1. Water Crisis of a Blue Planet
Freshwater on Earth is dwindling away too fast….

2. Where in earth all the waters are? Is the Earth not really watery?

3. The Earth indeed is WATERY!
70-75% of the
Earth's surface
is covered
with water
But this is no relief!

4. Water water everywhere not is single drop to drink!
97% of all Earth’s
water is in the
oceans
Leaving us in a FRESHWATER deficit situation!
It reminds us of what ancient mariner
Marco Polo once said
Water water everywhere not is single drop to drink!

5. We have 97% Salty Water only 3% Freshwater
Out of the 3% of the fresh water that the Earth has, 2% remains in a frozen state in glaciers and icecaps of the polar region and Greenland
2% is in
Frozen
state!
South Pole
North Pole

6. Where in Earth all the liquid freshwater are?
As evident, we are now left with just a
Meager 1% of freshwater available in liquid form
Where in Earth
all the liquid
freshwater are?

8. Summarizing pictorially

9. Comparing with a pie chart
How much of Earth's water is usable by humans?
Water usable by humans
Life on Earth is
impossible without
Groundwater !
Only this portion!
Only 0.3 % !
99.7 % UNUSABLE

10. Freshwater are available from different sources
Groundwater
29%
Lake
River
1 %
Streams
Glaciers at polar ice caps
70 % Unusable

11. What is Freshwater?
Freshwater is defined as water with less than 0.5 parts per thousand dissolved salts. Freshwater bodies include lakes and ponds, rivers, some bodies of underground water and many kinds of man-made freshwater bodies, such as canals, ditches and reservoirs. The ultimate source of freshwater is the precipitation of atmosphere in the form of rain and snow (Water Cycle)

12. Rivers contribute 0.0002% of the total freshwater
Free-flowing rivers provide several necessities. They're an important source of drinking water and irrigation for communities. They carry sediments that help create coastal wetland features such as marshes that provide habitats for many animal and plants. They also renew the supply of oxygen that fish and other aquatic life need to breathe.

14. It is estimated that the volume of groundwater comprises 30
It is estimated that the volume of groundwater comprises 30.1% of all freshwater resource on earth compared to 0.3% in surface freshwater. 1.5 billion people all over the world depend on Groundwater for drinking water

15. Groundwater exists because of A balancing act of nature called
Water Cycle

16. Groundwater
So the water on which our lives thrive are the ‘freshwater’ provided by GROUNDWATER which is so negligible [ only 0.3% of the total World Water ] in quantity and which we don’t see! These water under the ground are the Groundwater.
Amazingly, many people use groundwater but they don't even know it.

18. Groundwater serves many purposes
The main uses of ground water include:
irrigation uses
drinking water
other public uses
Supplying domestic water to people who do not receive public-supply water.
In many areas, the majority of water used for self-supplied domestic and livestock purposes come from ground-water sources.
Freshground water is used for many important purposes, with the
largest amount going toward irrigating crops.
Local city water agencies withdraw a lot of ground water for public uses, such as for delivery to homes, businesses, and industries, as well as for community uses such as firefighting, water services at public buildings, and for keeping local residents happy by keeping community swimming pools full of water.
Industries and mining facilities also used a lot of ground water.

19. Increasing Groundwater Demand
The agricultural sector is the largest user of water globally
and accounts for about 70% of the total freshwater
abstraction. Presently, industry accounts for 22% of the
global freshwater consumption. However, water consumption by industries is increasing, and likely to double over the next two decades. In fact, in high income countries, industrial water use already accounts for as much as 59% of the total fresh water consumption. The volume of water consumed per year by industry is estimated to be 1,170 km3/year by 2025.
People, especially in rural areas, are increasingly dependent on groundwater – up to 2 billion people, a third of the world’s population rely on it.

20. What is Groundwater?
97%of liquid freshwater is stored underground in aquifers within a few kilometers [mostly 2.4 kms] of the Earth’s surface almost everywhere, beneath hills, mountains, plains, and deserts.

21. Where is the groundwarer stored
Groundwater is stored in the ground in materials like gravel or sand. It's kind of like the earth is a big sponge holding all that water. Water can also move through rock formations like sandstone or through cracks in rocks.
An area that holds a lot of water, which can be pumped up with a well, is called an aquifer. Wells pump groundwater from the aquifer and then pipes deliver the water to cities, houses in the country, or to crops.

