Your search keyword '"Goossens, Sander J"' showing total 11 results

1. Exploring the Uranian system with the Uranus Orbiter & Probe Radio Science experiment: expected performance and possible enhancements

Author

Filice, Valerio, primary, Maistre, Sébastien Le, additional, Baland, Rose-Marie, additional, Cascioli, Gael, additional, Mazarico, Erwan, additional, and Goossens, Sander J, additional

Published

2024

2. Gravity Field of the Moon from the Gravity Recovery and Interior Laboratory (GRAIL) Mission

Author

Zuber, Maria T., Smith, David E., Watkins, Michael M., Asmar, Sami W., Konopliv, Alexander S., Lemoine, Frank G., Melosh, H. Jay, Neumann, Gregory A., Phillips, Roger J., Solomon, Sean C., Wieczorek, Mark A., Williams, James G., Goossens, Sander J., Kruizinga, Gerhard, Mazarico, Erwan, Park, Ryan S., and Yuan, Dah-Ning

Published

2013

3. Evidence for a Low Bulk Crustal Density for Mars from Gravity and Topography

Author

Goossens, Sander J, Sabaka, Terence J, Genova, Antonio, Mazarico, Erwan M, and Nicholas, Joseph B

Subjects

Lunar And Planetary Science And Exploration

Abstract

Knowledge of the average density of the crust of a planet is important in determining its interior structure. The combination of high-resolution gravity and topography data has yielded a low density for the Moon’s crust, yet for other terrestrial planets the resolution of the gravity field models has hampered reasonable estimates. By using well-chosen constraints derived from topography during gravity field model determination using satellite tracking data, we show that we can robustly and independently determine the average bulk crustal density directly from the tracking data, using the admittance between topography and imperfect gravity. We find a low average bulk crustal density for Mars, 2582 ± 209 kgm−3. This bulk crustal density is lower than that assumed until now. Densities for volcanic complexes are higher, consistent with earlier estimates, implying large lateral variations in crustal density. In addition, we find indications that the crustal density increases with depth.

Published

2017

4. High-degree Gravity Models from GRAIL Primary Mission Data

Author

Lemoine, Frank G, Goossens, Sander J, Sabaka, Terence J, Nicholas, Joseph B, Mazarico, Erwan, Rowlands, David D, Loomis, Bryant D, Chinn, Douglas S, Caprette, Douglas S, Neumann, Gregory A, Smith, David E, and Zuber, Maria T

Subjects

Astrophysics, Lunar And Planetary Science And Exploration

Abstract

We have analyzed Ka‒band range rate (KBRR) and Deep Space Network (DSN) data from the Gravity Recovery and Interior Laboratory (GRAIL) primary mission (1 March to 29 May 2012) to derive gravity models of the Moon to degree 420, 540, and 660 in spherical harmonics. For these models, GRGM420A, GRGM540A, and GRGM660PRIM, a Kaula constraint was applied only beyond degree 330. Variance‒component estimation (VCE) was used to adjust the a priori weights and obtain a calibrated error covariance. The global root‒mean‒square error in the gravity anomalies computed from the error covariance to 320×320 is 0.77 mGal, compared to 29.0 mGal with the pre‒GRAIL model derived with the SELENE mission data, SGM150J, only to 140×140. The global correlations with the Lunar Orbiter Laser Altimeter‒derived topography are larger than 0.985 between l = 120 and 330. The free‒air gravity anomalies, especially over the lunar farside, display a dramatic increase in detail compared to the pre‒GRAIL models (SGM150J and LP150Q) and, through degree 320, are free of the orbit‒track‒related artifacts present in the earlier models. For GRAIL, we obtain an a posteriori fit to the S‒band DSN data of 0.13 mm/s. The a posteriori fits to the KBRR data range from 0.08 to 1.5 micrometers/s for GRGM420A and from 0.03 to 0.06 micrometers/s for GRGM660PRIM. Using the GRAIL data, we obtain solutions for the degree 2 Love numbers, k20=0.024615+/-0.0000914, k21=0.023915+/-0.0000132, and k22=0.024852+/-0.0000167, and a preliminary solution for the k30 Love number of k30=0.00734+/-0.0015, where the Love number error sigmas are those obtained with VCE.

