Post on 27-Dec-2015
Water shortage in Jordan...
The climate in Jordan is a mix of Mediterranean and dry desert climate with minimal rainfall and high percentage of evaporation, resulting in limited water supply.
Groundwater contributes approximately to 54% of the total water supply and the unsustainable abstraction of groundwater, largely due to the increasing demand of the increasing population growth and due to agriculture expansion, is making the water status in Jordan very crucial.
The lack of water constitutes one of the most serious challenges to Jordan’s future economic growth. As a result, the efficient management of water resources is very crucial.
The innovative decentralized system to be used in the project is a patented hybrid system for the production of drinkable water from brackish water. The autonomous system constructed in Greece uses:
the wind energy with a vertical axis rotor, the solar energy with panels
Middle East Water Livelihood Initiative
Watershed modeling, monitoring and management component
Eng. Lubna Al-Mahasneh
WLI workshop,Tunisia September 2013
Introduction: Jordan is one of the countries that are suffering from water
shortage and land degradation.
Arid environments, such as Al-Badia, in Jordan are characterized by sporadic, low average annual rainfall and very high rainfall intensities that may cause runoff and erosion.
Water harvesting in dry areas is becoming a more reliable option to optimize the benefit of available rainwater for crop production and to decrease the soil erosion. In addition to use runoff water for recharge aquifers tapped for irrigation.
The effect of water harvesting on the reduction of soil erosion and runoff is not adequately known.
Main goal: Adapting the SWAT model to predict the impacts of
water harvesting interventions on bio-physical and hydrological parameters and to test the applicability to similar arid environments.
Specific objectives:1. To study the effects of selected water harvesting
interventions on sediment quantity, quality, and runoff.
2. To adapt and evaluate the applicability of SWAT model in a typical arid area of Jordan.
Sites/sub-watersheds selection and description: Four sites, representing small sub-watersheds (hill slopes) were
selected for modeling purposes in Al-Majidyya village 40 km south-east of Amman.
The sites are representing an arid area of Jordan (known locally as Al-Badia).
The sites are located in close proximity to each other to minimize differences in climate, soils, vegetation, topography (elevation, aspect, and slope).
The study area receives an average annual rainfall less than 150 mm.
Two small sub-watersheds (paired swales) were selected to measure soil erosion (sediment yield only), using geo-textile trap (silt fences) established at each outlet. one contains continuous contour ridges as water harvesting measures and planted with `Atriplex halimus shrubs.
Two small sub-watersheds were selected to measure runoff by establishing a weir as a control section at each outlet. One contains (Vallerani intermittent pits) as water harvesting intervention planted by Salsola shrubs.
SWAT model: SWAT2012 version with its interface of ArcGIS 10.0
was used to execute this study.The basic data required to develop the model input
parameters using the SWAT ArcGIS Interface were : Digital elevation model (DEM ) Soil map Landuse map Climate data Rainfall data using tipping bucket rain gauge with data
pod.
Hydrological and sediment data:The required information of eroded sediment yields on the geotextile traps was estimated and sampled.
information and samples of generated runoff at the weirs edge were recorded using flow meter probes and ISCO automatic samplers.
runoff monitoring (field measurements): runoff data :the depth and the flow of generated runoff
water were recorded using water measurements devices at the weir outlets.
runoff water samples weretaken using an ISCO automatic sampler at the weir outlets.
Runoff plots were constructed and samples of runoff water collected in the barrels after each significant rainfall event will be taken.
Amounts and nutrient (N, P, K) for all collected samples were analyzed in the laboratory.
Moisture contents using TDR were taken as transects in all sites. Water component balance were calculated.
soil erosion monitoring (field measurements): The sediment quantities were estimated and sampled
after each rainfall event. Nutrients (organic matter, N, P,K) and texture for
collected samples were analyzed in the laboratory .
Setup the model: Some of the parameters were modified to suit
the arid conditions and to consider the water harvesting interventions as followings:
Consider the contour ridges planted with Atriplex in the produced HRUs: by adding a new landuse class represents the WH.
modifying the crop databases for the paramters ( (HVI), (LAI), heat units ) for each class of existing landuse .
Modifying the management practices (SCS Curve number values) and the operations.
Model simulation: the whole period used to simulate the model
was Nov. 2005 to May. 2013. A period of 2005 till 2010 was used to warm
up the model. However, Two years of measured data for soil
erosion were collected during winter seasons of Nov. 2011/ May 2012 and Nov. 2012/ May. 2013.