22. Water Table
Aquifer – permeable rock or sediment that transmits water in a quantity great enough to be of use.

23. The Water Table
One inch of rain on one acre of ground results in 27,192 gallons of water (~100,000 L).
Material saturated with water lies below the water table.
Materials that conduct water (are porous and permeable) are aquifers.
Materials that do not conduct water (are well-cemented, unfractured, etc.) are aquicludes or confining layers.

24. AQUIFER
Is a Geologic unit that can store and transmit enough water to be a significant water resource
 - Large volume [ in relation to the amounts being removed annually]
 - Moderately high porosity
 - Facilitate easy movement of water toward a well

25. The water in lakes, rivers, or oceans is called surface water
Groundwater and surface water sometimes trade places. Groundwater can move through the ground and into a lake or stream. Water in a lake can soak down into the ground and become groundwater.

26. Groundwater and Surface Water are not separate

27. Groundwater Moves (often very slowly)
Water infiltrating the ground is recharge.
Groundwater flowing out from the ground is discharge.

28. SPRINGS Springs Stream Low permeability layer
Springs form where groundwater is forced up and onto the surface through openings in the ground. This is caused by the differences in the slope or "hydraulic gradient" in the aquifer. As rain falls and percolates underground, it exerts pressure on the water already in the aquifer, forcing some to the surface through natural openings. Springs are classified or categorized based on the amount water discharge. For example, in USA, the largest springs like Wakulla and Silver Springs are classified as "magnitude 1" springs which means they each discharges more than 65 million gallons of water a day - the equivalent of about 1.3 million bathtubs full!
Springs
Stream
Regional
Water
Table
Low permeability layer
Groundwater is forced up onto the
The surface through openings
In the ground

30. Clay-rich sediments tend to be impermeable.
Perched Water Table
Perched aquifers are common, since the geology of the near-surface can be fairly complex. Parts of an aquifer can become perched as a result of slight variations in the clay content of sediments.
Clay-rich sediments tend to be impermeable.

31. Influent and Effluent
When groundwater flows into streams they are called effluent.
When the water table drops, streams become influent,
and water leaks from the stream bed into the ground.

32. Where does groundwater come from?
Groundwater comes from rain, snow, sleet, and hail that soaks into the ground. The water moves down into the ground because of gravity, passing between particles of soil, sand, gravel, or rock until it reaches a depth where the ground is filled, or saturated, with water. The area that is filled with water is called the saturated zone and the top of this zone is called the water table. The water table may be very near the ground's surface or it may be hundreds of feet below.

33. How water moves down and become groundwater?
Gravity: Ground water slowly moves underground, generally at a downward angle (because of gravity), and may eventually seep into streams, lakes, and oceans.
The rocks below our feet: The rock below the Earth’s surface is the bedrock. But Earth’s bedrock consists of 23 many types of rock, such as sandstone, granite, and limestone. Bedrocks have varying amounts of void spaces in them where ground water accumulates and can also become broken and fractured; creating spaces that can fill with water. Some bedrock, such as limestone, is dissolved by water — which results in large cavities that fill with water. Most of the void spaces in the rocks below the water table are filled with water. But rocks have different porosity and permeability characteristics, and water does not move around the same way in all rocks.

34. Gravity doesn’t pull water all the way to the center of the
Earth. Deep in the bedrock there are rock layers made of dense
material, such as granite, or material that water has a hard time
penetrating, such as clay. These layers may be underneath the
porous rock layers and, thus, act as a confining layer to retard
the vertical movement of water. Since it is more difficult for
the water to go any deeper, it tends to pool in the porous layers
and flow in a more horizontal direction across the aquifer
confining layer

35. The same water on Earth is in circulation
When the water around is looked at, water in streams, rivers, and lakes is seen, which is known as “surface water.”However, there is much more water stored under the ground than on the surface. In fact, some of the water seen flowing in rivers comes from seepage of ground water into river beds. Water from precipitation continually seeps into the ground to recharge the aquifers, while at the same time water from underground aquifers continually recharges rivers through seepage. The water in the apple eaten yesterday may have fallen as rain half-way around the world last year or could have been used 100 million years ago by Dinosaur to give her baby a bath!