Published

2013

5. Properties of the Lunar Interior: Preliminary Results from the GRAIL Mission

Author

Williams, James G, Konopliv, Alexander S, Asmar, Sami W, Lemoine, Frank G, Melosh, H. Jay, Neumann, Gregory A, Phillips, Roger J, Smith, David E, Solomon, Sean C, Watkins, Michael M, Wieczorek, Mark A, Zuber, Maria T, Andrews-Hanna, Jeffrey C, Head, James W, Kiefer, Walter S, McGovern, Patrick J, Nimmo, Francis, Taylor, G. Jeffrey, Weber, Renee C, Boggs, D. H, Goossens, Sander J, Kruizinga, Gerhard L, Mazarico, Erwan, Park, Ryan S, and Yuan, Dah-Ning

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Gravity Recovery and Interior Laboratory (GRAIL) mission [1] has provided lunar gravity with unprecedented accuracy and resolution. GRAIL has produced a high-resolution map of the lunar gravity field [2,3] while also determining tidal response. We present the latest gravity field solution and its preliminary implications for the Moon's interior structure, exploring properties such as the mean density, moment of inertia of the solid Moon, and tidal potential Love number k(sub 2). Lunar structure includes a thin crust, a thick mantle layer, a fluid outer core, and a suspected solid inner core. An accurate Love number mainly improves knowledge of the fluid core and deep mantle. In the future, we will search for evidence of tidal dissipation and a solid inner core using GRAIL data.

Published

2013

6. Gravity Recovery and Interior Laboratory (GRAIL): Extended Mission and End-Game Status

Author

Zuber, Maria T, Smith, David E, Wieczorek, Mark A, Williams, James G, Andrews-Hanna, Jeffrey C, Head, James W, Kiefer, Walter S, Matsuyama, Isamu, McGovern, Patrick J, Nimmo, Francis, Stubbs, Christopher, Weber, Renee, Asmar, Sami W, Goossens, Sander J, Kruizinga, Gerhard, Mazarico, Erwan, Park, Ryan S, Yuan, Dah-Ning, Konopliv, Alexander S, Lemoine, Frank G, Melosh, H. Jay, Neumann, Gregory A, Phillips, Roger J, Solomon, Sean C, and Watkins, Michael M

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Gravity Recovery and Interior Laboratory (GRAIL) [1], NASA s eleventh Discovery mission, successfully executed its Primary Mission (PM) in lunar orbit between March 1, 2012 and May 29, 2012. GRAIL s Extended Mission (XM) initiated on August 30, 2012 and was successfully completed on December 14, 2012. The XM provided an additional three months of gravity mapping at half the altitude (23 km) of the PM (55 km), and is providing higherresolution gravity models that are being used to map the upper crust of the Moon in unprecedented detail.

Published

2013

7. Preliminary Results on Lunar Interior Properties from the GRAIL Mission

Author

Williams, James G, Konopliv, Alexander S, Asmar, Sami W, Lemoine, H. Jay, Melosh, H. Jay, Neumann, Gregory A, Phillips, Roger J, Smith, David E, Solomon, Sean C, Watkins, Michael M, Wieczorek, Mark A, Zuber, Maria T, Andrews-Hanna, Jeffrey C, Head, James W, Kiefer, Walter S, Matsuyama, Isamu, McGovern, Patrick J, Nimmo, Francis, Weber, Renee C, Boggs, D. H, Goossens, Sander J, Kruizinga, Gerhard L, Mazarico, Erwan, Park, Ryan S, and Yuan, Dah-Ning

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Gravity Recovery and Interior Laboratory (GRAIL) mission has provided lunar gravity with unprecedented accuracy and resolution. GRAIL has produced a high-resolution map of the lunar gravity field while also determining tidal response. We present the latest gravity field solution and its preliminary implications for the Moon's interior structure, exploring properties such as the mean density, moment of inertia of the solid Moon, and tidal potential Love number k2. Lunar structure includes a thin crust, a deep mantle, a fluid core, and a suspected solid inner core. An accurate Love number mainly improves knowledge of the fluid core and deep mantle. In the future GRAIL will search for evidence of tidal dissipation and a solid inner core.

Published

2013

8. Deriving the ancient lunar pole path from impact induced gravity anomalies

Author

Smith, David E, primary, Zuber, Maria T, additional, Goossens, Sander J, additional, Neumann, Gregory A, additional, and Mazarico, Erwan, additional

Published

2020

9. Lunar impact basins revealed by Gravity Recovery and Interior Laboratory measurements

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Zuber, Maria, Smith, David Edmund, Sori, Michael M., Soderblom, Jason, Miljkovic, Katarina, Neumann, Gregory A., Wieczorek, Mark A., Head, James W., Baker, David M. H., Solomon, Sean C., Lemoine, Frank G., Mazarico, Erwan Matias, Sabaka, Terence J., Goossens, Sander J., Melosh, H. Jay, Phillips, Roger J., Asmar, Sami W., Konopliv, Alexander S., Williams, James G., Andrews-Hanna, Jeffrey C., Nimmo, Francis, Kiefer, Walter S., Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Zuber, Maria, Smith, David Edmund, Sori, Michael M., Soderblom, Jason, Miljkovic, Katarina, Neumann, Gregory A., Wieczorek, Mark A., Head, James W., Baker, David M. H., Solomon, Sean C., Lemoine, Frank G., Mazarico, Erwan Matias, Sabaka, Terence J., Goossens, Sander J., Melosh, H. Jay, Phillips, Roger J., Asmar, Sami W., Konopliv, Alexander S., Williams, James G., Andrews-Hanna, Jeffrey C., Nimmo, Francis, and Kiefer, Walter S.

