Global Warming Effects on Irrigation Development and Crop Production: A World-Wide View ()
1. Introduction
In recent years, climate change issues have become the focus of the world opinion. Early in the 1970s, scientists had put forward climate warming as a global environmental issue. In 1988 the World Meteorological Organization and the United Nations Environmental Program established “the Intergovernmental Panel on Climate Change (IPCC)” [1] [2] . In 1992, the Rio Conference on Environment and Development passed “the United Nations Framework Convention on Climate Change “(the so-called Convention on Climate Change)” which prescribed that developed countries should combat climate change and its adverse effects [3] . Moreover, the Convention declared that “responses to climate change should be coordinated with social and economic development in an integrated manner for the achievement of sustained economic growth and the eradication of poverty”. The Convention recognized that all countries, especially developing countries, needed access to resources required to achieve sustainable social and economic development (Yang, 2012) [4] . In this context, the role of Agriculture is to meet the future challenges posed by food security by increasing production while conserving natural resources.
In the past, the increased demand for food has been satisfied by the expansion of agricultural land. Today, the prospects of increasing the gross cultivated area, in both the developed and developing countries are limited by the dwindling number of economically attractive sites for new large-scale irrigation and drainage projects. Therefore, any increase in agricultural production will necessarily rely largely on a more accurate estimation of crop water requirements on the one hand, and on major improvements in the operation, management and performance of existing irrigation and drainage systems, on the other hand.
The failings of present systems and the inability to sustainably exploit surface and ground water resources can be attributed essentially to poor planning, design, systems management and development. With a population that is expected to grow from 6 billion today to at least 8 billion by the year 2025, bold measures are essential if the problems of irrigation systems and shortage of food are to be avoided.
Concerning agricultural development, most of the world’s 270 million ha of irrigated lands and 130 million ha of rain-fed lands with drainage facilities were developed on a step-by-step basis over the centuries. Many of the systems structures have aged or are deteriorating. Added to this, the systems have to withstand the pressures of changing needs, demands and social and economic evolution. Consequently, the infrastructures in most irrigated and drained areas need to be renewed or even replaced and thus redesigned and rebuilt, in order to achieve improved sustainable production. This process depends on a number of common and well-coordinated factors, such as advanced technology, environmental protection, institutional strengthening, economic and financial assessment and human resource development. Most of these factors are well known and linked to uncertainties associated with climate change, world market prices and international trade. All the above factors and constraints compel decision-makers to review the strengths and weaknesses of current trends in irrigation and drainage and rethink technology, institutional and financial patterns, research thrust and manpower policy, so that service levels and system efficiency can be improved in a sustainable manner.
2. Irrigation Development and the Global Food Challenge
To solve the above problems massive investments have been made over the last few decades by governments and individuals and a concerted effort by the International Community. The challenge was to provide enough food for 2 billion more people, while increasing domestic and industrial water demand. Different scenarios have been developed to explore a number of issues, such as the expansion of irrigated agriculture, massive increases in food production from rain-fed lands, water productivity trends and public acceptance of genetically modified crops. Opinions differ among the experts as to some of the above issues. However, there is broad consensus that irrigation can contribute substantially to increasing food production.
Today, the world’s food production comes from a cultivated area of about 1.5 billion ha, representing 12% of the total land area (Schultz and De Wrachien, 2002) [5] . About 1.1 billion ha of cultivated land have no water management systems, though this area supplies 45% of food production. At present irrigation covers 270 million ha, i.e. 18% of the world’s arable land. Overall, irrigated land contributes to 40% of agricultural output and employs about 30% of population in rural areas. It uses about 70% of water withdrawn from global river systems. About 60% of this water is used consumptively, the rest returning to the river systems. Drainage of rain-fed crops covers about 130 million ha, i.e. 9% of the world’s arable land. In about 60 million ha of the irrigated lands there is a drainage system, as well. The 130 million or so hectares of drained rainfed land produces around 15% of crop output.
