Toilet flushing
THE IMAGE BANK / GETTY IMAGES
To flush or not to flush. That was the question that designers and ecologists were asking each other this week as hundreds of people — who spend a lot of time thinking about these things — convened for the annual World Toilet Summit and Expo in Macau.
The World Toilet Summit and Expo is like the Star Trek Convention of the waste management and sanitation world. Toilets on show run the gamut from a cardboard box complete with a hole, plastic bag and pouch of waterless magic pathogen-busting dust ($50), to a high-tech 'uber-toilet,' featuring an in-seat warmer/cooler, male and female water jets, an in-bowl light (why? why?) and a USB port so you can connect your mp3 player for your soothing tune of choice ($1,200).
But figuring out how to wean the world off the flush handle took center stage. Though the common flush toilet has remained largely the same since it's invention in 1596, the world it inhabits has changed drastically. City populations have mushroomed, sewers have become overburdened and water has become scarcer. Now, the flushing loo — that human innovation that lifted the industrialized world out of its own dirt, cholera and dysentery — is quickly becoming one of the more egregious instruments of waste in this time of acutely finite resources. "The world can't sustain this toilet," says Jack Sim, the founder of the World Toilet Organization — the other WTO — an organization that advocates for sustainable sanitation solutions for all. "This 'flush and forget' attitude creates a new problem which we have to revisit."
If you are, as Sim's said, one of the millions who tends to 'flush and forget' on a regular basis, chances are you're dumping up to 22 liters of drinkable water every day, one three- to six-liter flush at a time. But the problem doesn't stop there. What follows — the 'forget' part of the toilet experience — is the long and costly process of sanitizing the water that was clean before you answered nature's call. In the developed world, the flush toilet is our only direct link to the enormous — and exorbitant — engineering feat that is the modern urban sanitation system: the sewers, filtration plants, water treatment facilities, and finally, treated water disposal channels that send the scrubbed water into our rivers and lakes.
Using so much water per flush unnecessarily increases the volume of our waste and the cost of its transportation and treatment, ecologists say. If you don't put waste in water in the first place, then you don't have to spend money to remove it at the back end. The process also leaves a huge carbon footprint, says Rose George, author of The Big Necessity: The Unmentionable World of Human Waste and Why it Matters. In the UK, she says, "the sewage system uses as much energy as what the largest coal fire station in the [country] produces" — about 28.8 million tones of carbon dioxide a year.
But the fundamental shift in how we think about our waste, and by extension, dispose of it, needs to be to stop mixing liquids and solids, says the WTO's Sim. "The human body is designed to separate solids from liquid waste," and we should follow suit, he says. By separating fecal matter from urine at the source in what's called a "urine diversion toilet," a wider ecological system of waste disposal becomes possible. Solids can be composted for fertilizer and harvested for methane gas. Urine can be used to produce phosphorous and nitrogen and clean, drinkable water. (The question is, will people bring themselves to drink it?)
Ecological sanitation, as this call to arms is known in toilet circles, is already up and running in many spots around the world. In rural China, 15.4 million homes convert methane into power from what normally went down the pit behind the house. Household waste is stored in a state-subsidized "digester," a kind of metal stomach that breaks down the matter and releases methane gas which is trapped for reuse. In the French city of Lille, a small fleet of ten buses are also using methane, gleaned from the city's poop. And in some Indian villages, simple latrines have been built that separate waste and use it to produce compost and fertilizer at a per capita cost infinitesimally lower than any waste management budget in the West.
In a reversal of the traditional one-way innovation highway — from the West to the rest of the world — many of the best ideas in sanitation are coming from the developing world. And for now, the gap between these initiatives and the large-scale urban sanitary solutions of tomorrow is being filled by inventors and dreamers like Jack Sim and others who gathered this week in Macau. Among their larger visions for collective waste disposal and treatment on display was a network of low-water toilets that separated solids from liquids and assigned them to reservoirs shared by an apartment building or block of houses. Those resevoirs would then produce fertilizer, soil conditioner and energy producing methane — and dramatically cut the cost to the public of waste disposal.
But for many people, this is just hot air. "We have the luxury of flushing the toilet and just seeing it disappear," says George. The industry is stalled not only by that convenience, but by taboo. "People are uncomfortable talking about their own waste." It may have been quite some time since relating the adventures of your most recent bowel movement has constituted acceptable fodder for conversation, but nevertheless, says George, our 'bodily products' have to come back into the conversation somehow, if we are ever going to flush away the flush.
By DON DUNCAN / MACAU
http://www.time.com
सोमवार, 10 नवंबर 2008
रविवार, 9 नवंबर 2008
Epoxy Pipe Lining To Prevent Lead Contamination
During the 19th and early 20th century lead was widely used in major U.S. cities for water pipes because of its durability and malleability. Lead pipes were eventually superseded by galvanized steel and copper, and copper pipe became the predominant material selected for domestic water service and distribution in post-World War II residential construction.
Pipe corrosion and erosion-caused lead contamination, was the top source of lead-related health issues before the hazards of ingesting lead were realized. Stillbirth and high infant mortality were two of the worst effects of lead ingestion. Many other plumbing or pipe problems are easy to detect by seeing or listening, but without specifically testing for it, there is no way to detect lead in your water. The EPA offers general information about lead contamination and how to test for it on its website.
If you have lead in your water, it?s generally because of one (or more) of these: lead-based solder which used to be the primary way to join copper pipes, a lead service line pipe linking your house to the city or town water main, and brass (or chrome-plated brass) faucets. The U.S. Congress banned the use of lead solder containing greater than 0.2% lead in 1986. It also limited the lead composition of pipes, faucets, and all other plumbing materials to 8.0%.? As a result of this legislation, ?lead-free? brass legally can contain no more than 8% lead and plumbing installed before 1986 possibly contain higher levels of lead.
In older structures, lines from the city/town water main to the home or building may be a lead pipe . Unless your piping has been upgraded in the past 40 years, it is probably galvanized pipe which does not require lead solder for joining. Faucets should be checked to see if they are brass or chrome-plated, a licensed plumber should be able to tell you if they are. CuraFlo??s website offers a brief history of lead materials in water pipes.
If your pipes are the source, epoxy lining will prevent lead leaching into your drinking water. Because the epoxy lining creates a barrier between the metal pipe and the water coming in contact with it, it stops the chemical reaction that causes corrosion. It eliminates and prevents from reoccurring, leaching of lead and other metals into the water, as well as a host of other poor water quality issues such as: discolored water (red, brown, blue or yellow), metallic taste (caused by zinc or iron leeching in galvanized pipes), and water odor or bad taste (caused by bacteria).
A relatively unknown technology, epoxy pipe lining is not a new technology, –in fact it?s well proven. The U.S. Army Corps of Engineers and U.S. Navy have both ested and approved the use of epoxy pipe lining to prevent contaminants, including lead, from leaching into drinking water. Their reports are published and links to them can be found at http://curaflo.com/CuraFlo/ResourceCenter. The epoxy used by CuraFlo in epoxy pipe lining, CuraPoxy?, is certified to meet the U.S.
There is no need for health concerns when it comes to epoxy lining your pipes, CuraFlo?s epoxy, CuraPoxy?, is certified to meet ANSI/NSF Standard 61 - the U.S. government standard for safe potable (drinking) water. ANSI/NSF Standard 61 certification means that something is certified safe to be used in potable water pipes at temperatures up to 180? Fahrenheit or 82.2? Celsius. CuraFlo?s epoxy pipe lining process protects you from lead (and other metals) in your pipes leaching into your water by preventing these metals from leaching into your water.
by Dr. Dave Dunn
About the Author:
Dr. Dave Dunn is Vice President of Research and Development for CuraFlo which provides epoxy lining solutions for homes & commercial buildings. Dr. Dave holds a PhD in Polymer Chemistry from the University of Keele in England. You can contact dr dave about plumbing problems or plumbing repair. SEO
http://iconsclub.com
Pipe corrosion and erosion-caused lead contamination, was the top source of lead-related health issues before the hazards of ingesting lead were realized. Stillbirth and high infant mortality were two of the worst effects of lead ingestion. Many other plumbing or pipe problems are easy to detect by seeing or listening, but without specifically testing for it, there is no way to detect lead in your water. The EPA offers general information about lead contamination and how to test for it on its website.
If you have lead in your water, it?s generally because of one (or more) of these: lead-based solder which used to be the primary way to join copper pipes, a lead service line pipe linking your house to the city or town water main, and brass (or chrome-plated brass) faucets. The U.S. Congress banned the use of lead solder containing greater than 0.2% lead in 1986. It also limited the lead composition of pipes, faucets, and all other plumbing materials to 8.0%.? As a result of this legislation, ?lead-free? brass legally can contain no more than 8% lead and plumbing installed before 1986 possibly contain higher levels of lead.
In older structures, lines from the city/town water main to the home or building may be a lead pipe . Unless your piping has been upgraded in the past 40 years, it is probably galvanized pipe which does not require lead solder for joining. Faucets should be checked to see if they are brass or chrome-plated, a licensed plumber should be able to tell you if they are. CuraFlo??s website offers a brief history of lead materials in water pipes.
If your pipes are the source, epoxy lining will prevent lead leaching into your drinking water. Because the epoxy lining creates a barrier between the metal pipe and the water coming in contact with it, it stops the chemical reaction that causes corrosion. It eliminates and prevents from reoccurring, leaching of lead and other metals into the water, as well as a host of other poor water quality issues such as: discolored water (red, brown, blue or yellow), metallic taste (caused by zinc or iron leeching in galvanized pipes), and water odor or bad taste (caused by bacteria).
A relatively unknown technology, epoxy pipe lining is not a new technology, –in fact it?s well proven. The U.S. Army Corps of Engineers and U.S. Navy have both ested and approved the use of epoxy pipe lining to prevent contaminants, including lead, from leaching into drinking water. Their reports are published and links to them can be found at http://curaflo.com/CuraFlo/ResourceCenter. The epoxy used by CuraFlo in epoxy pipe lining, CuraPoxy?, is certified to meet the U.S.
There is no need for health concerns when it comes to epoxy lining your pipes, CuraFlo?s epoxy, CuraPoxy?, is certified to meet ANSI/NSF Standard 61 - the U.S. government standard for safe potable (drinking) water. ANSI/NSF Standard 61 certification means that something is certified safe to be used in potable water pipes at temperatures up to 180? Fahrenheit or 82.2? Celsius. CuraFlo?s epoxy pipe lining process protects you from lead (and other metals) in your pipes leaching into your water by preventing these metals from leaching into your water.
by Dr. Dave Dunn
About the Author:
Dr. Dave Dunn is Vice President of Research and Development for CuraFlo which provides epoxy lining solutions for homes & commercial buildings. Dr. Dave holds a PhD in Polymer Chemistry from the University of Keele in England. You can contact dr dave about plumbing problems or plumbing repair. SEO
http://iconsclub.com
Recycle sewage 'as a last resort'
THE federal agency responsible for establishing national health standards has warned the Queensland Government it should not proceed with its $2.5 billion plan to recycle sewage and industrial waste for drinking water unless it is "absolutely necessary".
National Health and Medical Research Council water quality advisory committee chairman Don Bursill issued the warning as the Gold Coast City Council launched an investigation into how unsafe recycled waste water was if put into a treatment plant's drinking water.
Sixty million litres of recycled waste water a day will be pumped to the Wivenhoe Dam, Brisbane's main drinking water source, from early next year.
The Queensland Government promised in 2006 that recycled water would be used for the drinking supply of the 2.6 million residents of southeast Queensland only as a "last resort".
Since the undertaking was given, Wivenhoe and other storages in the region have been replenished following good rainfall, but the Government insists recycled water should be introduced now to guarantee future supplies.
Professor Bursill said he supported water recycling, but only if it were absolutely necessary.
"I think that recycling waste water for potable purposes should be a choice of last report," he said.
"There are opportunities for problems to occur and if it can be avoided, I think it should be. The maintenance of public health should be the primary concern."
He said the Queensland Government had prepared itself well, accepting the NHMRC's Australian Water Recycling Guidelines and introducing the Water Supply (Safety and Reliability) Bill. However, the main cause for concern was the potential for human error.
"It is worth reminding people that although technology can achieve recycling for potable purposes, about 80 per cent of the failures that have occurred in conventional water supply systems in affluent countries have been due to human error rather than technology issues," Professor Bursill said.