36. Groundwater is precious, almost like Non-Renewable
Groundwater is a critical source of domestic water and industrial water. Because it is part of the limited budget of fresh (non-saline) water.
It can be viewed as a Non-renewable resource:
It is possible to withdraw it faster
than nature replenishes it through
“WATER CYCLE”

37. Pumping exceeds Replenishments
Pumping of groundwater by the world’s farmers exceeds natural replenishment by at least 160 billion cubic metres a year.
Agriculture is responsible for most of the depletion of groundwater, along with up to 70 per cent of the pollution. Both are accelerating.

38. This is becoming evident
Replenishment of Groundwater is too slow and our activities can create an imbalance in the hydrologic equation and can affect the quantity and quality of natural water resources available to current and future generations
This is becoming evident
during the recent
times
It’s a jeopardizing situation. What would happen
If all the groundwater finish up?

39. Groundwater Replenishment is too slow!
In a 100-year period, a water molecule spends 98 years in
the ocean, 20 months as ice, about 2 weeks in lakes and
rivers, and less than a week in the atmosphere.

40. Groundwater Recharge time comparison!

41. Confined and Unconfined Aquifers

42. UNSATURATED
ZONE
Water at very shallow depths might be just a few hours old; at moderate depth, it may be 100 years old; and at great depth or after having flowed long distances from places of entry, water may be several thousands of years old. Ground water is an important part of the water cycle, and is the part of rainfall that seeps down through the soil until it reaches rock material that is saturated with water. The ground above the water table may be wet to a certain degree, but it does not stay saturated. The unsaturated zone contains air and some water and support the vegetation on the Earth. The saturated zone below the water table has water filled in the tiny pores between rock particles and the cracks of the rocks.

43. Confined versus unconfined aquifers

44. Groundwater caters to almost all of our water need
Now the cocern is
Mankind and animals on Earth may face a grave
Ecological disaster
Due to rapid depletion of groundwater
The earth's water supply remains constant, but man is capable of altering the cycle of that fixed supply. Population increases, rising living standards, and industrial and economic growth have place greater demands on our natural environment. Our activities can create an imbalance in the hydrologic equation and can affect the quantity and quality of natural water resources available to current and future generations.

45. Emerging water shortages
Water crunch usually takes the form of aquifer overpumping and falling water tables. It is often not apparent. Unlike deforestation (which is observable), we come to know about falling water tables only when our wells go dry! The drilling of millions of well has pushed water withdrawals beyond recharge of many aquifers.
Rivers running dry are more visible. Some rivers even fail to reach sea! Some rivers now just trickling to sea.

46. Concerns Groundwater is scarce. Supply is limited.
Earth is overpopulating
Over-pumping of groundwater
due to overpopulation
- Groundwater exhausted places give rise to ‘Water Refugees’
- Croplands become barren when there is no more water left beneath
Groundwater supply is dependent on
‘Water Cycle’
- Deep aquifers are not historically rechargeable
Pollution of Groundwater

48. Earth cannot progress blindly
Overpumping
With traditional animal or human powered water lifting devices it was almost impossible historically to deplete aquifers. But with worldwide spread of powerful diesel and electric pumps during the last half century, overpumping has become a commonplace
Industrial progress has the
price to pay!
Earth cannot progress blindly

49. Falling Water Table
As the world demand for water has climbed, water tables have fallen in scores of countries, including China, India, and United States, which together produce nearly half of the world’s grain. Water tables are falling throughout the northern half of China. As the water table falls, springs and rivers go dry, lakes disappear, and wells dry up. Northern China is literally drying out.
In India also as the farmers try to feed an additional 16 million people each year, nearly the population equivalent of Australia, they are pumping more and more groundwater. This is dropping water tables in states that together contain a majority of India’s 1 billion people.

50. Water Table Water trapped under ground above an impermeable material
Located between the capillary fringe and the zone of saturation.
Zone of aeration is above where air can enter the pore spaces
Zone of saturation is
Where the rock is filled
With water

51. Cone of Depression

52. Effect of Groundwater Pumping

53. A researcher from IIT-Delhi claims that India had breached it water security level way back in by overexploiting the water resource

54. Drilling of wells for groundwater extraction

55. Groundwater Depletion in India
The latest data indicates that under Punjab and Haryana, water tables are falling by up to a meter per year.
The data for monitored wells in northern Gujarat suggest that the water table has fallen from a depth of 15 meters to 400 meters over the last 3 decades. At this point, the harvests of wheat and rice, India’s principal food grains, are still increasing. But within next few years, the loss of irrigation water could override technological progress and start shrinking the harvest, as it is already doing in China.

