Gradsouthwest’s Post

Early bird registration for the European Geosciences Union (EGU) General Assembly 2024 #EGU24 is available until 18 March, 13:00 CET: https://www.egu24.eu/ The IAS is co-sponsoring three Sessions: SSP1.3: Amalgamating chemistry, microbiology and sedimentology within a non-restrictive model. Atribute to Judith McKenzie’s career. ITS5.5/SSP1.14: Decoding the Geological Record: Accounting for the Incomplete and Distorted Record of Geological Events. SSP2.1: Carbonates-archives of time, space and change.

This link - https://lnkd.in/dkRfGJzM - will assist you speed up the process of attending the General Assembly 2025 of the European Geosciences Union (EGU). Furthermore, registration is now open for the first ever session on "Detection, analysis and forecasting of aeroallergens"

Non-invasive #imaging of soil-plant continuum processes, such as root and soil water distributions, can be used to optimize agricultural practices. This presentation from #SEG #NearSurface will show the how in-situ time-lapse horizontal crosshole ground penetrating radar (#GPR) and root images can be linked. Data collected for maize growing seasons in Germany is used, where root development and GPR permittivity were monitored at six depths across different treatments and soil types. With Lena Lärm of University of Bonn. Register: https://go.seg.org/3YhkfOm #GroundPenetratingRadar #Hydrogeophysics #Geophysics

We're thrilled to introduce our next endeavor: #NARCISSUS - Satellite-based Hydrogeological Risk Monitoring through #Spectroscopic Soil Moisture Measurement! 🌊 In collaboration with #IIT (Istituto Italiano di Tecnologia), NARCISSUS is a project co-financed by the Lazio Region for Industrial Competitive Repositioning. It aims to provide a more accurate #hydrogeologicalrisk monitoring tool than the current ones, using the latest satellite technology and spectroscopic soil moisture measurement techniques. 🚧 Areas abundant in water are more susceptible to hazards such as liquefaction and landslides. Therefore, precise knowledge of soil moisture is crucial for evaluating and preventing hydrogeological risks, a key focus area for NHAZCA. Through NARCISSUS, we're acquiring expertise in #hyperspectraldata acquisition, manipulation, fusion with other satellite data, and in-situ validation of soil moisture maps. This project combines elements of Industrial Research and Experimental Development, delving into technical-scientific themes with applications aimed at constructing a tool for soil moisture analysis, automatically updated with new information. Through the use of hyperspectral data and #ArtificialIntelligence we will develop a new and innovative monitoring system aimed at safeguarding our territory, community and resources. Stay tuned for updates on NARCISSUS as we continue to push the boundaries of innovation and geotechnical safety! #NARCISSUS #HydrogeologicalRisk #SatelliteMonitoring #NHAZCA #LandslideMonitoring #GeotechnicalMonitoring #EarthObservation

Non-invasive #imaging of soil-plant continuum processes, such as root and soil water distributions, can be used to optimize agricultural practices. This presentation from #SEG #NearSurface will show the how in-situ time-lapse horizontal crosshole ground penetrating radar (#GPR) and root images can be linked. Data collected for maize growing seasons in Germany is used, where root development and GPR permittivity were monitored at six depths across different treatments and soil types. With Lena Lärm of University of Bonn. 18 September 2024 | 10:00 AM (CDT) Register: https://go.seg.org/3YhkfOm #GroundPenetratingRadar #Hydrogeophysics #Geophysics

Risk Monitoring through Satellite images, that is what we do and what we develop, day after day.

18 Sept. at 10 a.m. U.S. Central time. Non-invasive #imaging of soil-plant continuum processes, such as root and soil water distributions, can be used to optimize agricultural practices. This presentation from #SEG #NearSurface will show the how in-situ time-lapse horizontal crosshole ground penetrating radar (#GPR) and root images can be linked. Data collected for maize growing seasons in Germany is used, where root development and GPR permittivity were monitored at six depths across different treatments and soil types. With Lena Lärm of University of Bonn. Register: https://go.seg.org/3YhkfOm #GroundPenetratingRadar #Hydrogeophysics #Geophysics

Non-invasive #imaging of soil-plant continuum processes, such as root and soil water distributions, can be used to optimize agricultural practices. This presentation from #SEG #NearSurface will show the how in-situ time-lapse horizontal crosshole ground penetrating radar (#GPR) and root images can be linked. Data collected for maize growing seasons in Germany is used, where root development and GPR permittivity were monitored at six depths across different treatments and soil types. With Lena Lärm of University of Bonn. Register: https://go.seg.org/3YhkfOm #GroundPenetratingRadar #Hydrogeophysics #Geophysics

Non-invasive #imaging of soil-plant continuum processes, such as root and soil water distributions, can be used to optimize agricultural practices. This presentation from #SEG #NearSurface will show the how in-situ time-lapse horizontal crosshole ground penetrating radar (#GPR) and root images can be linked. Data collected for maize growing seasons in Germany is used, where root development and GPR permittivity were monitored at six depths across different treatments and soil types. With Lena Lärm of University of Bonn. Register: https://go.seg.org/3YhkfOm #GroundPenetratingRadar #Hydrogeophysics #Geophysics

Non-invasive #imaging of soil-plant continuum processes, such as root and soil water distributions, can be used to optimize agricultural practices. This presentation from #SEG #NearSurface will show the how in-situ time-lapse horizontal crosshole ground penetrating radar (#GPR) and root images can be linked. Data collected for maize growing seasons in Germany is used, where root development and GPR permittivity were monitored at six depths across different treatments and soil types. With Lena Lärm of University of Bonn. Register: https://go.seg.org/3YhkfOm #GroundPenetratingRadar #Hydrogeophysics #Geophysics