共查询到20条相似文献,搜索用时 718 毫秒
1.
M. G. Bos H. van den Bosch H. Diemont H. van Keulen J. Lahr G. Meijerink A. Verhagen 《Irrigation and Drainage Systems》2007,21(1):1-15
The rural sustainability index is a scientifically based tool to quantify the performance of agriculture. The sustainability
of crop production is quantified from three perspectives; people, planet and profit. Within each perspective, one condition
was selected that must be met to warrant agriculture. These are: No hazardous work should be used within the crop production
chain; agricultural crops should not be grown on land allocated to nature by national law or regulations and, when a GM-crop
is present or is introduced in a region, it should not harm development opportunities of other farmers. If these excluding
conditions are met, the sustainability of agriculture is assessed through five performance indicators on school attendance,
water use and consumption, fertilizer use, pesticide use, and farm income. For each of the five indicators, critical values
and target values have been given that limit the transition range between non-sustainable and sustainable production. The
five indicators are combined into a sustainability index. The index aims at improving the socio-economic position of farmers
while protecting the environment.
相似文献
| M. G. BosEmail: |
2.
Recharge to the aquifer through seepage from irrigation canals is often quoted as one of the main causes for waterlogging
in Pakistan. In the design of drainage systems to control this waterlogging, rules-of-thumb are often used to quantify the
seepage from canals. This paper presents the option to use a groundwater model for a more detailed assessment. Groundwater
models may assist in evaluating the effect of recharge reducing measures such as interceptor drains along irrigation canals
and lining. These measures are commonly aimed at reducing the drainage requirement of adjacent agricultural lands.
In this paper an example is given of the application of a numerical groundwater model, aimed at assessing the effect of interceptor
drainage and canal lining in the Fordwah Eastern Sadiqia project, being a typical and well-monitored location in Pakistan.
The paper also presents references to other conditions. The model was used to obtain a better insight in the key hydraulic
parameters, such as the infiltration resistance of the bed and slopes of irrigation canals, the drain entry resistance of interceptor drains and the hydraulic conductivity of soil layers. The model was applied to assess the effectiveness and efficiency of interceptor drains under various conditions.
The results of the study show that the net percentage of intercepted seepage is too low to have a significant effect on the drainage requirement of the adjacent agricultural lands. Besides, the operation
of the system, with pumping required, is often an added headache for the institution responsible for operation of the system.
The marginal effect of interceptor drains and lining on the drainage requirement of adjacent agricultural land does not always
justify the large investments involved. It can be concluded that:
Relevant hydrological concepts and modelling parameters with respect to leakage from irrigation canals and interception by
interceptor drains are presented in a separate paper. 相似文献
| • | Use of rules-of-thumb to estimate components of the water balance of irrigation systems in designing drainage can be very misleading; |
| • | Interceptor drainage may cause induced seepage from irrigation canals, which is often an order of magnitude more than the net intercepted seepage; |
| • | Interceptor drains and canal lining do not significantly reduce the drainage requirements, or in other words, cannot prevent the need for the installation of a drainage system; |
| • | A numerical model can aid to evaluate proposed measures and strategies to alleviate water losses and drainage problems. |
3.
Donna Brennan 《Irrigation Science》2008,26(2):109-119
Adoption of more uniform sprinkler systems involves a trade off between increased capital expenditure on equipment and the
benefits associated with reduced water application when application is uniform. An empirical analysis of the economics of
lettuce production, grown using sprinkler systems under the windy conditions of the Swan Coastal plain in Western Australia
is presented, where the yield response to water exhibits eventual declining marginal productivity. A range of sprinkler designs
that have been field-tested for performance were examined. The optimal per-crop water application for the least efficient
system was up to double the application rate of the most efficient system. However, the economic analysis demonstrates that
there are clear incentives for adopting more water-efficient systems despite the higher capital cost, because of the yield
depressing effect of over-watering. Sensitivity analysis demonstrates substantially poorer incentives for improving irrigation
efficiency when yield relationships follow a Mitscherlich functional form.
