रविवार, 31 अगस्त 2008

Re-engineering Water Systems


There is much turbulence in India’s water economy, with the Kosi river breaching its embankment upstream in Nepal. The consequent disastrous flooding, widespread displacement and sheer misery of the affected do require long-term solutions beyond immediate relief measures. What’s needed are innovative institutional mechanisms, proactive policy and vision to develop, maintain and manage our water systems, termed hydraulic infrastructure.

The way ahead is a more holistic approach to tackle the myriad issues involved in water infrastructure, be it flood control, irrigation or hydroelectricity. And this would necessarily involve investment in water storage capacity and the like upstream, in Nepal. Now, it is notable that corporate entities such as the GMR group is setting up the 300 mw Upper Karnali project there. Others, such as the state-owned Satlej Jal Vidyut Nigam is promoting the 402 mw Arun III project. Also PTC, which is into power trading, has reportedly inked agreement to evacuate hydropower from two other projects in Nepal.

But what’s desirable is a corporate body labelled, say, Nepal-India Water Authority (Niwa), that is able to co-ordinate, manage and refurbish hydraulic infrastructure in the region. The potential is huge. It could be argued that dam projects, especially in the plains, tend not to take into account such externalities as social costs. But the fact remains that the Himalayan hydropower sites, with high gradient, seen from an economic, social or environmental perspective, are among the “most benign in the world,” as is generally agreed.


It is true that negotiating the vexed political economy of water systems management can be daunting indeed, even pan-India, leave alone cross-border institutional arrangements. Note that sometime ago, the minister for water resources wryly remarked that he was really the minister for water conflicts! Still, given the huge hyro potential of Nepal, of which at least 40,000 MW capacity is estimated to be perfectly viable, the gains from electricity sales likely ought to be attractive enough to chalk out detailed plans for co-operation, including requisite institutional design and attendant investment.

In the past, Nepal has not been very forthcoming when it comes to jointly tapping its hydro potential. The prospect of being short-changed may have been very real in the past. But with multiple power exchanges in the offing, there is likely to be much more transparency in the very process of price discovery.

Also, since it makes perfect sense to use hydropower for peaking purposes — for supply during hours of peak load in the system — it is actually an alternative to natural gas-fired plants and much more sustainable too. Hence, for purposes of policy proactivity, the price of hydroelectricity can be likewise benchmarked. Besides, the idea of an entity like Niwa would be to unlock shareholder value and be very much business-like for routine operations.

The point is that a bureaucratic, business-as-usual approach can be woefully inadequate for managing water systems in the Indo-Nepal border, as the Kosi breach at Kusaha has shown. The site is close to the Bhimnagar barrage on the Kosi, which is itself on a 199-year lease to New Delhi. Reports say that the central water resources ministry did get into correspondence with the civil engineering authorities in north Bihar, instructing the latter to strengthen embankments for the flood season.

Along with routine maintenance of the civil works, what’s surely needed is silt removal in rivers, afforestation, and generally speaking, a more holistic approach to flood control. Which is why a more permanent institutional setting, Niwa, would better concretise matters.

The plain fact is that India needs a lot more water infrastructure. Take storage capacity, for instance. We can barely store 30 days of rainfall, which is only a small fraction of that in the major river basins abroad. It has meant lowly per capita water storage. Given the real possibility of increased glacial melting in the Himalayas, and heightened variability of rainfall in large parts of the subcontinent, greater focus on hydraulic infrastructure would pay rich dividends.

The idea ought to be to tap the capital market for funds, and not merely rely on budgetary resources. The prime minister has rightly called for a setup like the Tennessee Valley Authority for the Brahmaputra. In parallel, we do need similar major water infrastructure, complete with modern management approaches for natural resources in the Indo-Nepal region. The objective ought to be to make water very much a stimulus for growth.

Ultimately though, for the benefits of water development to gush down, not just storage capacity is required but also conveyance (read canals) and participatory management. Actually, overinvestment in storage and underinvestment in conveyance and management of water systems can be doubly distorting. It’s all the more reason for a more broad-based policy approach on water, specifically and including Indo-Nepal.

Corporation to appoint consultant for 24-hour water supply

K.V. Prasad
— File Photo: K. Ananthan

‘Anytime water’: A view of the Pilloor Dam

Coimbatore: The Coimbatore Corporation is set to appoint a consultant to study the feasibility of 24-hour supply of drinking water in the city.

After a hazy picture for some months after the proposal was made, things seem to be getting clear now with the Corporation Council clearing the bid of a Chennai-based consultant for preparing a detailed project report.

The Corporation’s ambitious move for 24-hour supply hinges on the implementation of the Rs.113-crore Pilloor Phase II drinking water scheme under the Central Government’s infrastructure development programme - Jawaharlal Nehru National Urban Renewal Mission. The Corporation is pushing hard to get the project going after a delay of 10 years.

According to the Corporation, 125 million litres of drinking water a day from the Pilloor Dam, and another 75 million litres from the existing Siruvani scheme, will enable the Corporation to make the 24-hour supply that the mission mandates. One of the conditions for funding water schemes is that the local body concerned should ensure uninterrupted supply of drinking water.

After the feasibility study is done, the next stage is a 24-hour trial supply in 15 wards. With the Council giving the clearance, the Corporation seems to have moved closer to implementation. Apart from the main water scheme, the Corporation has to draw up a separate one for internal distribution that will facilitate 24-hour supply. The main project is to bring water only up to the city. ‘We need 10 to 20 more overhead tanks within the city to take care of the internal distribution. The existing main storage reservoirs are not sufficient,’ Mayor R. Venkatachalam says.

The Council’s clearance is very significant because there is no point in staggering supply despite having three drinking water schemes. ‘Our objective is ‘anytime water’ for the people in the city. No one’s daily routine should be disrupted by staggered or erratic supply schedule,’ he says.

Ten Commandments Of Healthy Living


Water is the best therapy for a glowing, youthful skin. Imagine sucking out the water from a tomato, the tomato is dried up and wrinkles. Same goes for the skin;

Written by Kathy Emiko

Thou shall drink at least eight glasses of water a day

“Your body is about 70 percent water; your muscles are about 75 percent water; your brain cells are about 85 percent water; even your bones are approximately 25 percent water. Water, is the most foundational aspect of health.”
– Princess Kathy Emiko


Water is the single most important nutrient for our bodies. It is involved in every function of our bodies; you can live five to seven weeks without food, but the average adult can last no more than five days without water.
Many people never drink water. Some don’t like the taste of water or they were never taught the importance of drinking it. Maybe, they were brought up drinking juice, soft drinks, milk, anything but water.

As a result, many people spend the day going from one caffeinated or sugar-based drink to another. They jump-start their morning with coffee; by midmorning they have a soda for another boost; then, drink another sweetened juice for lunch. Little do they know that all the caffeine and sugar actually steal water from their bodies, doing them more harm than good.

Water has many vital functions. It is the vehicle the body must use to flush out the waste produced in normal body functions. In weight loss, the body requires even more water to break down waste from fat. Adequate water also prevents the build up of uric acid within the body, which if excess leads to certain types of arthritis.

Being a mild laxative, water is essential for proper bowel function, activating the fibre you eat to form a bulky mass that moves through the GI tract easily and quickly. Water, first thing in the morning with a tablespoon of Apple Cider Vinegar or juice of lemon, makes a great wake-up for your system.

Water is the only liquid you consume that doesn’t require the body to work to metabolize or excrete it. The body has to work overtime to process and excrete the colourings and chemicals in sodas. Several other beverages, although fluid-based, actually remove water that is contained in the beverage itself. Many beverages such as coffee and sodas, contain tannic acid, a waste product that interferes with ion absorption and competes for excretion with the other bodily waste products such as uric acid.

Even juices do not provide the solid benefits of pure, wonderful water, since they require the body to work to process the substances they contain.
Water is essential for maintaining proper fluid balance. As you avoid excess salt, take in adequate protein and increase your water intake and your kidney function will increase. This three-point approach, releases excess stores of water, much like priming a pump.

Water is the natural diuretic. Water is essential for maintaining muscle tone, allowing muscle to contract naturally, thus preventing dehydration. Water also works to keep the skin healthy and resilient.

I am often asked, "How much water do I need?" My answer is always the same: eight to ten glasses each day. As you begin to meet this need by drinking more water, your natural taste for it will increase. As you learn what water does for your body, your motivation for drinking it will grow. Water drinking is habit forming - the more you drink, the more you want!

Neglecting the most basic pillar of health, your body and mind pay a terrible price - suffering from headaches, back pain, arthritis, skin problems, digestion problems and other ailments.

Water is the best therapy for a glowing, youthful skin. Imagine sucking out the water from a tomato, the tomato is dried up and wrinkles. Same goes for the skin; when the body is denied water, there is pre-mature aging and lots of wrinkles to battle with.

Water is refreshing with an added slice of fresh lemon or Apple Cider Vinegar. Make it your best drink today!