Human error was being blamed for a mistake at Gold Coast Water's Pimpana recycled water plant that resulted in staff drinking inadequately treated waste water.
The general public was not exposed to the water.
Gold Coast Mayor Ron Clarke said a staff member was believed to have been responsible for mixing up waste-water lines at the plant in September.
A pipeline was disconnected on Friday when the problem was uncovered.
Up to 240 employees and visitors who may have drunk water that was not fit for consumption are being contacted to determine if they had suffered any ill effects.
"Somebody has stuffed up and it should have been cross-checked before it happened," Mr Clarke said.
"If it had happened in the public works, it would have been disastrous. I am told that the checks are there to ensure that cannot happen."
Public meetings have been called in Brisbane on Saturday and on the Gold Coast on Sunday to protest against the recycled water plan.
Citizens Against Drinking Sewage secretary Aileen Smith said the Queensland Government could give no guarantees that a repeat of the cryptosporidium outbreak in 1993 in the US city of Milwaukee would be avoided.
More than 400,000 people fell ill and 100 died after drinking contaminated water from a treatment plant; the cause was never identified.
Recycled water will account for between 10 per cent and 25 per cent of southeast Queensland's drinking water, with the Government insisting it will be safe after treatment through a seven-stage process.
Source-http://www.theaustralian.news.com.au
National Health and Medical Research Council water quality advisory committee chairman Don Bursill issued the warning as the Gold Coast City Council launched an investigation into how unsafe recycled waste water was if put into a treatment plant's drinking water.
Sixty million litres of recycled waste water a day will be pumped to the Wivenhoe Dam, Brisbane's main drinking water source, from early next year.
The Queensland Government promised in 2006 that recycled water would be used for the drinking supply of the 2.6 million residents of southeast Queensland only as a "last resort".
Since the undertaking was given, Wivenhoe and other storages in the region have been replenished following good rainfall, but the Government insists recycled water should be introduced now to guarantee future supplies.
Professor Bursill said he supported water recycling, but only if it were absolutely necessary.
"I think that recycling waste water for potable purposes should be a choice of last report," he said.
"There are opportunities for problems to occur and if it can be avoided, I think it should be. The maintenance of public health should be the primary concern."
He said the Queensland Government had prepared itself well, accepting the NHMRC's Australian Water Recycling Guidelines and introducing the Water Supply (Safety and Reliability) Bill. However, the main cause for concern was the potential for human error.
"It is worth reminding people that although technology can achieve recycling for potable purposes, about 80 per cent of the failures that have occurred in conventional water supply systems in affluent countries have been due to human error rather than technology issues," Professor Bursill said.
Human error was being blamed for a mistake at Gold Coast Water's Pimpana recycled water plant that resulted in staff drinking inadequately treated waste water.
The general public was not exposed to the water.
Gold Coast Mayor Ron Clarke said a staff member was believed to have been responsible for mixing up waste-water lines at the plant in September.
A pipeline was disconnected on Friday when the problem was uncovered.
Up to 240 employees and visitors who may have drunk water that was not fit for consumption are being contacted to determine if they had suffered any ill effects.
"Somebody has stuffed up and it should have been cross-checked before it happened," Mr Clarke said.
"If it had happened in the public works, it would have been disastrous. I am told that the checks are there to ensure that cannot happen."
Public meetings have been called in Brisbane on Saturday and on the Gold Coast on Sunday to protest against the recycled water plan.
Citizens Against Drinking Sewage secretary Aileen Smith said the Queensland Government could give no guarantees that a repeat of the cryptosporidium outbreak in 1993 in the US city of Milwaukee would be avoided.
More than 400,000 people fell ill and 100 died after drinking contaminated water from a treatment plant; the cause was never identified.
Recycled water will account for between 10 per cent and 25 per cent of southeast Queensland's drinking water, with the Government insisting it will be safe after treatment through a seven-stage process.
Source-http://www.theaustralian.news.com.au
Young water guardians
Students combine His Majesty the King's philosophy with local knowledge to conserve water sources
The key points are we must have water to drink, to use and to support agriculture, since life is there. If there is water, people can live. If there is no electricity, people can live. But if there is electricity but no water, people can't live," says His Majesty King Bhumibol Adulyadej.
Students from Huai Yot School prepare the materials for their water conservation presentation.
In response to this important message, more than 400 Mathayom (high school) students from 20 schools nationwide participated in the first Junior Water Challenge (JWC) this year.
In Thai, the contest is named Pi Num Nong Raknam Tam Naew Pra Rajdamri, which means "Elder Students Lead the Younger Ones to Conserve Water Resources by Applying His Majesty the King's Initiatives".
The project is a collaborative effort by the Coca-Cola Foundation, the National Council on Social Welfare of Thailand, the Hydro and Agro Informatics Institute, the Royal Irrigation Department, the Ministry of Education, and the Office of the Royal Development Projects Board.
It aims to educate students on, and raise their awareness of, sustainable water management and conservation. Each participating school has to generate its own water conservation project. The campaign does not only ask students to conduct their projects within their own schools, but also encourages them to build water conservation networks in their community and nearby schools.
The final round was held at Khao Hin Sorn Development Study Centre, in Chachoengsao province, from Oct 8 to 10, and 80 students from the four winning schools in each region took part.
At the camp, each group presented an enthralling project and showed their passion and concern over water and environmental issues.
Students from Manchasuksa School present their water conservation initiative to fellow conservationists.
Saving a water basin
Jaehom Wittaya School in Lampang province, the northern region winner, presented the "Huai Hok Resource Conservation" project, which aims to conserve Huai Hok forest and Sam Sob Hok reservoir, the main water source of the Sam Sob Hok community.
"Formerly, Huai Hok forest was so arid that the villagers faced drought. So, we joined hands with the community to build check dams and plant more trees. We expect the forest to be enriched with water and wildlife through our efforts and those of our community members," said a student from Jaehom Wittaya School.
In the rainy season, water filled with silt flows into the reservoir. Check dams will block sediments and extraneous debris, as well as slow down the current.
So far, more than 1,300 check dams have been built. The school, together with the communities concerned, expects to build 200 more check dams within this year.
The students are also replanting Huai Hok forest, which is the water basin for Huai Hok (Hok canal), as many of its trees usually catch fire and burn down during the dry season.
Lake protectors
In Khon Kaen province, students in Manchasuksa School are noticing that Kud Khao reservoir, which is not only the main water source but also a recreation area for their community, is being polluted by the residents, as sewage flows directly into the reservoir.
Even though the effects are not yet serious due to the large expanse of the reservoir, the students want to stop the water from deteriorating.
Acting on their concerns, this winning team from the northeastern region created "The Conservation of Kud Khao Reservoir" project to tackle the problem.
To prevent further contamination, the students have initiated several campaigns to conserve their beloved lake - such as Nak Surb Sai Nam or "Water Resource Investigation Team", which will send out students to examine the water conditions at various points of the lake.
The students have also launched water treatment projects and arranged seminars for younger students to raise awareness of water conservation.
"After we graduate, we believe that the incoming generations will continue our intentions [and] preserve the good condition of our Kud Khao reservoir forever," said a student from Manchasuksa School.
Helping farmers
The winner from the central and eastern regions of Sa Kaeo province, Romklao Wattananakorn Sa Kaeo Ratchamangkalapisek School, showcased its "Young Water Leader Following His Majesty the King's Path" project.
Students noticed that the water released by the Irrigation Department did not reach the farmers properly, as some farms still lacked water. They discovered that the waterway had been blocked and damaged by weeds. Consequently, the students, in cooperation with the community and the Royal Irrigation Department, helped to clear and repair the waterway.
The project was also spurred by concerns over contaminated water sources inside the communities that resulted from the usage of chemical substances in local agricultural activities and livestock husbandry.
To attack the problem, the students promote the use of organic fertilisers and build environmental awareness among fellow students and people in the communities.
"We cannot live without water, since water is part of our life," said Pimsupa Madato, 17, a Mathayom 6 (Grade 12) student from Romklao Wattananakorn Sa Kaeo Ratchamangkalapisek School.
The students also tried to expand their network by persuading nearby schools to join their campaign. They expected 13 schools to sign up. To date, five schools have done so.
Stabilise soil with vetiver grass
Students from Huai Yot School in Trang province, the southern region winner, presented its "Vetiver Planting on the Banks of Huai Yot School's Reservoirs According to the Sufficiency Economy Philosophy" project, which aims to protect the two precious reservoirs near their school, which are also the major water sources for their community.
During the rainy season, heavy rains usually collapse the reservoirs' banks, causing the reservoirs to become shallow. The water bodies are also contaminated with garbage and rotten leaves.
The scheme aims to solve the problems by planting vetiver grass on the reservoirs' banks. With its deep thick roots, the grass will stabilise the soil and protect it from collapsing.
"We will use the grass for roofing. Also, we intend to produce paper from vetiver grass in the future," said a Huai Yot School student. They also expect that their school will be a vetiver grass distribution centre.
"The first prize is not our goal. Our goal is to implement the teachings of our King, who is our inspiration, on the methods of conserving water and soil. We pay respect to him by preserving water and using each drop of water prudently," the Huai Yot School students said, revealing the ultimate intention of their project.
Widening perceptions
"People of different backgrounds and ages come here to learn and live together and recognise the value of water" was Pimsupa's impression of the camp.
At this final phase at Khao Hin Sorn Development Study Centre, the students had the chance to meet fellow young water conservationists and present their projects before them, as well as learn more environmental and agricultural lessons.
The lessons include creating a water-based, organic fertiliser from garbage, vegetables and fruits, getting to know the various kinds of vetiver grass and their applications, learning how to do mixed gardening, and actually taking part in fishery activities, as well as listening to an English lesson presented by Andrew Biggs.
The students do not only gain more knowledge of His Majesty the King's initiatives, which they can apply to further develop their communities along with their water conservation projects, but they also learn to work as a team.
"I've learned to live and work with others, as well as listen to others' opinions and learn to solve the problems at hand. Sometimes we have different opinions, but we have to understand others' thoughts," said Komson Laypol, 17, a Mathayom 5 (Grade 11) student from Manchasuksa School.
He added that he would attempt to grow vetiver grass by planting it in a container suspended on the surface of the water as a way of treating the water in his project.
Formerly, Khao Hin Sorn was an extremely barren area. The villagers then donated a 264-rai plot of land to His Majesty to build a palace on, but the King chose to construct an agriculture development study centre on it instead. Ever since, this parched land has been fertile and filled with lush greenery. A large number of people visit the centre every year to study agricultural philosophy according to His Majesty the King.
Results
The first prize went to Romklao Wattananakorn Sa Kaeo Ratchamangkalapisek School, which was awarded a trophy from the Ministry of Education and a 50,000-baht scholarship. The second prize, a 30,000-baht scholarship and a certificate from the National Council on Social Welfare of Thailand, went to Jaehom Wittaya School.
Each of the two remaining teams received 10,000 baht and a certificate from the National Council on Social Welfare of Thailand.
The judges considered the content of the projects and the levels of participation of the students at the camps. In the end, their decision was based on three major criteria, namely, the planning, the method of application, and the result and sustainability of the project.
"The students were able to successfully convince the people in their community to take part in water conservation," Sombat Saleepattana of the Royal Irrigation Department, one of the judges, commented on the winning team.
"In Thailand, there is too little collaboration among students, the communities and the Royal Irrigation Department," he added.
Initiated in March on the occasion of World Water Day 2008, the JWC is part of the Raknam programme, a major community service project of the Coca-Cola conglomerate.
More information about the Raknam project is available at http://www.raknam.com .
www.bangkokpost.com
The key points are we must have water to drink, to use and to support agriculture, since life is there. If there is water, people can live. If there is no electricity, people can live. But if there is electricity but no water, people can't live," says His Majesty King Bhumibol Adulyadej.
Students from Huai Yot School prepare the materials for their water conservation presentation.
In response to this important message, more than 400 Mathayom (high school) students from 20 schools nationwide participated in the first Junior Water Challenge (JWC) this year.
In Thai, the contest is named Pi Num Nong Raknam Tam Naew Pra Rajdamri, which means "Elder Students Lead the Younger Ones to Conserve Water Resources by Applying His Majesty the King's Initiatives".
The project is a collaborative effort by the Coca-Cola Foundation, the National Council on Social Welfare of Thailand, the Hydro and Agro Informatics Institute, the Royal Irrigation Department, the Ministry of Education, and the Office of the Royal Development Projects Board.
