Airborne Sounding Radar for Desert Subsurface Exploration of Aquifers: Desert-SEA: Mission concept study [Space Agencies]
Author | Heggy, Essam |
Author | Moghaddam, Mahta |
Author | Palmer, Elizabeth M. |
Author | Brown, William M. |
Author | Blanton, J. Lee |
Author | Kosinski, Mikołaj |
Author | Sirri, Paul |
Author | Dixon, Edgar A. |
Author | Abotalib, Abotalib Z. |
Author | Normand, Jonathan C. L. |
Author | Clark, John |
Author | Klemens, Gary |
Author | Agranier, Matthieu |
Author | Guillon, François |
Author | Abdellatif, Akram A. |
Author | Khattab, Tamer |
Author | Tsvetanov, Zlatan |
Author | Shokry, Mohamed |
Author | Al-Mulla, Noor |
Author | Ramah, Mohamed |
Author | Bateni, Sayed M. |
Author | Tabatabaeenejad, Alireza |
Author | Avouac, Jean-Philippe |
Available date | 2024-08-19T05:21:31Z |
Publication Date | 2024 |
Publication Name | IEEE Geoscience and Remote Sensing Magazine |
Resource | Scopus |
ISSN | 24732397 |
Abstract | Shallow aquifers are the largest freshwater bodies in the North African Sahara and the Arabian Peninsula. Their groundwater dynamics and response to climatic variability and anthropogenic discharge remain largely unquantified due to the absence of large-scale monitoring methods. Currently, the assessment of groundwater dynamics in these aquifer systems is made primarily from sporadic well logs that barely cover a few percent of the geographical extent of these water bodies. To address this deficiency, we develop the use of an ultra-wideband (UWB) very high frequency (VHF) interferometric airborne sounding radar, under a collaboration between NASA and the Qatar Foundation, to characterize the depth and geometry of the shallowest water table in large hyperarid hydrological basins in North Africa and the Arabian Peninsula. Herein, we describe the science objectives, measurement requirements, instrument design, expected performance, flight implementation scenarios, primary targets for investigation, and the first technology demonstration of the concept. Our performance analyses suggest that an airborne, nadir-looking sounding radar system operating at a 70-MHz center frequency with a linearly polarized folded-dipole antenna array - enabling a bandwidth (BW) of 50 MHz - and a surface signal-to-noise ratio (SNR) of 85 dB flying at an altitude of 500-2,000 m can map the uppermost water table depths of aquifer systems spanning tens of kilometers at a vertical resolution of 3 m in desiccated terrains to an average penetration depth of 50 m, with a spatial resolution of 200 m. For the first time, this airborne concept will allow time-coherent high-resolution mapping of the uppermost water tables of major aquifer systems in hyperarid areas, providing unique insights into their dynamics and responses to increasing climatic and anthropogenic stressors, which remain largely uncharacterized. The aforementioned significantly surpasses the existing capabilities for mapping shallow aquifers in these harsh and remote environments, which relies today on data collected on different timescales from sparse well logs that do not cover their geographic extents. A list of key abbreviations for this article can be found in 'The Key Abbreviations Used in This Article. |
Sponsor | The authors are very grateful to John Wilson of the United States Agency for International Development (USAID), and Paul Rosen, Anthony Freeman, Ken Wolfenbarger, Ziad Haddad, and Charles Elachi of the Jet Propulsion Laboratory and California Institute of Technology (Caltech) for their support, which initiated this work. The authors are also grateful to Nabil Alhusseini of the Bin Omran Trading & Telecommunications Company for his generous donation to the University of Southern California (USC) Arid Climates and Water Research (AWARE) Center, which enabled a large part of this research development. This work was supported in part by the USAID under the Further Advancing the Blue Revolution Initiative (FABRI) under Grant 1001624-13S-19790 attributed to Caltech and USC for PI Essam Heggy; in part by the Keck Space Institute at Caltech for PI Jean-Philippe Avouac and PI Essam Heggy; in part by the Zumberge Research and Innovation Fund of USC allocated to the AWARE Center; and in part by a research agreement between USC and the Qatar Environment and Energy Research Institute at Hamad Bin Khalifa University in Qatar. The work of Tamer Khattab was funded by QRDI- QNRF grant no. AICC03-0530-200033. The work of Elizabeth M. Palmer and of Sayed M. Bateni was supported by the U.S. Department of State Bureau of Educational and Cultural Affairs under Fulbright U.S. Scholar Awards 11563-QA and 10563-QA, respectively. |
Language | en |
Publisher | IEEE |
Subject | Antenna arrays Dipole antennas Dynamics Groundwater resources Hydrogeology NASA Probes Signal to noise ratio Ultra-wideband (UWB) Aquifer systems Concept studies Freshwater bodies Groundwater dynamics Mission concepts Shallow aquifers Sounding radar Space agency Subsurface exploration Well logs Aquifers airborne sensing airborne sensor anthropogenic effect aquifer desert synthetic aperture radar water table Arabian Peninsula North Africa |
Type | Article |
Pagination | 162-185 |
Issue Number | 1 |
Volume Number | 12 |
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