Long-Term Solutions For Low Water


What rivers and reservoirs are telling us: Plan ahead
Great ideas — from using treated waste water for irrigation to designing buildings so they capture rain for watering the surrounding landscape — are generally ignored as cities and counties build their own buildings

The ways to solve water problems in the short term run the gamut from inconvenient to draconian, depending on how bad the problem is allowed to get. Start with restricting use voluntarily. If that's not sufficient, go to mandatory restrictions. Impose fines on those who don't fall in line and make them more and more painful as necessary to win compliance. The next step is rationing — it's extreme, but one communities out West are familiar with.

In the long run, of course, we can plan ahead to make sure our water needs are met. That requires a combination of making sure there's adequate supply and taking steps to rein in demand.

We're surrounded with reminders of why we need to plan long term, as communities take short-term measures to try to bring demand in line with diminished supply. Up in the Richmond area, low water levels in the James River have prompted water restrictions. In one county, residents can't use a sprinkler on an established lawn. James City County is looking at restricting boating and fishing at the Little Creek Reservoir, as it did last winter, because the water level has fallen so far. That's in part because the Waterworks is having to draw more from it, since the flow in the Chickahominy River — the area's main water source — is so low you'd have to go back to the World War II era to see it so bad. The Waller Mill reservoir is low, too.

Ask officials why, and they point to the weather, to longer and drier summers. If that pattern prevails, it'll have a significant impact on our water situation and ratchet up the importance of long-term solutions.

But they take time and money, lots of time and money. Newport News has already invested two decades and millions of dollars on preparing for the King William Reservoir, which will provide a secure long-term water source for the region — and we're nowhere near ready to turn the tap.

It's fair to say that the region hasn't been nearly as on the ball when it comes to managing the other side of the equation: consumption. Great ideas — from using treated waste water for irrigation to designing buildings so they capture rain for watering the surrounding landscape — are generally ignored as cities and counties build their own buildings, and decide what they'll require, or encourage, of private builders. James City displays the right spirit with a nice program of incentives to encourage residents to make choices that cut water use, from drought-tolerant plants to water-efficient dishwashers. That protects the aquifer and sends a message people need to hear more often about how to tamp down demand. But the county doesn't have much company, and a lot of potential for water savings is left unexplored in this region.

When it comes to the supply side, there aren't a lot of options. It's easy for opponents to take pot shots at the King William Reservoir, and their doing so is one reason it's been so long in coming, but there aren't many alternatives for meeting our long-term needs. Desalination doesn't seem to be feasible on the scale we need. Ground water is a source under pressure, and James City is worrying about whether the state will allow future withdrawals at the level its growth will demand. Those longer, hotter summers sure won't help.

The ultimate solution, if supply and demand don't line up, is refusing new connections to the water system — new homes and new businesses. That is not a healthy place for a community to be, but it's a place some communities across the nation are finding themselves as they see water levels fall in their rivers, lakes and aquifers.

No one's talking about that around here. But if we don't secure our long-term supply and rein in unnecessary consumption, we might be.

सोमवार, 25 अगस्त 2008

Growing rice with center-pivot irrigation saves water, fuel

Research to be shown at MU Delta Center field day, Sept. 2
"With center-pivot irrigation, we could grow rice on fields with hills. It really opens up possibilities to other farmers who couldn't grow rice before."

Missouri

Rice is an important crop in southeastern Missouri, and a staple food for many people worldwide. Traditionally, rice is grown with flood irrigation, a method that reduces weeds but is labor-intensive, requires lots of water and limits production to areas with the right climate and soil.

Missouri is one of only six states that have the water, climate and terrain needed for commercial rice production. But researchers at the University of Missouri Delta Research Center are looking at a new way of growing rice, one that could expand rice production to places where it had been thought impossible.

Gene Stevens, Extension agronomist at the center, and MU research associate Jim Heiser, will discuss their preliminary findings at the Delta Research Center field day, Sept. 2, Portageville, Mo., in the Missouri Bootheel.

The MU researchers are experimenting with center-pivot irrigation, an overhead sprinkler system commonly used on corn and soybeans. On rice, the technique requires less labor, water and fuel than traditional rice farming.

"The main purpose of this experiment is to reduce water," Stevens said. "So far this season, we've used half the water and energy with this system compared to a traditional rice field."

Stevens and Heiser started the experiment this spring, comparing the performance of pivot-irrigated rice to a traditional flooded rice field. The pivot showed its water-saving potential after just a few weeks.

"On our flooded field, we used about 2 million gallons of water on a 6-acre field in just two-and-a-half weeks," Heiser said. "On the pivot system, we haven't even put out 1 million gallons yet and we've been watering for probably three weeks longer."

A global rice shortage and strained water resources in many rice-growing parts of the world underscore the need for an alternative rice production system, Stevens said.

"With the demand of rice in the world, and people in Asia not having enough rice, we can grow more rice in more fields with this system," he said.

The method could triple rice production in Missouri, Stevens said. "With center-pivot irrigation, we could grow rice on fields with hills. It really opens up possibilities to other farmers who couldn't grow rice before."
Missouri has about 200,000 acres of flood-irrigated rice, but expanding the crop is constrained by the sandy and silt soils that predominate in southeast Missouri, the state's rice-producing heart. Sandy soils leach water and make flooding cost-prohibitive, said Joe Henggeler, MU Extension irrigation specialist at the Delta Center.

"If you try to flood-irrigate sandy soil, it's very difficult because it's just too porous, and irrigation costs would go up significantly," he said. "You'd keep pumping water all the time, so farmers won't plant on these soils. But with a pivot, you're just applying smaller amounts of water every couple of days."
The Delta Center experiment has been set up on soil that is poor for traditional rice production. "It's very sandy and has a bad history of weed problems," Heiser said. "But we want to see what we can do under the worst circumstances, because if we can prove it to farmers under those conditions, they'll feel more comfortable trying it on their own land."

The three-year study is funded by the Missouri Department of Natural Resources. Mid-Valley Irrigation donated the center pivot.

If the project proves to be practical, it could encourage more farmers to grow rice and therefore increase the amount of rice in the food chain, Heiser said.

"A lot of farmers already have center pivots," he said. "They wouldn't have to learn a new system. They'd just have to learn to use it on rice."

मंगलवार, 19 अगस्त 2008

Environmental Pollution


The environmental problems in India are growing rapidly. The increasing economic development and a rapidly growing population that has taken the country from 300 million people in 1947 to over one billion people today is putting a strain on the environment, infrastructure, and the country’s natural resources. Industrial pollution, soil erosion, deforestation, rapid industrialization, urbanization, and land degradation are all worsening problems. Overexploitation of the country's resources be it land or water and the industrialization process has resulted in considerable environmental degradation of resources.

The skies over North India are seasonally filled with a thick soup of aerosol particles all along the southern edge of the Himalayas, streaming southward over Bangladesh and the Bay of Bengal. - NASA research findings.
The cost of environmental damage in India would shave 4 percent off of the country's gross domestic product. Lost productivity from death and disease due to environmental pollution are the primary culprits.
The government agency responsible for environmental affairs is the Ministry of Environment and Forests (MoEF). Coping with India’s industrial pollution is perhaps the agency’s top priority. MoEF recognizes the need to strike a balance between development and protecting the environment in administering and enforcing the country’s environmental laws and policies. The government heightened the Ministry’s powers with the passage of the 1986 Environment Protection Act. This act built on the 42nd amendment to India's constitution in 1976 that gave the government the right to step in and protect public health, forests, and wildlife. This amendment however had little power as it contained a clause that stated it was not enforceable by any court. India is the first country in the world to pass an amendment to its constitution ostensibly protecting the environment.

Air Pollution
There are four reasons of air pollution are - emissions from vehicles, thermal power plants, industries and refineries. The problem of indoor air pollution in rural areas and urban slums has assumed significant attention lately.
India’s environmental problems are exacerbated by its heavy reliance on coal for power generation. Coal supplies more than half of the country’s energy needs and is used for nearly three-quarters of electricity generation. While India is fortunate to have abundant reserves of coal to power economic development, the burning of this resource, especially given the high ash content of India’s coal, has come at a cost in terms of heightened public risk and environmental degradation. Reliance on coal as the major energy source has led to a nine-fold jump in carbon emissions over the past forty years. The government estimates the cost of environmental degradation has been running at 4.5% of GDP in recent years.
The low energy efficiency of power plants that burn coal is a contributing factor. India's coal plants are old and are not outfitted with the most modern pollution controls. Given the shortage of generating capacity and scarcity of public funds, these old coal-fired plants will remain in operation for sometime. Power plant modernization to improve the plant load factor, improvements in sub-transmission and distribution to cut distribution losses, and new legislation to encourage end user energy conservation were all mentioned as part of the energy efficiency effort. The government has taken steps to address its environmental problems. As of now the use of washed coal is required for all power plants.
Vehicle emissions are responsible for 70% of the country’s air pollution. The major problem with government efforts to safeguard the environment has been enforcement at the local level, not with a lack of laws. Air pollution from vehicle exhaust and industry is a worsening problem for India. Exhaust from vehicles has increased eight-fold over levels of twenty years ago; industrial pollution has risen four times over the same period. The economy has grown two and a half times over the past two decades but pollution control and civil services have not kept pace. Air quality is worst in the big cities like Kolkata, Delhi, Mumbai, Chennai, etc.
Bangalore holds the title of being the asthma capital of the country. Studies estimate that 10 per cent of Bangalore’s 60 lakh population and over 50 per cent of its children below 18 years suffer from air pollution-related ailments.
CHENNAI: Exhaust from vehicles, dust from construction debris, industrial waste, burning of municipal and garden waste are all on the rise in the city. So are respiratory diseases, including asthma. At least six of the 10 top causes of death are related to respiratory disease, says Dr D Ranganathan, director (in-charge), Institute of Thoracic Medicine.
Mumbai: Not only are levels of Suspended Particulate Matter above permissible limits in Mumbai, but the worst pollutant after vehicular emissions has grown at an alarming rate. The levels of Respirable Suspended Particulate Matter (RSPM), or dust, in Mumbai’s air have continued to increase over the past three years.
These cities are on the World Health Organization's list of top most polluted cities. Vehicle exhaust, untreated smoke, and untreated water all contribute to the problem. Continued economic growth, urbanization, and an increase in the number of vehicles, together with lax enforcement of environmental laws, will result in further increases in pollution levels. Concern with New Delhi's air quality got so bad that the Supreme Court recently stepped in and placed a limit on the number of new car registrations in the capital.
The effects of air pollution are obvious: rice crop yields in southern India are falling as brown clouds block out more and more sunlight. And the brilliant white of the famous Taj Mahal is slowly fading to a sickly yellow.