It aims to educate students on, and raise their awareness of, sustainable water management and conservation. Each participating school has to generate its own water conservation project. The campaign does not only ask students to conduct their projects within their own schools, but also encourages them to build water conservation networks in their community and nearby schools.
The final round was held at Khao Hin Sorn Development Study Centre, in Chachoengsao province, from Oct 8 to 10, and 80 students from the four winning schools in each region took part.
At the camp, each group presented an enthralling project and showed their passion and concern over water and environmental issues.
Students from Manchasuksa School present their water conservation initiative to fellow conservationists.
Saving a water basin
Jaehom Wittaya School in Lampang province, the northern region winner, presented the "Huai Hok Resource Conservation" project, which aims to conserve Huai Hok forest and Sam Sob Hok reservoir, the main water source of the Sam Sob Hok community.
"Formerly, Huai Hok forest was so arid that the villagers faced drought. So, we joined hands with the community to build check dams and plant more trees. We expect the forest to be enriched with water and wildlife through our efforts and those of our community members," said a student from Jaehom Wittaya School.
In the rainy season, water filled with silt flows into the reservoir. Check dams will block sediments and extraneous debris, as well as slow down the current.
So far, more than 1,300 check dams have been built. The school, together with the communities concerned, expects to build 200 more check dams within this year.
The students are also replanting Huai Hok forest, which is the water basin for Huai Hok (Hok canal), as many of its trees usually catch fire and burn down during the dry season.
Lake protectors
In Khon Kaen province, students in Manchasuksa School are noticing that Kud Khao reservoir, which is not only the main water source but also a recreation area for their community, is being polluted by the residents, as sewage flows directly into the reservoir.
Even though the effects are not yet serious due to the large expanse of the reservoir, the students want to stop the water from deteriorating.
Acting on their concerns, this winning team from the northeastern region created "The Conservation of Kud Khao Reservoir" project to tackle the problem.
To prevent further contamination, the students have initiated several campaigns to conserve their beloved lake - such as Nak Surb Sai Nam or "Water Resource Investigation Team", which will send out students to examine the water conditions at various points of the lake.
The students have also launched water treatment projects and arranged seminars for younger students to raise awareness of water conservation.
"After we graduate, we believe that the incoming generations will continue our intentions [and] preserve the good condition of our Kud Khao reservoir forever," said a student from Manchasuksa School.
Helping farmers
The winner from the central and eastern regions of Sa Kaeo province, Romklao Wattananakorn Sa Kaeo Ratchamangkalapisek School, showcased its "Young Water Leader Following His Majesty the King's Path" project.
Students noticed that the water released by the Irrigation Department did not reach the farmers properly, as some farms still lacked water. They discovered that the waterway had been blocked and damaged by weeds. Consequently, the students, in cooperation with the community and the Royal Irrigation Department, helped to clear and repair the waterway.
The project was also spurred by concerns over contaminated water sources inside the communities that resulted from the usage of chemical substances in local agricultural activities and livestock husbandry.
To attack the problem, the students promote the use of organic fertilisers and build environmental awareness among fellow students and people in the communities.
"We cannot live without water, since water is part of our life," said Pimsupa Madato, 17, a Mathayom 6 (Grade 12) student from Romklao Wattananakorn Sa Kaeo Ratchamangkalapisek School.
The students also tried to expand their network by persuading nearby schools to join their campaign. They expected 13 schools to sign up. To date, five schools have done so.
Stabilise soil with vetiver grass
Students from Huai Yot School in Trang province, the southern region winner, presented its "Vetiver Planting on the Banks of Huai Yot School's Reservoirs According to the Sufficiency Economy Philosophy" project, which aims to protect the two precious reservoirs near their school, which are also the major water sources for their community.
During the rainy season, heavy rains usually collapse the reservoirs' banks, causing the reservoirs to become shallow. The water bodies are also contaminated with garbage and rotten leaves.
The scheme aims to solve the problems by planting vetiver grass on the reservoirs' banks. With its deep thick roots, the grass will stabilise the soil and protect it from collapsing.
"We will use the grass for roofing. Also, we intend to produce paper from vetiver grass in the future," said a Huai Yot School student. They also expect that their school will be a vetiver grass distribution centre.
"The first prize is not our goal. Our goal is to implement the teachings of our King, who is our inspiration, on the methods of conserving water and soil. We pay respect to him by preserving water and using each drop of water prudently," the Huai Yot School students said, revealing the ultimate intention of their project.
Widening perceptions
"People of different backgrounds and ages come here to learn and live together and recognise the value of water" was Pimsupa's impression of the camp.
At this final phase at Khao Hin Sorn Development Study Centre, the students had the chance to meet fellow young water conservationists and present their projects before them, as well as learn more environmental and agricultural lessons.
The lessons include creating a water-based, organic fertiliser from garbage, vegetables and fruits, getting to know the various kinds of vetiver grass and their applications, learning how to do mixed gardening, and actually taking part in fishery activities, as well as listening to an English lesson presented by Andrew Biggs.
The students do not only gain more knowledge of His Majesty the King's initiatives, which they can apply to further develop their communities along with their water conservation projects, but they also learn to work as a team.
"I've learned to live and work with others, as well as listen to others' opinions and learn to solve the problems at hand. Sometimes we have different opinions, but we have to understand others' thoughts," said Komson Laypol, 17, a Mathayom 5 (Grade 11) student from Manchasuksa School.
He added that he would attempt to grow vetiver grass by planting it in a container suspended on the surface of the water as a way of treating the water in his project.
Formerly, Khao Hin Sorn was an extremely barren area. The villagers then donated a 264-rai plot of land to His Majesty to build a palace on, but the King chose to construct an agriculture development study centre on it instead. Ever since, this parched land has been fertile and filled with lush greenery. A large number of people visit the centre every year to study agricultural philosophy according to His Majesty the King.
Results
The first prize went to Romklao Wattananakorn Sa Kaeo Ratchamangkalapisek School, which was awarded a trophy from the Ministry of Education and a 50,000-baht scholarship. The second prize, a 30,000-baht scholarship and a certificate from the National Council on Social Welfare of Thailand, went to Jaehom Wittaya School.
Each of the two remaining teams received 10,000 baht and a certificate from the National Council on Social Welfare of Thailand.
The judges considered the content of the projects and the levels of participation of the students at the camps. In the end, their decision was based on three major criteria, namely, the planning, the method of application, and the result and sustainability of the project.
"The students were able to successfully convince the people in their community to take part in water conservation," Sombat Saleepattana of the Royal Irrigation Department, one of the judges, commented on the winning team.
"In Thailand, there is too little collaboration among students, the communities and the Royal Irrigation Department," he added.
Initiated in March on the occasion of World Water Day 2008, the JWC is part of the Raknam programme, a major community service project of the Coca-Cola conglomerate.
More information about the Raknam project is available at http://www.raknam.com .
www.bangkokpost.com
Villagers accuse Kerala of encroaching TN land
Theni (PTI): Yet another inter-state dispute involving Tamil Nadu and its neighbours appear to be brewing with local body officials and erstwhile zamindars of three villages in this district accusing Kerala of 'encroaching' a site, believed to have been visited by Lord Rama, and converting it into a tourist spot.
The Kerala Tourism department had installed a 50-feet tall statue of "Adhivasis" (tribal couple with a baby) at the site, Ramarkal Mettu, and was also collecting money from tourists for visiting the place, according to Appaji Rajkumar, erstwhile Zamindar of Kombai.
Ramkumar says he possessed "copper plate documents", to prove that Ramarkal Mettu belonged to Tamil Nadu. He wondered how Tamil Nadu forest department allowed Kerala to construct the statue in "our territory and earn revenue".
A foreset official, however, said the department had raised objections when Kerala began work on the statue some three years ago itself. The site, situated six km from Kombai, belonged to reserve forest area of Tamil Nadu, he said.
But at that time Tamil Nadu officials did not have survey documents. "Now that we have the documents we have again conveyed our objections to the Kerala Government," he said.
Ramarkal Mettu is considered a sacred place for the Hindus as it was here, according to the legend, Lord Rama performed the last rites for the bird "Jatayu", killed after a fight with Ravana to save Sita while she was being abducted by him to Lanka. Red stones symbolic of blood stains of Jatayu can seen in the area even today.
Tamil Nadu is already involved in disputes with Karnataka over sharing of Cauvery waters and Hogenakkal Drinking Water project besides Periyar Dam issue with Kerala and row over a check dam across Palar by Andhra Pradesh.
Courtesy- The Hindu
The Kerala Tourism department had installed a 50-feet tall statue of "Adhivasis" (tribal couple with a baby) at the site, Ramarkal Mettu, and was also collecting money from tourists for visiting the place, according to Appaji Rajkumar, erstwhile Zamindar of Kombai.
Ramkumar says he possessed "copper plate documents", to prove that Ramarkal Mettu belonged to Tamil Nadu. He wondered how Tamil Nadu forest department allowed Kerala to construct the statue in "our territory and earn revenue".
A foreset official, however, said the department had raised objections when Kerala began work on the statue some three years ago itself. The site, situated six km from Kombai, belonged to reserve forest area of Tamil Nadu, he said.
But at that time Tamil Nadu officials did not have survey documents. "Now that we have the documents we have again conveyed our objections to the Kerala Government," he said.
Ramarkal Mettu is considered a sacred place for the Hindus as it was here, according to the legend, Lord Rama performed the last rites for the bird "Jatayu", killed after a fight with Ravana to save Sita while she was being abducted by him to Lanka. Red stones symbolic of blood stains of Jatayu can seen in the area even today.
Tamil Nadu is already involved in disputes with Karnataka over sharing of Cauvery waters and Hogenakkal Drinking Water project besides Periyar Dam issue with Kerala and row over a check dam across Palar by Andhra Pradesh.
Courtesy- The Hindu
No freeloaders
Nature cannot offer services without payment anymore
The dejected eyes of Kartar Chand Rana, 52, panned the breached checkdam in his village, Kuhan. As head of the gram vikas samiti he ordered the breaking of the embankment of the very dam that fed his half hectare land until last year. It was the best thing to do under the circumstances. The dam had silted over and the only way to clear the reservoir was to break the wall and let the water wash down all the mud. The immediate cause of the blockage: dumping of debris from the construction of a PWD road that connected Kuhan to the highway. Kuhan petitioned the PWD to pay for the reservoir’s clean-up, but nothing happened. After many gloomy discussions in the village square the farmers took the tough decision—to breach the dam wall in pre-monsoon of 2007. Now they are collecting funds to install iron gates to plug the breach and prevent similar problems in the future.
Kuhan is tucked far away in the hills of Himachal Pradesh’s Kangra district.
It is a typical changar—a region that receives high rainfall and yet faces water shortages due to lack of storage facilities. In 2003 the village pooled resources and with some help from a watershed development project constructed a checkdam on Gulana Khad, a nullah that ran across the village. With irrigation now available crop production increased six times; it was now possible to grow vegetables and fruits for cash.
The honeymoon lasted only a year. By 2005 the reservoir collected silt and its capacity halved. The worried villagers looked for a lasting solution. There was no quick formula they could apply here. With help from Winrock International, a non-profit organization, the villagers diagnosed the problem and came up with a unique prescription.
Most of the silt came from the grazing land of Ooch, a village high up the nullah. How to control it? How to get Ooch farmers to make the effort that will solve Kuhan’s problems?
Both villages discussed the dam and its silt and reached a formal agreement. Ooch banned grazing for eight years on its four-hectare common land and planted saplings of fruit, fodder bearing trees as well as bamboo and elephant grass. In exchange, Kuhan paid for these saplings and even worked out an arrangement to sell irrigation water to Ooch as and when required. The silt load in the nullah reduced and the villagers rejoiced again.
That was before PWD entered the scene and destroyed all that villagers of Kuhan and Ooch had achieved. “We entered into an eight-year agreement with Ooch to save our checkdam only to break the dam ourselves,” lamented Rana, who won, lost, won and lost again the battle to secure irrigation and therefore prosperity for his people. “The dam opened our eyes to the problem of erosion in our area,” said Purshottam Singh, 66-year-old farmer who participated in the project in Ooch. Singh felt the joint project was as beneficial for Ooch as it was for Kuhan, if not more. It stemmed erosion and gave the village more fodder and beneficial trees in the bargain.