2.1. Developments in Irrigation
Over the last forty years, the irrigation has been a major contributor to the growth of food and fiber supply for a global population that has more than doubled, from 3 to over 6 billion people. Global irrigated area increased by around 2% a year in the 1960s and 1970s, slowing down to around 1% in the 1980s, and lower still in the 1990s. Between 1965 and 1995 the world’s irrigated land grew from 150 to 260 million ha. Nowadays it is increasing at a very slow rate because of the significant slowdown in new investments, combined with the loss of irrigated areas due to salination and urban encroachment.
Notwithstanding these achievements, today the majority of agricultural land (1.1 billion ha) still has no water management system. In this context it is expected that 90% of the increase in food production will have to come from existing cultivated land and only 10% from conversion from other uses. In the rainfed areas with no water management systems some improvements can be achieved with water harvesting and watershed management. However, in no way can the cultivated area with no water management contribute significantly to the required increase in food production. For this reason, the share of irrigated and drained areas in food production will have to increase. This can be achieved either by installing irrigation or drainage facilities in the areas without a system or by improving and modernizing existing systems. The International Commission on Irrigation and Drainage (ICID) estimates that within the next 25 years, this process may result in a shift of the contribution to the total food production to around 30% for the areas with no water management system, 50% for the areas with an irrigation system and 20% for the rainfed areas with a drainage system (Schultz, 2002) [6] [7] . Researchers/ readers interested in in irrigation and drainage and in crop production under changing climate conditions may like to read articles quoted in [35] [37] [40] [47] .
2.2. The Global Food Challenge
As the world population continues to grow so too does the need to constantly increase the food production. Several actions are required to cope with this increasing demand. Globally, the core challenge must be to improve water productivity. Where land is limiting, yields per unit area must also be enhanced. These measures lead to two basic development directions [8] :
¨ increasing the yield frontier in those areas where present levels of production are close to their potential;
¨ closing the yield gap where considerable production gains can be achieved with current technology.
Based on the above assumptions, three models of food and irrigation water demand have been developed by non-governmental organizations for the time horizon 2025 (Plusquellec, 2002) [9] . These three models predict that present irrigated agriculture would have to increase by 15% - 22%. Moreover, water withdrawals for irrigation are also expected to increase at unprecedented rates, a major challenge considering that environmentalists argue that irrigation withdrawals should be reduced, as they have great expectations in the potential of biotechnology in agriculture.
Although the scenarios differ considerably, it is generally agreed that the world is entering the twenty-first century on the brink of a new food crisis, as ominous, but far more complex, that the famine it faced in the 1960s. Some analysts believe that what is needed is a new and “greener revolution” to increase productivity again and boost production. But the challenges are far more complex than simply producing more food, because global conditions have changed since the green revolution years.
3. Climate and Climatic Change
3.1. The Greenhouse Effect
Over the past centuries, the Earth’s climate has been changing due to a number of natural processes, such as gradual variation in solar radiation, meteorite impacts and, more importantly, sudden volcanic eruptions in which solid matter, aerosols and gases are ejected into the atmosphere. Ecosystems have adapted continuously to these natural changes in climate, and flora and fauna have evolved in response to the gradual modifications to their physical surroundings, or have become extinct.
Human beings have also been affected by and have adapted to changes in local climate, which, in general terms, have occurred very slowly. Over the past century, however, human activities have begun to affect the global climate. These effects are due not only to population growth, but also to the introduction of technologies developed to improve the standard of living. Human-induced changes have taken place much more rapidly than natural changes. The scale of current climate forcing is unprecedented and can be attributed to greenhouse gas emissions, deforestation, urbanization, and changing land use and agricultural practices. The increase in greenhouse gas emissions into the atmosphere is responsible for the increased air temperature, and this, in turn, induces changes in the different components making up the hydrological cycle such as evapotranspiration rate, intensity and frequency of precipitation, river flows, soil moisture and groundwater recharge. Mankind will certainly respond to these changing conditions by taking adaptive measures such as changing patterns in land use. However, it is difficult to predict what adaptive measures will be chosen, and their socio-economic consequences [10] -[15] .