Fully 80 percent of urban waste in India ends up in the country's rivers, and unchecked urban growth across the country combined with poor government oversight means the problem is only getting worse. A growing number of bodies of water in India are unfit for human use, and in the River Ganga, holy to the country's 82 percent Hindu majority, is dying slowly due to unchecked pollution.
New Delhi's body of water is little more than a flowing garbage dump, with fully 57 percent of the city's waste finding its way to the Yamuna. It is that three billion liters of waste are pumped into Delhi's Yamuna (River Yamuna) each day. Only 55 percent of the 15 million Delhi residents are connected to the city's sewage system. The remainder flush their bath water, waste water and just about everything else down pipes and into drains, most of them empty into the Yamuna. According to the Centre for Science and Environment, between 75 and 80 percent of the river's pollution is the result of raw sewage. Combined with industrial runoff, the garbage thrown into the river and it totals over 3 billion liters of waste per day. Nearly 20 billion rupees, or almost US $500 million, has been spent on various clean up efforts.
The frothy brew is so glaring that it can be viewed on Google Earth.
Much of the river pollution problem in India comes from untreated sewage. Samples taken recently from the Ganges River near Varanasi show that levels of fecal coliform, a dangerous bacterium that comes from untreated sewage, were some 3,000 percent higher than what is considered safe for bathing.
Agara city's waste finding its way to the
River Yamuna

Groundwater exploitation
Groundwater exploitation is a serious matter of concern today and legislations and policy measures taken till date, by the state governments (water is a state subject) have not had the desired effect on the situation.
Plastic Pollution
Plastic bags, plastic thin sheets and plastic waste is also a major source of pollution.

Municipal solid waste
Municipal solid waste is solid waste generated by households, commercial establishments and offices and does not include the industrial or agricultural waste. Municipal solid waste management is more of an administrative and institutional mechanism failure problem rather than a technological one.

Greenhouse Gas Emissions
India emits the fifth most carbon of any country in the world. At 253 million metric tons, only the U.S., China, Russia, and Japan surpassed its level of carbon emissions in 1998. Carbon emissions have grown nine-fold over the past forty years. In this Industrial Age, with the ever-expanding consumption of hydrocarbon fuels and the resultant increase in carbon dioxide emissions, that greenhouse gas concentrations have reached levels causing climate change. Going forward, carbon emissions are forecast to grow 3.2% per annum until 2020. To put this in perspective, carbon emissions levels are estimated to increase by 3.9% for China and by 1.3% for the United States. India is a non-Anneand 500-odd mines awaiting approval of the Centre, the pollution would increase manifold in the x I country under the United Nations Framework Convention on Climate Change, and as such, is not required to reduce its carbon emissions. An historical summary of carbon dioxide (CO2) emissions from fossil fuel use in India is increasing rapidly and causes global warming.
All inhabitants of our planet have an equal right to the atmosphere, but the industrialized countries have greatly exceeded their fair, per-capita share of the planet’s atmospheric resources and have induced climate change. The most developed countries possess the capital, technological and human resources required for successful adaptation, while in the developing countries, a large proportion of the population is engaged in traditional farming, that is particularly vulnerable to the changes in temperature, rainfall and extreme weather events associated with climate change.
According to the UN Framework Convention on Climate Change and the Kyoto Protocol , the most industrialized countries are mainly responsible for causing climate change. Thus equity requires that they should sharply reduce their emissions in order to arrest further climate change and allow other countries access to their fair share of atmospheric resources in order to develop.
Pollution of Indian Seas
The first sophisticated Pollution Control Vessel to patrol the seas for oil spills and other environmental exigencies is likely to be ready by October, 2008, Vice Admiral Rusi Contractor, Director-General, Indian
Coast Guard, said in the 11th National Oil Spill Disaster Contingency Plan (NOSDCP) preparedness meeting on April 23, 2008. Mr. Contractor said the proposed induction of at least three specialised vessels by mid- 2009 would shorten the response time to an emergency. The Coast Guard chief highlighted the importance of enforcement of maritime laws. He said 90 per cent of trade was essentially sea-borne and substantial numbers of vessels were old and un-seaworthy or single-hull vessels and raised the risk of significant pollution of Indian waters.
He said pollution remedy measures were being thought of following the various international conventions on environmental pollution that would also include exhaust and greenhouse gas emissions from ships and energy efficiency certification. He pointed out that none of 10 accidents involving vessels during 2007 in Indian waters had resulted in an oil spill.
NASA research findings
Latest research findings by NASA and Stanford University indicate that aerosol pollution will slow down winds, impacting normal rainfall pattern in tropical countries. The unique combination of meteorology, landscape (relatively flat plains framed by the Himalayas to the north and open ocean to the south), and the large population maximize the effects of aerosol pollution in India. The skies over North India are seasonally filled with a thick soup of aerosol particles all along the southern edge of the Himalayas, streaming southward over Bangladesh and the Bay of Bengal. Most of this air pollution comes from human activities.
Accumulation of aerosol particles in the atmosphere also makes clouds last longer without releasing rain. This is because atmospheric water forms deposits on naturally occurring particles, like dust, to form clouds. But if there is pollution in the atmosphere, the water has to deposit on more particles. Thus it causes lesser rain.

The most polluted places in India
Vapi in Gujarat and Sukinda in Orrisa is among the world's top 10 most polluted places, according to the Blacksmith Institute, a New York-based nonprofit group.
Vapi : Potentially affected people: 71,000 -Pollutants: Chemicals and heavy metals due to its Industrial estates.
Sukinda: Potentially affected people: 2,600,000. -Pollutants: Hexavalent chromium due to its Chromite mines.
The most polluted cities in India
As many as 51 Indian cities have extremely high air pollution, Lucknow, Raipur, Faridabad and Ahmedabad topping the list. An environment and forest ministry report, released on September 14, 2007 has identified 51 cities that do not meet the prescribed Respirable Particulate Matter (RSPM) levels, specified under the National Ambient Air Quality Standards (NAAQS). In 2005, an Environmental Sustainability Index (ESI) placed India at 101st position among 146 countries.
Taking a cue from the finding, the Central Pollution Control Board (CPCB) formulated NAAQS and checked the air quality, which led to the revelation about air quality in leading cities.
According to the report, Gobindgarh in Punjab is the most polluted city, and Ludhiana, Raipur and Lucknow hold the next three positions. Faridabad on the outskirt of Delhi is the 10th most polluted city, followed by Agra, the city of Taj Mahal. Ahmedabad is placed 12th, Indore 16th, Delhi 22nd, Kolkata 25th, Mumbai 40th, Hyderabad 44th and Bangalore stands at 46th in the list. The Orissa town of Angul, home to National Aluminium Company (NALCO), is the 50th polluted city of the country.
Emissions of gaseous pollutants: satellite data
Scientists and researchers from around the world gathered at ESRIN, ESA’s Earth Observation Centre in Frascati, Italy, recently to discuss the contribution of satellite data in monitoring nitrogen dioxide in the atmosphere. Using nitrogen dioxide (NO2) data acquired from 1996 to 2006 by the Global Ozone Monitoring Experiment (GOME) instrument aboard ESA’s ERS-2 satellite, Nitrous oxide emissions over India is growing at an annual rate of 5.5 percent/year. The location of emission hot spots correlates well with the location of mega thermal power plants, mega cities, urban and industrial regions.
Emissions of gaseous pollutants have increased in India over the past two decades. According to Dr Sachin Ghude of the Indian Institute of Tropical Meteorology (IITM), rapid industrialization, urbanization and traffic growth are most likely responsible for the increase. Because of varying consumption patterns and growth rates, the distribution of emissions vary widely across India.
Reduce pollutions: suggestions
Reduce tax on incomes and institute a tax on pollution was a suggestion environmental crusader Al Gore had for India to tackle the issue of global warming effectively. "Reduce tax on employees and employers and put a tax on pollution.
The more carbon dioxide one emits the more he pays in taxes," said Gore in an interactive session at the India Today Conclave here on March 16, 2008. Replying to a question by Minister of State for External Affairs Anand Sharma, Gore also suggested subsidising clean energy generation instead of carbon fuels like kerosene.