Ecosystem services
The agreement between Kuhan and Ooch still stands. It is an example of how relations between two villages can be reworked to mutual benefit, centred on natural resources. The written agreement as negotiated between the two villages is what is called “payments for ecosystem services” (PES) in contemporary natural resource management parlance. The idea behind PES is to first identify environmental services or ecosystem services.
These can be anything, from clean water, clean air, flood control, creation of soil, food production, fisheries, timber production, carbon sequestration to countless other benefits that underpin human wellbeing.
Identification of an ecosystem service implies that people understand its importance and want to preserve it. And they are willing to pay for this. PES creates a market for ecosystem services where users directly pay service providers. This concept has been gaining ground around the world though in India it is relatively new. Kuhan is a classic PES example where water is the ecosystem service and Ooch the service provider for its role in maintaining the health of the nullah. A buyer-seller arrangement was brokered. Since Ooch had to compromise on grazing to save the water from siltation, Kuhan, being the beneficiary, compensated for it. Kuhan generated its own funds to pay Ooch when it delivered an environmental service. To extend the logic of the Kuhan-Ooch joint venture to forests, people will want to conserve them if they were paid to do so.
Kuhan is an important example, albeit on a small scale, not only of a successful PES model, but also what it implies for the future of resource management. There are lessons in it for policymakers.
PES gained momentum with the release of the Millennium Ecosystem Assessment (MEA) in 2005. The MEA recognized that benefits accrued from natural ecosystems were widely recognized, but poorly valued. “Increasingly it is becoming clear that traditional economic concepts like the GDP only reflect economic values leaving out the state of natural resources. One might know the rate of growth of a country’s economy, but still have little idea about whether this growth is sustainable”, agrees Rajeev Semwal, ecologist and consultant with the non-profit organization, LEAD India, a nd a proponent of PES.
Value of forests
Payment for ecosystem services is calculated using a variety of methods by ecologists and economists. One of the areas where India has made progress is Net Present Value (NPV) calculator. NPV assigns value to forests. It is an additional cost to be paid for the diversion of forest land (See “Diversion Route”, Down To Earth, October 16-31, 2008).
Another tool is the mandatory compensation required to be given by project for conversion of forestland as per the Forest Conservation Act. All this money is collected in a central fund called CAMPA, short for Compensatory Afforestation Management and Planning Authority (see “States may get CAMPA money”, Down To Earth, April 16-30, 2008). There is at present over Rs 6000 crore lying unused under this head.
The problem with systems like NPV is that it is tricky to value most environmental services. For instance, it is easier to calculate the value of trees based on their timer value or fruit value, but it is difficult to fix a sum for other services of a forest like water, beauty, home for animals and plants. Then again, as Vikram Dayal, Associate Professor, Institute of Economic Growth, said, “Collection of NPV or CAMPA funds is one thing but there is no clarity on what is to be done with the money”. The policy lacks direction, he believed. This could have serious implications if PES was to become a tool for conservation.
Dayal was part of another study commissioned by WWF that examined introducing suitable economic instruments in India, including PES. The study was carried out in three sites—Gangtok, Shimla and Munnar. It calculated costs and benefits of two specific services: urban water services and landscape beauty. The results will be used to assess and identify opportunities for broader application of PES.
“In Himachal, PES is already working in the Great Himalayan National Park where communities are paid Rs 5000 annually if no fires occur in the area they patrol; but there is no formal regulatory mechanism to say that you paid for this service”, said T R Manoharan, of WWF who co-led the economic instruments project. Clearly, Dayal and Manoharan find the government unprepared to adopt the PES model or the buyer-seller arrangement for resource management.
Sejal Worah, also of WWF was, however, optimistic. She spoke from her experiences in the economic instruments study: the private sector was quite happy to pay for these services as it made their access to resources easier but the public sector still seemed reluctant. “The good thing is that nobody rejected outright the idea of paying for using an environmental service.”
Valuation of ecosystem services forms the basis for informed decision-making. “One needs to examine both the way numbers are made and how effectively they help shape policy decisions that can be widely accepted,” Dayal summarized. On a note of caution he added that some market-based methods were best thought of as coming up with minimum prices of services, as they often did not consider the harder-to-value components of an ecosystem’s worth like clean air. Even Semwal felt monetary estimates were easy to comprehend, but hid assumptions, approximations, and simplifications. They measured only certain kinds of value. But they also integrated information about supply and demand, of what is important to people, however imperfectly.
Rethinking policy based on PES
In 2006 a study by the Indian Institute of Forest Management (IIFM), Bhopal pinned the numbers on Himachal Pradesh and Madhya Pradesh’s forest wealth. It put the value of Himachal Pradesh’s forests at Rs 13,23,000 crore including the value of services they provide. “Our watershed services alone value Rs 1,06,000 crore annually, so why should the state not earn money from its resources?” asked Pankaj Khullar, principal chief conservator of forests, Himachal Pradesh.
The 12th Finance Commission (2005-10) for the first time recognized the need to invest in resources and earmarked Rs 1000 crore for five years to be given to states for preserving forests. Himachal Pradesh’s annual share was Rs 20 crore, a pittance compared to the standing value of its forests. Given the money they can earn by selling forest resources, this is obviously not enough incentive to preserve forests. The state government therefore took steps towards realizing the value of these services by trading them through the World Bank as carbon credits. The credits brought in money equivalent to the amount of CO2 absorbed through afforestation activities. The money that Himachal earns from this will go to the communities working on th project.
Himachal Pradesh Chief Minister Prem Kumar Dhumal, was upbeat when he said: “We aim to preserve our forests and the 20 plus-year-old green felling ban is testimony to that”. He further stated.that trading in carbon credits provided funds and hence the incentive to preserve forests.
PES better than CDM
Himachal intends to use CDM as another form of PES. CDM does not consider standing forests and excludes the community from its fold by entering into an agreement with formal institutions like the government. “Untouched natural forests store three times more carbon dioxide than previously estimated and 60 per cent more than plantation forests,” said Chetan Agarwal of Winrock International who brokered the Kuhan-Ooch agreement. Therefore, PES agreements like the one between Kuhan and Ooch, he felt, might just be the right mechanism to save old forests and their services. “Even if one were to engage in CDM projects, fluctuation in the rate of carbon credits would mean uncertainty for the people who invest in these,” he said.
“PES, however, requires clear community rights over resources to succeed,”opined Agarwal. Citing the example of central India, he added, that the government has never really engaged with the tribals to settle their rights resulting in large tracts of land being classified as forests. The result today is conflicts. In such a sitution it is not possible to attempt any PES arrangements between users and providers. “Further one needs ‘sweat equity’, what the community invests in conservation must also be computed in the cost of resources,” said he.
Summing up the status of PES, Worah of the WWF study stated that though there was enthusiasm among private parties to pay for ecosystem services the stage was not set as yet. With the governance structure and policies not conducive to PES, value as well as payments for ecosystem services is still contentious. Therefore, small application of PES is possible, but scaling it up is still a far cry.
SUPRIYA SINGH
Courtesy- Down To Earth
Water returns to Saurashtra
Ahmedabad, Nov 8 (IANS) It’s a happy homecoming for the farmers of Saurashtra. Faced with scarcity of water they left their land and profession. But today, thanks to a new water management system employed by the state government, a reverse migration is in progress.
‘I left with my family for Surat in 2002. My land was fallow for lack of water. My two sons began earning Rs.15,000 at a diamond polishing factory. I returned early this year after seeing plenty of water in the check dams in the region,’ says Kanubahi Rambhai Suva, 62, of Khaki Jalia village.
He owns 15 bighas (about nine acres) of land in Upleta taluka (sub district) of Rajkot district in the parched Saurashtra region of Gujarat. Upleta is on the banks of the Moj river 300 km from here.
Today Suva has harvested 675 kg of genetically modified Bt cotton, fetching him Rs.15,000 per bigha. After cotton he plans to sow wheat. His earning works out to Rs.150,000 per annum.
Suva is one of the farmers who have set the trend of reverse migration.
Along with Suva, 25 families had left Khaki Jalia village. Except for five families all are back in their native village.
As a result of water management there has been a change in the lifestyle of the farmers, says Dhavnat K. Suva of Kakhi Jalia. ‘Today most of us have motorcycles and are prosperous. You can see the prosperity. I was cultivating sugarcane 20 years ago. Water scarcity made me venture into business. Now I am back to my old cultivation and am happy.’
There are 30,000 small check dams and 300 large ones built in Saurashtra.
Today there are 35 check dams, including a couple of large ones, on the Moj river’s 50 km stretch. Check dams store water throughout the year and help in irrigation when rains fail.
‘Earlier it was very difficult getting water for even one crop in a year. Now we have three crops,’ says farmer Maldebhai Bodar of Sevantara village who owns 50 bighas of land.
These check dams help irrigate 600 hectares directly and 1,000 hectares indirectly in a 4-km radius, Jayanti Patel of Kolki village of Upleta taluka said.
In 2001, 12,000 check dams were built in Gujarat. Today there are over 100,000 small and big check dams, with the irrigation department and other government agencies playing a major role in their construction.
Of 5,600 villages in Saurashtra, 3,000 villages have small and medium check dams while there are 300 large check dams in the region.
‘Three hundred more check dams will be built on big rivers in Saurashtra at a cost of Rs.15 million by 2009 end,’ said Irrigation and Urban Housing Minister Nitin Patel.
‘Work on 60 big check dams will begin after Diwali on 80:20 basis (80 percent cost to be incurred by the state government),’ Patel had told IANS.
Saurashtra has 70 rivers. In 30 of them check dams have been constructed. Now 3,000 villages have 30,000 check dams. Of the seven districts of Saurashtra, most check dams are in Jamnagar followed by Bhavnagar, Amreli, Junagadh, Rajkot and Porbandar.
Surendranagar is covered by the Sujalam Sufalam scheme that brings in water from the river Narmada. Yet, it has 71 check dams.
‘It is not enough if good rains are there. What is required is availability of water at the right time. During 1994-95 there was more rain than today, yet the crop output has gone up now,’ said former agriculture minister Bhupendrasinh Chudasama during whose tenure the maximum check dams were built.
http://www.sindhtoday.net
शनिवार, 8 नवंबर 2008
INVITATION
Water Portal in Hindi
We are very happy to be launching India Water Portal in Hindi on November 18th at a function in New Delhi. The URL for the new site is http://hindi.indiawaterportal.org and a preview version of the website can be seen there currently. We welcome your comments and feedback.
The launch event will be at Constitution Club, New Delhi on November 18th from 10:30am to 4:30pm. The Minister of State for Water Resources has expressed interest in the effort and will be coming as Chief Guest. Anupam Mishra will join us as a main speaker and Rohini Nilekani will preside the Function. The official launch & press conference will be in the morning session and we are planning a technology sharing session in the afternoon. The agenda and details will be sent out shortly.
We would be delighted if you'll can join us at the event. Please reply at water.community@gmail.com if you are interested in attending and we will follow up to make sure you get all the information,
Venue- Constitution Club, VP house, Rafi marg in front of Shram Shakti Bhawan, New Delhi
Date & Time- November 18th from 10:30am to 4:30pm.
Contact- Minakshi Arora- 09250725116
Water Community India
hindi.indiawaterportal.org
We are very happy to be launching India Water Portal in Hindi on November 18th at a function in New Delhi. The URL for the new site is http://hindi.indiawaterportal.org and a preview version of the website can be seen there currently. We welcome your comments and feedback.
The launch event will be at Constitution Club, New Delhi on November 18th from 10:30am to 4:30pm. The Minister of State for Water Resources has expressed interest in the effort and will be coming as Chief Guest. Anupam Mishra will join us as a main speaker and Rohini Nilekani will preside the Function. The official launch & press conference will be in the morning session and we are planning a technology sharing session in the afternoon. The agenda and details will be sent out shortly.
We would be delighted if you'll can join us at the event. Please reply at water.community@gmail.com if you are interested in attending and we will follow up to make sure you get all the information,
Venue- Constitution Club, VP house, Rafi marg in front of Shram Shakti Bhawan, New Delhi
Date & Time- November 18th from 10:30am to 4:30pm.
