattacceca, Jérôme, Joy, Katherine H., Mortimer, James I., Pernet-Fisher, John F., Russell, Sara, Snape, Joshua F., and Weiss, Benjamin P.

Abstract

The Moon is the only planetary body other than the Earth for which samples have been collected in situ by humans and robotic missions and returned to Earth. Scientific investigations of the first lunar samples returned by the Apollo 11 astronauts 50 years ago transformed the way we think most planetary bodies form and evolve. Identification of anorthositic clasts in Apollo 11 samples led to the formulation of the magma ocean concept, and by extension the idea that the Moon experienced large-scale melting and differentiation. This concept of magma oceans would soon be applied to other terrestrial planets and large asteroidal bodies. Dating of basaltic fragments returned from the Moon also showed that a relatively small planetary body could sustain volcanic activity for more than a billion years after its formation. Finally, studies of the lunar regolith showed that in addition to containing a treasure trove of the Moon’s history, it also provided us with a rich archive of the past 4.5 billion years of evolution of the inner Solar System. Further investigations of samples returned from the Moon over the past five decades led to many additional discoveries, but also raised new and fundamental questions that are difficult to address with currently available samples, such as those related to the age of the Moon, duration of lunar volcanism, the lunar paleomagnetic field and its intensity, and the record on the Moon of the bombardment history during the first billion years of evolution of the Solar System. In this contribution, we review the information we currently have on some of the key science questions related to the Moon and discuss how future sample-return missions could help address important knowledge gaps. Keywords: Earth-Moon system; Lunar evolution; Sample-return; Solar System, UK Science and Technology Facilities Council (STFC) (grants ST/P005225/1 to RT, ST/M001253/1 to KHJ, and ST/P000657/1 to MA), Royal Society (grant RS/UF140190 to KHJ), European Commission Horizon 2020 Research and Innovation programme (Marie Skłodowska-Curie Actions Fellowship grant 794287 to JFS), Agence Nationale de la Recherche (project Maglune ANR-14-CE33-0012 to JG), NASA Solar System Workings program (grant NNX15AL62G to BPW), NASA Solar System Exploration Virtual Institute (grant NNA14AB01A to BPW)

Published

2020

49. Meteorite cloudy zone formation as a quantitative indicator of paleomagnetic field intensities and cooling rates on planetesimals

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Maurel, Clara, Weiss, Benjamin P, Bryson, James F.J., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Maurel, Clara, Weiss, Benjamin P, and Bryson, James F.J.

Abstract

Metallic microstructures in slowly-cooled iron-rich meteorites reflect the thermal and magnetic histories of their parent planetesimals. Of particular interest is the cloudy zone, a nanoscale intergrowth of Ni-rich islands within a Ni-poor matrix that forms below ∼350 °C by spinodal decomposition. The sizes of the islands have long been recognized as reflecting the low-temperature cooling rates of meteorite parent bodies. However, a model capable of providing quantitative cooling rate estimates from island sizes has been lacking. Moreover, these islands are also capable of preserving a record of the ambient magnetic field as they grew, but some of the key physical parameters required for recovering reliable paleointensity estimates from magnetic measurements of these islands have been poorly constrained. To address both of these issues, we present a numerical model of the structural and compositional evolution of the cloudy zone as a function of cooling rate and local composition. Our model produces island sizes that are consistent with present-day measured sizes. This model enables a substantial improvement in the calibration of paleointensity estimates and associated uncertainties. In particular, we can now accurately quantify the statistical uncertainty associated with the finite number of islands acquiring the magnetization and the uncertainty on their size at the time of the record. We use this new understanding to revisit paleointensities from previous pioneering paleomagnetic studies of cloudy zones. We show that these could have been overestimated by up to one order of magnitude but nevertheless still require substantial magnetic fields to have been present on their parent bodies. Our model also allows us to estimate absolute cooling rates for meteorites that cooled slower than <10,000 °C My −1 . We demonstrate how these cooling rate estimates can uniquely constrain the low-temperature thermal history of meteorite parent bodies. Using the main-group pallasit

Published

2020

50. Secondary magnetite in ancient zircon precludes analysis of a Hadean geodynamo

Author

Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Borlina, Cauê S., Weiss, Benjamin P., Lima, Eduardo A., Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Borlina, Cauê S., Weiss, Benjamin P., and Lima, Eduardo A.

Abstract

Zircon crystals from the Jack Hills, Western Australia, are one of the few surviving mineralogical records of Earth’s first 500 million years and have been proposed to contain a paleomagnetic record of the Hadean geodynamo. A prerequisite for the preservation of Hadean magnetization is the presence of primary magnetic inclusions within pristine igneous zircon. To date no images of the magnetic recorders within ancient zircon have been presented. Here we use high-resolution transmission electron microscopy to demonstrate that all observed inclusions are secondary features formed via two distinct mechanisms. Magnetite is produced via a pipe-diffusion mechanism whereby iron diffuses into radiation-damaged zircon along the cores of dislocations and is precipitated inside nanopores and also during low-temperature recrystallization of radiation-damaged zircon in the presence of an aqueous fluid. Although these magnetites can be recognized as secondary using transmission electron microscopy, they otherwise occur in regions that are indistinguishable from pristine igneous zircon and carry remanent magnetization that postdates the crystallization age by at least several hundred million years. Without microscopic evidence ruling out secondary magnetite, the paleomagnetic case for a Hadean–Eoarchean geodynamo cannot yet been made., Seventh Framework Programme (European Commission) (Grant FP/2007-2013), European Research Council (Grant 320750), Natural Environment Research Council (Great Britain) (Grant NE/P002498/1), National Science Foundation (U.S.) (Grant EAR1647504), National Science Foundation (U.S.). Division of Earth Sciences (Grant 1339051)

Published

2020