相似文献
| Donna BrennanEmail: |
4.
Accurate irrigation scheduling is important to ensure maximum yield and optimal water use in irrigated cotton. This study
hypothesizes that cotton water stress in relatively humid areas can be detected from crop stress indices derived from canopy
reflectance or temperature. Field experiments were conducted in the 2003 and 2004 crop seasons with three irrigation treatments
and multiple cultivars to study cotton response to water stress. The experiment plots were monitored for soil water potential
(SWP), canopy reflectance and canopy temperature. Four crop stress indices namely normalized difference vegetative index (NDVI),
green NDVI (GNDVI), stress time (ST) index and crop water stress index (CWSI) were evaluated for their ability to indicate
water stress. These indices were analyzed with classic mixed regression models and spatial regression models for split-plot
design. Rainfall was plentiful in both seasons, providing conditions representative of irrigated agriculture in relatively
wet regions. Under such wet weather conditions, excessive irrigation decreased lint yield, indicating the necessity for accurate
irrigation scheduling. The four crop stress indices showed significant responses to irrigation treatments and strong correlation
to SWP at shallow (0.2 m) depth. Spatial regression models were able to accurately explain the effect of irrigation treatment,
while classic split-plot ANOVA models were confounded by collinearity in data across space and time. The results also verified
that extreme humidity can mask canopy temperature differences with respect to ambient temperature, adding errors to canopy
temperature-based stress indicators.
相似文献
| Sreekala G. BajwaEmail: |
5.
The spatial and temporal pattern of root water uptake in partially wetted soil was studied in the root zone of a 6-year-old microsprinkler-irrigated almond tree. The water balance of about one quarter of the root zone’s wetted soil volume (2.0×2.0×0.9 m3) was determined by catch cans, neutron probe and tensiometer measurements. Twenty-five neutron probe access tubes with catch cans were distributed in a square grid of 50 cm spacing. Eight pairs of tensiometers were installed at depths of 82.5 and 97.5 cm in a regular pattern between the access tubes. Neutron probe readings at 15 cm depth increments and tensiometer readings were taken at time intervals of 4–24 h. The rate of soil water depletion was calculated and used to estimate the spatial and temporal distributions of root water uptake. Soil water dynamics was studied in two stages: (1) during a week of conventional irrigation management with three irrigation events; and (2) during a period of 16 days without irrigation, after the monitored soil volume was thoroughly moistened so that soil water was easily available everywhere, initially. The zones of maximum root water uptake were the same for both stages in periods of high local rates of water application. After water applications, root water uptake occurred initially near the tree trunk and then progressed towards the root system periphery, thereby changing locations of maximum root water uptake and shifting to root zone regions with minimum soil water stress.
相似文献
| Kouman S. KoumanovEmail: Phone: +359-32-692349Fax: +359-32-670808 |
6.
A drip-irrigation module was developed and included in an ecosystem model and tested on two independent datasets, spring and
autumn, on field-grown tomato. Simulated soil evaporation correlated well with measurements for spring (2.62 mm d−1 compared to 2.60 mm d−1). Changes in soil water content were less well portrayed by the model (spring r
2 = 0.27; autumn r
2 = 0.45). More independent data is needed for further model testing in combination with developments of the spatial representation
of below-ground variables. In a fresh-water drip-irrigated system, about 30% of the incoming water was transpired, 40% was
lost as non-productive evaporative flows, and the remainder left the system as surface runoff or drainage. Simulations showed
that saline water irrigation (6 dS m−1) caused reduced transpiration, which led to higher drainage and soil evaporation, compared with fresh water. Covering the
soil with plastic mulch resulted in an increase in yield and transpiration. Finally, two different drip-irrigation discharge
rates (0.2 and 2.5 l h−1) were compared; however the simulations indicated that the discharge rate did not have any impact on the partitioning of
the incoming water to the system. The model proved to be a useful tool for evaluating the importance of specific management
options.