Contact- Minakshi Arora- 09250725116
Water Community India
hindi.indiawaterportal.org
मंगलवार, 16 सितंबर 2008
Studies confirm poor water quality in Mumbai
Dead fish in my drinking water source
As monsoon comes, Mumbai's water supply gets contaminated. This year, too, the situation seems grim. Two recent studies have indicted Mumbai's drinking water supply. One study has found Escherichia coli (E coli) in the city's drinking water supply, while the other has traced high levels of oil and grease in a major drinking water source.
The Municipal Corporation of Greater Mumbai (mcgm), in its annual water samples testing report, has said 10 samples of drinking water collected from posh Mumbai suburbs such as Colaba, Byculla and Dahisar were loaded with E coli.
The bacterium causes gastroenteritis, diarrhoea and severe kidney damage. Another 80 samples were highly contaminated with coliform bacteria and were unfit for drinking, said the report. According to the who, the level of coliform bacteria in drinking water should not be exceed 10 per 100 ml, whereas E coli should be absent.
A blame game has already begun. mcgm contends that Mumbai's water supply pipelines are almost 100 years old and leaky. Hence, during the rainy season, sewage seeps through the pipelines and contaminates drinking water with E coli. It also blames the residents' societies for not cleaning water tanks regularly. Health experts, however, differ. "Every year during monsoon, I receive a large number of patients suffering from gastroenteric problems linked chiefly to contaminated water…But residents are helpless as they cannot sue the mcgm. The Indian government has only recommended drinking water standards but not made them legally binding," says a physician based in Gorai.
In a separate incident, over 700 kg of dead fish were found floating in the Bhatsa Lake on July 10. The lake, located in Thane district, is a major source of drinking water to Mumbai.
Initially the authorities blamed it on local residents for poisoning the lake water to catch fish. But later tests by Mumbai-based Central Institute of Fisheries Education showed high levels of oil and grease effluents in the water—89 mg per litre (mg/l). The permissible limit of such contaminants in water sources is up to 10 mg/l. Local residents say the waste oil has been released by Shahpur-based Liberty Oil Mills Ltd.
mcgm has demanded action against the company and the Maharashtra Pollution Control Board is investigating the matter.
NIDHI JAMWAL
SURYA SEN
गुरुवार, 4 सितंबर 2008
Constructing Water Balance
Introduction
To understand the water regime of a specific area for water resource planning one of the first tasks is to understand the water balance of that area. Water balance is a budgeting exercise that assesses the proportion of the rainfall that becomes stream flow (or runoff), evapotranspiration, and drainage (or groundwater recharge).
Objectives of Water Balance Demonstration
1. To introduce the reader to a simple water balance model, namely, the Thorntwaite-Mather model, henceforth referred to as the T-M model (Thorntwaite et al, 1955;1957; Steenhuis et al, 1986);
2. To provide the reader with the tools to construct a water balance for her/his own region of interest, with the help of video tutorials and a sample Excel spreadsheet that can be downloaded and modified.
This document is intended for general instructive purposes for an audience that has some basic knowledge of water resources and associated terminology. No advanced expertise should be needed to understand and use this tutorial.
There can be various models to construct water balance of an area; the model that is used here for demonstration is T-M Model which has an advantage of being one of the most simple models. It can be used to determine a general estimate of the water balance regime, for individual fields to small watersheds.
Applications and Limitations : However, as in all scientific investigation, this tutorial should be used responsibly and with a full knowledge of the user's specific study area. This model and its variants have been used, for example, for irrigation scheduling of individual fields, water budgeting of small watersheds, generating actual evapotranspiration estimates for comparison with other methods - to name a few applications.
Being a lumped model, in the form described, the T-M model does not provide spatially distributed predictions, nor does it perform flow routing routines.
To understand the water regime of a specific area for water resource planning one of the first tasks is to understand the water balance of that area. Water balance is a budgeting exercise that assesses the proportion of the rainfall that becomes stream flow (or runoff), evapotranspiration, and drainage (or groundwater recharge).
Objectives of Water Balance Demonstration
1. To introduce the reader to a simple water balance model, namely, the Thorntwaite-Mather model, henceforth referred to as the T-M model (Thorntwaite et al, 1955;1957; Steenhuis et al, 1986);
2. To provide the reader with the tools to construct a water balance for her/his own region of interest, with the help of video tutorials and a sample Excel spreadsheet that can be downloaded and modified.
This document is intended for general instructive purposes for an audience that has some basic knowledge of water resources and associated terminology. No advanced expertise should be needed to understand and use this tutorial.
There can be various models to construct water balance of an area; the model that is used here for demonstration is T-M Model which has an advantage of being one of the most simple models. It can be used to determine a general estimate of the water balance regime, for individual fields to small watersheds.
Applications and Limitations : However, as in all scientific investigation, this tutorial should be used responsibly and with a full knowledge of the user's specific study area. This model and its variants have been used, for example, for irrigation scheduling of individual fields, water budgeting of small watersheds, generating actual evapotranspiration estimates for comparison with other methods - to name a few applications.
Being a lumped model, in the form described, the T-M model does not provide spatially distributed predictions, nor does it perform flow routing routines.
Composting toilets – the future of sanitation?
Ask any water supply board engineer and he will tell you that the bigger headache is sewage management and not water supply. Statistics will also show that almost all of India has access to water supply –of varying quantity and quality no doubt- but far too few have access to good sanitation.
The Millennium Development Goal adopted by the UN in September 2000 and of which India is a signatory seeks to halve the number of people without access to sanitation by 2015. That means India will have to build at least half of 115 million toilets to cover half of 78% of our rural population and 24% of its urban population un-served sanitation units by the year. A huge task indeed.
Typical sanitation solutions have included the septic tank or simply a pit latrine. Both tend to pollute ground water and are environmentally unsatisfactory. Even in water resource rich area like Goa or Kerala inadequate sanitation has ended up contaminating ground water to such an extent that many wells are unusable. Sanitation and water supply are inextricably linked. If it is not ‘fouling the nest’ it is the unavailability of water which has made many toilets unusable in rural area. If you do not have water to drink will you use it for a toilet?
On the other hand area wide underground sewerage systems with treatment facilities are difficult to provide and are costly ventures. They tend to be energy consuming and generally do not work satisfactorily. For scattered houses in outlying areas of cities, in villages, in places with a high water table and in hard rock area technically appropriate solutions are either not available or are costly to implement.
In such a scenario one emerging solution is a dry composting toilet. A composting toilet collects human waste and converts it to a fertilizer resource for plant growth without polluting water bodies or groundwater.
One such urine separating composting toilet system looks like this
An Eco-san separating pan
Tin drum for faeces and barrel for urine collection
The front portion of the pan is for the urine and the rear part with a cover is for the faeces, much like the plumbing system in human beings. After using the toilet the faeces is covered with sawdust. If toilet papers are used they are also put in the portion where the faeces go, alternately wash water can also go there. The important point is to cover the used portion completely with sawdust. The toilet is surprisingly a no smell toilet and there are no other problems of flies, gnats or insects. The urine is collected in a plastic barrel and after dilution with water in proportions of 1 to 3 or 1 to 8 can be used for plants, especially trees, where it makes a good fertilizer with its high nitrogen content.
The faeces is collected in a tin box and once the tin box is full it is replaced
with another. The full box is allowed to compost for 3 weeks and then transferred for further composting to either a large composting drum or to to an earthen pit. When covered with leaves the material composts very well in about 3 to 6 months and can be used as a soil nutrient.
Waste composting in two tin drums
below the rain water collection drum
Tippy tap’ for washing with minimum water
For washing purpose a ‘tippy tap’ – a product developed by the Centre for Applied Rural Technology, Mysore- can be used with which the wash job can be done along with hand cleaning with as less as 80 ml of water. The ‘tippy tap’ can be placed in the toilet for washing along with a saw dust container for covering the faeces.
This ecological method of sanitation consumes less than a litre of water per day for a family, converts human waste to a fertilizer resource, is clean, hygienic and functional and can be constructed almost anywhere irrespective of high water tables, hard rock below the ground or any other conditions which prevent the construction of regular toilets. By harvesting water from the rooftop of the toilet into a simple 200 litre drum all the water requirement of washing in the toilet can be met by the toilet roof itself.
Rooftop rain collected in a 200 litre drum for use in Eco-san
The urine separating WC’s are available not only in the Indian type but also in the European type. These toilets are being used in individual houses as well as flats.Eco-san alternatives are coming up in many places in the world including Sweden, Germany, Denmark, the USA, China and Sri Lanka to name a few. India too has its Eco-san heroes in Dr Bindeshwar Pathak of the Sulabh movement and Paul Calvert in Trivandrum, Kerala.
S.Vishwanath and Chitra Vishwanath
www.inika.com/chitra
www.rainwaterclub.org
For more information log on to www.rainwaterclub.org or call 080-23641690.
The Millennium Development Goal adopted by the UN in September 2000 and of which India is a signatory seeks to halve the number of people without access to sanitation by 2015. That means India will have to build at least half of 115 million toilets to cover half of 78% of our rural population and 24% of its urban population un-served sanitation units by the year. A huge task indeed.
Typical sanitation solutions have included the septic tank or simply a pit latrine. Both tend to pollute ground water and are environmentally unsatisfactory. Even in water resource rich area like Goa or Kerala inadequate sanitation has ended up contaminating ground water to such an extent that many wells are unusable. Sanitation and water supply are inextricably linked. If it is not ‘fouling the nest’ it is the unavailability of water which has made many toilets unusable in rural area. If you do not have water to drink will you use it for a toilet?
On the other hand area wide underground sewerage systems with treatment facilities are difficult to provide and are costly ventures. They tend to be energy consuming and generally do not work satisfactorily. For scattered houses in outlying areas of cities, in villages, in places with a high water table and in hard rock area technically appropriate solutions are either not available or are costly to implement.
In such a scenario one emerging solution is a dry composting toilet. A composting toilet collects human waste and converts it to a fertilizer resource for plant growth without polluting water bodies or groundwater.
One such urine separating composting toilet system looks like this
An Eco-san separating pan
Tin drum for faeces and barrel for urine collection
The front portion of the pan is for the urine and the rear part with a cover is for the faeces, much like the plumbing system in human beings. After using the toilet the faeces is covered with sawdust. If toilet papers are used they are also put in the portion where the faeces go, alternately wash water can also go there. The important point is to cover the used portion completely with sawdust. The toilet is surprisingly a no smell toilet and there are no other problems of flies, gnats or insects. The urine is collected in a plastic barrel and after dilution with water in proportions of 1 to 3 or 1 to 8 can be used for plants, especially trees, where it makes a good fertilizer with its high nitrogen content.
The faeces is collected in a tin box and once the tin box is full it is replaced
with another. The full box is allowed to compost for 3 weeks and then transferred for further composting to either a large composting drum or to to an earthen pit. When covered with leaves the material composts very well in about 3 to 6 months and can be used as a soil nutrient.
Waste composting in two tin drums
below the rain water collection drum
Tippy tap’ for washing with minimum water
For washing purpose a ‘tippy tap’ – a product developed by the Centre for Applied Rural Technology, Mysore- can be used with which the wash job can be done along with hand cleaning with as less as 80 ml of water. The ‘tippy tap’ can be placed in the toilet for washing along with a saw dust container for covering the faeces.
This ecological method of sanitation consumes less than a litre of water per day for a family, converts human waste to a fertilizer resource, is clean, hygienic and functional and can be constructed almost anywhere irrespective of high water tables, hard rock below the ground or any other conditions which prevent the construction of regular toilets. By harvesting water from the rooftop of the toilet into a simple 200 litre drum all the water requirement of washing in the toilet can be met by the toilet roof itself.
Rooftop rain collected in a 200 litre drum for use in Eco-san
The urine separating WC’s are available not only in the Indian type but also in the European type. These toilets are being used in individual houses as well as flats.Eco-san alternatives are coming up in many places in the world including Sweden, Germany, Denmark, the USA, China and Sri Lanka to name a few. India too has its Eco-san heroes in Dr Bindeshwar Pathak of the Sulabh movement and Paul Calvert in Trivandrum, Kerala.
S.Vishwanath and Chitra Vishwanath
www.inika.com/chitra
www.rainwaterclub.org
For more information log on to www.rainwaterclub.org or call 080-23641690.
बुधवार, 3 सितंबर 2008
Overuse of ground water poses environmental threat to Asia
A recent study found underground water is being exploited faster than it can be replenished in many Asian nations. — VNS File Photo
Bali — The overuse of ground water resources is becoming a huge threat to Asian nations, warned environmental experts at a seminar in Bali, Indonesia.
