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Modelling Soil Moisture Balance for Okra Cultivars in Makurdi
Agro Climate Using Decision Support System for Agro Technology
Transfer (DSSAT)
Ben I.E., Enokela O.S.
Department of agricultural and environmental Engineering, Joseph Sarwuan Tarka University Makurdi
DOI: https://doi.org/10.51583/IJLTEMAS.2024.130714
Received: 10 July 2024; Revised: 24 July 2024; Accepted: 27 July 2024; Published: 14 August 2024
Abstract: Soil moisture balance from okra (abelmoschus esculentus) field was performed on experimental plot of the Department
of Agricultural and Environmental Engineering, Joseph Sanwuan Tarka University Makurdi -Nigeria. Field and laboratory
experiments were conducted on four okra cultivars planted and irrigated by drip system at different levels (80% (I
1
), 60% (I
2
),
45% (I
3
), and 15% (I
4
)) according to the agronomic practices of okra. Decision Support System for agro technology Transfer
(DSSAT) model for the Crop Environment Resource Synthesis (CERES) was used to model soil moisture balance by linear
regression (multivariate analysis of variance, (MANOVA)) and validated. The soil was sandy loam with high field capacity (FC)
at I
4
and nearly uniform drainage (D) except for I
4..
Runoff (R) decreases from 35.71 for I
1
to 0.07 for I
4
implying that R, D and
change in water storage (∆S) are functions of the amount and duration of irrigation. The models reported an acceptable deviation
from the ideal line of the R and ∆S at higher values confirming degree of the correlation between the observed and predicted
dataset but experienced difficulties with estimating lower values due to lower magnitudes in irrigation. From the foregoing it is
concluded that decreasing water application results in an increase in irrigation and the reverse is also true.
Keywords: Irrigation levels, okra, Makurdi agro climate, soil moisture balance, modeling
I. Introduction
Imbalance in water demand and supply for agriculture has drawn many attentions on model technologies and management
innovations that can maximize irrigation water use [1] [2], [3], [4]. In the contemporary social, economic, institutional, climatic,
soil and other environmental variables, plant growth and development has been influenced by the presence of adequate moisture,
warmth and aeration in the soil [5]. Hence; soil moisture as a matter of fact integrates the water balance components of land
surface hydrology [6], [7], and over time to develop antecedent hydrologic fluxes [8]. It can be used to determine soil moisture
balance components (SMBCs) from a hydrologic balance which relates soil moisture losses to a dryness index, describing the
partitioning of precipitation into evapotranspiration, runoff, and deep infiltration [9]. Climate, soil, and vegetation conditions of
any ecology nurtured soil moisture dynamics and plant water stress in field experiments on ecosystem response to shifts in the
rainfall regime, showing that plant crucially depends not only on the total rainfall during the growing season but also on the
intermittency and magnitude of the rainfall events [10], [11].
Reducing the vulnerability of agriculture to climate change, and ultimately decreasing the risks associated to food security,
requires integrated and sustainable water management, adaptation of cropping systems and management practices, adopting an
efficient use of both rainfall and irrigation water. This is critical considering the steady increase of global population and the
limitations on availability of natural resources, particularly in vulnerable agricultural areas with water scarcity [12], [13], [2],
[14]. Although, soil water balance model for many crops exist, however the water balance application for okra field has not been
investigated. Thus, most farmers do not know when to irrigate and what quantities of water to be used for irrigation and also
when to apply the drainage system in their farm, this is because they do not have the knowledge of soil moisture behavior. Hence
this study has generated set of data from the field and was used to model SMBFO by DSSAT model
II. Materials and Method
The Study Area
Based on Koppen’s Scheme of Classification, Makurdi –Nigeria lies within the AW Climate (Tropical Savannah Climate) and
experiences two distinct seasons, the wet/rainy season and the dry/summer season. The rainy season lasts from April to October
with annual rainfall in the range of 100-200mm [15]. The dry season begins in November and ends in March. Temperatures in
Makurdi fluctuate between 23 – 40 degrees Celsius [16]. The vegetation of the Makurdi consists of rain forests which have tall
trees, tall grasses and oil palm trees with mixed grasses and trees that are generally of average height. The topography is mainly
undulating plains with occasional elevations of between 1,500 m and 3,000m above sea level according to [16]. The main
geological formations are sandy-loam shelf basement complex and alluvial plains. These together with its location in the
transition belt between the north and south ecologies and a favourable rainfall pattern account for its support for a wide variety of
crops [17]
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Makurdi metropolitan is located in central Nigeria along the Benue River trough and lies between Latitudes 70 and 80N as well as
Longitude 80 and 90 E. with average relief of 120 m [18]. The relative humidity ranges between 50 % and 80 % and are season
dependent. The highest relative humidity occurs between June and September while the lowest is December to February [18].
