In the field of hydrogeology, storage properties are physical properties that characterize the capacity of an aquifer to release groundwater. These properties are storativity (S), specific storage (Ss) and specific yield (Sy). According to Groundwater, by Freeze and Cherry (1979), specific storage, [m−1], of a saturated aquifer is defined as the volume of water that a unit volume of the aquifer releases from storage under a unit decline in hydraulic head.[1]

They are often determined using some combination of field tests (e.g., aquifer tests) and laboratory tests on aquifer material samples. Recently, these properties have been also determined using remote sensing data derived from Interferometric synthetic-aperture radar.[2][3]

Storativity

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Definition

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Storativity or the storage coefficient is the volume of water released from storage per unit decline in hydraulic head in the aquifer, per unit area of the aquifer. Storativity is a dimensionless quantity, and is always greater than 0.

 
  •   is the volume of water released from storage ([L3]);
  •   is the hydraulic head ([L])
  •   is the specific storage
  •   is the specific yield
  •   is the thickness of aquifer
  •   is the area ([L2])

Confined

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For a confined aquifer or aquitard, storativity is the vertically integrated specific storage value. Specific storage is the volume of water released from one unit volume of the aquifer under one unit decline in head. This is related to both the compressibility of the aquifer and the compressibility of the water itself. Assuming the aquifer or aquitard is homogeneous:

 

Unconfined

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For an unconfined aquifer, storativity is approximately equal to the specific yield ( ) since the release from specific storage ( ) is typically orders of magnitude less ( ).

 

The specific storage is the amount of water that a portion of an aquifer releases from storage, per unit mass or volume of the aquifer, per unit change in hydraulic head, while remaining fully saturated.

Mass specific storage is the mass of water that an aquifer releases from storage, per mass of aquifer, per unit decline in hydraulic head:

 

where

  is the mass specific storage ([L−1]);
  is the mass of that portion of the aquifer from which the water is released ([M]);
  is the mass of water released from storage ([M]); and
  is the decline in hydraulic head ([L]).

Volumetric specific storage (or volume-specific storage) is the volume of water that an aquifer releases from storage, per volume of the aquifer, per unit decline in hydraulic head (Freeze and Cherry, 1979):

 

where

  is the volumetric specific storage ([L−1]);
  is the bulk volume of that portion of the aquifer from which the water is released ([L3]);
  is the volume of water released from storage ([L3]);
  is the decline in pressure(N•m−2 or [ML−1T−2]) ;
  is the decline in hydraulic head ([L]) and
  is the specific weight of water (N•m−3 or [ML−2T−2]).

In hydrogeology, volumetric specific storage is much more commonly encountered than mass specific storage. Consequently, the term specific storage generally refers to volumetric specific storage.

In terms of measurable physical properties, specific storage can be expressed as

 

where

  is the specific weight of water (N•m−3 or [ML−2T−2])
  is the porosity of the material (dimensionless ratio between 0 and 1)
  is the compressibility of the bulk aquifer material (m2N−1 or [LM−1T2]), and
  is the compressibility of water (m2N−1 or [LM−1T2])

The compressibility terms relate a given change in stress to a change in volume (a strain). These two terms can be defined as:

 
 

where

  is the effective stress (N/m2 or [MLT−2/L2])

These equations relate a change in total or water volume (  or  ) per change in applied stress (effective stress —   or pore pressure —  ) per unit volume. The compressibilities (and therefore also Ss) can be estimated from laboratory consolidation tests (in an apparatus called a consolidometer), using the consolidation theory of soil mechanics (developed by Karl Terzaghi).

Determination of the storage coefficient of aquifer systems

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Aquifer-test analysis

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Aquifer-test analyses provide estimates of aquifer-system storage coefficients by examining the drawdown and recovery responses of water levels in wells to applied stresses, typically induced by pumping from nearby wells.[4]

Stress-strain analysis

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Elastic and inelastic skeletal storage coefficients can be estimated through a graphical method developed by Riley.[5] This method involves plotting the applied stress (hydraulic head) on the y-axis against vertical strain or displacement (compaction) on the x-axis. The inverse slopes of the dominant linear trends in these compaction-head trajectories indicate the skeletal storage coefficients. The displacements used to build the stress-strain curve can be determined by extensometers,[5][6] InSAR[7] or levelling.[8]

Laboratory consolidation tests

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Laboratory consolidation tests yield measurements of the coefficient of consolidation within the inelastic range and provide estimates of vertical hydraulic conductivity.[9] The inelastic skeletal specific storage of the sample can be determined by calculating the ratio of vertical hydraulic conductivity to the coefficient of consolidation.