相似文献
| Louise KarlbergEmail: |
7.
Water tension thresholds for processing tomatoes under drip irrigation in Central Brazil 总被引:3,自引:0,他引:3
Drip irrigation has the potential to save water and mitigate foliar diseases for processing tomato production in Central Brazil.
Four experiments were carried out at Embrapa Vegetables, Brasília, Brazil, to establish irrigation management strategies during
vegetative, fruit development, and maturation growth stages of drip-irrigated processing tomato. Soil water tension (SWT)
threshold values ranging from 5 to 120 kPa were evaluated. Plants growing under higher water deficit during the vegetative
stage showed root systems up to 10 cm deeper than those irrigated more frequently. Maximum fruit yield was reached when irrigations
were performed at SWT thresholds of 35, 12, and 15 kPa during vegetative, fruit development, and maturation growth stages,
respectively. Total soluble solids content was not affected by irrigation treatments during vegetative and fruit development
stages, but increased as SWT increased during fruit maturation growth stage.
相似文献
| Waldir A. MarouelliEmail: |
8.
Laboratory evaluation of dual-frequency multisensor capacitance probes to monitor soil water and salinity 总被引:1,自引:0,他引:1
Real-time information on salinity levels and transport of fertilizers are generally missing from soil profile knowledge bases.
A dual-frequency multisensor capacitance probe (MCP) is now commercially available, for sandy soils, to simultaneously monitor
volumetric soil water content (VWC) measured as a percentage and salinity as a unitless volumetric ion content (VIC). The
objectives of this research were to assess the relationship of salinity and water content with these dual-frequency MCPs under
laboratory conditions, and assess its potential for field use in sandy soils of the mid-Atlantic region of the US. Water and
salinity studies were conducted in two sand-filled PVC columns, 1.2 m long by 0.25 m ID. Each column was instrumented with
ten dual-frequency capacitance sensors and two thermocouple temperature sensors. Four salinity levels were studied in the
two columns using 0.5, 1, 2, and 4 dSm−1 NH4NO3 solutions. Water, salinity, and temperature readings were continuously recorded at 1-min intervals. The VIC values were found
to be primarily qualitative, but combined with real-time VWC measures the probe could still be an important fertigation management
tool to provide near-continuous real-time information on fertilizer penetration, spread and subsequent changes during crop
growth.
相似文献
| J. L. StarrEmail: |
9.
Opportunities for water saving with higher yield from the system of rice intensification 总被引:1,自引:0,他引:1
The system of rice intensification (SRI) developed in Madagascar, is showing that by changing the management of rice plants,
soil, water and nutrients it can increase the yields of irrigated rice by 25–50% or more while reducing water requirements
by an equivalent percent. This gives farmers incentive to reduce their irrigation water use when growing rice, especially
since SRI methods can also reduce farmers’ costs of production which increases their net income ha−1 by even more than yield. Even though these results sound fantastic, the validity of SRI concepts and practices has been demonstrated
in more than 20 countries to date. This article considers, first, the methods that make these improvements possible and how
these are achieved. It then briefly surveys SRI experience in five Asian countries, incentives in addition to yield, water-saving
and profitability for adopting SRI, and possible limitations or disadvantages with the methodology. Next, it comments on the
debate over SRI in the agronomic literature and then adds to the empirical record by reporting in some detail on SRI evaluations
in two of India’s main rice-growing states, Andhra Pradesh and Tamil Nadu, where water availability is becoming more problematic
and where SRI use is spreading. Finally, the article briefly discusses some implications of saving irrigation water by changing
resource management rather than by using on more or different inputs.
相似文献
| Norman UphoffEmail: |
10.
