Sodium Adsorption Ratio (SAR)

SAR matters because the *type* of salt is as important as the *amount*. A high-EC water dominated by calcium and magnesium (gypsiferous well water) actually improves soil structure when applied; the same EC dominated by sodium (sea-water intrusion, blackstrap brine) destroys structure within seasons. The combined EC × SAR risk matrix (Ayers & Westcot 1985 Figure 1): low EC + high SAR is the most dangerous combination because rain dilutes the salts but leaves sodium attached to clay, accelerating dispersion.

Field symptoms of high-SAR water: surface sealing after rain, ponding that doesn't infiltrate, white sodium efflorescence in evaporation rings, and slow seedling emergence as crusts harden. Soil tests confirm: ESP (Exchangeable Sodium Percentage) above 15% defines sodic soil; pH typically rises above 8.5 because sodium hydrolyses water to form sodium hydroxide. Reclamation requires gypsum (calcium sulfate) applied at rates calculated from soil-test ESP plus leaching with low-SAR water.

Management strategies: (1) prefer Ca/Mg-dominated water sources when blending well supplies; (2) apply gypsum 1–5 t/ha annually as preventive maintenance on borderline soils; (3) avoid surface flood irrigation that maximizes evaporation and SAR concentration — switch to drip or buried emitters; (4) plant deep-rooted halophytes (date palm, atriplex, distichlis) on heavily sodic plots while reclamation proceeds. WiseYield logs SAR alongside EC in the lab-analyses tab so users see both salinity *and* sodicity risk on the same dashboard.