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7.3: Measurement of Salinity

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    Electrical conductivity (EC) is used frequently to estimate the salt concentration of solutions. This method is based upon the fact that salts dissociate into charged ions in water and can conduct an electric current. As the concentration of salts increases, the capacity of the solution to conduct an electrical current, called electrical conductivity, increases. Electrical conductivity is expressed in units of Siemens per meter (S/m). For most natural systems, the EC unit of dS/m (10-1 S/m) is convenient and is equal numerically to millimhos/cm, an outmoded unit. The approximate relationship between osmotic potential (Ψo, bars) and electrical conductivity (EC, dS/m) is:

    Ψo = 0.36 EC

    The relationship between salt concentration (C) in units of mg/L and EC is approximated by:

    C = 640 EC

    It is important to remember that electrical conductivity is sensitive to the temperature of the solution. Between the temperatures of 15° and 35°C, a one degree increase in temperature increases EC by about 2%. A solution at 35°C that measures an EC of 5 dS/m will have an EC of 4 dS/m if the temperature of the solution is decreased to 25°C. For consistency, ECs are normally reported at a temperature of 25°C.

    Ideally, soil salinity should be measured at the soil water content found in the field. This is not easily done although several methods are now available that operate at field water contents. The most common method of determining soil salinity is by extracting a solution from a soil sample that has been saturated. The procedure begins by taking a soil sample in the field. The sample is brought to saturation in a laboratory by adding distilled water and then a sample of the saturated soil solution is extracted by vacuum filtration. The electrical conductivity of this saturated extract (ECe) is then measured.

    7.3: Measurement of Salinity is shared under a CC BY-NC-ND 4.0 license and was authored, remixed, and/or curated by LibreTexts.