Heavy Rains, Chinese Dams Lead to Flooding


Heavier than normal monsoon rain has led to severe flooding throughout Burma, especially in Karen and Mon states and along the Mekong River.

The flooding from torrential rains began the first week of August causing extensive damage to homes and displacing hundreds of people in Pa-an located on the Salween River in eastern Burma.

According to a Pa-an resident, the flooding was the worst in his lifetime. Heavy rain continued for several days, extensively disrupting transportation.

“Newly planted rice fields are covered with water and more than 100 people who lived on the bank of the Salween have taken refuge in schools building,” he said.

Communities in Moulmein and Mudon also faced torrential rains and flooding.

Trees were blown down by high winds and some homes and schools lost their roofs in the storms. Local rubber plantations and gardens were also damaged.

State media reported on Friday that a high tide of from 20.1 to 20.90 feet is expected on the Rangoon River from August 17 to 22.

Meanwhile, villagers who live near the Mekong River in Shan Sate and in several provinces in Laos and Thailand also faced severe flooding as the water level in the river rises.

A staff member of the Mekong Post, a Chiang Rai-based community media group that monitors the Mekong River area, told The Irrawaddy that flooding is affecting farmland regions in Laos and Burma.

On Thursday, Tuenjai Deetes, a Thai human rights activist and former senator, visited affected areas in Chiang Rai Province, where more than 30 villages were flooded.

Tuenjai said the flooding is a long-term concern for people living along the Mekong River which run through China, Thailand, Burma, Laos, Cambodia and Vietnam. one of the main problems, she said, is a series of river dams built by China in the past decade, according to a report on the Mekong Post Web site.

Recently in the Golden Triangle area of northern Thailand where the borders of Thailand, Burma and Laos converge, the Mekong River reached its highest level in 30 years, flooding homes and farmland.

Local residents said the Mekong flooding is increased when the dams in China open their water gates to lower the water level in the reservoirs, effecting countries downstream.

Northeastern Thailand also experienced severe flooding along the Mekong River in Nakorn Phanom Province, which borders Laos.

Rescue operations in flood-hit Punjab


Army has been called in for rescue operations in the flood-affected areas along the Sutlej River in Punjab.

Nearly 40 villages near Shahkot Lohian in Jallandhar District have submerged due to 150-feet breach in its embankments.
About 400 marooned families have been taken to safer places. The breach is being plugged on war-footing.

Due to release of more water from Bhakara Nagal Dam into the river, the bundh around the river was washed away. About 5000 acres of paddy crops have been totally damaged, official sources said.

Besides the help of Army and Police, the cooperation of NGOs and religious organisations have been sought to deal with the situation.

The district administration has assured that very soon the situation would be brought under control and the people relocated to safe places.

Meanwhile, Pakistan authorities are reported to have lodged a strong complaint with their Indian counterparts over the release of flood waters from the Sutlej River, claiming that this has damaged considerable swathes of farmland in West Punjab.

Heavy monsoon rain in Himachal Pradesh has contributed to the rising water level in rivulets and dams.

http://economictimes.indiatimes.com

We are transforming rural India: PM


Irrigation, watershed development, rain fed areas development, and flood management had received special attention.‘Our effort at increasing investment in rural areas and reducing the debt burden of farmers has turned our agricultural economy around.
Prime Minister Manmohan Singh Friday said his government was committed to ‘transforming rural India’ and the results have already begun showing with a turnaround of the agricultural economy for the first time.

Addressing the nation from the ramparts of the Red Fort as India celebrated the 61st anniversary of its independence from British rule, Manmohan Singh said he had delivered his first Independence Day address from the same platform four years ago with the commitment to give a ‘new deal to rural India.’

And this was being achieved, he said.

‘Our effort at increasing investment in rural areas and reducing the debt burden of farmers has turned our agricultural economy around. After almost a decade of stagnation especially from 1998 to 2004, investment in agriculture is increasing and there has been a revival in this area.

‘We have had record production of foodgrains, cotton and sugar in 2007-08,’ the prime minister said amid cheers from the thousands of people assembled on the rain-washed greens in front of the Red Fort in the old city.

Our farms are once again green. Our godowns are once again filling up. Our farmers are once again hopeful about their future and their welfare.’
The prime minister said that through the Rashtriya Krishi Vikas Yojana (National Agricultural Development Plan), the government was investing Rs.25,000 crore (Rs250,000 million/$6 billion) in agriculture.

He said that to provide relief to debt-distressed farmers, banks loans to the tune of about Rs.71000 crore (Rs.710,000 million/$8 billion) had been waived.

In the past four years, he said, the government had increased bank credit for agricultural sector from Rs.81,000 crore to Rs.225,000 crore and reduced the interest rates for farm loans.

And in order to improve the economic conditions of farmers the government had increased the procurement prices for food grains - 50 percent for wheat and 30 percent for paddy. The National Food Security Mission had been set up to enhance production of rice, wheat and pulses.

Irrigation, watershed development, rain fed areas development, and flood management had received special attention.

The National Rural Health Mission had been expanding public health facilities and services in rural areas.

He described the National Rural Employment Guarantee Programme as a ‘historic initiative’ that is providing minimum livelihood support to the millions of needy rural poor and was ‘aimed to soften the sharp edges of poverty’.

Saying that he had spent the first 10 years of his life in a village that had no electricity, no drinking water supply, no doctor, no roads and no phones, he said though after independence there had been considerable development in rural areas, ‘yet many of our citizens still live a life that I lived in my childhood’.
That is why when our government took over, we launched Bharat Nirman - a project to build rural infrastructure.

‘Our government is committed to transforming rural India. In these four years we have taken important initiatives. I am confident that a new and prosperous India will be built due to our efforts,’ he declared

http://www.sindhtoday.net

Soil-less Agriculture Is Expanding

By AYŞENUR BOZKURT İSTANBUL
Since the water is provided to the plants in a controlled environment, it can be utilized efficiently and waste can be avoided. Irrigation is done through an automatic process.

The concept of "soil-less agriculture" may be new for many of us, but it is important for global agriculture -- specifically for providing food for billions of people at a time when global warming and drought have reduced agricultural efficiency. With global warming, the availability of water has decreased, resulting in increasing levels of famine. Soil-less agriculture may be the solution, or at least a part of the solution, in a number of climates.

How can the agriculture industry develop without soil? Speaking with Today's Business, Professor Sermin Akıncı, a lecturer at the agriculture faculty of Sütçü İmam University in Kahramanmaraş, defines it as "a kind of agricultural production in which plants are fed through a number of materials, such as shavings, bark, compost, sand, pebbles and processed clay in organic and inorganic environments."

There are many reasons why soil-less agriculture is preferred by many farmers. Loss of soil, the problem of weeds and the excessive need for fertilizer and water can be listed as the leading reasons for switching to soil-less crops. "Since the world's rapid population growth requires meeting increasing food needs, there is a risk that soil may not be efficient enough," Akıncı notes. "This system is used in some countries that do not have normal, adequate soil for agriculture, such as Arab countries and Israel, which have many desert areas, and Japan, where the territory is inclined and stony," she adds. "Crop areas are left fallow when the soil is exhausted, but this is not a solution for top efficiency and it is neither economical nor practical." She argues that soil-less agriculture is a cultivation method that can be applied in every type of region that is not appropriate for cultivation."

In soil where the same crops are always planted, diseases and weeds may become chronic problems. The use of insecticides and herbicides to cope with such problems is harmful for consumers' health and the environment and it also presents problem for exporting crops.

Akıncı contends that with soil-less agriculture it is possible to overcome these chronic issues. "It is possible to sterilize plant food mixture and cultivation area to feed the plants, and root diseases can be prevented," she explains, adding: "Since the cultivation process is controlled carefully, the risk of a crop being attacked by harmful insects can be minimized. Soil-less agriculture provides a way to eliminate weeds and it also minimizes the need for hormones. It is a solution that does not give rise to air pollution and does not harm human health."

Many proponents of soil-less farming point out that the use of fertilizer required by normal cultivation methods causes environmental pollution, but that with soil-less agriculture it is possible that to provide sufficient nourishment without fertilizer. The limited use of fertilizer helps the process. Moreover, temperature and oxygen levels can be controlled, which also helps the nourishment process.

Because of global warming, the world's water resources are in danger. Traditional agricultural methods relying on soil waste water because the soil absorbs water after the plants use what they need and the rest goes evaporates into the air. Traditional methods use four to five times the water required in soil-less farming, industry advocates argue. Since the water is provided to the plants in a controlled environment, it can be utilized efficiently and waste can be avoided. Irrigation is done through an automatic process. The system works very well and the crops grown with this type of farming yield more fruit.

