404 Organic waste reuse and recycling: technology and management
Table 8.6 Relationship of potential problems to concentration of major inorganic
constituents in irrigation waters for arid and semi-arid climates (Ayers and Westcot
1976)
Problem and related constituent No problem Increasing
problem
Severe
problem
Salinitya
EC of irrigation water, mmhos/cm
Permeability
EC of irrigation water, mhos/cm
SAR (sodium adsorption ratio)b
Specific ion toxicityc
From root absorption
Sodium (evaluated by SAR)
Chloride, meq/L
Chloride, mg/L
Boron, mg/L
From foliar absorption
(sprinklers)d
Sodium, meq/L
Sodium, mg/L
Chloride, meq/L
Chloride, mg/L
Miscellaneouse
HCO 3 - , meq/L
HCO 3 - , mg/L
<0.75>0.5
<6.0<3
<4
<142
<0.5<3.0
<69
<3.0
<106<1.5
<900.75-3.0<0.5
6.0-9.03.0-9.0
4.0 – 10
142-355
0.5-2.0>3.0
>69
>3.0 >1061.5-8.5
90-250>3.0<0.2
>9.0>9.0
>10 >355
2.0-10.0>8.5
>520pH Normal range = 6.5-8.5
Note: Interpretations are based on possible effects of constituents on crops and/or soils.
Suggested values are flexible and should be modified when warranted by local
experience or special conditions of crop, soil, and method of irrigation.
a Assuming water for crop plus water needed for leaching requirement will be applied.
Crops vary in tolerance to salinity. Electrical conductivity (EC) mmhos/cm x 640 =
approximate total dissolved solids (TDS) in mg/L or ppm.
b
[]()Ca Mg/ 20.^5SAR Na
+=where Na = sodium; Ca = calcium; Mg = magnesium, in all meq/L.
c Most tree crops and woody ornamentals are sensitive to sodium and chloride (use
values shown). Most annual crops are not sensitive.
d Leaf areas wet by sprinklers (rotating heads) may show a leaf burn due to sodium or
chloride absorption under low-humidity, high-evaporation conditions. (Evaporation
increases ion concentration in water films on leaves between rotations of sprinkler
heads.)
e HCO 3 - with overhead sprinkler irrigation may cause a white carbonate deposit to form
on fruit and leaves.