Caractérisation et suivi du système hydrogéologique multidimensionnel
Une liste de jeux de données pour le suivi et la caractérisation du système hydrogéologique multidimensionnel est donnée dans le tableau ci-dessous avec les liens vers les jeux de données correspondants.
Elle est publiée dans Hydrology and Earth System Sciences par Hermans et al (2023):
T. Hermans, P. Goderniaux, D. Jougnot, J. Fleckenstein, P. Brunner, F. Nguyen, N. Linde, J. A. Huisman, O. Bour, J. Lopez-Alvis, R. Hoffmann, A. Palacios, A-K. Cooke, Á.Pardo-Álvarez, L. Blazevic, B. Pouladi, P. Haruzi, M. Kenshilikova, P. Davy, and T. Le Borgne. Advancing measurements and representations of subsurface heterogeneity and dynamic processes: towards 4D hydrogeology. Hydrology and Earth System Sciences, 27, 255–287, 2023. [ DOI ]
Les données peuvent être téléchargées à partir des liens indiqués dans le tableau ci-dessous en créant un compte dans la base de données H+ à l’adresse https://hplus.ore.fr/en/database/acces-database.
Si vous souhaitez contribuer à ces jeux de données avec de nouvelles données pertinentes, pour toute question, merci de contacter :
- tanguy.le-borgne@univ-rennes1.fr
- camille.bouchez@univ-rennes1.fr
- meruyert.kenshilkova@univ-rennes1.fr
| Dimension | Jeu de données | Site | Lien vers le jeu de données | Publications |
|---|---|---|---|---|
| A. 3D + time | A.1 Time-lapse geophysical monitoring of heat transport: 2D time-lapse ERT cross-sections + 3D multiple nested wells data during heat tracer test | Hermalle, Belgium | https://hplus.ore.fr/en/hermalle/ | Hermans et al. (2015b, 2018) Hoffmann et al. (2019) |
| A.2 Time-lapse geophysical monitoring of hyporheic zone processes: 2D surface Electromagnetic Inuction + 2D time-lapse ERT (section) | Theis site, Ohio, USA | https://doi.org/10.4211/hs.69204f1ee49c4176a8aab5f4832c7b76 | McGarr et al. (2021) | |
| B. 2D + time | B.1 Time-lapse geophysical monitoring of water infiltration in the vadose zone: 2D time-lapse ERT and seismic cross-sections + TDR monitoring of water content during irrigation | Ploemeur, France | https://hplus.ore.fr/en/blazevic-et-al-2020-water-data | Blazevic et al. (2020) |
| B.2 GPR imaging of fracture opening during hydraulic test: Borehole and surface GPR+ optical televiewer + core logging during high pressure injection test | Aspö hard rock laboratory, Sweden | https://hplus.ore.fr/en/molron-et-al-2021-eg-data https://hplus.ore.fr/en/molron-et-al-2020-eg-data | Molron et al. (2020, 2021) | |
| B.3 GPR imaging of tracer transport in fractured media: Borehole GPR + conductivity and fluorescence monitoring during tracer test | Ploemeur, France | https://hplus.ore.fr/en/shakas-et-al-2017-grl-data | Shakas et al. (2016, 2017) | |
| B.4 Use of Vp/Vs ratio to monitor subsurface water content: 2D time-lapse seismic cross-sections P- and surface-wave survey, SH-wave refraction acquisition, travel-time tomography | Ploemeur, France | https://hplus.ore.fr/en/pasquet-et-al-2015-nsg-data | Pasquet et al. (2015) Dangeard et al. (2018) | |
| B.5 Time-lapse geophysical monitoring of water infiltration in karstic environment: 2D time-lapse ERT cross-sections during rainfall events | LSBB, France | https://hplus.ore.fr/en/carriere-et-al-2022-dib-data | Carrière et al. (2015, 2022) | |
| B.6 Time-lapse geophysical monitoring of seawater intrusion: 2D time-lapse cross-hole ERT in coastal aquifer | Argentona, Spain | https://hplus.ore.fr/en/palacios-et-al-2020-HESS-data | Palacios et al. (2020) | |
