Offshore freshened groundwater

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Fig. 1 Global map of water stress and distribution of OFG system, thickness and minimum salinity values. Square symbols represent area where OFG thickness is unknown

Offshore freshened groundwater (OFG) is water that contains a Total Dissolved Solid (TDS) concentration lower than sea water, and which is hosted in porous sediments and rocks located in the sub-seafloor. OFG systems have been documented all over around the world and have an estimated global volume of around 1 × 106 km3.[1] Their study is important because they may represent an unconventional source of potable water for human populations living near the coast, especially in areas where groundwater resources are scarce or facing stress[2]

Elements and processes

OFG usually presents salinity values < 33 Practical Salinity Units (PSU). They are located at water depth < 100 m and within 55 km of the coast in both siliciclastic and carbonatic aquifers along active and passive margins. OFG systems are usually composed by multiple OFG bodies which are altogether < 2 km thick (Fig.1)

The principal emplacement mechanisms for OFG systems are (from the most common to the least common):

  • Meteoric recharge by rainfall which can be either a paleo-meteoric event during sea level low stands or an active-meteoric recharge via permeable connections between offshore and onshore aquifers (Fig. 2).[1][3][4][5][6][7]
  • Diagenesis due to post‐sedimentary alteration processes leading the release of freshwater and accumulation in deeply buried marine sediments in high Pressure and Temperature conditions .[8][9][10]
  • Sub‐glacial and pro‐glacial injection such as sub-glacial melting, sub-glacial drainage systems, reversal of groundwater flow direction with respect to modern flow patterns.[11][12][13][14]
  • Decomposition of gas hydrates as a result of changing in temperatures or pressures which lead to the release of low salinity pore water.[15][16][17][18]

The geological settings have a major control on OFG development: the majority are hosted in coarser siliciclastic materials, with porosity values around 30% to 60%, constraint by a permeability contrast (predominantly sand to clay).[19] Topographic gradients have a major impact on OFG emplacement[1] as topography-driven flow is one of the most important mechanisms controlling discharge of freshwater offshore.

Fig. 2 Schematic figure showing how freshened groundwater was deposited offshore when the seafloor was exposed at lower sea-levels. Credit: MARCAN project

Investigation

Different methods can be used to characterize and assess OFG occurrences:

Applications and potential of OFG

OFG systems are receiving increasing attention as they may be used as an unconventional source of

potable water in coastal areas, where groundwater resources are being rapidly depleted or contaminated.[2] 60% of the global population lives in areas of water stress[26] defined as the ratio of total water withdrawals to available renewable surface and groundwater supplies (Fig.1). Climate change, rapid population growth, and urbanization have a negative impact on water stress especially in coastal communities.[27] Therefore, OFG has been proposed as an alternative source of freshwater to mitigate water scarcity and groundwater depletion in areas of water stress[26]

Fig. 3 CSEM systems in different configurations which can be used to map OFG

References

  1. ^
    S2CID 228825409
    .
  2. ^
    S2CID 155062553
    .
  3. ISSN 0016-7606
    .
  4. ISSN 0022-1694
    .
  5. S2CID 131954295
    .
  6. ISSN 0309-1708
    .
  7. S2CID 5799094
    .
  8. ISSN 2296-6463
    .
  9. ISSN 0091-7613
    .
  10. doi:10.1029/94JB01187
    .
  11. S2CID 55470663
    .
  12. doi:10.1029/2003EO190001
    .
  13. ISSN 0148-0227
    .
  14. ISSN 0025-3227
    .
  15. ISSN 0012-8252
    .
  16. ISSN 0304-4203
    .
  17. doi:10.1029/2008JB005702
    .
  18. ISSN 0025-3227
    .
  19. doi:10.5281/zenodo.4247833
    , retrieved 2022-10-10
  20. ISSN 2076-3263
    .
  21. PMID 32170097
    .
  22. S2CID 198417528
    .
  23. ISSN 2296-6463
    .
  24. S2CID 129754540
    .
  25. S2CID 55300744
    .
  26. ^ a b Damania et al., (2017). Uncharted waters: The new economics of water scarcity and variability. Washington, D.C.: World Bank. https://openknowledge.worldbank.org/bitstream/handle/10986/28096/211179v2.pdf?sequence
  27. ^ Hofste, R. W., Kuzma, S., Walker, S., Sutanudjaja, E. H., Bierkens, M. F., Kuijper, M. J., ... & Reig, P. (2019). Aqueduct 3.0: Updated decision-relevant global water risk indicators. World Resources Institute, 1-53.
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