《Agricultural Water Management》2004,66(2):145-151
Agricultural growers need investment and cost guidelines for drip irrigation to evaluate the economics of getting crops into production as quickly as possible and to minimise economic losses from drought during the productive life of an olive orchard. The benefits of irrigation may include; better olive survival, earlier crop production, greater yields, efficient nutrient distribution, less plant stress, reduced yield variability and improved crop quality.This research was conducted to help olive growers make decisions regarding investments in drip irrigation systems. This analysis was aimed at the farm business level to provide an economic rationale for investing in drip irrigation systems.The net present value (NPV) criterion was used to determine the discounted break-even investment results from published responses to drip irrigation systems. Growers with typical drip irrigation systems can expect investments of US$ 2244 ha−1 with 1.6 ha blocks of olives. Analysis of survey findings indicate that net present value was US$ 3464 ha−1 after an initial investment of US$ 2244 ha−1. 相似文献
11.
Daily evapotranspiration estimates from extrapolating instantaneous airborne remote sensing ET values 总被引:1,自引:1,他引:0
José L. Chávez Christopher M. U. Neale John H. Prueger William P. Kustas 《Irrigation Science》2008,27(1):67-81
In this study, six extrapolation methods have been compared for their ability to estimate daily crop evapotranspiration (ETd) from instantaneous latent heat flux estimates derived from digital airborne multispectral remote sensing imagery. Data used
in this study were collected during an experiment on corn and soybean fields, covering an area of approximately 12 × 22 km,
near Ames, Iowa. ETd estimation errors for all six methods and both crops varied from −5.7 ± 4.8% (MBE ± RMSE) to 26.0 ± 15.8%. Extrapolated ETd values based on the evaporative fraction (EF) method better compared to eddy covariance measured ET values. This method reported
an average corn ETd estimate error of −0.3 mm day−1, with a corresponding error standard deviation of 0.2 mm day−1, i.e., about 5.7 ± 4.8% average under prediction when compared to average ETd values derived from eddy covariance energy balance systems. A solar radiation-based ET extrapolation method performed relatively
well with ETd estimation error of 2.2 ± 10.1% for both crops. An alfalfa reference ET-based extrapolation fraction method (ETrF) yielded an overall ETd overestimation of about 4.0 ± 10.0% for both crops. It is recommended that the average daily soil heat flux not be neglected
in the calculation of ETd when utilizing method EF. These results validate the use of the airborne multispectral RS-based ET methodology for the estimation
of instantaneous ET and its extrapolation to ETd. In addition, all methods need to be further tested under a variety of vegetation surface homogeneity, crop growth stage,
environmental and climatological conditions.
相似文献
| José L. Chávez (Corresponding author)Email: |
| Christopher M. U. NealeEmail: |
| John H. PruegerEmail: |
| William P. KustasEmail: |
12.
Impact of research on water use for irrigation in Israel 总被引:1,自引:1,他引:0
Marcel Fuchs 《Irrigation Science》2007,25(4):443-445
The decrease of annual irrigation application rate observed since 1950 was reversed in 1988 as a result of a sudden increase
of the amount of treated effluents used for irrigation. Intensification of research on irrigation with effluents and marginal
water starting in 1994 resulted four years later in the renewal of the decrease of irrigation application rate.
Contribution No. 614/06 from the Agricultural Research Organization, The Volcani Center, Bet Dagan, Israel.
相似文献
| Marcel FuchsEmail: |
13.
Weighing lysimeters are the standard method for directly measuring evapotranspiration (ET). This paper discusses the construction,
installation, and performance of two (1.52 m × 1.52 m × 2.13-m deep) repacked weighing lysimeters for measuring ET of corn
and soybean in West Central Nebraska. The cost of constructing and installing each lysimeter was approximately US $12,500,
which could vary depending on the availability and cost of equipment and labor. The resolution of the lysimeters was 0.0001 mV V−1, which was limited by the data processing and storage resolution of the datalogger. This resolution was equivalent to 0.064
and 0.078 mm of ET for the north and south lysimeters, respectively. Since the percent measurement error decreases with the
magnitude of the ET measured, this resolution is adequate for measuring ET for daily and longer periods, but not for shorter
time steps. This resolution would result in measurement errors of less than 5% for measuring ET values of ≥3 mm, but the percent
error rapidly increases for lower ET values. The resolution of the lysimeters could potentially be improved by choosing a
datalogger that could process and store data with a higher resolution than the one used in this study.
