World Water Development Report 2015: water in a sustainable world

Earth is facing a 40% shortfall in water supply by 2030, unless we dramatically improve the management of this precious resource warns this latest edition of the UN World Water Development Report.

The 2015 edition of the United Nations World Water Development Report (WWDR 2015), titled Water for a Sustainable World, will be launched at the official celebration of the World Water Day, on March 20. 

The WWDR 2015 demonstrates how water resources and services are essential to achieving global sustainability. Taking account of economic growth, social equity and environmental sustainability, the report’s forward-looking narrative describes how major challenges and change factors in the 

modern world will affect – and can be affected by – water resources, services and related benefits. 

The report provides a comprehensive overview of major and emerging trends from around the world, with examples of how some of the trend‐related challenges have been addressed, their implications for policy‐makers, and further actions that can be taken by stakeholders and the international community.

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Content Courtecy :indiaenvironmentportal

These Amazing People made Mangalyaan successful. They are the reason why we are Proud.

Mangalyaan finally reached it’s orbit. It was really a proud moment for all of us. Let us look at those people who made it possible. Feel free to hit share.

Anxious moments at ISRO work desk, moments before Chandrayaan reached its orbit.

Women Power- Women played a significant role in the upliftment of the society, but now they have achieved the same in the field of science.

The Scientists who made it possible. ISRO scientists pose for the camera as they succeed in their mission.

A Happy PM : Narendra Modi (L) congratulates the Chairman of ISRO Dr. K Radhakrishnan after the organistation’s Mars Orbiter Spacecraft spacecraft successfully entered the Mars orbit

It’s the time to celebrate, The Scientists at ISRO cheer after Chandrayaan reaches in the orbit.

Indian Prime Minister Narendra Modi (L) meets scientists before the Mars Orbiter Spacecraft (MoM) spacecraft successfully enters the Mars orbit at the Indian Space Research Organisation’s (ISRO

Image Coutecy: Yahoo

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Content Courtecy : KRISHNA

What is Biogas & How Do We Make It? INFOGRAPHIC

Biogas systems provide economic, energy, and environmental benefits for farms, businesses, and communities. These systems enable the capture and use of methane while also addressing waste management and nutrient recovery needs, finds the Biogas Opportunities Roadmap, released by the Obama Administration.

If its full potential was realized, a cost-effective biogas industry could produce enough energy from the livestock sector to power 1 million average American homes.

Biogas is primarily a mixture of methane and carbon dioxide produced by the bacterial decomposition of organic materials in the absence of oxygen. Depending on the source of organic matter, biogas typically contains 50-70% methane, 30-40% carbon dioxide, and trace amounts of other constituents, such as hydrogen sulfide, hydrogen, nitrogen, and siloxanes.

Methane is both a potent greenhouse gas and a valuable source of energy. Today, methane accounts for nearly 9% of domestic greenhouse gas emissions. Thirty six percent of these emissions come from the agricultural sector, equivalent to over 200 million tons of carbon pollution. While methane’s lifetime in the atmosphere is much shorter than carbon dioxide, it is more efficient at trapping radiation. Pound for pound, the comparative impact of methane on climate change is over 20 times greater than carbon dioxide over a 100-year period.

This Biogas Opportunities Roadmap builds on progress made to date to identify voluntary actions that can be taken to reduce methane emissions through the use of biogas systems and outlines strategies to overcome barriers to a robust biogas industry in the United States. It supports the U.S. dairy industry’s voluntary 2008 goal to reduce its greenhouse gas emissions by 25% by 2020.

Learn more:

Read the full Roadmap.

Check out a fact sheet about the Biogas Opportunities Roadmap.

Content Courtesy: 1sun4all

India's forest cover is on the up – but are the numbers too good to be true?

Forest cover in India increased by 5871 sq km (2266 sq miles) between 2010 and 2012.

That’s the cheery headline news from the State of the Forest Report 2013 released this month by India’s environment minister, Prakash Javadekar. The findings appear to mark a turnaround from the previous survey, which had found a marginal decline in forests.

But the fine print reveals a less rosy picture. The bulk of the increase in forest cover – about 3800 sq km – was in just one state, the report shows, and is partly attributed to a correction in previous survey data.

In fact, India may be losing quality forests. Dense forests are degrading into scrub or sparsely covered forest areas in many states, says the report. “Moderately dense” forest cover – areas with a tree canopy density of between 40-70% – shrank by 1991 sq km in the two-year period, while “open forests” with less than 40% canopy increased by 7831 sq km.