Abstract

Observations from the Gravity Recovery and Interior Laboratory (GRAIL) mission indicate a marked change in the gravitational signature of lunar impact structures at the morphological transition, with increasing diameter, from complex craters to peak-ring basins. At crater diameters larger than ~200 km, a central positive Bouguer anomaly is seen within the innermost peak ring, and an annular negative Bouguer anomaly extends outward from this ring to the outer topographic rim crest. These observations demonstrate that basin-forming impacts remove crustal materials from within the peak ring and thicken the crust between the peak ring and the outer rim crest. A correlation between the diameter of the central Bouguer gravity high and the outer topographic ring diameter for well-preserved basins enables the identification and characterization of basins for which topographic signatures have been obscured by superposed cratering and volcanism. The GRAIL inventory of lunar basins improves upon earlier lists that differed in their totals by more than a factor of 2. The size-frequency distributions of basins on the nearside and farside hemispheres of the Moon differ substantially; the nearside hosts more basins larger than 350 km in diameter, whereas the farside has more smaller basins. Hemispherical differences in target properties, including temperature and porosity, are likely to have contributed to these different distributions. Better understanding of the factors that control basin size will help to constrain models of the original impactor population.

Published

2015

10. Lunar impact basins revealed by Gravity Recovery and Interior Laboratory measurements

Author

Neumann, Gregory A., primary, Zuber, Maria T., additional, Wieczorek, Mark A., additional, Head, James W., additional, Baker, David M. H., additional, Solomon, Sean C., additional, Smith, David E., additional, Lemoine, Frank G., additional, Mazarico, Erwan, additional, Sabaka, Terence J., additional, Goossens, Sander J., additional, Melosh, H. Jay, additional, Phillips, Roger J., additional, Asmar, Sami W., additional, Konopliv, Alexander S., additional, Williams, James G., additional, Sori, Michael M., additional, Soderblom, Jason M., additional, Miljković, Katarina, additional, Andrews-Hanna, Jeffrey C., additional, Nimmo, Francis, additional, and Kiefer, Walter S., additional

Published

2015

11. Lunar impact basins revealed by Gravity Recovery and Interior Laboratory measurements

Author

Neumann, Gregory A., Zuber, Maria T., Wieczorek, Mark A., Head, James W., Baker, David M. H., Solomon, Sean C., Smith, David E., Lemoine, Frank G., Mazarico, Erwan, Sabaka, Terence J., Goossens, Sander J., Melosh, H. Jay, Phillips, Roger J., Asmar, Sami W., Konopliv, Alexander S., Williams, James G., Sori, Michael M., Soderblom, Jason M., Miljković, Katarina, Andrews-Hanna, Jeffrey C., Nimmo, Francis, and Kiefer, Walter S.

Subjects

Geophysics, 13. Climate action, Gravity anomalies, Lunar basins, Lunar craters, FOS: Earth and related environmental sciences, Planetology

Abstract

Observations from the Gravity Recovery and Interior Laboratory (GRAIL) mission indicate a marked change in the gravitational signature of lunar impact structures at the morphological transition, with increasing diameter, from complex craters to peak-ring basins. At crater diameters larger than ~200 km, a central positive Bouguer anomaly is seen within the innermost peak ring, and an annular negative Bouguer anomaly extends outward from this ring to the outer topographic rim crest. These observations demonstrate that basin-forming impacts remove crustal materials from within the peak ring and thicken the crust between the peak ring and the outer rim crest. A correlation between the diameter of the central Bouguer gravity high and the outer topographic ring diameter for well-preserved basins enables the identification and characterization of basins for which topographic signatures have been obscured by superposed cratering and volcanism. The GRAIL inventory of lunar basins improves upon earlier lists that differed in their totals by more than a factor of 2. The size-frequency distributions of basins on the nearside and farside hemispheres of the Moon differ substantially; the nearside hosts more basins larger than 350 km in diameter, whereas the farside has more smaller basins. Hemispherical differences in target properties, including temperature and porosity, are likely to have contributed to these different distributions. Better understanding of the factors that control basin size will help to constrain models of the original impactor population.