| C. 1D + time | C.1 Magnetic resonance sounding monitoring of water in a headwater catchments: Time-lapse magnetic resonance sounding | Strengbach, France | https://hplus.ore.fr/en/lesparre-et-al-2020-joh-data | Lesparre et al. (2020) |
| C.2 Fiber optic DTS monitoring for estimating thermal conductivity and groundwater flux in porous media: Fiber optic DTS and heat tracer experiments in a sand tank | Poitiers, France | https://hplus.ore.fr/en/simon-et-al-2020-wrr-data | Simon et al. (2020, 2022) | |
| C.3 Fiber-optic monitoring of heat transfer in fractured media: Fiber optic-DTS monitoring during thermal and solute tracer tests | Ploemeur, France | https://hplus.ore.fr/en/delabernardie-et-al-2018-wrr-data | De La Bernardie et al. (2018) | |
| C.4 Use of gravimeter time series for hydrological model calibration in a karst aquifer: Ten years gravimetry time series using iGrav superconducting gravimeter | Larzac, France | https://hplus.ore.fr/en/igrav-gravity-dataset | Fores et al. (2018, 2017) | |
| C.5 Time-lapse absolute quantum gravity measurements to monitor water storage in karstic environments: Gravimeter time series | Larzac, France | https://zenodo.org/record/4279110#.YicgCpbjJPZ | Cooke et al. (2021) | |
| C.6 Self-potential monitoring of natural rainfall and saline tracer infiltrations at the agricultural test site (HOBE network): Self-potential, time series | Voulund, Denmark | https://data.mendeley.com/datasets/6r8898657w/1 | Hu et al. (2020) | |
| C.7 Fiber-optic and borehole temperature monitoring of heat transfer in stream valleys: Fiber optic-DTS and borehole temperature monitoring of naturally occurring temperature fluctuations in groundwater upwelling areas in wetlands | Holtum stream lowlands, Denmark | https://hplus.ore.fr/en/evi-1/ https://water.columbia.edu/people/upmanu-lall | Tirado-Conde et al. (2019) | |
| D. High resolution imaging of heterogeneity combined with tracer tests | D.1 3D Seismic imaging of a karstic aquifer combined with multiple cross borehole tracer tests: 3D seismic bloc and tracer tests | Poitiers, France | https://hplus.ore.fr/en/mari-et-al-2009-ogst-data https://hplus.ore.fr/en/poitiers/ | Mari et al. (2009) |
| D.2 GPR Imaging of sand layered aquifer with multiple 2D profiles and tracer tests: Crosshole GPR and tracer tests | Krauthausen, Germany | https://teodoor.icg.kfa-juelich.de/geonetwork/srv/fre/login.form | Gueting et al. (2015, 2017) | |
| E. Multiple tracer experiments | E.1 Solute and heat tracer tests for characterizing heat transfer in fractured granite: Convergent and push-pull tests with injection of hot water, cold water and salt | Choutuppal, India | https://hplus.ore.fr/en/hoffmann-et-al-2021-groundwater-data | Hoffmann et al. (2021b) |
| E.2 Solute and dissolved gaz tracer tests for characterizing transport in Chalk: Convergent and push-pull tests with heat, helium, argon, xenon and uranine | Mons, Belgium | https://hplus.ore.fr/en/hoffmann-et-al-2020-hydrogeology-of-the-chalk-data https://hplus.ore.fr/en/hoffmann-et-al-2020-grl-data | Hoffmann et al. (2020, 2021a) | |
| E.3 Salt and dissolved oxygen tracer tests for characterizing transport and transit-times in a riparian zone: Time-series of EC, dissolved oxygen, and water temperature and stage | Selke River, Falkenstein, Germany | https://www.hydroshare.org/resource/51b3933c4987427e94e51e3339237755/ https://www.hydroshare.org/resource/476a188d9f894a77a3ed404949680cab/ | Nogueira et al. (2021a, 2021b) |