Rich agricultural produce within Makurdi include yams, rice, beans, cassava, potatoes, maize, soya beans, sorghum, millet and
cocoyam. Makurdi also hosts one of the longest stretches of river systems in the country with great potential for a viable fishing
industry, dry season farming through irrigation and for an inland water highway [19].
Field Experiment
A 4 irrigation levels plot replicated by 3 cultivars of okra making a total of 12 experimental plots measuring 1m by 1m each were
developed for contributing very good surface runoff to the downstream (Plate 1). Paving of the slope with burnt bricks was
adopted to stabilize the slopping side in the boundary. A transverse 0.2 % non-erosive bed slope was adopted for the downstream
portion of the plots in accordance with [20].
Plate 1: Experimental Plots Planted with Okra
The field capacity (Fc) at the experimental site was determined as the moisture content of the soil sample when drained
completely (usually within 24 to 48 hrs) in accordance with the method described by [21], [21]. Field capacity was computed as
in equation (1),
(1)
where;
Is the weight of wet soil + Crucible
Is the weight of oven dry soil + Crucible
Permanent wilting point (PWP) for the experimental field is the lowest water content of soil measured after plant has stopped
extracting water and were at or near premature death or became dormant as a result of water stress [22]. To determine the PWP
under field conditions, an okra plant with a well-developed tap root system at their maximum vegetative growth was identified
from each cultivar, water was withheld at the end of the experiment and the plant allowed wilting. The soil moisture at that point
was determined by oven dry method at 105 – 110
o
C as the PWP.
Deep drainage water was determined according to [23]as follows
D = Amount of moisture above
(2)
where:
D = Drainage (mm)
FC = Field capacity (mm)
PWP = permanent wilting point (mm).
The runoffs from the plots were conveyed through a pipe into a plastic sump for measurement at the end of every irrigation (Plate
1).
Change in soil water storage (∆S) was estimated according to [24] as difference between the amount of water added (precipitation
+ Irrigation amount), and the amount of water lost (drainage + unsaturated flow or runoff + soil evaporation + root water uptake).
For non-rainy period
∆S
i
= I
T
– I
i
(3)
where;
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I
T
is the total amount of water irrigated on each plot
I
i
is the amount of water irrigated to each plot at ith level
Model Description
The water model in the Decision Support System for Agro technology Transfer (DSSAT) was represented by one-dimensional
and linear water model below was adopted:
∆S = P + I – T – E – R – D (4)
where:
∆S = Change soil water storage
P = Precipitation
I = Irrigation
T = Transpiration
E = Evaporation
R = Runoff
D = Drainage
The one-dimensional and linear water model computes the daily changes in soil moisture due to precipitation (P), irrigation
infiltration (I), vertical drainage (D), unsaturated flow or runoff (R) and evapotranspiration as sets of data.
Estimation of Model Parameters
The DSSAT requires information to calculate processes such as root uptake (T), drainage (D), and soil water evaporation (E).