Model simulations and calibration

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Simulations of land subsidence incorporate data on aquifer-system storage and hydraulic conductivity. Calibrating these models can lead to optimized estimates of storage coefficients and vertical hydraulic conductivity.[8][10]

Specific yield

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Values of specific yield[11]
Material Specific Yield (%)
min avg max
Unconsolidated deposits
Clay 0 2 5
Sandy clay (mud) 3 7 12
Silt 3 8 19
Fine sand 10 21 28
Medium sand 15 26 32
Coarse sand 20 27 35
Gravelly sand 20 25 35
Fine gravel 21 25 35
Medium gravel 13 23 26
Coarse gravel 12 22 26
Consolidated deposits
Fine-grained sandstone   21  
Medium-grained sandstone   27  
Limestone   14  
Schist   26  
Siltstone   12  
Tuff   21  
Other deposits
Dune sand   38  
Loess   18  
Peat   44  
Till, predominantly silt   6  
Till, predominantly sand   16  
Till, predominantly gravel   16  

Specific yield, also known as the drainable porosity, is a ratio, less than or equal to the effective porosity, indicating the volumetric fraction of the bulk aquifer volume that a given aquifer will yield when all the water is allowed to drain out of it under the forces of gravity:

 

where

  is the volume of water drained, and
  is the total rock or material volume

It is primarily used for unconfined aquifers, since the elastic storage component,  , is relatively small and usually has an insignificant contribution. Specific yield can be close to effective porosity, but there are several subtle things which make this value more complicated than it seems. Some water always remains in the formation, even after drainage; it clings to the grains of sand and clay in the formation. Also, the value of specific yield may not be fully realized for a very long time, due to complications caused by unsaturated flow. Problems related to unsaturated flow are simulated using the numerical solution of Richards Equation, which requires estimation of the specific yield, or the numerical solution of the Soil Moisture Velocity Equation, which does not require estimation of the specific yield.

See also

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References

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  • Freeze, R.A. and J.A. Cherry. 1979. Groundwater. Prentice-Hall, Inc. Englewood Cliffs, NJ. 604 p.
  • Morris, D.A. and A.I. Johnson. 1967. Summary of hydrologic and physical properties of rock and soil materials as analyzed by the Hydrologic Laboratory of the U.S. Geological Survey 1948-1960. U.S. Geological Survey Water Supply Paper 1839-D. 42 p.
  • De Wiest, R. J. (1966). On the storage coefficient and the equations of groundwater flow. Journal of Geophysical Research, 71(4), 1117–1122.
Specific
  1. ^ https://www.un-igrac.org/sites/default/files/resources/files/Groundwater%20book%20-%20English.pdf [bare URL PDF]
  2. ^ Béjar-Pizarro, Marta; Ezquerro, Pablo; Herrera, Gerardo; Tomás, Roberto; Guardiola-Albert, Carolina; Ruiz Hernández, José M.; Fernández Merodo, José A.; Marchamalo, Miguel; Martínez, Rubén (2017-04-01). "Mapping groundwater level and aquifer storage variations from InSAR measurements in the Madrid aquifer, Central Spain". Journal of Hydrology. 547 (Supplement C): 678–689. Bibcode:2017JHyd..547..678B. doi:10.1016/j.jhydrol.2017.02.011. hdl:10045/63773.
  3. ^ Tomás, R.; Herrera, G.; Delgado, J.; Lopez-Sanchez, J. M.; Mallorquí, J. J.; Mulas, J. (2010-02-26). "A ground subsidence study based on DInSAR data: Calibration of soil parameters and subsidence prediction in Murcia City (Spain)". Engineering Geology. 111 (1): 19–30. Bibcode:2010EngGe.111...19T. doi:10.1016/j.enggeo.2009.11.004.
  4. ^ Chow, Ven Ten (June 1952). "On the determination of transmissibility and storage coefficients from pumping test data". Eos, Transactions American Geophysical Union. 33 (3): 397–404. Bibcode:1952TrAGU..33..397C. doi:10.1029/tr033i003p00397. hdl:2142/94351. ISSN 0002-8606.
  5. ^ a b Riley, F. S. (1969). Analysis of borehole extensometer data from central California. International Association of Scientific Hydrology. Publication 89, 423–431.
  6. ^ Cleveland, Theodore G.; Bravo, Rolando; Rogers, Jerry R. (September 1992). "Storage Coefficients and Vertical Hydraulic Conductivities in Aquitards Using Extensometer and Hydrograph Data". Groundwater. 30 (5): 701–708. Bibcode:1992GrWat..30..701C. doi:10.1111/j.1745-6584.1992.tb01556.x. ISSN 0017-467X.
  7. ^ Tomás, R.; Herrera, G.; Delgado, J.; Lopez-Sanchez, J. M.; Mallorquí, J. J.; Mulas, J. (2010-02-26). "A ground subsidence study based on DInSAR data: Calibration of soil parameters and subsidence prediction in Murcia City (Spain)". Engineering Geology. 111 (1): 19–30. Bibcode:2010EngGe.111...19T. doi:10.1016/j.enggeo.2009.11.004. ISSN 0013-7952.
  8. ^ a b Hoffmann, Jörn; Galloway, Devin L.; Zebker, Howard A. (February 2003). "Inverse modeling of interbed storage parameters using land subsidence observations, Antelope Valley, California". Water Resources Research. 39 (2): 1031. Bibcode:2003WRR....39.1031H. doi:10.1029/2001WR001252. ISSN 0043-1397.
  9. ^ Relationships between basic soils-engineering equations and basic ground-water flow equations (Report). US Geological Survey. 1980. doi:10.3133/wsp2064.
  10. ^ Burbey, Thomas J. (2020-03-01). "Extensometer forensics: what can the data really tell us?". Hydrogeology Journal. 28 (2): 637–655. doi:10.1007/s10040-019-02060-6. ISSN 1435-0157.
  11. ^ Johnson, A. I. (1967), Specific yield: compilation of specific yields for various materials, Water Supply Paper 1662-D, Washington, D.C.: U.S. Government Printing Office, p. 74, doi:10.3133/wsp1662D