Concern global patterns the following considerations can be drawn from analysis of the hydrologic and meteorological time series available:
・ Average global temperature rose by 0.6˚C during the 20th century [16] .
・ 1990’s was the warmest decade and 1998 the warmest year since 1861 [17] .
・ The extent of snow cover has decreased by 10% since the late 1960s [18] .
・ Average global sea level rose between 0.1 and 0.2 meters during the 20th century [19] [20] .
・ Precipitation increased by 0.5% to 1% per decade in the 20th century over the mid and high latitudes of the northern hemisphere and by between 0.2% and 0.3% per decade over the tropics (10˚N to 10˚S) [21] .
・ Precipitation decreased over much of the northern sub-tropical (10˚N to 30˚N) land areas during the 20th century by about 0.3% per decade [22] .
・ The frequency of heavy rain events increased by 2% to 4% in the mid and high latitudes of the northern hemisphere in the second half of the 20th century. This could be the result of changes in atmospheric moisture, thunderstorm activity, large-scale storm activity, etc. [23]
・ Over the 20th century land areas experiencing severe drought and wetness have increased [23] .
・ Some regions of Africa and Asia recorded an increase in the frequency and intensity of drought in the last decade [24] .
・ CO2 concentration has increased by 31% since 1750 [25] .
・ 75% of CO2 emissions is produced by fossil fuel burning, the remaining 25% by land use change especially deforestation [25] .
・ Methane CH4 has increased by 151% since 1750 and continues to increase. Fossil fuel burning, livestock, rice cultivation and landfills are responsible for emissions [26] .
・ Nitrous Oxide (N2O) has increased by 17% since 1750 and continues to increase. This gas is produced by agriculture, soils, cattle feed lots and the chemical industry [27] .
・ Stratospheric Ozone (O3) layer has been depleting since 1979 [28] .
3.2. Climate Change Scenarios
Current scientific research is focused on the enhanced greenhouse effect as the most likely cause of climate change in the short-term. Until recently, forecasts of anthropogenic climate change have been unreliable, so that scenarios of future climatic conditions have been developed to provide quantitative assessments of the hydrologic consequences in some regions and/or river basins. Scenarios are “internally-consistent pictures of a plausible future climate” (Wigley et al., 1986) [29] . These scenarios can be classified into three groups:
¨ hypothetical scenarios;
¨ climate scenarios based on General Circulation Models (GCMs) [30] ;
¨ scenarios based on reconstruction of warm periods in the past (paleoclimatic reconstruction).
The plethora of literature on this topic has been recently summarized by the Intergovernmental Panel on Climate Change [31] .
The scenarios of the second group have been widely utilized to reconstruct seasonal conditions of the change in temperature, precipitation and potential evapotraspiration at basin scale over the next century. GCMs are complex three-dimensional computer-based models of the atmospheric circulation, which provide details of changes in regional climates for any part of the Earth. Until recently, the standard approach has been to run the model with a nominal “pre-industrial” atmospheric carbon dioxide (CO2) concentration (the control run) and then to rerun the model with doubled (or sometimes quadrupled) CO2 (the perturbed run). This approach is known as “the equilibrium response prediction”. The more recent and advanced GCMs are, nowadays, able to take into account the gradual increase in the CO2 concentration through the perturbed run. However, current results are not sufficiently reliable.
4. Climate Change and Irrigation Requirements
Agriculture is a human activity that is intimately associated with climate. It is well known that the broad patterns of agricultural growth over long time scales can be explained by a combination of climatic, ecological and economic factors. Modern agriculture has progressed by weakening the downside risk of these factors through irrigation, the use of pesticides and fertilizers, the substitution of human labor with energy intensive devices, and the manipulation of genetic resources. A major concern in the understanding of the impacts of climate change is the extent to which world agriculture will be affected. Thus, in the long term, climate change is an additional problem that agriculture has to face in meeting global and national food requirements. This recognition has prompted recent advances in the coupling of global vegetation and climate models.