However, due to lack of instrumentation, already established maximum root water uptake (0.03 cm
3
) of water cm
-1
of root day
-
1
, by [25], [26] for okra was applied. The set of data from the parameters were modeled by generalize MANOVA using Minitab
20 computer software.
The soil moisture balance for okra (SMBFO) was developed from water (DSSAT) for the Crop Environment Resource Synthesis
(CERES) using the set of data from the field experiments and Minitab 16 statistical package.
Model Validation
To validate the water balance models, the predicted (p) results of components of water balance, such as soil water storage,
evapotranspiration, deep percolation from root zone to buffer zone were compared with the observed (o) by plotting.
III. Results
Data set for modeling
Table 1 is the result (data sets) for the model imputes parameters (I, R, D, E, T ∆S) generated from the field experiment
From Table 1, the change in ∆S was nearly uniform irrespective of the okra cultivar. However, cultivar P
2
demonstrates the
highest ∆S
2
meaning that the particular species does not demand much water during this period in Makurdi agro climate. P
4
consequently has very low ∆S
4
meaning that the amount of water taken by the plant nearly equal the amount of water supplied in
as much as evapotranspiration, runoff and deperculation remain constant.
Modeling SMBFO
The data set for impute parameters in Table 1 were tested on the DSSAT model by multivariate analysis of variance (MANOVA)
using general linear MANOVA by MINITAB software and the result shown in Table 2. We can see from Table 2 that ∆S
1
has a
statistically significant effect on I, R, D, E, T (F (1, 2) = 4.77; p < .005; ∆S
2
(F (1, 2) = 3.56; p < .005; ∆S
3
(F (1, 2) = 5.39; p <
.005.and ∆S
4
(F (1, 2) = 4.83; p < .005. The results for between subject effects for the model input (Table 1) show coefficient of
determination (R
2
) been 0.705; 0.640, 0.729 and 0.708 for ∆S
1
, ∆S
2
, ∆S
3
, and ∆S
4
respectively for the corrected model. The total
output is the sum of the individual output which is 1 and the corrected total (rest of the output) which is 3.
Table 1: Soil Moisture Balance Parameter for Surface Drip (SD) Irrigation during 2021 and 2022
I
1
(80%)
Irrigation amount
(mm)
Runoff (mm)
Drainage
(mm)
E
T
Change in soil
moisture
P1
I
1
(80%)
160
35.00
2.50
8.678
0.03
113.5
I
2
(60%)
90
13.51
1.41
8.678
0.03
115.3
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I
3
(45%)
30
5.60
1.65
8.678
0.03
116.15
I
4
(15%)
13
0.53
2.0
8.678
0.03
114.93
P2
I
1
(80%)
160
30
1.47
8.678
0.03
66.01
I
2
(60%)
90
34.76
2.58
8.678
0.03
74.86
I
3
(45%)
30
16.19
5.62
8.678
0.03
64.97
I
4
(15%)
13
5.71
2.83
8.678
0.03
66.77
P3
I
1
(80%)
160
35.10
0.85
8.678
0.03
13.77
I
2
(60%)
90
15.71
2.57
8.678
0.03
13.79
I
3
(45%)
30
4.40
3.21
8.678
0.03
13.73
I
4
(15%)
13
0.63
2.83
8.678
0.03
15.41
P4
I
1
(80%)
160
35.71
3.18
8.678
0.03
1.49
I
2
(60%)
90
10.95
4.73
8.678
0.03
2.35
I
3
(45%)
30
5.71
3.18
8.678
0.03
2.80
I
4
(15%)
13
0.07
2.91
8.678
0.03
1.95
Table 2: ANOVA for Test of Between Subject Effects for Water Balance Model Imputes
Source
Dependent Variable
Type III Sum
of Squares
Df
Mean Square
F
Sig. D
Corrected
Model
∆S1
5600.016
a
1
5600.016
4.771
0.161
∆S2
5414.501
b
1
5414.501
3.563
0.200
∆S3
5938.525
c
1
5938.525
5.390
0.146
∆S4
5661.970
d
1
5661.970
4.839
0.159
Intercept
∆S1
14824.161
1
14824.161
12.629
0.071
∆S2
15906.801
1
15906.801
10.467
0.084
∆S3
15404.750
1
15404.750
13.983
0.065
∆S4
15331.031
1
15331.031
13.102
0.069
Error
∆S1
2347.549
2
1173.774
∆S2
3039.373
2
1519.686
∆S3
2203.370
2
1101.685
∆S4
2340.218
2
1170.109
Total
∆S1
17431.403
4
∆S2
19093.796
4
∆S3
17908.276
4
∆S4
17908.408
4
Corrected Total
∆S1
7947.565
3
∆S2
8453.874
3
∆S3