相似文献
| José O. Payero (Corresponding author)Email: |
| Suat IrmakEmail: |
14.
A systematic and quantitative approach to improve water use efficiency in agriculture 总被引:6,自引:2,他引:4
As the competition for the finite water resources on earth increases due to growth in population and affluence, agriculture
is faced with intensifying pressure to improve the efficiency of water used for food production. The causes for the relatively
low water use efficiency in agriculture are numerous and complex, including environmental, biological, engineering, management,
social, and economic facets. The complexity of the problem, with its myriads of local variations, requires a comprehensive
conceptual framework of the underlying physical and biological processes as the basis to analyze the existing situation and
quantify the efficiencies, and to plan and execute improvements. This paper proposes such a framework, based on the simple
fact that the overall efficiency of any process consisting of a chain of sequential step is the product of the efficiency
(i.e., output/input ratio) of its individual component steps. In most cases of water use, a number of process chains, both
branching and merging, are involved. Means to integrate the diverging and converging chains are developed and presented as
equations. Upscaling from fields to regions and beyond are discussed. This chain of efficiencies approach is general and can
be applied to any process composed of chains of sequential steps. Here the framework is used to analyze the systems of irrigated
and dryland crop production, and animal production on rangeland. Range of plausible efficiencies of each step is presented
as tables, with values separately for the poor and for the good situation of circumstances, management and technology. Causes
of the differences in efficiency of each step, going from water delivery to soil water extraction, transpiration, photosynthesis,
and conversion to crop biomass and yield, and to animal product are briefly discussed. Sample calculations are made to demonstrate
how modest differences in the efficiencies of the component steps are manifested as large to huge differences in the overall
efficiency. Based on an equation quantifying the impact of changes in efficiency of component steps on the overall efficiency,
it is concluded that generally, it is more effective to made modest improvements in several or more steps than to concentrate
efforts to improve one or two steps. Hence, improvement efforts should be systematic and not overly concentrated on one or
two components. The potential use of the same equation as the point of departure to optimize the allocation of economic resource
among the component steps to maximize the improvement in the overall water use efficiency is elaborated on. The chain of efficiencies
framework provides the means to examine the current levels of efficiency along the pathways of agricultural water use, to
analyze where inefficiencies lie by comparing with the range of known efficiency values in the tables presented, to assess
the potential improvements that may be achieved in various parts and their impact on the overall efficiency, and to aid in
the optimal allocation of resources for improvements.
相似文献
| Theodore C. HsiaoEmail: |
15.
Economics,adoption determinants,and impacts of micro-irrigation technologies: empirical results from India 总被引:1,自引:1,他引:0
Micro-irrigation technologies are promoted for various reasons in India. Despite the reported significant economic advantages,
and the concerted support of the government and NGOs, the current micro-irrigation area in India remains an insignificant
proportion of its potential. This paper analyzes: (1) the economics of alternative micro-irrigation technologies, (2) the
determinants of adoption, (3) the poverty outreach of the different micro-irrigation systems, and (4) the sustainability implications
of micro-irrigation adoption. In line with the findings of other studies, this study indicates that micro-irrigation technologies
result in a significant productivity and economic gains. The most important determinants of micro-irrigation adoption include
access to groundwater, cropping pattern, availability of cash, and level of education, the social status and poverty status
of the farmer. Contrary to the expectations, the majority of the current adopters of low-cost micro-irrigation systems are
the better-off farmers. The study indicates that the impact of micro-irrigation systems on the sustainability of groundwater
resources depends upon the magnitude of the overall productivity gain following the shift from traditional irrigation method
to micro-irrigation system, the pattern of use of the saved water, and the type and potential number of adopters.