56. Groundwater Pollution

57. Groundwater pollution is difficult to clean up
Groundwater can become polluted, or contaminated. It can become polluted from leaky underground tanks that store petroleum products, leaky landfills, or when people apply too much fertilizer or pesticides on their fields or lawns. When pollutants leak, spill, or are carelessly dumped on the ground they can move through the soil.
Because it is deep in the ground, groundwater pollution is generally difficult and expensive to clean up. Sometimes people have to find new places to dig a well because their own became contaminated

58. Groundwater Pollution

59. Pollution in Water
When pollutants enter the ground, they spread out in the groundwater.
If there is no movement of the groundwater, they disperse evenly in all directions.
Thought provoking question:
How can pollution move in water and how does pollution get into the water?

60. Sewage Contamination
Sunita Narain of the Centre for Science and Environment in India argues convincingly that a water-based disposal system with sewage treatment facilities is neither environmentally nor economically viable for India. An Indian family of 5, producing 250 litres of exrement in a year and using a water toilet, requires 150,000 litres of water to wash away the wastes.
As currently designed, India’s sewer system is actually a pathogen-dispersal system. It takes a small quantity of contaminated material and use it to make vast quantities of groundwater unfit for human use, often simply discharging it into nearby rivers or streams

61. Contaminant Flow

62. Sewage
contamination

63. Salt Water Intrusion
One consequence of overpumping in coastal regions is the encroachment of saline seawater into fresh aquifers.
To combat this, many coastal communities re-inject wastewater into coastal aquifers.

64. Fresh Groundwater contaminated by Saline water near coastal region

65. Rising sea level due to Global Warming will salinate more groundwater

66. Groundwater is exploited more because -
Groundwater is available throughout the year (when not depleted), including during the dry season enabling farmers to double crop their land.
Productivity of groundwater is found to be more than surface water [ Yields of food grains in Punjab for land irrigated with water from wells was 5.5 tons per hectare, whereas, yield with water from canals averaged 3.2 tons per hectare

67. Farmers losing to Cities
Water Refugees!
It takes 1000 tons of water to grow 1 ton of wheat, it takes only 14 tons to make 1 ton of steel.

68. Increased Cost of Supply
As per Geological Environmental Monitoring Institute (GEMI) in Beijing, reported that under Hebei Province in the heart of North China Plain, the average level of the deep aquifer dropped 2.9 meters [nearly 10 feet] in Deep wells [ drilled ] around Beijing now have to reach 1,000 meters to tap fresh water, adding dramatically to the cost of supply.

69. Decline in Grain Production
Falling water tables, combined with reduced government grain support prices and the loss of farm labour in provinces of China that are rapidly industrializing, are shrinking China’s Grain Harvest. Wheat crops after peaking 123 million tons in 1997, declined to 87 million tons in 2003, a drop of nearly 30 percent

70. Groundwater demand will exceed
its supply in 2025
More than one billion people on earth already lack access to fresh drinking water. If current trend persists, by 2025, the demand for freshwater is expected to rise to 56%, exceeding the amount that is currently available.

71. will reduce freshwater availability per person
Overpopulation
[ Earth’s population would be 1200 crore in 2050 ]
will reduce freshwater
availability per person
By 2000, available freshwater per person dropped to 7,800 cubic metres from 9,000 cubic metres in 1989, and is
expected to plummet to 5,100 cubic metres per person by 2025, when the global population is projected to reach 8 billion.

72. Groundwater need will increase from
54% to 70% In 2025
The world’s six billion people are already using about 54% of all the accessible freshwater contained in rivers, lakes and underground aquifers. By 2025 the human’s share will be 70%, based on the population increase.

73. Freshwater use will increase upto 90% within next 25 years..
NOT TOO LONG TOO FINISH IT UP ENTIRELY !
If per capita consumption of water resources continues to rise at its current rate, humankind could be using over 90% of all available freshwater within 25 years.

