Accuracy and Resolution of SWOT Altimetry: Foundation Seamounts

Yu, Y.; Sandwell, D. T.; Dibarboure, G.; Chen, C.; Wang, J.

doi:10.1029/2024ea003581

Cited by 3 publications

References 23 publications

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Imaging Magma Reservoirs From Space With Altimetry‐Derived Gravity Data

Le Mével

2024

AGU Advances

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I investigate the detectability of magma reservoirs in the vertical gravity gradient (VGG) anomalies calculated from satellite altimetry data. First, I calculate a suite of synthetic seamount models to show the expected VGG anomaly characteristic wavelength and amplitude for a simplified magmatic system, hydrothermal system, and a caldera infill, varying their dimensions for a given depth and density contrast. I find that most magmatic and hydrothermal systems create VGG anomalies with a characteristic wavelength and amplitude greater than the data uncertainty and are therefore detectable. The proposed approach consists in three main steps: (a) calculate the VGG from the two components of the deflection of the vertical, (b) calculate and remove the gravity contribution of the bathymetry interface using an independent bathymetry data set (e.g., acquired by multibeam echosounders) to obtain a VGG Bouguer gravity anomaly, (c) invert the Bouguer VGG anomaly to obtain a 3D density model. I image a 6‐by‐8‐km low density body between 3 and 9 km depth under Brothers volcano in the Kermadec arc. I hypothesize that it represents the main magmatic system, possibly with a minor fraction of hydrothermal fluids at the shallower depths. There are about 225 submarine volcanoes globally that could be studied with satellite altimetry‐derived gravity data to potentially image their magmatic system. Future altimetry data will increase the gravity data resolution and allow us to image smaller features. This is thus an invaluable data set for the study of underexplored submarine volcanoes and can help improve our volcano hazards assessment.

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Imaging Magma Reservoirs From Space With Altimetry‐Derived Gravity Data

Le Mével

2024

AGU Advances

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Abyssal marine tectonics from the SWOT mission

Yu,

Sandwell,

Dibarboure

2024

Science

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The global ocean covers 71% of Earth’s surface, yet the seafloor is poorly charted compared with land, the Moon, Mars, and Venus. Traditional ocean mapping uses ship-based soundings and nadir satellite radar altimetry—one limited in spatial coverage and the other in spatial resolution. The joint NASA–CNES (Centre National d’Etudes Spatiales) Surface Water and Ocean Topography (SWOT) mission uses phase-coherent, wide-swath radar altimetry to measure ocean surface heights at high precision. We show that 1 year of SWOT data offers more detailed information than 30 years of satellite nadir altimetry in marine gravity, enabling the detection of intricate seafloor structures at 8-kilometer spatial resolution. With the mission still ongoing, SWOT promises critical insights for bathymetric charting, tectonic plate reconstruction, underwater navigation, and deep ocean mixing.

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The calculation and analysis of along-track and cross-track crossover SSHs discrepancies from wide-swath altimetry data

Zhu,

Li,

Guo

et al. 2024

Preprint

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The wide-swath sea surface height (SSH) data, obtained from the Surface Water and Ocean Topography (SWOT) project, hold great significance for studying global water distribution and improving the resolution of the ocean gravity field. Compared to traditional altimeter data, the wide-swath data provide more tracks per pass, which increases the time required for calculating crossover points. To address this, the limited area method for calculating along-track and cross-track crossover points between ascending and descending passes is proposed. Based on the varying sizes of the crossover zone at different latitudes, the crossover zone can be defined within a limited area. The crossover points are then calculated from the wide-swath data within this limited area. This method is compared with other approaches, showing that it can precisely identify crossover points in a manner consistent with the latitude difference method while requiring only about one-fourth of the time. Additionally, crossover discrepancies of SWOT-measured SSHs are analyzed. Results indicate that SSH accuracy from Level 2 products is lower at the swath edges compared to the middle. The Level 3 product achieves an accuracy of approximately 0.05 m. Overall, the limited area method efficiently determines exact crossover positions and significantly reduces time consumption, and the accuracy of SSHs from the Level 2 product at the edge of the swath is lower than that at the middle of the swath. The accuracy of SSHs from the Level 3 product is consistent with that from traditional altimeters.

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Accuracy and Resolution of SWOT Altimetry: Foundation Seamounts

Cited by 3 publications

References 23 publications

Imaging Magma Reservoirs From Space With Altimetry‐Derived Gravity Data

Imaging Magma Reservoirs From Space With Altimetry‐Derived Gravity Data

Abyssal marine tectonics from the SWOT mission

The calculation and analysis of along-track and cross-track crossover SSHs discrepancies from wide-swath altimetry data

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