8141.896
3
∆S4
8002.187
3
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Table 3 is the multivariate test design of intercept and ∆S parameters for the different levels of irrigations. The results were exact
for Wilks' Lambda, at 0.05 level of significance The multivariate tests table is an attestation to the actual result of the one-way
MANOVA. To determine whether the one-way MANOVA was statistically significant we looked at the "Sig.D" column. From
Table 2 the "Sig." value was .000, which means p < .005. Therefore, we can conclude that the model impute variable were
significantly dependent on amount of irrigation (p < .005).
The general estimable function is unity as the estimated marginal means increases gradually for I and R with increasing ∆S. The
trend however fluctuates in D with the highest value of 5.5 at of 1
3
, and 70
(Figure 1 - 5). The trends were uniform for E and
T for all values of. This shows that the mean for I, R, D, E, T were statistically significantly different between ∆S (p < .005)
Mean values were statistically significantly different between ∆S (p < .005), These differences can be easily visualized by the
plots generated by this procedure, as shown in Figure 1- 5:
Table 3: The Multivariate Test Design of Intercept and water balance parameters
Multivariate Tests
a
Effect
Value
F
Hypothesis
df
Error df
Sig.
Intercept
Wilks' Lambda
.019
26.274
b
2.000
1.000
0.137
I1
Wilks' Lambda
1.000
.
b
.000
1.500
0.000
I2
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
I3
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
I4
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
R1
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
R2
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
R3
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
R4
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
D1
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
D2
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
D3
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
D4
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
E
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
T
Wilks' Lambda
1.000
.
b
.000
1.500
0.000.
a. Design: Intercept + I1 + I2 + I3 + I4 + R1+ R2 + R3 + R4 + D1 + D2 + D3+ D4 + E + T
b. Exact statistic
Model validation
The results for validation of the new model are demonstrated by the plot of the observed vs the predicted as can be seen in Figure
6 - 8. From the plots there were linear correlation and nonlinear correlation between predicted and observed model parameters at
different levels of irrigations.
a. R Squared = .705 (Adjusted R Squared = .557)
b. R Squared = .640 (Adjusted R Squared = .461)
c. R Squared = .729 (Adjusted R Squared = .594)
d. R Squared = .708 (Adjusted R Squared = .561)
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∆S
Fig 1: Estimated Marginal Means for I
∆S
Fig 2: Estimated Marginal Means for runoff (R)
∆S
Fig 3: Estimated Marginal Means for (D)
∆S
Fig 4: Estimated Marginal Means for (E)
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∆S
Figure 5: Estimated Marginal Means for T
Fig 6: Residual Plots for R
Fig 7: Residual Plots for drainage (D)
Figure 8: Residual Plots for irrigation (I)
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IV. Discussion
Parameter estimation for prediction
The soil moisture balance parameters considered in the experiment were P, I, R, D, E and T. No rainfall was recorded because the
study period coincides with the dry season, the irrigation were scheduled for 160, 90, 30 and 13 mm as I
1
, I
2
, I
3
and I
4,
respectively. The results indicated a decreasing order of D, R, and ∆S from I
1
to I
4
as attested to by the plot in Figure 9 (P
1
- P
2
).