In the last decade, global vegetation models have been developed that include parameterizations of physiological processes such as photosynthesis, respiration, transpiration and soil water in-take (Bergengren et al.) [32] . These tools have been coupled with General Circulation Models (GCMs) and applied to both paleoclimatic and future scenarios (Doherty et al. and Levis et al. [33] [34] . The use of physiological parameterizations allows these models to include the direct effects of changing CO2 levels on primary productivity and competition, along with the crop water requirements. In the next step the estimated crop water demands could serve as input to agro-economic models which compute the irrigation water requirements (IR), defined as the amount of water that must be applied to the crop by irrigation in order to achieve optimal crop growth.
On the global scale, scenarios of future irrigation water use have been developed by Seckler et al. [35] and Alcamo et al. (2000). Alcamo et al. employed the raster-based Global Irrigation Model (GIM) [37] of Döll and Siebert (2002) [36] , with a spatial resolution of 0.50 by 0.50. This model represents one of the most advanced tools today available for exploring the impact of climate change on IR at worldwide level.
More recently, the GIM has been applied to explore the impact of climate change on the irrigation water requirements of those areas of the globe equipped for irrigation in 1995 (Döll, 2002) [36] . Estimates of long-term average climate change have been taken from two different GCMs:
¨ the Max Planck Institute for Meteorology (MPI-ECHAM4), Germany;
¨ the Hadley Centre for Climate Prediction and Research (HCCPR-CM3), UK.
The following climatic conditions have been computed:
¨ present-day long-term average climatic conditions, i.e. the climate normal 1961-1990 (baseline climate) [38] ;
¨ future long-term average climatic conditions of the 2020s and 2070s (climatic change) [39] .
For the above climatic conditions, the GIM computed both the net and gross irrigation water requirements in all 0.50 by 0.50 raster cells with irrigated areas. “Gross irrigation requirement” is the total amount of water that must be applied such that evapotraspiration may occur at the potential rate and optimum crop productivity may be achieved. Only part of the irrigated water is actually used by the plant and evapotranspirated. This amount, i.e. the difference between the potential evapotranspiration and the evapotranspiration that would occur without irrigation, represents the “net irrigation requirement” (IRnet. [40] ).
The simulations show that irrigation requirements increase in most irrigated areas north of 40˚N, by up to 30%, which is mainly due to decreased precipitation, in particular during the summer. South of this latitude, the pattern becomes complex. For most of the irrigated areas of the arid northern part of Africa and the Middle East, IRnet diminishes. In Egypt, a decrease of about 50% in the southern part is accompanied by an increase of about 50% in the central part [41] . In central India, baseline IRnet values of 250 - 350 mm are expected to more than double by the 2020s [42] . In large parts of China the impact of climate change is negligible (less than 5%), with decreases in northern China, as precipitation is assumed to increase [43] . When the cell-specific net irrigation requirements are summed up over the world regions, increases and decreases of the cell values caused by climate change almost average out, increasing by 3.3% in the 2020s and by 5.5% in the 2070s [5] [40] (Table 1). Climate Change and Water Availability.
Table 1. The simulations also show that in areas equipped for irrigation in 1995 IRnet is likely to increase in 66% of these areas by the 2020s and in 62% by the 2070s.
Irrigated areas of 1995, under 1961-1990 average observed climate (“baseline”), and scaled with MPI-ECHAM4 or HCCPR-CM3 climate change scenarios for 2020-2029 (“2020s”) and 2070-2090 (“2070s”).
In order to assess the problem of water scarcity, the appropriate averaging units are not world regions but river basins.
