The competition for water in irrigated agriculture with other water users h
as increased demand for accurate determination of soil water status for eff
icient irrigation. There has been much interest in measuring topsoil hydrau
lic properties, including soil matric potential (SMP), as a tool for irriga
tion scheduling. Currently, many methods are available to measure SMP, incl
uding tensiometers, electrical resistance units, heat dissipation, and filt
er paper techniques. However, their acceptance is limited because of limita
tions in different applications (i.e., soil type, measurement range, accura
cy, etc.). Soil hygrometers may be better-suited instruments to measure SMP
when they are used in fine-textured soils (i.e., clay). The objectives of
this experiment were: (1) to determine the mean SMP in topsoil (0-0.30 m) a
t the onset of irrigation, resulting in maximum corn (Zea mays L.) grain yi
eld using a dew point soil hygrometer; (2) to relate these SMP values to th
e full profile (0-0.90 m) available water (AW) to determine the optimum val
ue of SMP for scheduling irrigations for summer-grown corn under a Mediterr
anean climate; and (3) to determine the number of soil samples required for
a valid representation of SMP measured with a dew point hygrometer under f
ield conditions.
An experiment with three irrigation treatments (S-1, S-2, and S-3) was cond
ucted on a clay soil (47% clay). Three irrigation treatments were based on
replenishing the 0.90 m root zone to the field capacity when the soil water
dropped to 75% (S-1), 50% (S-2), and 25% (S-3) of available water holding
capacity (AWHC). A dryland treatment (S-4) was also included. The mean SMPs
for topsoil at the onset of irrigation were -303, -406, and -635 kPa for S
-1, S-2, and S-3 treatments, with grain yields of 5333, 6058, and 4570 kg/h
a, respectively. The dryland treatment resulted in the minimum yield of 740
kg/ha. Results showed that the mean SMP value of -406 kPa can be a reliabl
e point to apply irrigations for corn grown in this soil. the relationship
between 0-0.30 m depth SMP versus full profile (crop root zone) AW was foun
d to be: SMP = 2150-4.35AW (r(2) = 0.80, n = 47, SMP in kPa, AW in mm). Thi
s equation can be used to estimate full profile AW using 0-0.30 m depth SMP
. For this soil and no-rainfall condition, monitoring one layer (topsoil) S
MP can be used to estimate full profile AW. Results also showed that 28 +/-
8 or 20 +/- 5 soil samples are needed to obtain +/- -10 kPa precision of S
MP measurements for the maximum yielding treatment (S-2) at 95% and 90% con
fidence levels, respectively. For these soil conditions, the dew point soil
hygrometer is a well-suited device that can be used to measure SMP for irr
igation scheduling. It is sensitive and consistent, and easy to calibrate a
nd use.