ETc and Kc were nearly uniform from their plots indicating that it does not depend largely on the amount of irrigation however to
an extent on the prevailing climatic variables and the nature of the soil. Runoff decreases from 35.71 for I
1
schedule to 0.07 for I
4
.
This implies that runoff D and ∆S are functions of the amount and duration of irrigation in as much as other factor and the soil
conditions remain the same.
Figure 9(P
1
- P
2
). Response of ∆S and Kc to irrigations level for Okra cultivars
There is no relationship between D and the irrigation levels as it is purely a function of the soil characteristics and the plant
characteristics. Crop root uptake of the okra was based on the maximum 8.678 established for the plant from previous research
while the evapotranspiration was calculated as 0.03 from pan experiment at the site.
Modeling and Model
The modeling process was based on already established DSSAT model for the CERES. The DSSAT provided for net irrigation
for the entire plot throughout the season (December - February) which is off-rainy season.
The corrected or modified SMBFO provided for components like irrigation (I) runoff (R), drainage (D) and evapotranspiration
(ET) for evaluation of change in water storage (∆S). ∆S is defined as the amount of water readily available for crop for extraction
from its root zone [27] and depends on soil types, depth and distribution of roots within the soil mass [28]. Though the model
outputs were similar in trend, however they were contrary to the findings of [29] who reported higher values than the values
0
50
100
150
I1 I2 I3 I4
R D ∆s ETc Kc
0
50
100
150
I1 I2 I3 I4
R D ∆s ETc Kc
0
50
100
150
I1 I2 I3 I4
R D
∆s
ETc Kc
0
50
100
150
I1 I2 I3 I4
R D
∆s
ETc Kc
P
1
P
2
P
3
P
I
P
2
P
3
P
4
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obtained from this study. The model recorded ∆S which varied from 5600.016 mm in I
2
to 5661.970.18 mm in I
4
. This shows a
significant correlation between irrigation and ∆S with Sig.d between 0.161 and 0.159 from I
1
to I
4
V. Conclussion
Makurdi agro-ecological zones of Nigeria experiences variation in available soil moisture under different irrigation schedule. The
SMBFO model has proved that I, R, and D were positively significant implying that they are the major contributors to ∆S while E
and T are dependent on the prevailing climatic condition of the study area. Most significant from the interaction of the model
parameters is I followed with R then D. Plot of observed vs predicted reported an acceptable deviation from the ideal line of the R
and ∆S at higher values, this is confirming degree of the correlation between the observed and predicted dataset. However, in
some cases, the low values of the R, ∆S, D and ETc failed to be simulated accurately using the standalone predictive models. Yet,
the developed hybrid models revealed better degree of correlation as it can be observed for the models. The values presented here
belong to the predicted/observed values of all growth stages putted together. It is therefore recommended that this study be
extended to;
1 Different soils locations of Nigeria
2 Different climate location in Nigeria
Reference
1. Pereira F.L. Gash J.H.C., David J.S., David T.S., Monteiro P.R. Valente F(2009) Modelling interception loss from
evergreen oak Mediterranean savannas: Application of a tree-based modelling approach Agricultural and Forest
Meteorology Volume 149, Issues 3–4, 11 March 2009, Pages 680-688
2. Pereira L.S (2017). Water, Agriculture and Food: Challenges and Issues," Water Resources Management: An
International Journal, Published for the European Water Resources Association (EWRA), Springer; European Water
Resources Association (EWRA), vol. 31(10), pages 2985-2999, DOI 10.1007/s11269-017-1664Porporato, 2005
3. Jovanovic N., Musvoto C., de Clercq W.P, Pienaar C., Petja B., Zairi A., Hanafi S., Ajmi T., Mailhol J.C, Cheviron
B., Albasha R., Solomon H., Yazew E, Kifle M., Yohannes D.F., Aregay G., Habtegebreal K., Gebrekiros A., Woldu
V and Froebrich J (2018) A Comparative Analysis of Yield Gaps and Water Productivity on Smallholder Farms in
Ethiopia, South Africa and Tunisia: Comparative Analysis of Yield Gaps and Water Productivity March 2018 Irrigation
and Drainage 69(2) DOI: 10.1002/ird.2238
4. Mallareddy M., Thirumalai kumar R., Balasubramanian P., Naseeruddin R. Nithya N., Mariadoss A., Eazhilkrishna N.,
Choudhary A.K., Deiveegan M, Subramanian E., Padmaja B and. Vijayakumar S (2023) Maximizing Water Use
Efficiency in Rice Farming: A Comprehensive Review of Innovative Irrigation Management Technologies.