However, there are some challenges to soil-less farming. First and foremost, it requires technological investment and modern equipment. But because the revenue from these crops will be maximized, the system can pay for itself in just a few years.

Since different food mixtures are needed to cultivate different plants, farmers must be familiar with the necessary elements for replacing soil. If the mixture is made with incorrect ratios, the crops may be lost at harvest time.

In the integrated soil-less agriculture system, which reuses water over and over, there is some risk of in the early stages of crop development. If the system malfunctions, environmental pollution may result.

Akıncı says: "The sector is growing fast and becoming institutionalized, especially in cities such as İzmir, Antalya and Mersin. And more are following the suit, including Manisa, Muğla, Adana, Aydın, Kütahya, Denizli, Kahramanmaraş and Şanlıurfa."

The crop most commonly cultivated through the soil-less system is tomato, two to three times as efficient as traditional methods, particularly in winter. But pepper, aubergine, cucumber and melon can also be cultivated in this way. Of course, the method is not restricted to edible crops, and flowers such as roses, tulips and orchids can be grown.

Soil-less agriculture is expanding throughout the world, particularly in the US, Japan, Holland, England, Canada, Germany, Russia, Australia, New Zealand, South Africa, the Bahamas, Kuwait, Brazil, Poland, Singapore, Iran and the United Arab Emirates.

http://www.todayszaman.com

सोमवार, 18 अगस्त 2008

Key Findings of the TERI Report – Kala Dera


In 2004, the International Campaign Against Coca-Cola forced the company to agree to an independent assessment of its bottling operations in India.

The assessment, which only looked at six Coca-Cola bottling plants in India (out of fifty) confirmed what the communities in Kala Dera, Varanasi and other places have been saying – that the Coca-Cola company is responsible for worsening the already existing water shortages and pollution.

The assessment – conducted by TERI in India – found that Coca-Cola’s continued operations in Kala Dera “would continue to be one of the contributors to a worsening water situation and a source of stress to the communities around.”

The report made four recommendations for the Coca-Cola bottling plant in Kala Dera:

• Transport water from the nearest aquifer that may not be stressed (very difficult to find)
• Store water from low-stress seasons (may not exist!)
• Relocate the plant to a water-surplus area (very difficult to find)
• Shut down the facility

Some other key findings of the TERI assessment regarding Kala Dera:

• The Kaladera area was declared as “overexploited” by the Central Ground Water Board in 1998. Yet Coca-Cola decided to locate its bottling plant and begin operations in 2000. Why did the Coca-Cola company begin operations knowing very well that water problems already existed in Kala Dera?
• Coca-Cola refused to share the “Environmental Impact Assessment” – which looks at the impacts the bottling plant would have on the water, the environment and the community – before building the plant.
• Coca-Cola’s peak production months are in April, May and June – Coca-Cola takes the most amount water when the community has the least amount of water.
• Coca-Cola is relying heavily on rainwater harvesting to conserve water. But since the rainfall is scanty, the recharge achieved is unlikely to be meaningful.
• The TERI team visited Coca-Cola’s rainwater harvesting structures and found them to be “dilapidated.”
• The Rajasthan Water Policy, 1999, strongly advocates judicious and economically sound allocation of water resources to different sectors, with water supply for drinking as the first priority followed by irrigation, power generation, and industry sectors.
• The assessment found that Coca-Cola operated on a principle dedicated just to business continuity, and community water issues have been completely neglected.

For more information, visit www.IndiaResource.org or email info@IndiaResource.org

रविवार, 17 अगस्त 2008

Drinking water in Gaza Strip contaminated with high levels of nitrate

Source: Environmental News Network
Palestinian and German scientists have recommended to the authorities in the Gaza Strip that they take immediate measures to combat excessive nitrate levels in the drinking water. 90 per cent of their water samples were found to contain nitrate concentrations that were between two and eight times higher than the limit recommended by the World Health Organization (WHO), say the researchers from the University of Heidelberg and the Helmholtz Centre for Environmental Research (UFZ) writing in the specialist journal Science of the Total Environment.

Over the long term they recommend that the best protection would be provided by quality management for groundwater resources. Groundwater is the only source of drinking water for the majority of people living in the Gaza Strip. In babies younger than six months, nitrate can lead to methaemoglobinaemia, to diarrhoea and to acidosis. The WHO therefore recommends keeping nitrate levels to 50 milligrams per litre or less. According to unpublished research, half of the 640 infants tested were already showing signs of methaemoglobinaemia. The new Palestinian-German study confirms earlier water analyses and is the first study to pinpoint a source of the contamination. With the help of isotope analyses, the researchers were able to demonstrate that the nitrate pollution can be traced back to manure used in farming and to wastewater.

With over 2600 people per square kilometre, the Gaza Strip is one of the most densely populated areas on earth. Because of their isolation, the inhabitants of this area between the Mediterranean, Egypt and Israel are reliant on being self-sufficient. The fields are mostly fertilized with chicken and cow dung. Artificial fertilizers account for only around a quarter of the fertilizer used. Because of the area's geology and the semi-arid climate, it is fairly easy for impurities to seep down from the surface into the aquifier system. Organic fertilizers and wastewater are the main causes of the nitrate contamination in the groundwater, followed by sewage sludge and artificial fertilizers.

This was revealed by the isotope ratios of nitrogen (15N/14N) and oxygen (18O/16O) in the nitrate. Isotopes are variations of the same chemical element that have a different number of neutrons in their nuclei. 18O and 15N are stable, i.e. non-radioactive, isotopes that are heavier than 'normal' oxygen (16O) or nitrogen (14N) and can therefore be measured using a mass spectrometer. 'The lower 15N nitrogen isotope values in the sewage sludge indicate that the nitrate in the Gaza groundwater comes primarily from manure used as fertilizer,' explains Dr Karsten Osenbrück of the UFZ. Between 2001 and 2007 the scientists took water samples from 115 municipal wells and 50 private wells on seven occasions. They measured nitrate concentrations of between 31 and 452 milligrams per litre. Only 10 of the 115 municipal wells examined were found to have a nitrate level below the WHO guideline value. The situation with the private wells was equally serious: apart from three, all the wells were found to have nitrate levels that were between five and seven times higher than the WHO recommendations.

Water, water, every well


The fast depletion of groundwater can be countered effectively only by rainwater harvesting, learns Michael Patrao, after meeting Michael Sadanand Baptist, a small farmer from Chikmagalore.

Adversity can often lead to despair. But in some cases adversity can lead to innovation and invention as in the case of Michael Sadanand Baptist, a small farmer from Chikmagalore.

Baptist has a small farm of 5 acres of agriculture land five km away from Chikmagalore, where he grows arecanut and horticultural produce like sapota and mango. He sunk 28 borewells in various places in his farm, but all of them failed. He could pump very little water and that too at intervals.

But Baptist did not despair. In 2002 he adopted the conventional method of recharging borewells. He dug a 10ft x 10 ft tank and filled it with filtering materials including charcoal, sand and small granite stones. He realised that the percolation rate of water was very slow and there was overflow of water which went a waste.


Baptist then experimented with a 5 ft x 15 ft tank with only the top 2 ft of filtering material, leaving the rest of the tank space for storage and percolation of water. He was able to harvest more rainwater and as a result all his borewells got recharged with continuous flow of water when pumped.

“Since this situation gave us impetus to improve this harvesting system in the most economic and scientific manner, we took to this profession so that we could lend better services to farmers,” he says. Michael, along with his partner Vijayraj, set up the Farmland Rainwater Harvesting System which has, for the past four years, recharged over 2,000 borewells across the State, in addition to over 1,000 roof top rainwater harvesting.
Michael saw an opportunity in the water shortage faced by Karnataka. As per the recent survey conducted by the Government of Karnataka, there are more than 2.7 million borewells in the State. The water in these borewells are either declining by the day or drying up completely.

At present, the borewell depth ranges from 200 ft to 1,300 ft in the State. In Kolar, Chitradurga, Bellary and Chennagiri the borewell depth has reached more than 800 ft to 1,300 ft and in parts of Bangalore the depth has reached 1,100 ft. In spite of drilling borewells to these depths the yield in the borewell ranges from 1,500 LPH to 6,500 LPH and moreover, as the depth increases, the quality of water gets worse, besides pumping of water also costs more.

The depletion of underground water has even reached the Malnad region and people are facing water problem in peak summer. In coastal Karnataka, despite adequate rains of about 3,000 mm per annum, during summer days a number of open wells and borewells get dried up.

Rainwater is the purest form of water but when it falls on rooftop or ground, this water gets mixed with dirt particles and becomes polluted. To overcome this problem, Michael and Vijayraj with over five years of experiments and innovation came out with rainwater harvesting filters, which instantly filter the rainwater after it is collected and is an improvement over conventional filters.

The research and development of the duo’s Farmland Rainwater Harvesting System involved studying the pattern of rainfall in rural and urban India, intensity of rainfall, type of houses, pipeline used for rainwater drain outlets, reutilization, recharging of ground water and tube well. It is scientifically designed and built to give long and dependable service.

