The increasing population has created great
pressure on food security and agricultural productivity. The rapid increase in
population is causing competition for land, water, energy, and other resources
that contribute to food production in the era of climate change. By 2050
approximately 70% more food will have to be produced to feed growing
populations, while climate change is estimated to have already reduced global
yields of maize and wheat by 3.8% and 5.5%, respectively. The continuous use of
chemical fertilizers, current farming practices, and greenhouse gas emissions
are severely affecting the climate. Present water shortage is one of the
primary world issues and according to climate change projections, it will be
more critical in the future. Since water availability and accessibility are the
most significant constraining factors for crop production, addressing this
issue is indispensable for areas affected by water scarcity. Climate change
will significantly impact agriculture by increasing water demand, limiting crop
productivity, and reducing water availability in areas where irrigation is most
needed or has a comparative advantage. Global atmospheric temperature is predicted
to rise by approximately 4C by 2080, consistent with a doubling of atmospheric
CO2 concentration.
Mean
temperatures are expected to rise at a faster rate in the upper latitudes, with
slower rates in equatorial regions. Mean temperature rise at altitude is
expected to be higher than at sea level, resulting in an intensification of
convective precipitation and acceleration of snowmelt and glacier retreat. In
response to global warming, the hydrological cycle is expected to accelerate as
rising temperatures increase the rate of evaporation from land and sea. Thus
rainfall is predicted to rise in the tropics and higher latitudes but decreases
in the already dry semi-arid to arid mid-latitudes and the interior of large
continents.
Water-scarce
areas of the world will generally become drier and hotter. Both rainfall and
temperatures are predicted to become more variable, with a consequent higher
incidence of droughts and floods, sometimes in the same place. Runoff patterns
are harder to predict as they are governed by land use as well as uncertain
changes in rainfall amounts and patterns. Substantial reductions (up to 40%) in
regional runoff have been modeled in southeastern Punjab (Multan, Bahawalpur
& DG Khan) and in other areas where annual potential evapotranspiration
exceeds rainfall. Relatively small reductions in rainfall will translate into
much larger reductions in the runoff, for example, a 5 percent fall
precipitation in southeastern Punjab will result in a 25 percent reduction in
runoff. In glacier-fed river systems, the timing of flows will change, although
mean annual runoff may be less affected. As temperature rises, the efficiency
of photosynthesis increases to a maximum and then falls, while the rate of
respiration continues to increase more or less up to the point that a plant
dies.
All
other things being equal, the productivity of vegetation thus declines once the
temperature exceeds an optimum. In general, plants are more sensitive to heat
stress at specific (early) stages of growth, (sometimes over relatively short
periods) than to seasonal average temperatures. The increased atmospheric
temperature will extend the length of the growing season in the northern
temperate zones but will reduce it almost everywhere else. Coupled with
increased rates of evapotranspiration, the potential yield, and crop water
productivity will fall. However, because yields and water productivity are now
low in many parts of the developing world, this does not necessarily mean that
they will decline in the long term. Rather, farmers will have to make agronomic
improvements to increase productivity from current levels. Increased
atmospheric concentrations of CO2 enhance photosynthetic efficiency
and reduce rates of respiration, offsetting the loss of production potential
due to temperature rise.
However,
early evidence was obtained from plant level and growth chamber experiments and
has not been corroborated by field-scale experiments; it has become clear that
all factors of production need to be optimal to realize the benefits of CO2
fertilization. Early hopes for substantial CO2 mitigation of
production losses due to global warming have been restrained. Agriculture will
also be impacted by more active storm systems, especially in the tropics, where
cyclone activity is likely to intensify in line with increasing ocean
temperatures. Evidence for this intuitive conclusion is starting to emerge.
Sea-level rise will affect drainage and water levels in coastal areas,
particularly in low-lying deltas, and may result in saline intrusion into
coastal aquifers and river estuaries. Estimates of incremental water required to
meet future demand for agricultural production under climate change vary from
40–100 percent of the extra water needed without global warming. The amount
required for irrigation from ground or surface water depends on the modeling
assumptions on the expansion of irrigated areas between 45 and 125 million ha. One
consequence of greater future water demand and likely reductions in supply is
that the emerging competition between the environment and agriculture for raw
water and consequently the matching of supply and demand is harder to
reconcile.
Conclusions
Water
is a key resource for the development of any human activity. In many countries,
the available water supply and the uneven distribution of these resources in
time and space are pressing issues. It is projected that a large share of the
world’s population, up to two-thirds, will be affected by water scarcity over
the next several decades. The availability of water for farming is an essential
condition for achieving satisfactory and profitable yields, both in terms of
unit yields and quality.
The
correlation between the expected increase in irrigation water requirements,
critical values of renewable freshwater resources, and economic water scarcity
indicate the necessity for regional policy coordination and careful water
management strategies at the national and site levels. Such policy coordination
and water management strategies could avail themselves of scientific research
that should actively involve in dealing with water scarcity.
Currently,
Bio-molecular and genetic research to find more drought-tolerant cultivars, on
water scarcity and its impact on future irrigation requirements and yield. More
investments in infrastructure development (i.e., dams and water supply pipe
networks) would help future populations to cope with the growing water demand
and where an uneven distribution of precipitation in time is expected. These
investments are especially needed in those areas affected by water scarcity.
The application of efficient water management strategies is a key element to
increase water productivity. Assessment of crop management strategies, the
improvement of irrigation systems, and irrigation schemes can lead to more
efficient and sustainable agricultural water management.
About
the Author:
Muhammad
Nazim is employed in the Department
of Agronomy, MNS-University of Agriculture Multan, Pakistan.
Prof.
Dr. Shazia Anjum is the Dean, Faculty of Sciences, The Islamia University of
Bahawalpur, Pakistan.
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