This study was supported by the Comprehensive Assessment of Water Management in Agriculture (CA) and IWMI-TATA Water Policy
Program.
相似文献
| R. E. NamaraEmail: |
16.
Combining remote sensing and economic analysis to support decisions that affect water productivity 总被引:2,自引:1,他引:1
P. J. G. J. Hellegers R. Soppe C. J. Perry W. G. M. Bastiaanssen 《Irrigation Science》2009,27(3):243-251
In this paper, an innovative method—that combines a technical and socio-economic analysis—is presented to assess the implications
of policy decisions on water productivity. In the technical part, the variability in crop water productivity (CWP) is analyzed
on the basis of actual water consumption and associated biomass production using the Surface Energy Balance Algorithm for
Land (SEBAL). This generates input for the socio-economic analysis, which aims to quantify the foregone economic water productivity
(EWP) of policy decisions to allocate water in a social optimal way. The basis for arguments to transfer water between categories
of users will be strengthened and be more objective when the productivity in existing and alternative uses is known. The usefulness
of such an approach is shown in the South African part of the Inkomati Basin, where according to the Water Act, water has
to be reserved for basic human needs and to protect aquatic ecosystems. The opportunity costs, in terms of foregone EWP, of
decisions to divert water away from agriculture are assessed. The results show that diverting water away from crops with a
low CWP is not always the most cost-effective way in terms of foregone EWP.
This paper is written in the framework of ‘A demonstration project in the Inkomati Basin’ (Soppe et al. 2006) funded by the ‘Partners for Water II’ program of the Dutch government.
相似文献
| P. J. G. J. HellegersEmail: |
17.
Behavior of temperature-based water stress indicators in BIOTIC-controlled irrigation 总被引:1,自引:1,他引:0
A subsurface drip irrigation study with cotton used canopy temperature to determine signals for irrigation control during 2002–2004. Timing of irrigation applications was controlled by the biologically identified optimal temperature interactive console (BIOTIC) protocol, which used stress time (ST) and a crop-specific optimum temperature to indicate water stress. ST was the cumulative daily time quantity when cotton canopy temperature exceeded 28°C. STs between 5.5 and 8.5 h in 1 h increments were irrigation signal criteria, which produced different irrigation regimes. This investigation examined the association among ST, daily average canopy temperature (T
c), canopy and air temperature difference (T
c−T
a), and the relative crop water stress index (RCWSI) including their relationship with lint yield. Number of irrigation signals decreased linearly with ST at the rate of −10.2 and −8.7 irrigations per 1 h increase of ST in 2003 and 2004. There were significant curvilinear relationships between ST and the average daily stress on days with irrigation signals and for days without irrigation signals across years. The percentage of positive daily (T
c−T
a) values increased with ST level. ST and T
c were positively related in all irrigation signal treatments with 5.5 and 6.5 h being significant in 2003 and 2004. Yield declined at the rate of 343 kg lint/ha for each 1 h increase of ST for days with irrigation signals. ST, mathematically the most simple of the canopy temperature-based parameters, provided the most consistent estimate of crop water stress and correlation with lint yield. The power of ST to characterize water stress effects on crop productivity evolves from being an integrated value of time while canopy temperature exceeds a physiologically based threshold value.
相似文献
| D. F. WanjuraEmail: Phone: +1-806-7235241Fax: +1-806-7235272 |
18.