Professor Brahma Chellaney, from the India-based Strategic Studies Centre for Policy Research, said underground water in Asia is being pumped to the surface at such a high rate that the ground water can not be replenished by rain.
"Over-exploitation of aquifers will affect ecosystems, and in turn accelerate global warming," said Dr Chellaney, speaking at the two-day seminar on the strategic Importance of water in Asia.
The seminar, organised by the Konrad Adenauer Foundation (KAF)last week, aimed to help Asian journalists specialising in environmental issues to better understand the current water shortage in Asia and the ramifications for the future.
An example of the immediate results of ground water overuse was raised by Julian Gearing, correspondent for Asia Times in Bangkok, who said one of the reasons why pavements and sidewalks in Bangkok were sinking was overuse of aquifers.
"A majority of people in Bangkok rely on piped water and don’t
pump water from wells," said Gearing. "They are not aware of the strain being put on the aquifers largely by large and small-scale industry."
Dr Chellaney said rapid urban expansion in China’s capital Beijing, with a population of 17 million, was exhausting the local water supply.
More than two-thirds of Beijing’s water supply is now pumped from subterranean reserves.
In addition to concerns over the over-exploitation of underground water, pollution is also presenting another formidable challenge as levels of heavy metals and arsenic rise in some natural water supplies.
Agricultural pollutants, such as fertilisers and pesticides, and industrial pollutants were also seeping into ground water reserves in many areas.
Ha Noi’s sinking
The increasing use of ground water by urban households has caused severe pollution in Viet Nam’s capital city Ha Noi.
The capital’s current underground water use is about 700,000 cu.m a day and is predicted to rise two fold by 2010. It is one of the factors leading to the sinking ground in many parts of the city, according to the Ha Noi Institute for Science Technology and Construction Economics.
Participants at Bali’s seminar agreed that national governments should improve management of underground exploitation and better protect existing ground water reserves.
The seminar also agreed that Asian nations will have to solve eleven major water problems, including massive water-use by the agricultural sector, conflicts over water resources, shortages of drinking water, floods, rising demand for water in industrial use, ownership and pricing of water, pollution, river use, sanitation, underground water use and water resource threats. — VNS
Marine team sounds alarm for reefs
Fourteen scientists warn of the necessity of reducing carbon dioxide to save coral
By Helen Altonn
Recommendations to prevent what one scientist calls "osteoporosis of the reef" have been presented to the U.S. Coral Reef Task Force, holding its final meeting of the International Year of the Reef in Kona.
Fourteen leading climate and marine scientists and coral reef managers from the U.S. and Australia developed the "Honolulu Declaration on Ocean Acidification and Reef Management" during a workshop convened here by the Nature Conservancy two weeks ago.
Presenting the findings and recommendations to the task force at a business meeting Wednesday was Rod Salm, the conservancy's tropical marine conservation director for the Asia-Pacific area.
"The reefs of the world are at risk, and Hawaii's isolated reefs are especially vulnerable to stresses of any kind, particularly to the rapidly emerging stress brought on by climate change," he told the task force.
Suzanne Case, executive director of the conservancy in Hawaii, said: "Coral reefs are the lifeblood of our oceans, and we depend on them for survival.
"Without urgent action to limit carbon dioxide emissions and improve management of marine protected areas, even vast treasured reefs like the Great Barrier Reef and Northwestern Hawaiian Islands will become wastelands of dead coral."
The "Honolulu declaration" will be presented to the United Nations and to other national, regional and international forums to obtain commitments to address what marine scientists call "the greatest climate change threat facing coral reefs globally."
The ocean absorbs about one-third of atmospheric carbon dioxide, which combines with sea water to form carbonic acid, a process called ocean acidification. Carbonic acid erodes calcium carbonate needed by corals and other calcifying organisms to build their skeletons.
"The most important, overarching thing is to stabilize CO2 emissions," Salm said in an interview. But the scientists recognize that is "a long, convoluted political process" and that there would be a lag time even if it were accomplished because of a reservoir of atmospheric carbon dioxide dissolving in sea water, he said.
"Our goal was to work on ways we could buy time for coral reefs while CO2 levels are stabilized and eventually, hopefully, rolled back."
Atmospheric carbon dioxide is expected to double in 50 years if current emission trends continue and "ocean acidification will continue to an extent and at rates that have not occurred for tens of millions of years," Salm said.
"Ocean acidification is creeping, progressive and insidious ... a weakening of the reef structure that makes corals more vulnerable to breakage from waves and human use."
Unlike mass coral bleaching, when corals stressed by increased temperature become white, it is difficult to detect when any coral species is threatened by acidification, he said.
"The best evidence we have suggests that when atmospheric CO2 levels reach 560 parts per million, many reefs will already have moved from net growth to net erosion." The current level is 385 parts per million, he said.
"There is hope in what came out of our workshop because we have come up with practical steps people can take that are not hugely costly and will not marginalize progress made," Salm said.
The most practical policy is to mandate that climate change actions, including those addressing rising ocean acidification, sea level and temperatures, be included in marine protected management plans, he said.
On the management side, he said, "The most obvious thing that needs to be done is to put all efforts possible into reducing as many stresses on the reef systems as we can" from people, boats, overfishing, pollution and other destructive impacts.
The less stressed corals are, the more healthy and resilient they are and better able to respond to climate changes, he said.
More science also is needed to identify less vulnerable coral reefs - those most likely to survive changing ocean conditions - so they can be protected, he said.
"I think it's very encouraging," he added. "I just hope we're able to buy time long enough to get CO2 emissions under control."
By Helen Altonn
Recommendations to prevent what one scientist calls "osteoporosis of the reef" have been presented to the U.S. Coral Reef Task Force, holding its final meeting of the International Year of the Reef in Kona.
Fourteen leading climate and marine scientists and coral reef managers from the U.S. and Australia developed the "Honolulu Declaration on Ocean Acidification and Reef Management" during a workshop convened here by the Nature Conservancy two weeks ago.
Presenting the findings and recommendations to the task force at a business meeting Wednesday was Rod Salm, the conservancy's tropical marine conservation director for the Asia-Pacific area.
"The reefs of the world are at risk, and Hawaii's isolated reefs are especially vulnerable to stresses of any kind, particularly to the rapidly emerging stress brought on by climate change," he told the task force.
Suzanne Case, executive director of the conservancy in Hawaii, said: "Coral reefs are the lifeblood of our oceans, and we depend on them for survival.
"Without urgent action to limit carbon dioxide emissions and improve management of marine protected areas, even vast treasured reefs like the Great Barrier Reef and Northwestern Hawaiian Islands will become wastelands of dead coral."
The "Honolulu declaration" will be presented to the United Nations and to other national, regional and international forums to obtain commitments to address what marine scientists call "the greatest climate change threat facing coral reefs globally."
The ocean absorbs about one-third of atmospheric carbon dioxide, which combines with sea water to form carbonic acid, a process called ocean acidification. Carbonic acid erodes calcium carbonate needed by corals and other calcifying organisms to build their skeletons.
"The most important, overarching thing is to stabilize CO2 emissions," Salm said in an interview. But the scientists recognize that is "a long, convoluted political process" and that there would be a lag time even if it were accomplished because of a reservoir of atmospheric carbon dioxide dissolving in sea water, he said.
"Our goal was to work on ways we could buy time for coral reefs while CO2 levels are stabilized and eventually, hopefully, rolled back."
Atmospheric carbon dioxide is expected to double in 50 years if current emission trends continue and "ocean acidification will continue to an extent and at rates that have not occurred for tens of millions of years," Salm said.
"Ocean acidification is creeping, progressive and insidious ... a weakening of the reef structure that makes corals more vulnerable to breakage from waves and human use."
Unlike mass coral bleaching, when corals stressed by increased temperature become white, it is difficult to detect when any coral species is threatened by acidification, he said.
"The best evidence we have suggests that when atmospheric CO2 levels reach 560 parts per million, many reefs will already have moved from net growth to net erosion." The current level is 385 parts per million, he said.
"There is hope in what came out of our workshop because we have come up with practical steps people can take that are not hugely costly and will not marginalize progress made," Salm said.
The most practical policy is to mandate that climate change actions, including those addressing rising ocean acidification, sea level and temperatures, be included in marine protected management plans, he said.
On the management side, he said, "The most obvious thing that needs to be done is to put all efforts possible into reducing as many stresses on the reef systems as we can" from people, boats, overfishing, pollution and other destructive impacts.
The less stressed corals are, the more healthy and resilient they are and better able to respond to climate changes, he said.
More science also is needed to identify less vulnerable coral reefs - those most likely to survive changing ocean conditions - so they can be protected, he said.
"I think it's very encouraging," he added. "I just hope we're able to buy time long enough to get CO2 emissions under control."
Marine team sounds alarm for reefs
Fourteen scientists warn of the necessity of reducing carbon dioxide to save coral
By Helen Altonn
Recommendations to prevent what one scientist calls "osteoporosis of the reef" have been presented to the U.S. Coral Reef Task Force, holding its final meeting of the International Year of the Reef in Kona.
Fourteen leading climate and marine scientists and coral reef managers from the U.S. and Australia developed the "Honolulu Declaration on Ocean Acidification and Reef Management" during a workshop convened here by the Nature Conservancy two weeks ago.
Presenting the findings and recommendations to the task force at a business meeting Wednesday was Rod Salm, the conservancy's tropical marine conservation director for the Asia-Pacific area.
"The reefs of the world are at risk, and Hawaii's isolated reefs are especially vulnerable to stresses of any kind, particularly to the rapidly emerging stress brought on by climate change," he told the task force.
Suzanne Case, executive director of the conservancy in Hawaii, said: "Coral reefs are the lifeblood of our oceans, and we depend on them for survival.
"Without urgent action to limit carbon dioxide emissions and improve management of marine protected areas, even vast treasured reefs like the Great Barrier Reef and Northwestern Hawaiian Islands will become wastelands of dead coral."
The "Honolulu declaration" will be presented to the United Nations and to other national, regional and international forums to obtain commitments to address what marine scientists call "the greatest climate change threat facing coral reefs globally."
The ocean absorbs about one-third of atmospheric carbon dioxide, which combines with sea water to form carbonic acid, a process called ocean acidification. Carbonic acid erodes calcium carbonate needed by corals and other calcifying organisms to build their skeletons.
"The most important, overarching thing is to stabilize CO2 emissions," Salm said in an interview. But the scientists recognize that is "a long, convoluted political process" and that there would be a lag time even if it were accomplished because of a reservoir of atmospheric carbon dioxide dissolving in sea water, he said.
"Our goal was to work on ways we could buy time for coral reefs while CO2 levels are stabilized and eventually, hopefully, rolled back."
Atmospheric carbon dioxide is expected to double in 50 years if current emission trends continue and "ocean acidification will continue to an extent and at rates that have not occurred for tens of millions of years," Salm said.
"Ocean acidification is creeping, progressive and insidious ... a weakening of the reef structure that makes corals more vulnerable to breakage from waves and human use."
Unlike mass coral bleaching, when corals stressed by increased temperature become white, it is difficult to detect when any coral species is threatened by acidification, he said.
"The best evidence we have suggests that when atmospheric CO2 levels reach 560 parts per million, many reefs will already have moved from net growth to net erosion." The current level is 385 parts per million, he said.
"There is hope in what came out of our workshop because we have come up with practical steps people can take that are not hugely costly and will not marginalize progress made," Salm said.
The most practical policy is to mandate that climate change actions, including those addressing rising ocean acidification, sea level and temperatures, be included in marine protected management plans, he said.
On the management side, he said, "The most obvious thing that needs to be done is to put all efforts possible into reducing as many stresses on the reef systems as we can" from people, boats, overfishing, pollution and other destructive impacts.
The less stressed corals are, the more healthy and resilient they are and better able to respond to climate changes, he said.
More science also is needed to identify less vulnerable coral reefs - those most likely to survive changing ocean conditions - so they can be protected, he said.
"I think it's very encouraging," he added. "I just hope we're able to buy time long enough to get CO2 emissions under control."
By Helen Altonn
Recommendations to prevent what one scientist calls "osteoporosis of the reef" have been presented to the U.S. Coral Reef Task Force, holding its final meeting of the International Year of the Reef in Kona.