Climate predictions from four state-of-the-art General Circulation Models were used to assess the hydrologic sensitivity to climate change of nine large, continental river basins (Nijssen et al., 2001). The river basins were selected on the basis of the desire to represent a range of geographic and climatic conditions. Four models have been used:
¨ the Hadley Centre for Climate Prediction and Research (HCCPR-CM2), UK;
¨ the Hadley Centre for Climate Prediction and Research (HCCPR-CM3), UK;
¨ the Max Planck Institute for Meteorology (MPI-ECHAM4), Germany;
¨ the Department of Energy (DOE-PCM3), USA.
All predicted transient climate response to changing greenhouse gas concentrations and incorporated modern land surface parameterizations. The transient emission scenarios differ slightly from one model to another, partly because they represent greenhouse gas chemistry differently.
Changes in basin-wide, mean annual temperature and precipitation were computed for three decades in the transient climate model runs (2025, 2045 and 2095) and hydrologic model simulations were performed for decades centered on 2025 and 2045 [43] .
The main conclusions are summarized below.
¨ All models predict a warming for all nine basins, but the amount of warming varies widely between the models, especially for the longer time horizon. The greatest warming is predicted to occur during the winter months in the highest latitudes [44] . Precipitation generally increases for the northern basins, but the signal is mixed for basins in the mid-latitudes and tropics, although on average slight precipitation increases are predicted [45] .
¨ The largest changes in hydrological cycle are predicted for the snow-dominated basins of mid to higher latitudes, as a result of the greater amount of warming that is predicted for these regions. The presence or absence of snow fundamentally changes the water balance, due to the fact that water stored as snow during the winter does not become available for runoff or evapotranspiration until the following spring’s melt period [45] .
¨ Globally, the hydrological response predicted for most of the basins in response to the GCMs predictions is a reduction in annual stream flow in the tropical and mid-latitudes. In contrast, high-latitude basins tend to show an increase in annual runoff, because most of the predicted increase in precipitation occurs during the winter, when the available energy is insufficient for an increase in evaporation. Instead, water is stored as snow and contributes to stream flow during the subsequent melt period [45] .
5. Planning and Design of Irrigation Systems under Climate Change
Uncertainties as to how the climate will change and how irrigation systems will have to adapt to these changes, are challenges that planners and designers will have to cope with. In view of these uncertainties, planners and designers need guidance as to when the prospect of climate change should be embodied and factored into the planning and design process (De Wrachien and Feddes, 2004) [46] . An initial question is whether, based on GCM results or other analyses, there is reason to expect that a region’s climate is likely to change significantly during the life of a system. If significant climate change is thought to be likely, the next question is whether there is a basis for forming an expectation about the likelihood and nature of the change and its impacts on the infrastructures [47] .
The suitability and robustness of an infrastructure can be assessed either by running “what if scenarios” that incorporate alternative climates or through synthetic hydrology by translating apparent trends into enhanced persistence [46] .
When there are grounds for formulating reasonable expectations about the likelihood of climate changes, the relevance of these changes will depend on the nature of the project under consideration. Climate changes that are likely to occur several decades from now will have little relevance for decisions involving infrastructure development or incremental expansion of existing facilities’ capacity. Under these circumstances planners and designers should evaluate the options under one or more climate change scenario to determine the impacts on the project’s net benefits. If the climate significantly alters the net benefits, the costs of proceeding with a decision assuming no change can be estimated. If these costs are significant, a decision tree can be constructed for evaluating the alternatives under two or more climate scenarios (Hobbs et al., 1997) [48] .
Delaying an expensive and irreversible project may be a competitive option, especially in view of the prospect that the delay will result in a better understanding as to how the climate is likely to change and impact the effectiveness and performance of the infrastructure [46] .