74. Water will become a scarce commodity
By 2025, according to projections, more than 2.8 billion people in 48 countries will be facing water stress or scarcity.

75. 40% of the Global Population would be water starved
By 2050, the situation would even worsen
40% of the Global Population would be water starved
By 2050, the number of water short countries soars to 54, affecting 4 billion people, or 40% of the projected global population. The worst hit areas are in the Middle East, North Africa and in sub-Saharan Africa.

76. Importance of Groundwater in World Water Turnover
Every year the water turnover on Earth involves 577,000 km3
of water. It is the water that evaporates from the oceanic surface
(502,800 km3) and from land (74,200 km3). The same water
amount falls as atmospheric precipitation (on the ocean 458,000
km3 and on land 119,000 km3). The difference between
precipitation and evaporation from land surface (119,000 -
74,200 = 44,800 km3/year) represents the total runoff of Earth’s
rivers (42,600 km3/year), and a direct groundwater runoff to
the ocean (2200 km3/year). Base flow for major rivers such as
the Mississippi, Niger, and Yangtze comes from groundwater
sources.
TRIVIA !
If all the water vapours in the atmosphere fall to the ground
as PRECIPITATION at once, the Earth would
be covered with only about 2.54 cms of water!

77. How to fight back the shortage of Groundwater?
Stabilizing world population
Raising land productivity
Raising water storage capacity
Realistic Pricing of water to discourage wastage and
encourage efficient water use
To decide judiciously on ‘Surface water’ and ‘groundwater’ usage
In India 44 million hectares irrigated by SURFACE WATER and 42
Millions hectares irrigated by GROUNDWATER.
Reducing seepage from irrigation canals
Using of low-pressure close to surface sprinklers
Employing ‘drip irrigation’ where water is supplied directly to root
zone of plants and thereby reducing water usage
Rainwater harvesting at local level
Managing waste without discharging it into local environment and
Allowing water to be recycled indefinitely
Use of waterless composting toilet

78. Employing Wastage Reduction Techniques
Just on way to our office, we can see the construction of a new concrete Canal which would probably replace the old canal where water meant for irrigation gets seeped down. The concrete canal would prevent that wastage.

79. Anna Hazare’s Effort
Ralegaon Siddhi is a village in Parner Taluka of Ahmednagar District , Maharashtra, India. It is considered a model of environmental conservation. Since 1975, led by Anna Hazare, the village has carried out programs like
tree planting
terracing to reduce soil erosion and
digging canals to retain rainwater.
Fixing tank
In 1975 the village was afflicted by drought. The village tank could not hold water as the embankment dam wall leaked. Work began with the percolation tank construction. Once this was fixed, the seven wells below filled with water in the summer for the first time.
Now the village has water year round, as well as a grain bank, a milk bank, and a school. There is no longer any poverty.

80. Rainwater Harvesting
Rainwater harvesting is the gathering, or accumulating and storing, of rainwater.
Traditionally, rainwater harvesting has been practiced in arid and semi-arid areas, and has provided drinking water, domestic water, water for livestock, water for small irrigation and a way to replenish ground water levels.
Arvari river is a small river in Rajasthan. It flows through the Alwar District of Rajasthan.
Due to Water harvesting methods, the river has become a perennial river from seasonal one

81. Rajendra Singh’s effort
Rajendra Singh is a well known water conservationist from Alwar, Rajasthan in India. He won the Ramon Magsaysay Award for community leadership in 2001 for his pioneering work in water management. He is the founder of an NGO called Tarun Bharat Sangh. The NGO has been instrumental in fighting the slow bureaucracy and has helped villagers take charge of water management in their area, through the use of check dams and other time-tested as well as path-breaking techniques. This NGO played a vital role in reviving Arvari River

82. Check Dam

83. TRIVIA !
If all the world’s water were fit into a gallon jug, the fresh water available for us to use would equal only about one
Tablespoon!
In a five-minute shower we use 95 to 190 litres of water.
To brush our teeth we use 7.5 litres of water.

84. TRIVIA !

85. TRIVIA ! In the future wars in the Middle East will
more likely be fought
Over water than over oil ! !

86. Droughts

87. Let this not
Happen!

88. End of Slide Show
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