Fourteen leading climate and marine scientists and coral reef managers from the U.S. and Australia developed the "Honolulu Declaration on Ocean Acidification and Reef Management" during a workshop convened here by the Nature Conservancy two weeks ago.
Presenting the findings and recommendations to the task force at a business meeting Wednesday was Rod Salm, the conservancy's tropical marine conservation director for the Asia-Pacific area.
"The reefs of the world are at risk, and Hawaii's isolated reefs are especially vulnerable to stresses of any kind, particularly to the rapidly emerging stress brought on by climate change," he told the task force.
Suzanne Case, executive director of the conservancy in Hawaii, said: "Coral reefs are the lifeblood of our oceans, and we depend on them for survival.
"Without urgent action to limit carbon dioxide emissions and improve management of marine protected areas, even vast treasured reefs like the Great Barrier Reef and Northwestern Hawaiian Islands will become wastelands of dead coral."
The "Honolulu declaration" will be presented to the United Nations and to other national, regional and international forums to obtain commitments to address what marine scientists call "the greatest climate change threat facing coral reefs globally."
The ocean absorbs about one-third of atmospheric carbon dioxide, which combines with sea water to form carbonic acid, a process called ocean acidification. Carbonic acid erodes calcium carbonate needed by corals and other calcifying organisms to build their skeletons.
"The most important, overarching thing is to stabilize CO2 emissions," Salm said in an interview. But the scientists recognize that is "a long, convoluted political process" and that there would be a lag time even if it were accomplished because of a reservoir of atmospheric carbon dioxide dissolving in sea water, he said.
"Our goal was to work on ways we could buy time for coral reefs while CO2 levels are stabilized and eventually, hopefully, rolled back."
Atmospheric carbon dioxide is expected to double in 50 years if current emission trends continue and "ocean acidification will continue to an extent and at rates that have not occurred for tens of millions of years," Salm said.
"Ocean acidification is creeping, progressive and insidious ... a weakening of the reef structure that makes corals more vulnerable to breakage from waves and human use."
Unlike mass coral bleaching, when corals stressed by increased temperature become white, it is difficult to detect when any coral species is threatened by acidification, he said.
"The best evidence we have suggests that when atmospheric CO2 levels reach 560 parts per million, many reefs will already have moved from net growth to net erosion." The current level is 385 parts per million, he said.
"There is hope in what came out of our workshop because we have come up with practical steps people can take that are not hugely costly and will not marginalize progress made," Salm said.
The most practical policy is to mandate that climate change actions, including those addressing rising ocean acidification, sea level and temperatures, be included in marine protected management plans, he said.
On the management side, he said, "The most obvious thing that needs to be done is to put all efforts possible into reducing as many stresses on the reef systems as we can" from people, boats, overfishing, pollution and other destructive impacts.
The less stressed corals are, the more healthy and resilient they are and better able to respond to climate changes, he said.
More science also is needed to identify less vulnerable coral reefs - those most likely to survive changing ocean conditions - so they can be protected, he said.
"I think it's very encouraging," he added. "I just hope we're able to buy time long enough to get CO2 emissions under control."
What Flow From Dams
D. Murali
Chennai: The major outputs of a multi-purpose dam and reservoir project include hydropower, irrigated agriculture, water supply, fishing, flood control, drought prevention, and the value of recreational activities and tourism revenues. But there are also many negative direct impacts such as costs of resettlement, value of lost ecosystem, submerged cultural heritage, and reduction in fish output upstream, reminds a new book: ‘Indirect Economic Impacts of Dams: Case Studies from India, Egypt and Brazil’ edited by Ramesh Bhatia, Rita Cestti, Monica Scatasta and R.P.S. Malik (www.academicfoundation.com).
They group, under the indirect economic impacts, the inter-industry linkages (backward and forward, resulting in an increase in the demand for outputs for other sectors), and consumption-induced impacts arising from additional incomes generated by the dam project. The authors argue that accounting for these impacts is necessary for facilitating more informed decisions relating to the funding of the project and also its subsequent evaluation.
Indirect effects can be measured through estimation of multipliers, the book explains. For example, a multiplier of 1.75 shows that for every one rupee of value-add generated directly by a project at maturity, another 75 paise are generated in the form of indirect effects.
Reservoir of findings!
Agriculture, a growth engine
There are a few States in India where the procurement of agricultural products at minimum support price (MSP) is undertaken even when the market prices are higher than the MSP, while at the same time there are States where the farmers are not able to sell their produce to the procurement agencies with market prices collapsing below MSP.
How paradoxical, observes R.S. Deshpande in one of the essays included in ‘Reforming Indian Agriculture: Towards Employment Generation and Poverty Reduction,’ edited by Sankar Kumar Bhaumik (www.sagepublications.com).
The author describes three models of grain procurement. “The first model is that of Punjab, Haryana, and Uttar Pradesh, where the procurement agencies are well set and the procurement of grains is a regular activity.” In these places, distress caused to farmers is minimum; and the farmers’ political lobby keeps the MSP moving up, says Deshpande.
“The second model is the bureaucratic circuitous route of procurement existing in Maharashtra, Andhra Pradesh, Karnataka, Gujarat, and West Bengal.” Here, the time lag between the price collapse and actual procurement goes through a lot of circuitous procedures; so much so, the policy becomes redundant and ineffective, the author bemoans.
The third model, according to him, is what Tamil Nadu, Bihar, and Madhya Pradesh follow, by selectively effecting procurement to a few regions, crops, and groups of farmers.
Chennai: The major outputs of a multi-purpose dam and reservoir project include hydropower, irrigated agriculture, water supply, fishing, flood control, drought prevention, and the value of recreational activities and tourism revenues. But there are also many negative direct impacts such as costs of resettlement, value of lost ecosystem, submerged cultural heritage, and reduction in fish output upstream, reminds a new book: ‘Indirect Economic Impacts of Dams: Case Studies from India, Egypt and Brazil’ edited by Ramesh Bhatia, Rita Cestti, Monica Scatasta and R.P.S. Malik (www.academicfoundation.com).
They group, under the indirect economic impacts, the inter-industry linkages (backward and forward, resulting in an increase in the demand for outputs for other sectors), and consumption-induced impacts arising from additional incomes generated by the dam project. The authors argue that accounting for these impacts is necessary for facilitating more informed decisions relating to the funding of the project and also its subsequent evaluation.
Indirect effects can be measured through estimation of multipliers, the book explains. For example, a multiplier of 1.75 shows that for every one rupee of value-add generated directly by a project at maturity, another 75 paise are generated in the form of indirect effects.
Reservoir of findings!
Agriculture, a growth engine
There are a few States in India where the procurement of agricultural products at minimum support price (MSP) is undertaken even when the market prices are higher than the MSP, while at the same time there are States where the farmers are not able to sell their produce to the procurement agencies with market prices collapsing below MSP.
How paradoxical, observes R.S. Deshpande in one of the essays included in ‘Reforming Indian Agriculture: Towards Employment Generation and Poverty Reduction,’ edited by Sankar Kumar Bhaumik (www.sagepublications.com).
The author describes three models of grain procurement. “The first model is that of Punjab, Haryana, and Uttar Pradesh, where the procurement agencies are well set and the procurement of grains is a regular activity.” In these places, distress caused to farmers is minimum; and the farmers’ political lobby keeps the MSP moving up, says Deshpande.
“The second model is the bureaucratic circuitous route of procurement existing in Maharashtra, Andhra Pradesh, Karnataka, Gujarat, and West Bengal.” Here, the time lag between the price collapse and actual procurement goes through a lot of circuitous procedures; so much so, the policy becomes redundant and ineffective, the author bemoans.
The third model, according to him, is what Tamil Nadu, Bihar, and Madhya Pradesh follow, by selectively effecting procurement to a few regions, crops, and groups of farmers.
Desertification of Terai region of Nepal
Every day, 2000 trucks have been exporting sand and stone to India from Kanchanpur to Maorang. Nowadays, by the side of the southern boarder of Nepal, government of India is constructing highway. Stone and sand are cheap in Nepal, so Indian contractors are buying it materials from Nepal. Export will certainly help to Nepali economy. However, it will increase desertification of Terai.
One truck can carry 20 cubic feet, in average, construction materials. Hence, everyday, 40 thousand cubic feet materials have been exporting India. Nepali exporters are earning Rs 21,500 profit per truck. Therefore, this is very attractive dealing for Nepali. Export permission is granted by District Development Committee, Forest Office and Customs office. All government agencies are concentrating only from economic perspective. Nobody is focusing impact of export on environment of Chure and Terai region.
Level of river is deepening in some areas of Terai region. Irrigation system is not working in Butwal areas due to low level of water in some river. Next year, these problems will be increased rapidly in other parts also. In addition, breadth of river is increasing in Terai region.
Chure area is fragile from the point of geological point of view. Its structure is weak. Nowadays, people started to take out stone from this reason. During rainy season, rivers which are flowing from these areas may leave soil and other debris in terai region. Agriculture land will be filled with such a unnecessary materials. In the end livelihood of farmer of terai region will be very much painful.
Government has made plan to implement Integrated Watershed Programme in Chure area. It has purpose Chure-Terai development programme. On the other hand, National Park and Wildlife Act and Regulation mentioned that only local people can use forest resources for their use only, not for commercial purpose. According to act, wood, stone are forest resources. People can not take these resources outside that area. It clearly shows that act has not given permission to use forest resources for commercial purpose.
It is time to study the situation of Chure-Terai region and find some area and quantity which can be taken or extracted. However, it would affect less for environment. On the other hand, revenue should be increased by making competition among buyers. Nevertheless, sustainable development should be prime concern.
One truck can carry 20 cubic feet, in average, construction materials. Hence, everyday, 40 thousand cubic feet materials have been exporting India. Nepali exporters are earning Rs 21,500 profit per truck. Therefore, this is very attractive dealing for Nepali. Export permission is granted by District Development Committee, Forest Office and Customs office. All government agencies are concentrating only from economic perspective. Nobody is focusing impact of export on environment of Chure and Terai region.
Level of river is deepening in some areas of Terai region. Irrigation system is not working in Butwal areas due to low level of water in some river. Next year, these problems will be increased rapidly in other parts also. In addition, breadth of river is increasing in Terai region.
Chure area is fragile from the point of geological point of view. Its structure is weak. Nowadays, people started to take out stone from this reason. During rainy season, rivers which are flowing from these areas may leave soil and other debris in terai region. Agriculture land will be filled with such a unnecessary materials. In the end livelihood of farmer of terai region will be very much painful.
Government has made plan to implement Integrated Watershed Programme in Chure area. It has purpose Chure-Terai development programme. On the other hand, National Park and Wildlife Act and Regulation mentioned that only local people can use forest resources for their use only, not for commercial purpose. According to act, wood, stone are forest resources. People can not take these resources outside that area. It clearly shows that act has not given permission to use forest resources for commercial purpose.
It is time to study the situation of Chure-Terai region and find some area and quantity which can be taken or extracted. However, it would affect less for environment. On the other hand, revenue should be increased by making competition among buyers. Nevertheless, sustainable development should be prime concern.
INTERVIEW WITH DIPAK GYAWALI
Gyawali spoke with Puran P Bista and Ghanashyam Ojha.
Excerpts
Q: Why did the Koshi breach its embankment? Who was responsible for the repair work-- India or Nepal?
DipakG: It is important to step back a bit to realize that this catastrophe happened because of the unholy confluence of three things: wrong technological choice for this kind of a hydro-ecological regime, wrong institutional arrangements resulting from the Koshi Treaty that are not right for managing this kind of a trans-boundary river system, and wrong conduct in public service over the last half-century, which includes aspects of corruption as well as what people in Delhi like to deride as “Bihari politics”, but has been an intrinsic part of Independent India. After all, when the British left India, Bihar was one of the most advanced states of India, Patna University one of the top universities (which helped found Tribhuwan University), and when my grandmother was ill in Taulihawa, my father and grandfather took her, not to Lucknow nearby or Delhi but to Patna for treatment because the hospital there was the best. Today can we say the same for Independent India's Bihar? I argue that this decline in Bihar's prosperity absolutely matches the rise in “Bihari politics” brought about in no small measure by the Koshi project.
But let us start with the technological aspect, when the lateral, left-bank embankment (not the barrage across the river) collapsed on 18th August: it was not a natural disaster, but a man-made tragedy. The river flow at the time was lower than the minimum average flow for the month of August, and hence not even close to a normal flood, which had not even begun during this monsoon. In the Koshi, it generally occurs from mid-August to mid-September, and when this natural stress is added to a man-made tragedy, together they have all the potential to become a major calamity of a generation.