Furthermore, these will be used for calibration
and verification the model outputs. The results as followings:
Contour Ridge site
0
0.01
0.02
0.03
0.04
0.05
0.06
0.07
0.08
Oct-11 Nov-11 Dec-11 Jan-12 Feb-12 Mar-12 Apr-12Month/year
Sed
imen
t yie
ld (
ton
\ha)
Simulated
measured
the model output without calibration for monthly sediment yield was over estimated as illustrated in the figure comparing with the measured one. no sediments were observed in the field (CR) during all storms within the simulation period.
Figure 1
Feb-11Sep-11Apr-12Oct-12May-13Nov-13Jun-14
-0.00200
0.00000
0.00200
0.00400
0.00600
0.00800
0.010000
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
sed observed t_onsed simrainfall mm
Feb-11Sep-11Apr-12Oct-12May-13Nov-13Jun-140.00000
0.00500
0.01000
0.01500
0.02000
0.02500
0.03000
0.03500
0.04000
0.04500
0.050000
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
sed observed t_onsed simrainfall mm
Contour Ridge site _monthly basis
Pond.mgt
Jan2013
Feb 2012/Jan.2011
Feb 2012/Jan.2011Jan2013
Jan2013
The figure shows that: the magnitude variation of simulated monthly sediment yield for the selected storms does not match the observed sediment loads. Timings of occurrence of the peaks for observed and simulated sediment yield as well. they look in the same pattern but the model over-predicted sediment amounts during the January and February, 2012 except the storm happened at December 2011.
Figure 1
-0.10000
0.00000
0.10000
0.20000
0.30000
0.40000
0.50000
0.60000
0.700000
0.5
1
1.5
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sed observed t_onsed simrainfall mm
Jan2013
Barley site _monthly basis
Feb 2012/Jan.2011
Rangeland site
0 100 200 300 400 500 600 700 800 900
-0.002
5.20417042793042E-18
0.00200000000000001
0.00400000000000001
0.00600000000000001
0.00800000000000001
0.01 0
2
4
6
8
10
12
14
16
18
20
Q CMS obs
SIM cms
rainfall mm
0 100 200 300 400 500 600 700 800 900
-0.000499999999999991
9.10729824887824E-18
0.000500000000000009
0.00100000000000001
0.00150000000000001
0.00200000000000001
0.00250000000000001 0
2
4
6
8
10
12
14
16
18
20
Q CMS obsSIM cmsrainfall mm
Vallerani site_daily basis
the simulated runoff for these sites was under predicted from measured one
comparison between measured and simulated Biomass year 2011/2012
0.0
100.0
200.0
300.0
400.0
500.0
600.0
700.0
800.0
Contour ridge vallerani barley
Site name
measured
simulated
0.0
100.0
200.0
300.0
400.0
500.0
600.0
700.0
800.0Bi
omas
s yi
eld
(kg/
ha)
The model is under predicted the biomass production for the sites implemented by water harvesting interventions. the model is well matched with measured by assumption of applying fertilizers of 10 kg/ha N for barley site.
challenges and limitations: The application of the SWAT in arid regions
requires modifications of the existing SWAT databases and parameters.
little or no data or available literature for the crops planted in the study area (Atriplex, Salsola shrubs and winter barley).
Another challenge was how to consider the continuous contour ridges / Vallerani intermittent as certain types of water harvesting interventions implemented in the sites to consider in the model.
Conclusions:
The measured data for sediment yields present an evidence that the water harvesting interventions reduce the soil erosion and can aid in reducing losses where the soil erosion from watersheds contributes a large amount of top soil and nutrients each year.
The water harvesting interventions have a potential to optimize the benefit of rainfall especially in the arid environment.
The biomass results can be significant for the farmers to adopt the water harvesting interventions which maximize the productivity.
The model requires fine-tuning to the input model parameters to include the established continuous contour ridges and vallerani pits (WH) interventions in the sites and its impacts that reduce the soil erosion and runoff.
Achievement:• Submitting full paper titled as
“Adapting SWAT model for the evaluation of water harvesting systems in an arid environment: a case from Jordan" in the SWAT conference proceedings which was presented in the SWAT conference 2013, France. http://swat.tamu.edu/media/77367/b32-
al-mahasneh.pdf,•
http://swat.tamu.edu/media/81472/Book-of-Abstracts-Post-Conference.pdf