The roof top water drain pipes (down flow pipes) are joined together and connected to the inlet of rain water filter.

When the rainwater flows by gravity through the inlet of filter and enter the upper housing, it allows the rainwater to flow into the SS-304 filter element in angular motion at specific velocity, which creates cohesive force and segregates dirt particles and clean water individually. Thereby, dirt particles and waste materials are flushed out through the drain outlet, while clean rain water passes through the clean water outlet and gets into the sump, tank, well, bore well or re-charging well.

The Government Higher Primary School, Allampura, just 5 km away from Chikmagalore, is a model for how successfully rainwater filter works. Filtered water gets collected in a tank and students use it with the help of a hand pump. The project was executed under the Rural Development and Panchayat Raj.

Rainwater harvesting will soon be a must


BWSSB minister Katta Subramanya Naidu, concerned over large-scale unregulated use of groundwater, on Monday promised to issue an ordinance to enforce this Act.
BANGALORE: Ensure your building is equipped with rainwater harvesting technology in the next few months. If not, local authorities will install one for you and collect the expenses later.

These are the provisions of the Karnataka Ground Water (Regulation and Control of Development and Management) Bill 2007. It also includes establishment of the Karnataka Ground Water Authority.

Though approved by the cabinet in 2007, this Bill is yet to be placed before the legislature for approval. But BWSSB minister Katta Subramanya Naidu, concerned over large-scale unregulated use of groundwater, on Monday promised to issue an ordinance to enforce this Act.

Even though the Act is applicable to the entire state, the government is concentrating on making rainwater harvesting equipment mandatory for all new buildings — residential and commercial — in Bangalore.

Aimed at replenishing groundwater, the Act, once it becomes operational, makes it mandatory for users of groundwater through well or borewell to register with the Ground Water Authority within 120 days of its establishment.

"The campaign will start soon," Naidu said.

बुधवार, 13 अगस्त 2008

CLEAN-India


Creating awareness on water quality

Armed with test tubes, chemical reagents and a heady dose of determination, schoolchildren in Delhi and across India are waging a battle against water pollution. By wading into rivers, dipping into groundwater and tapping municipal water outlets, these children are learning about what makes their local water source safe, or not, to drink. Even more importantly, they are learning what they can do to make a difference in their communities and their environment.

In 1996, Development Alternatives (DA) launched the Community Led Environment Action Network India (CLEAN – India) after the success of the Delhi Environment Action Network (DEAN) program. The CLEAN – India program targets children by working with local schools to promote environmental awareness among the students and to foster a greater sense of stewardship for their natural resources. As the future leaders of India, these children are in the best position to influence their communities and catalyze change for the better.
Over the years, the initial group of five schools grew, and now we are working with almost forty schools in the Delhi area alone and monitoring over 150 sites across the city for water quality. Added to those numbers are the numerous schools in communities across India, such as Shillong, Faizabad, Ladakh, Bangalore, Berinag (Kumaon Hills), Jhansi, Sagar, Bilaspur, Lalitpur, Madurai, and Thiruvananthapuram.

So far, the CLEAN – India program has been a great success. The children involved in the program are enthusiastic and plans are in the works to continue expanding the program to more towns and villages across India and even in other South Asian countries. The program itself has grown beyond water quality monitoring and now includes:

water quality monitory with the jal TARA kit;
air quality monitoring with the pawan TARA kit;
water harvesting and conservation activities;
water filtration using the Slow Sand Filtration Unit;
education on vermicomposting and paper recycling;
tree planting activities;
anti-polybag, firecracker and chemical dye campaigns;
Adopt-a-slum; and
environmental audits.
Water harvesting and filtration are two of our newest projects. In cooperation with local schools, we are promoting the use of these technologies to conserve and reuse water resources. Already, three schools in Delhi have constructed underground tanks to capture unused tap water from their drinking water fountains and reuse it for gardening and other maintenance activities. Owing to the success of the project, plans exist to implement this initiative in our other CLEAN – India locations.

Similarly, we are looking to install our Slow Sand Filtration Units in schools and communities in Delhi and beyond. These Units have been developed by the TARA Environmental Monitoring Facility to naturally filter bacteria and other contaminants from the municipal water supply using a specific ratio of fine sand and pebbles. In addition to our own offices in Delhi and our field unit in Orchha, one school in the suburb of Noida has benefited from this technology. We are currently negotiating with a residential community in the Delhi area to implement the project there. Once the financial, environmental and health benefits of this system are known, we will be able to disseminate the technology over a wider area.

Gevra Checkdam, Jhansi District:

A Case Study:

The Gevera Checkdam has been providing local farmers with water for their crops since it was built in 1993-94. The benefits of the checkdam have been recognized by the farmers, who have already asked: “Can’t you make this checkdam taller ?”.
Extending the checkdam would increase its capacity and therefore, provide more water for the farmers and their families.

Economic

Since checkdams are built using local labour and materials, the capital, building and maintenance costs are kept to a minimum. Earthen embankments require little or no money to build and can be constructed using mud from the field. Masonry structures, however, need greater financial and technical inputs due to the more intensive labour and material requirements used in their construction. Nevertheless, the total cost of irrigating one hectare of land using a checkdam has been calculated at much less than the cost of doing the same with a large dam or canal networks. While a checkdam can irrigate a farmer’s field for five to eight (5-8) thousand Rupees per hectare, a large dam requires over two hundred thousand (200,000) Rupees to accomplish the same task.The much lower cost of using checkdams makes this technology more accessible to rural farmers who would otherwise be unable to afford more expensive options. This is especially beneficial in the Bundelkhand region, which has one of the highest poverty levels in India.

Environmental

The on-going debate regarding the sustainability of large-scale water development projects such as canals and dams points to the need to explore alternative options which are less disruptive to the natural and social environment. Because checkdams work on a micro level the effects they have on their environment are also more localized. Unlike large dams, checkdams flood only a small area and this sometimes for just a few months following the monsoon. Consequently, checkdams avoid the socially disruptive human displacement that occurs with the construction of larger dams.

Effects on well levels can often be seen as far as a 300m inland from the stream with consequent improvements in soil moisture levels and an increase in the irrigation potential of the area.A checkdam not only helps local farmers to increase the amount of water in their wells, but it also captures soil particles as they are washed downstream from the farmers’ fields. The nutrient-rich sediment that accumulates behind the checkdam can be used as fertilizer during the dry season when the water level drops.

The ability of checkdams to raise the depleted groundwater table has wider ranging effects for local vegetation and animal populations.The riparian zone along the checkdam is regenerated and the lush vegetation creates habitat for birds, fish, insects and other animals. Checkdams can therefore be an integral part of any watershed development scheme that incorporates both soil and water conservation and the restoration of local biodiversity.

Equitable

Since checkdams can be adapted to suit a variety of local conditions, their benefits can reach a greater portion of the population. Remote areas that are usually by-passed by large government infrastructure development programs can now enjoy access to water for only minimal financial and labour input. The low cost of building and maintaining checkdams enables even the poorest farmer, regardless of caste or social status, to benefit from access to irrigation water.

The water harvested by a checkdam is also available to other groups. Women and children benefit from access to a nearby water source for domestic needs such as cooking and washing. The time saved in fetching water can be used to pursue other income-generating activities or education opportunities, which has a long-term impact on livelihood promotion and sustainability.

Empowering and endogenous

Community input into the site selection, design and construction process fosters a greater sense of commitment in maintaining the structure and ensuring that the benefits are distributed equitably among the stakeholders. Local control of the checkdam also enables either individual farmers or community groups to optimize water and irrigation usage based on their immediate needs. By severing the dependence of these communities on large government projects, checkdams also empower these villages and individuals to take responsibility for their own livelihoods.

Why checkdams?

For such simple structures, the advantages of checkdams are many. Of all the available technologies and methods used for water harvesting, checkdams provide the most benefits in terms of overall livelihood generation and sustainability, while reducing many of the negative impacts larger projects such as dams and reservoirs can have on the social and natural environment. Due to this, checkdams are what we at DA call an Appropriate Technology.

Appropriate technologies are ones where a balance has been struck between social, economical, ecological and technical factors.

How To Construct Checkdam


You don’t have to be an engineer to understand how checkdams work. Simply put, checkdams are small earthen or masonry barriers placed across streams or nallahs that capture water as it flows downstream. The pressure created by the impounded water helps to improve infiltration and raise the local groundwater table.Full wells, along with the availability of the surface water for irrigation, benefit farmers and communities living around the checkdam long after the monsoon rains have ended.