Irrigation scheduling requires an operational means to quantify plant water stress. Remote sensing may offer quick measurements with regional coverage that cannot be achieved by current ground-based sampling techniques. This study explored the relation between variability in fine-resolution measurements of canopy temperature and crop water stress in cotton fields in Central Arizona, USA. By using both measurements and simulation models, this analysis compared the standard deviation of the canopy temperature
to the more complex and data intensive crop water stress index (CWSI). For low water stress, field
was used to quantify water deficit with some confidence. For moderately stressed crops, the
was very sensitive to variations in plant water stress and had a linear relation with field-scale CWSI. For highly stressed crops, the estimation of water stress from
is not recommended. For all applications of
one must account for variations in irrigation uniformity, field root zone water holding capacity, meteorological conditions and spatial resolution of T
c data. These sensitivities limit the operational application of
for irrigation scheduling. On the other hand,
was most sensitive to water stress in the range in which most irrigation decisions are made, thus, with some consideration of daily meteorological conditions,
could provide a relative measure of temporal variations in root zone water availability. For large irrigation districts, this may be an economical option for minimizing water use and maximizing crop yield.
相似文献
| M. P. González-DugoEmail: Phone: +34-957-016030Fax: +34-957-016043 |
19.
Water quality is one of the potential concerns associated with the development of coalbed natural gas (CBNG) in the Powder River Basin (PRB) of Wyoming and Montana. Large quantities of water (hereafter referred to as CBNG water) are being co-produced and often discharged in the process of exploring natural gas from coal seams. Use of CBNG water for irrigating croplands may be beneficial if factors associated with soil salinity and sodicity are controlled. This study evaluated effects of five water and three soil treatments applied to a mixed-hay cropland on selected soil chemical properties using a split plot design. Water treatments consisted of Piney Creek water (PC or control), direct irrigation with CBNG water (electrical conductivity or EC of 1.38 dS m−1 and sodium adsorption ratio or SAR of 24.3 mmol1/2 L−1/2) with no amendments (NT), CBNG water mixed with solution grade gypsum (G), CBNG water acidified using sulfur burner and mixed with gypsum (GSB) and CBNG water mixed with Piney Creek water (PC/CBNG). Soil treatments consisted of gypsum (G), elemental sulfur (S), combination of these two (GS) and no treatment or the control (NT). Pre (Summer 2003) and post treatment (Fall 2004) soil samples were collected to a depth of 60 cm (top three horizons: A, Bt1 and Bt2) to evaluate the effects of treatments on soil pH, EC, SAR, and sulfate (SO42−) concentrations. Comparisons between pre and post irrigation soil chemistry data indicated CBNG water with no amendments significantly increased (P ≤ 0.05) Na+ concentration within the soil profile. Plots treated with a combination of the GSB water treatment and the GS soil amendments were most effective in maintaining the low SAR values at surface soil layer. In all treatment combinations, both EC and SAR increased significantly in the top two sampling depths (A and Bt1 horizons). Further studies are required to evaluate applications of leaching fractions at the end of each irrigation season for its effectiveness at moving Na+ below the rooting zone. 相似文献
20.
Water scarcity and the high consumption of water resources in agriculture have strengthened the need to manage and optimize
irrigation systems. Among surface irrigation systems, furrow irrigation with cutback is commonly used because of its potentially
higher irrigation efficiency, lower costs and relative simplicity. The performance of this system is affected by various management
and design variables, and hence different management scenarios should be evaluated before it is applied in practice. For this
purpose, empirical functions for the performance evaluation indices are useful. This paper employs sensitivity, dimensional
and regression analyses in the development of empirical functions for application efficiency, deep percolation, runoff and
distribution uniformity. The proposed functions were evaluated using a numerical zero-inertia model and field measured data.
Coefficients of determination for E
a, D
r, R
r and U
cc were calculated to be 0.90, 0.91, 0.90 and 0.84, respectively. These values indicate that the proposed functions enable the
performance indices to be predicted satisfactorily. Values for the indices calculated using the developed dimensionless functions
showed a very good agreement with both the outputs of the zero-inertia model and values calculated from measured field data.
As the functions were general (not site and irrigation specific) and explicit, they could prove to be of practical significance
in both conventional and optimal design and management of free-draining, graded furrow irrigation systems with cutback flows.
相似文献
| M. NavabianEmail: |