Aside from the climate change issue, the high costs of and limited opportunities for developing new large scale projects, have led to a shift away from the traditional, fairly inflexible planning principles and design criteria for meeting changing water needs and coping with hydrological variability and uncertainty. Efficient, flexible works designed for current climatic trends would be expected to perform efficiently under different environmental conditions. Thus, institutional flexibility that might complement or substitute infrastructure investments is likely to play an important role in irrigation development under the prospect of global climatic change. Frederick et al. (1997) proposed a five-step planning and design process for water resource systems, for coping with uncertain climate and hydrologic events, and potentially suitable for the development of large irrigation schemes [49] .
If climate change is recognized as a major planning issue (first step), the second step in the process would consist of predicting the impacts of climate change on the region’s irrigated area. The third step involves the formulation of alternative plans, consisting of a system of structural and/or non-structural measures and hedging strategies that address, among other concerns, the projected consequences of climate change. Non-structural measures that might be considered include modification of management practices, regulatory and pricing policies. Evaluation of the alternatives, in the fourth step, would be based on the most likely conditions expected to exist in the future with and without the plan [50] . The final step in the process involves comparing the alternatives and selecting a recommended development plan. Here in the authors have cited some sample plans by various governemnts [47] -[99] . We have listed a reference [79] , to find the proper names for various countries. If the reader likes to find a climate action plan for his country of interest, just go to google.com and type in or search for climate action for country of your interest. We have cited climate action plans proposed by few countries like USA, India, China, and Europen contintent.
The planning and design process needs to be sufficiently flexible to incorporate consideration of and responses to many possible climate impacts. Introducing the potential impacts of and appropriate responses to climate change in planning and design of irrigation systems can be both expensive and time consuming. The main factors that might influence the worth of incorporating climate change into the analysis are the level of planning (local, national, international), the reliability of GCMs, the hydrologic conditions, the time horizon of the plan or life of the project [94] [95] .
6. Concluding Remarks
¨ Agriculture will have to meet the future challenges posed by food security by increasing production while conserving natural resources.
¨ With a population that is expected to grow from 6 billion today to at least 8 billion by the year 2025 [100] [101] , bold measures are essential if the problems of irrigation systems and shortage of food are to be avoided.
¨ Different scenarios have been developed to explore a number of issues, such as the expansion of irrigated agriculture, massive increases in food production from rainfed lands and water productivity trends. Opinions differ among experts as to some of the above issues. However, there is broad consensus that irrigation can contribute substantially to increasing food production in the years to come.
¨ Most of the world’s irrigation systems were developed on a step-by-step basis over the centuries and were designed for a long life (50 years or more), on the assumption that climatic conditions would not change. This will not be so in the future, due to global warming and the greenhouse effect. Therefore, engineers and decision-makers need to systematically review planning principles, design criteria, operating rules, contingency plans and water management policies.
¨ Uncertainties as to how the climate will change and how irrigation systems will have to adapt to these changes are issues that water authorities are compelled to address. The challenge is to identify short-term strategies to cope with long-term uncertainties. The question is not what the best course for a project is over the next fifty years or more, but rather, what is the best direction for the next few years, knowing that a prudent hedging strategy will allow time to learn and change course.
¨ The planning and design process needs to be sufficiently flexible to incorporate consideration of and responses to many possible climate impacts. The main factors that will influence the worth of incorporating climate change into the process are the level of planning, the reliability of the forecasting models, the hydrological conditions and the time horizon of the plan or the life of the project.
The development of a comprehensive approach that integrates all these factors into irrigation project selection requires further research on the processes governing climate changes, the impacts of increased atmospheric carbon dioxide on vegetation and runoff, the effect of climate variables on crop water requirements and the impacts of climate on infrastructure performance.
Acknowledgements
Heartfelt acknowlegements to all the authors, cited in this global warming review article. Because of the enormous challenge that our human race is going through in this 21st century, we the authors of this article, took liberty to share the knowledge and findings and plans that many of you have posted on the web sites. I hope we all scientists of diffrent countries share our know how in advance before we face the worst scenerios of human, plants and nature suffering due to our own negligence or unawareness.