But there is more to them than that. By helping to harvest rainwater for domestic and irrigation purposes, checkdams are also helping to improve livelihoods. A farmer who could only plant one crop per year can now grow two or three, allowing him to move from a subsistence living to one where he can sell his surplus at the market.Women too benefit from access to more water. The time saved in fetching water from distant sources is now spent pursuing other income-generating activities. A more stable income means better nutrition and education opportunities for the children and an overall improvement in the daily life of the entire family.

http://www.devalt.org

रविवार, 10 अगस्त 2008

People's school for water literacy

A private high school in Sirsi, in northern Karnataka is not stopping at imparting academic education. It has also started teaching practical water literacy to the people of five Malnad districts. The rain centre at the school, with 28 examples of rain water harvesting, opened in early June. Shree Padre reports.
This private high school, Neernalli Madhyamika Shikshanalaya at Neernalli, seven kilometres from Sirsi, district headquarters of Uttara Kannada in Karnataka will play a double role henceforth. Apart from imparting academic high school education, it will teach water literacy to the people of adjoining five Malnad districts. From early June, the school has started hosting the Malenadu Male Kendra - Kengre (MMKK), first of its kind and a one-stop information clearinghouse for rural rainwater harvesting in the country.

In and around the school there are 28 models of water conservation and RWH. Infiltration pit, contour trench, staggered trench, open well recharge, bore well recharge, gully plug, recharge through termite hills, roof water usage and educative demonstrations like measuring rain, leaky taps, tippy tap, etc., are some among them. Adjoining the playground, there is a percolation tank to which all the run-off from the former would go. The name board says that it's the 'water vessel' of the hamlet. Shivanand Kalave, a development journalist and RWH activist is the brain behind this project.

A model for ground water recharge that's popular locally. Pic: Shree Padre.

Apart from the models, MMKK includes a few real and working RWH structures that are not used for teaching. A serious student of water conservation can see many interesting structures in a half an hour drive from Neernalli. These include Johads, tanks of Sonda constructed in 8th century, a unique traditional check-dam constructed by Sheeliga community that allows the wooden logs to escape from above during rainy season.

There are many 'tell-tale' spots that can impart the lesson of afforestation, problems of monoculture, natural regeneration, how soil erosion can be checked by facilitating growth of grass all around etc. Of course, there should be an experienced guide to explain these lessons to the visitors. With Kalave around, you get many interesting insights about biodiversity, forest development, ill-effects of deforestation etc.

Kalave is an impressive communicator. He has been spreading awareness about RWH in the state since the last five to six years. His studies of the relation between forest and water and the need for biodiversity are so impressive that even forest officials invite him for slide-shows for their own staff.

"What's the size of the infiltration pit we have to dig?"
"At what distance from the well we have to dig the pit?"

"Are there any persons in our area who are harvesting rain wherefrom we can see and learn?"

"What are the filter media that we have to fill the pits with?"

Questions asked by citizens on rain water harvesting, addressed by Shivanand Kalave and the rain centre.


• The Malnad Mela
• Good news on conservation


After the RWH slide-shows, Kalave was getting many queries like: "What's the size of the infiltration pit we have to dig?", "At what distance from the well we have to dig the pit?", "Are there any persons in our area who are harvesting rain wherefrom we can see and learn?", "What are the filter media that we have to fill the pits with?" and so on. Shivanand felt that just showing the 'real' photographs in slide-shows was not enough. There should be a centre where all the models are shown from where people could 'see and learn'.

There was another development in the recent years that catalysed the dream of the rain centre into reality. Four years ago, Kengre river, 13 kms away that was supplying water to Sirsi town started drying up in summer. Municipal authorities decided to construct a big dam in Kengre river to supply water to Sirsi. This would have adversely affected the local farming community. The dam would cut off the flow going downstream. Farmers organised themselves and started vehemently protesting this. "Don't play with our livelihoods by constructing the dam here. Desilt the tanks at Sirsi, start harvesting rain there," these villagers told the municipal authorities. Many meetings, heated arguments followed. Finally proposal for the dam was withdrawn.

Awareness for self-help

Once the initial heat subsided, Kalave felt that the path of confrontation does not bring solutions. Instead, he thought, it would be better if Sirsi citizens are made aware about self-help regarding water. Consistent efforts motivated 300 families to take up open well recharging on their own. Most of the lodgings in the town are harvesting water in a big way. Thanks to Shivanand's painstaking campaign, RWH has caught up in Sirsi now.

"We dreamed of the rain centre without a penny in our pocket," recalls Shivanand. Absence of a rain centre was a bottleneck for the movement. Kalave explained his dream in December 2004 to local MP, Ananthkumar Hegde. Convinced about the concept, Hegde gave Rs.2 lakhs from his fund. Subsequently, Madyamika Shikshana Samithi, the trust that runs this school patted his back with Rs.50,000 and offering its 5-acre location to develop the rain centre. The display board and information posters were sponsored by Forest Department and the local Kanara District Co-operative Credit Society bank. It is refreshing to note that including the beneficiaries of Shivanand Kalave's RWH campaign, government departments and organisations have joined hands in making this dream into a reality.

How much rain falls on a sq.meter area? Pic: Shree Padre.

Students and teachers of this high school are now being taught to impart water literacy to visitors. Interestingly, the methods that would be shown here in relevant to whole heavy rainfall area of Malnad comprising of Uttara Kannada, Dakshina Kannada, Udupi, Chikmaglore, Kodagu and Shimoga. Shivanand cautions about the importance of water harvesting in this otherwise forested part of Karnataka. "In Malnad, there should be a tank above the arecanut gardens. A devara kadu (sacred forest) in its catchment has to support this tank by percolating the rainwater into it and protecting it from silt. Unfortunately, our betta lands (upper hillocks adjoining the gardens) have turned barren. Unless and until they develop canopy cover, our life won't be sustainable."

"The urban-rural conflict of ours clearly made us realise that we need to make serious efforts to educate our people, may they be urban or rural. After all, nobody can live without water, you see," points out M S Hegde, Chairman, MMKK. "So, we thought 'showing by doing' is the only way that will catch public attention. Our rain centre is the result of three years preparation. In the meantime, we were successful in grooming hundreds of ambassadors of RWH, who are eager to share their success with fellowmen."

The Sirsi zilla panchayat CEO S G Shivananda Moorthy has clear plans to utilise the rain centre. Says he, "We will encourage all the schools and colleges to take students teams to the centre under the leadership of one or two interested teachers. Our gram panchayat members and officials would have a clear cut idea of what RWH is by seeing all the models and taking a round in the nearby forests. Such lessons are very difficult to understand without seeing a live model. We're bringing out a monthly newsletter by name Grameena Bharatha from the district panchayat. Henceforth, we will keep one page for soil and water conservation, success stories and lessons from Malenadu Male Kendra."

V Vijay Mohan Raj, Deputy Conservator of Forests, Sirsi is happy. "We have 133 grama aranya samithis in about 100 villages. Our district Uttara Kannada has forests covering 40,000 hectares. But unfortunately, these are in very serious degradation. We have already initiated many soil and water conservation measures including construction of new johads inside the forest. For us, the rain centre is very handy to boost up the interest of farmers and to make them understand the relation between forest, soil and water. If more and more local people understand and start acting towards the conservation, it is good for our forests."

Shivanand Kalave. Pic: Shree Padre.
Shivanand says that each day, they, the water activists get so many phone calls asking how RWH can be done at their house or field. "This is really laudable because these are the persons who are ready to do it without government subsidy. At the same time, it is really ironical that just for the want of clear guidance or moral support, thousands of people are not being able to harvest rain. Our state government has to take serious note of this and if not anything else, take immediate steps for mass education in water conservation." No doubt, initiatives like this rain centre by local communities maybe one in each district, would catalyse water literacy considerably.

H2O House for real life experience

An 'H2O House' is the second stage dream of MMKK. (H20 is the chemical name of water). Elaborates Shivanand, "It will be a typical tiled Malnad house with roof water harvesting, solar lighting, grey water reuse, kitchen and all the hands on eco-friendly techniques incorporated. It will have an LCD projector, a library and meeting hall with staying facilities for 50 people. Visitors will have a real life experience in drinking rainwater and using and forming an opinion about all these simple, but sustainable systems." The estimated cost of 'H2O House' is Rs.40 lakhs. MMKK is seeking voluntary contributions by public and private organisations for this purpose. ⊕

Shree Padre

http://www.indiatogether.org

An Interview with Depinder Kapur

Country Representative of WaterAid India

Water Aid is the largest international donor agency exclusively focussed on water and Sanitation issues. Depinder Kapur, Country Representative of WaterAid India talks about Water Aid’s activities to overcome poverty by developing access to safe water, sanitation and hygiene education. More in this open and frank conversation with Mr. Kapur.

How does India’s multi-lingual, multi-ethnic character, its diversities in lifestyles, customs and the like affect your working?
More than the ethnic barriers it is the worsening livelihoods and marginalization of the rural poor, slum dwellers that we have to reckon with in our working. Lack of livelihood security leads to increased migration in rural areas, shopping malls displacing slum dwellers in cities and a general lack of hope is the biggest barrier for community participation in our projects and programs.

We have to be careful of language barriers in communication and not be overly dependent on standard communication materials and training kits.

What prompted the decision to expand your work to the northern states? Has the shift from working in the south to working in the north required any specific adaptations to your approach, tools and techniques?
We shifted focus to states where sanitation coverage was the lowest, water quality and access is a challenge and where government programs and systems have a bad reputation for efficiency and accountability. WAI work is more in the central and eastern belt of India, with very small projects. Our work in policy advocacy remains country wide and not restricted to a few states.