Water 2023, 15(10), 1802; https://doi.org/10.3390/w15101802
5. Gavrilescu M. (2021). Water, Soil, and Plants Interactions in a Threatened Environment. Water 2021, 13(19),
2746; https://doi.org/10.3390/w13192746
6. Rodriguez-Iturbe I, and Porporato A. (2005). Ecohydrology of Water-Controlled Ecosystems. Cambridge University
Press, pp: 460.
7. Lesk C., Anderson W., Rigden A., Coast O., Jägermeyr J., McDermid S., Davis F.F and Konar M (2022). Compound
heat and moisture extreme impacts on global cropyields under climate change Nature Reviews Earth & Environment
Nature Reviews Earth & Environment 3(12):872–889 DOI: 10.1038/s43017-022-00368-8
8. Costa-Cabral M.C, Richey J E, Goteti G, Lettenmaier DP, Feldkotter C, Snidvongs A. (2008). Landscape structure and
use, climate, and water 489 movement in the Mekong River basin. Hydrological Processes, 22: 1731-1746.
9. Naorem N., Jayaraman. S, Dang Y.P.,
Dalal R.C.,
Sinha N.K., Rao Ch. S and Patra A.K (2023) Soil Constraints in an
Arid Environment—Challenges, Prospects, and Implications. Agronomy 2023, 13(1),
220; https://doi.org/10.3390/agronomy13010220
10. Amilcare P, Edoardo D, and Ignacio R, (2004) Soil Water Balance and Ecosystem Response to Climate Change. Am.
Nat. 2004. Vol. 164, pp. 625–632.
11. Ridolfi L., D'Odorico P., Porporato A. and Rodriguez-Iturbe I. (2000) Impact of climate variability on the vegetation
water stress Journal of Geophysical Research Atmospheres 105(D14):18013-18026 DOI: 10.1029/2000JD900206
12. Smith, M. (2000) Optimizing Crop Production and Crop Water Management under Reduced Water Supply. Food and
Agricultural Organization, Rome, 20 p;
13. Foley J.A., Ramankutty N., Brauman K.A., Cassidy E.S., Gerber J.S. Johnston M., Mueller N.D., O’Connell C., Ray
D.K., West P.C., Balzer C., Bennett E.M., Carpenter S.R., Hill J. , Monfreda C. , Polasky S. , Rockström J., Sheehan
J., Siebert S. , Tilman D. , Zaks D.P.M. (2011). Solutions for a cultivated planet, Nature, 478 (2011), pp. 337-
342, 10.1038/nature10452
14. Stringer C., Fraser E.D.G., Harris D., Lyon C., Pereira L., Ward C.F.M. Simelton E. (2020). Adaptation and
development pathways for different types of farmers, Environmental Science & Policy Volume 104, February 2020,
Pages 174-189
15. Mobolade T.D. and Pourvahidi P (2022) Bioclimatic Approach for Climate Classification of Nigeria.
Sustainability 12(10):4192 DOI: 10.3390/su12104192
INTERNATIONAL JOURNAL OF LATEST TECHNOLOGY IN ENGINEERING,
MANAGEMENT & APPLIED SCIENCE (IJLTEMAS)
ISSN 2278-2540 | DOI: 10.51583/IJLTEMAS | Volume XIII, Issue VII, July 2024
www.ijltemas.in Page 129
16. Ologunorisa E.T and Tor T. (2006). The Changing Rainfall Pattern and Its Implication for Flood Frequency in Makurdi,
Northern Nigeria. J. Appl. Sci. Environ. Manage. 10 (3): 97 – 102.