Q: Why is this project the wrong technological choice?
DipakG: Koshi is one of the most violent rivers in the world because it is not just a river with water in it but also a massive conveyor belt of sediment from the Himalaya to the Bay of Bengal. This is a natural geological process that is responsible for creating not just Bangladesh but also much of Bihar out of the ancient Tethys Sea. Some one hundred million cubic meters of gravel, sand and mud flow out of Chatara every year. Lest we forget, all the collected water and matter brought by Tamor, Arun and Sun Kosi rivers, all the way from Kanchenjunga in the east, through Makalu and Everest to Langtang in the west have to pass through this one gorge at Chatara. And as the river slows down in the flat Tarai plains, the sediment settles down raising the river bed and forcing the river to overflow its bank before finding a new course.
This process has essentially created the inland delta over which the Koshi has swung from Supaul in the west to Katihar in the east, like a pendulum suspended at Chatara. In the last half century, this process has been arrested by “jacketing” the Koshi within embankments at the western extreme of the delta; but this has only forced the river to deposit all the sediment within this narrow “jacket”, raised the river bed, perching the river some four meters above the surrounding land. It was a recipe ripe for this kind of catastrophe to eventually happen, as it has now.
You have to be extremely careful when you start fooling around with such awesome forces of nature. What happens when you do so without proper understanding can be easily studied on the Tinau, south of Butwal: in 1961, India built the Hattisunde barrage on the Tinau's inland delta to supply irrigation water to Marchawar in the south, but the river changed course in the following year and the barrage has been standing high and dry since then, a tribute to man's stupidity, and an equally great tribute to his incapacity to learn from mistakes. You don't build such hydro-technical structures on an unstable delta fan, and the Koshi today is just Tinau repeated at a more massive scale.
Q: What do we know of the science behind these things?
DipakG: We have been studying the Tinau and its problems since the mid-1990s, which is just the same as the Koshi except at a much smaller scale. For the Koshi, the best example is the comparison of current river flow conditions of the lower Ganga with the map prepared in 1779 by Colonel Rennel for Governor General Warren Hastings. His map shows us that the Koshi actually joined the Mechi-Mahananda, which joined the Teesta. While the Koshi has swung west, the Teesta itself has swung east to meet the Brahmaputra, while the Brahmaputra has swung from meeting the Megna to meeting the Ganga. This shows how extremely volatile the dynamically shifting pattern of this region's hydro-ecological is.
This disaster was waiting to happen because the intervention into the natural regime through the Koshi project was bad science that ignored the problem of sediment in the river. As regards science, we should also remember that deforestation has really no significant linkage with Koshi sedimentation: we have more forest cover in the Koshi catchment today, thanks also to community forestry, than we ever did in our past history; and the Myth of Himalayan Degradation (that floods in Bangladesh are due to poor farmers in Nepal cutting trees) has been scientifically debunked over two decades ago. It is Himalayan geo-tectonics coupled with the monsoon regime that is the cause of Koshi sedimentation and floods, and that cannot be battled against with bad science and even worse policy prescriptions of indiscriminate embankment building following from such bad science.
Q: Can we repair the breach once the monsoon is over?
DipakG: I doubt it, simply because the breach now is no longer a rupture in the side embankment that can be plugged once the water level goes down and the Koshi starts flowing along its original main channel. What we are seeing is the main stem of the river itself flowing through it, capturing centuries' old channel and changing its course. To change it back is like damming the Koshi anew with a new barrage, in addition to making the river do a “high jump” of at least four meters to flow along its recently abandoned bed. Believe me, it won't be too happy doing that now or in the coming years, and will find some way to continuously breach the embankment in other weak spots, and no engineer can guarantee that this won't happen, although they will have lots of fun playing with all kinds of expensive toys “to tame the Koshi”.
The problem now is no longer just the breach at Kusaha in Nepal: it is totally uncertain where the new Koshi channel will be in the middle and lower delta in Bihar. Currently, satellite pictures show that it might be moving along the Supaul channel; but I think this might just be a massive ponding that is occurring with Koshi filling every depression, canal, old oxbow lake or the space between the indiscriminately built embankments. Since the land naturally slopes eastwards, depending upon whether the coming September floods are a four lakh cusecs flood or a nine lakh one (as happened in 1968) the new Koshi could be as far east as Katihar. Even if it does not go that far this year, it is inevitable it will do so in the years to come. This river morphology dynamics has to be looked at before any new embankments or repairs of old ones can be considered.
Q: What might be correct technology then?
DipakG: First, let us put to rest another wrong technology, a high dam on the Koshi. It is wrong because it would take two or more decades to construct, thus failing to address problems of current and immediate future concerns, is extremely expensive, does not address the primary problem of sedimentation (the reservoir will fill up too soon with Himalayan muck), has no convincing answer regarding the cost of attending to high seismicity in the region as well as diversion of peak instantaneous flood during construction (it is a major engineering challenge with no easy solution), and will create more social problems when indigenous population in Nepal have to be evicted from their ancestral homes. A Koshi high dam would be tantamount to Nepal importing downstream seasonal floods as permanent features of its landscape for questionable benefits to it. I think neither India nor Nepal is in a position to afford the technical, economic and social costs associated with it.
The immediate requirements of Nepal and Bihar (and by immediate I mean from now till ten or so years) will have to be met by new and alternative technologies suited to an unstable but very fertile flood plain. Such adaptive technologies with strong social components have been traditionally used by people in the form of houses on stilts and building villages with raised plinth levels that keep life and property safe but allow the flood to easily pass by leaving fertile silt behind. It will also call into serious question the current design practices in the transportation, housing, agriculture and other sectors, forcing the adopting of new approaches that look not so much to the watershed but to the 'problemshed' for answers. There is nothing called a permanent solution (how 'permanent' is a permanent concrete dam, after all?); but building houses on stilts is a cheaper, more 'doable' and thus a better solution.
Q: Why do you say that the current management setup of the Koshi barrage and embankments was a wrong institutional arrangement?
DipakG: The answer to that question can come from looking at the highly undiplomatic and breathtakingly ill-informed statement that came out from the Indian embassy in the immediate aftermath of the breach by blaming Nepal for it. When forcing the Koshi Treaty on Nepal in the 1950s, India took upon itself all responsibility for design, construction, operation and maintenance of the Koshi project, leaving Nepal absolutely no room to do anything except allow India to quarry all the boulders they like (which incidentally are rarely used in the Koshi but find themselves black marketed to all the aggregate crushers from Muzzafferpur to Siliguri!!)
The Koshi Treaty has been criticized very often for many reasons, but the reason some of us from the socio-environmental solidarity to criticize it is because of the neo-colonial mode that is built into its institutional make-up. Instead of a proper bi-national management arrangement, Nepal can only be a by-stander even for matters within its own territory: it can't order the opening of gates during floods or the supply of irrigation waters to its fields during the dry season. Everything is in the hands of the Delhi hydrocracy, which has conveniently (and to my mind, illegitimately) washed its hands off it by hiving it off to the Bihar hydrocracy. There is institutional irresponsibility built into the treaty at every level, which was seen at the time of its signing as a “construction” treaty rather than a management one, hence you can never get sustainable and scientific management out of it. In a tragic and perverse way, the current catastrophe has washed away the very foundations of that treaty and calls for revisiting the management of the Koshi in a more sane and equitable manner.
Q: What exactly did you mean by “bad conduct”, then?
DipakG: Even if you had a wrong institutional arrangement, right conduct could have still got things done more than semi-right. What happened here was that the entire Koshi project has become a synonym for the corruption that goes by the name of Bihari politics, which “New Nepal” seems to be importing with glee. Consider the following quote from an Indian scholar studying the problem.
Such is the racket of breaches that out of the 2.5 to 3 billion rupees spent annually by the Bihar government on construction and repair works, as much as 60 percent used to be pocketed by the politician-contractors-engineers nexus. There is a perfect system of percentages in which there is a share for everyone who matters, right from the minister to the junior engineer. The actual expenditure never exceeds 30 percent of the budgeted cost and after doling out the fixed percentages, the contractors are able to pocket as much as 25 percent of the sanctioned amount. A part of this they use to finance the political activities of their pet politicians and to get further projects sanctioned. Thus the cycle goes on. [The result is that...] the contractor's bills are paid without verifying them. The same lot for boulders and craters are shown as freshly purchased year after year and the government exchequer is duped of tens of millions. Many of the desiltation and repair and maintenance works shown to have been completed are never done at all and yet payments are made....So much is the income of the engineers from the percentages that the engineers do not bother to collect their salaries.
(Fighting the Irrigation Mafia in Bihar, by Indu Bharati in the Economic and Political Weekly from Bombay in 1991, quoted by Dipak Gyawali in his book Water in Nepal/Rivers, Technology and Society, Zed Books, London and Himal Books, Kathmandu, 2001.)
This is what I mean by “wrong conduct”. My understanding, based on information filtering out of Saptari and Sunsari and on local FM channels, is that local cadres of ruling political parties got wise to the corruption practiced from across the border and began to demand a share, which was difficult for the Bihari contractors to agree to because of the high rake-in demanded by their traditional political and civil servant bosses in Patna and higher up. There were, it seems, tough negotiations going on before the start of the monsoon season, but no agreement could be reached. No formal approach was made by the Koshi officials to the most India-friendly government in power in Nepal because the issue to be resolved was not doing the work but sharing the booty. Which is why the complaint that the contractors had come on August 8 to strengthen the embankment but were not allowed to, itself begs the question: how come you come to do the repair works (if that is what you wanted to do) in the middle of the monsoon and not in January?
Q: What should be the priority now?
DipakG: There are three things needed to be done on a war footing in order of priority:
First, this is a major humanitarian tragedy of global proportions, and it should be attended to with an open heart, generous pockets and caring hands. If Biharis are coming into Nepal because that is where the only high ground is, they should be welcomed, all relief should be provided to them too, but a record should be kept and they must be handed over to the Indian government soon after the monsoon. It must be recognized that the displaced fifty thousand or so Nepalis are in all probability permanently displaced (over their village, the new Koshi probably runs and will do so for the forseeable future) and need to be housed in camps before a permanent settlement is found. Perhaps the now emptying Bhutanese refugee camps should be used for the purpose.
Second, a bridge should be constructed over the Koshi at Chatara on a war footing and the traffic along the Mahendra highway restored to connect east Nepal with the rest of the country as soon as possible. The current Kosi barrage bridge will in all probability remain as the Hattisunde barrage on the Tinau, a defunct monument of interest to future archaeologists; but even if restored, we will need a ferry system over the new Koshi channel before we can get to it.
Third, a serious public review and debate must ensue over the Koshi project and the treaty that brought about this catastrophe. The investigations and debate must be conducted jointly by civic movements in Nepal and India so that a sane path forward can be charted. Hydrocracies of both countries can contribute to this exercise, but their judgment and legitimacy are now in question, as is their hitherto unchallenged policy hegemony.
Dipak Gyawali, former Minister for Water Resources, heads Nepal Water Conservation Foundation and is hydropower expert.
Sources Of River Pollution
The sources of pollution of Ganga or for that matter any other river can be classified broadly into two categories namely;
(i) Point sources - these are organised sources of pollution where the pollution load can be measured e.g. surface drains carrying municipal sewage or industrial effluents, sewage pumping stations and sewerage systems, trade effluents from industries etc.
(ii) Non-point sources - these are non-measurable sources of pollution such as run-off from agricultural fields carrying chemicals and fertilizers, run-off from areas used for dumping of solid waste and open defecation, dumping of unburnt/half burnt dead bodies and animal carcasses, dhobi ghats, cattle wallowing, mass bathing, floral offerings etc.
(i) Point sources - these are organised sources of pollution where the pollution load can be measured e.g. surface drains carrying municipal sewage or industrial effluents, sewage pumping stations and sewerage systems, trade effluents from industries etc.
(ii) Non-point sources - these are non-measurable sources of pollution such as run-off from agricultural fields carrying chemicals and fertilizers, run-off from areas used for dumping of solid waste and open defecation, dumping of unburnt/half burnt dead bodies and animal carcasses, dhobi ghats, cattle wallowing, mass bathing, floral offerings etc.
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