Abstract:
World is facing an acute water crisis due to the increase of world
population, droughts, land degradation, and food demand. This increases the
concern over conservation of water. One of the most important factors related to
water management is crop evapotranspiration. In the present research work, the
reference crop evapotranspiration (ETo) is estimated by using ten empirical
models which are widely used in Indian conditions namely, Thornthwaite (1948),
Hargreaves et al., (1985), Turc (1961), Christiansen (1968) Pan Evaporation,
FAO-24 Blaney-Criddle (1977), FAO-24 Modified Penman (1977), FAO-24
Open Pan (1977), Preistly-Taylor, Makkinik and FAO-56 Penman-Monteith
(1991).
The accuracy of these reference evapotranspiration models were evaluated
by comparing it with FAO-56 Penman-Monteith using six years monthly average
meteorological data for the period January, 2011-December, 2016. Then the
models were validated with lysimetric data. The weekly water balance studies
were conducted in lysimeter to find the actual reference evapotranspiration. The
model values were estimated using weekly meteorological data for the period
January-May 2017 during which the lysimeter study was conducted. Then best fit
relations were developed between the estimated values (ETo EST ) and observed
values (ETo LYM ) for the humid tropical region.
Among the different empirical models, Turc model showed the highest ETo
value (14.92 mm/day) while the Priestly-Taylor showed the lowest (0.62
mm/day). Thornthwaite, Blaney-Criddle and Modified Penman model gave closer
values to each other 7.32, 8.9 and 7.09 mm/day respectively. While Christiansen,
Penman-Monteith, Open Pan and Makkinik models gave values like 3.08, 3.23,
3.24 and 2.22 mm/day respectively which were slightly lower compared to the
values obtained from the Hargreaves model (4.7 mm/day). The statistical
comparison was made by considering FAO-56 PMM as the standard model using
six year average monthly meteorological data. The Modified Penman model gavethe best performance with R 2 of 0.96 with RMSE 3.95 and RelRMSE 1.22
followed by Hargreaves model. The Open Pan method ranked the third one. The
models, Christiansen, Priestly-Taylor and Makkinik were underestimated while
Thornthwaite, Turc and Blaney-Criddle models overestimated.
For validation of the models, weekly ETo estimated from models were
compared with ETo observed from lysimeter for the period January-May, 2017.
The Hargreaves model showed the best performance with R 2 0.83 and RMSE
0.82. The Turc model was highly over estimated while Blaney-Criddle and
Modified Penman models were only slightly overestimated. The Penman-
Monteith and Makkinik models were slightly underestimated while Priestly-
Taylor highly underestimated with R 2 0.56 and the RMSE 4.29. Hence it is
concluded that Hargreaves (HAM), Open Pan (OPM) and Christiansen (CHM)
models were found to be in close agreement with lysimetric data and hence these
models were suggested for use in this humid tropical region. Therefore
relationships were developed between these empirical model output and the
lysimetric data (LYM). The relationships developed were as follows: ETo LYM =
0.79HAM + 0.45, ETo LYM = 0.79CHM + 1.60 and ETo LYM = 0.63OPM + 2.04.
Finally the results of this research can be recommended for humid tropical
region for irrigation scheduling, selection of cropping pattern, optimum allocation
of water resources and efficient use of water.