17. Abah R C. (2013) An application of Geographic Information System in mapping flood risk zones in a north central city
in Nigeria. African Journal of Environmental Science and Technology Vol. 7(6), pp. 365-371, June 2013 DOI:
10.5897/AJEST12.182 ISSN 1996-0786 © 2013 Academic Journals http://www.academicjournals.org/AJEST
18. Adaikwu, A. O., Obi, M. E., and Ali, A. (2012). Assessment of degradation Status of Soils in Selected areas of Benue
State, Southern Guinea Savanna of Nigeria. Nigerian Journal of Soil Science, 22 (1):171-180.
19. Stocker, T.F., D. Qin, G.K. Plattner, M. Tignor, S. K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex and P.M. Midgley
(eds. (2024)]. Projected Climatic Trends and their Environmental Impact on Agriculture Productivity in Makurdi
Nigeria. Available from. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, Pp. 2 –
33.[22] BN [accessed Jun 24 2024].
20. Walstra, J., Heyvaert, V. M. A. and Verkinderen, P. (2007), Mapping the alluvial landscapes of Lower Khuzestan (SW
Iran), in Smith, M. J., Paron, P. and Griffi th, J. S. (eds.), Geomorphological mapping: a professional handbook of
techniques and applications, Elsevier, Amsterdam.
21. Mbah, C.N. (2012) Determining the Field Capacity, Wilting point and Available Water Capacity of some Southeast
Nigerian Soils using Soil Saturation from Capillary Rise. Nig J. Biotech. Vol. 24 (2012) 41-47 ISSN: 0189 17131
Available online at www.biotechsocietynigeria.org.
22. Tolk, J.A. Soils, permanent wilting points. Water Sci. 2003, 92, 927–929. [Google Scholar]
23. Simalenga TE (ed) (1994). Participatory Research and Development of Agricultural Engineering Technologies.
Proceedings of AGROTEC Onfarm Trials regional workshop held in Embu, Kenya
24. Hillel D (2004) Introduction to environmental soil physics. Elsevier Academic Press, Amsterdam/ Boston/ Heidelberg/
London/New York/Oxford/Paris/San Diego/San Francisco/Singapore/Sydney/Tokyo
25. Tiwari K N, Mal P K, Singh R M and Chattopadhyay A. (1998). Response of okra (Abelmoschus esculentus (L.)
Moench.) to drip irrigation under mulch and non-mulch conditions. Agricultural Water Management 38: 91–10
26. Bahadur A, Singh K P, Rai A, Verma J and Rai M (2009) Physiological and yield response of okra (Abelmoschus
esculentus) to irrigation scheduling and organic mulching. Available from: Indian Journal of Agricultural Sciences 79
(10): 813–15, October 2009 https://www.researchgate.net/publication/215925787 [accessed Jul 09 2024].
27. Steduto, P., Hsiao, T.C., Fereres, E. and Raes, D., (2012). Crop yield response to water (Vol. 1028, p. 99). Rome, Italy:
FAO.
28. Carr M.K.V. (2011). The water realtion and irrigation requirements of oil palm (elaeis gueneenisis): A Review.
Experimental Agriculture, 47(4); 629-652. Doi;10.1017/s0014479711000494
29. Hashim M.A.A., Naima Siam., Ali A Aldosari K.A. Al-Gaadi, V.C. Patil, Elkamil Tola, Rangaswamy Madugundu and
M.S. Samdani (2012) Determination of Water Requirement and Crop water productivity of Crops Grown in the Makkah
Region of Saudi Arabia Australian Journal Of Basic And Applied Sciences 6(9):196-206