We have found different approaches work in different regions of India. Sanitation Fund approach does well in Orissa and Bihar but not in MP. Citizens Action work on public hearings and accountability works well in Jharkhand and Bundelkhand where there are well developed local NGO partners and networks already working on Rights issues. Community managed toilets are a new initiative in central and western India that WAI introduced in MP and Orissa, based on our learning’s from Trichy and it shows signs of early success. Therefore we have not prescribed any set tools and approaches as a standard practice.

In the last phase of our work in central and eastern India 2004-2007), we have focused on Open Defecation Free villages and slums, Infrastructure Deficiency Mapping in urban slums and city wide slums improvement, capacity building of partner NGOs and strategic partnerships with state governments, other organizations(UNH) and Municipalities. We are introducing new approaches (Citizens action, IWRM, District Wide Approach, Menstrual Hygiene and Community Based Water Quality Monitoring) and strengthening the old ones that have worked well.

We are now gearing up for partnerships that are more strategic and influencing, monitoring health outcomes beyond ODF and greater accountability through Citizens Report.

Working in the social sector is of course not about competing with other agencies doing similar activities, but each of us brings some special inputs to it. What do you see as the unique features of WAI’s initiatives?

Three unique features;
1. Commitment to community based approaches in programming (for water and sanitation in both urban and rural areas), we see community formal and informal groups (as demonstrated in Trichy and Gwalior slums community toilets) as the sustainable institutional options for water and sanitation programmes.

2. We see our role as an independent voice and a champion of greater accountability, having the advantage of program experience as well as learning, research and engagement with a majority of civil society, researchers and activists.

3. Working in partnership with other governments, organizations and civil society, to support where required, new demonstration projects and learning initiatives. We also work together, where required, with networks and organizations other than the government for policy influence and greater accountability of service providers.


After considerable lobbying, you have managed to get the government to modify its sanitation subsidies to incorporate low cost latrines. What were the issues here?
WAI has emphasized demand driven and community led approaches in our work. Sanitation Fund and community incentives are better than individual incentives of household BPL sanitation subsidy. The core issue was of people constructing toilets only when they were convinced about its need and not because there was a subsidy to avail.

Sanitation subsidies were reduced but are up again in the last one year. Now states are coming up with higher level of subsidy schemes and there is a danger of contracted out toilet constructions to reap this benefit.

While advocating for reduction in subsidy for construction (from Rs. 2,000 to Rs. 500) - WAI also advocated for,

1. Increasing the investment on hygiene promotion and behaviour change communications.

2. Supporting households with alternate financing mechanisms, like community based sanitation fund, credit, and cross subsidies in interest

3. Strengthening the community based supply chains like trained masons, locally produced materials like slabs, rings blocks etc


What are the broad mechanisms you employ in giving the rural poor a voice in water related decision making, and the challenges you have been facing there?
Water related decision making requires an understanding of the larger level water management issues, including water supply and distribution systems. Sometimes it is issues related to electricity supply that curtail water supply, tax and incentive structures, besides the technical options. In the absence of which people will not understand what is affecting their drinking water crisis and will tend to blame themselves. We work through local NGOs and capacity building technical organizations in order to forge a greater understanding on Water Quality and Integrated Water Management among the local NGO partners and communities.

Water stress and livelihood crisis in central and semi arid regions of the country, is pushing people out of agriculture. Micro and local solutions to water crisis and water quality do not work. The crisis of ground water is not being addressed by government through regulation, policy or price incentives. Some research institutions on water are also justifying the current situation by saying that nothing can be done to regulate ground water since India has many small extractors of ground water. Absence of strong mass a movement based on basic needs / issues of people, presents a major challenge in our efforts to create an environment where core issues are taken up outside Committees and Policy Groups set up by government, into the public domain.

WAI as part of its policy work is raising the issue of water quality and people centric IWRM concerns for India. In our program we are working towards community based water quality monitoring, influencing the state governments to monitor water quality more effectively and implement mitigation measures.

In partnership with various civil society networks (WASH India and other forums) for policy work with the government, including research and collaboration, WAI seeks to support pro - poor decision making. Through our knowledge dissemination work and policy influence, our focused engagement with agencies and organizations, our own initiatives of public recognition to the good work, we provide a platform for informing and influencing.

We support our partners and other civil society organizations and even state governments, municipalities and gram panchayats – with the lessons learned from not only our work but also from the good work done by others – to be in a better position, in order to be more effective in supporting a people’s agenda for change in the water and sanitation sector.

WAI works in several countries. Are you able to bring a common approach to your work across countries or do you find the specificities of country situations overwhelmingly dictating the nature of responses? [ed – it’d be nice if you could give a few examples]
As part of our International Strategy, WaterAid is committed to supporting a few core pro - poor and people’s agenda that are monitored through annual country program performance and mid term strategy reviews. These are: Partnership (with local government), Equity and Inclusion, Water Resources Management, Sanitation, Hygiene, Sustainability. In addition to our core focus on urban and rural programs.

While individual country programme approaches and ways of work differ, we do try and ensure that we remain committed to our internal strategy work together on few common priorities. We then try and share knowledge on these priorities and seek to improve ourselves.

Recently some of the major international approaches have been on – IWRM, Urban programme learnings, Sanitation and Local Government Financing.

In the Asia where WA works in 4 countries (India, Pakistan, Nepal and Bangladesh), we find that the urban slums situation is quite similar while the rural areas are all different. There is a good learning environment for urban slums work (Orangi Pilot Project in Pakistan) and also in some aspects of community approaches in rural areas ( CLTS approach in Bangladesh). We find value in cross learning and experience sharing and try to keep our partners in the forefront of such learning initiatives.

You have been pivotal in bringing about 100% sanitization in some of India’s slums. It must have been a great challenge. Could you tell us a little about this?
Denial of sanitation is a human right violation for a very significant majority of Indian citizens who cannot afford to live in regular housing. It is not a policy failure but an outcome of the complete absence of pro - poor commitment in urban planning. It is based on the wrong assumption that slum dwellers are temporary residents for whom the State does not need to provide low cost housing. It has resulted in the poor being dislocated from slums within the cities and thrown out to the periphery.

WAI work has been to support individual sanitation facilities where possible and community infrastructure as a low cost alternative option. Child Friendly Community Toilets were the first major initiative of WAI in Trichy city in the year 2000. When the world was celebrating new millennium and promises of post industrial society, we were promoting (with our local NGO partner Gramalaya), basic community facilities and a commitment from the Municipality to provide water and electricity in slums.

Community toilets need to be upgraded with washing and bathing facilities, as has been done in Trichy. WAI has worked with Municipalities and the ADB project in 4 cities in Madhya Pradesh, to scaleup this initiative. In other states (Orissa and Jharkahnd) a few of our partners have taken up urban community toilets work. We have done a review of our Trichy experience, where we have analysed the operational viability of different community managed toilets and come out with Policy recommendations for urban pro poor slums.

We see an increasing tendency of Municipalities to sub contract the Public Toilets to agencies who are only interested in it for commercial purposes. They then end up sub contracting it to others. In the process, the quality of service and affordability are compromised.

WAI has recently been considering the idea of coming out with a citizen’s report on water and sanitation in India. What is the thinking behind this?
WAI currently supports programs in 10 states with 43 NGO partners. Our programs have brought out experience and lessons that have formed the basis for policy advocacy. Our research and policy work has also been significant and has enabled us to extend our policy advocacy work beyond our project experience alone. We have produced 3 national level reports of major significance in water and sanitation in the last 3 years. The National Status report on water and sanitation was the first of its kind, followed by the ADB Water Policy Review (urban water and sanitation projects in 4 states) and the Sanitation For All publication for SACOAN.

We are now in a position to support and lead the initiative on a Citizens Report on Water and Sanitation.

The thinking from WAI has been driven by a desire to put into action our strategic commitment to be an independent voice in the sector. To be closer to reality on the ground, to provide for a platform and to bring together a coalition of organizations and individuals, to present to the nation what is happening in water and sanitation issues that are pro - poor and should be a national issue. To prick the consciousness of people, to listen, to see, hear the reality and to act.

When Anil Agarwal took up the First Citizens Report on Environment, even he could not have imagined the impact a report like that could have. A Citizen’s Report that captures what is happening and tries to learn from the people, is bound to generate valuable knowledge. By identifying a few core issues, getting local people and experts debating on them, generates out of the box ideas, brings equality and balance in what are otherwise numerous technical reports and scholarly pieces that are not even read. Therefore the process of coming out with a Ctizens Report, with many people and organizations working together, is as much an output as the final report.

We have had a launch workshop in Delhi on 12th Jan 2008 where an endorsement was made in favour of this Report. We also formed 3 groups. The first is a Coalition Group that includes anyone who is agreeing with and willing to support this initiative. Second an Advisory Group of eminent personalities who can provide moral leadership and advise to the report writing and dissemination later on. Third, a Task Force consisting of people who can actively work on writing the Report.

We urgently seek the greater participation of individuals, organizations and civil society in this initiative, in any of the 3 Groups.

Depinder Kapur, Country Representative
WaterAid India