Another potential worry: the Himalayan northeastern region, which holds one-fourth of the country’s forests, has seen a small decline of 627 sq km in forest cover.

India’s total forest cover now stands at 697,898 sq km or 21.23% of the country’s area. That’s well short of the official goal to get cover up to 30% of land area (in February, the government approved a £4.46m project to increase forest area).

Yet there’s been an overall rising trend in the recorded forest cover over the past decade – no mean feat given the dramatic acceleration in economic development in the same period.

This upward trend seems far-fetched to many conservationists, however. One environmental watchdog group, the Environment Impact and Assessment Resource and Response Centre, noted that an average of 135 hectares (333 acres) of forest land a day was given over for power, mining and other development projects last year. The group expressed dismay at the environment minister’s suggestion that degraded or open forests should be harvested to reduce wood imports.

Both conservationists and scientists have long questioned the Indian forest survey’s accuracy and methods. They’ve argued that the survey relies too heavily on low-resolution satellite imagery, which fails to capture small-scale deforestation, and that the definition of forest used by the report is too broad to be meaningful.

The forest cover data does not, for instance, distinguish between tree species, land use or ownership. A paper published in May by scientists led by NH Ravindranath of the Indian Institute of Science in Bangalore suggested that an almost seven-million-hectare recorded increase in forest cover between 1997 and 2011 could be accounted for by an increase in commercial plantations.

India could be potentially over-reporting the forest cover by including many plantation categories and fruit orchards…. Even the inclusion of plantations of Eucalyptus, Casuarina, Poplar, etc. under forest cover is questionable from a conservation perspective. India also could be potentially under-reporting deforestation by reporting only the gross forest area and changes at the national and state level, which may mask any forest loss, if the rate of afforestation is higher than deforestation rates.

With India seeking to tap international climate funds for afforestation, “there is need for a new approach to monitoring and reporting of forest area to meet the challenges of forest conservation, research and reporting to UN agencies,” the authors said.

Forest officials too have criticised the survey methods. In 2012, a joint director at the Forest Survey of India, which prepares the report, took on his own organisation when he flagged the discrepancy between the official forest data for the northeastern state of Meghalaya, which showed an increase in cover, and what he saw happening on the ground: forests being destroyed by illegal mills and mining.

Mining in this green, resource-rich region continues to be a concern. A recent report by India’s Comptroller and Auditor General found only one of 16 limestone mining licenses in the state of Meghalaya had obtained environmental clearances. “[T]he forest department has no idea as to whether the mining lease areas it granted forest clearance fall within forest area,” the report said.

Content Courtersy: theguardian

Bioaccumulation and Biomagnification

Heavy metals (mercury, lead, cadmium), pesticides and herbicides (such as DDT) and endocrine-disrupting chemicals (PCB’s and BPA’s) do not readily biodegrade. These are fat-soluble substances that are stored in organisms and are not quickly broken down by bacteria or other decomposers. Bioaccumulation is the process by which persistent pollutants accumulate in the fatty tissues of organisms. These pollutants are absorbed at a greater rate than they are released and therefore build up within the individual organism. Biomagnification is the process by which persistent pollutants increase in concentration up a food chain. So secondary and tertiary consumers have higher concentrations than producers and primary consumers.

This phenomena has been observed with DDT, causing the thinning of eggshells in raptors, such as the threatened Peregrine Falcon. Rachel Carson, a marine biologist and conservationist,  made the American public aware of the environmental problems caused by synthetic pesticides, such as DDT, in her famous book, “Silent Spring”. DDT is now prohibited in most developed countries.

Mercury has been shown to bioaccumulate in marine food webs, affecting higher order consumers, such as dolphins, sharks and swordfish. As such, Food Standards of Australia and New Zealand recommend that the intake of certain types of fish is limited.

Content Courtesy : vceenviroscience

Safeguarding Our Future Water & Energy Systems-INFOGRAPHIC

As the Energy Department pursues our important mission areas of climate change, energy security and environmental responsibility, we must take into account dynamic interactions among our energy system, the population, the economy, other infrastructure systems and natural resources. One crucial interaction is that between our present-day energy and water systems, reports the DOE.

The interdependencies between our water and energy systems are clear — and becoming more prominent. Water is used in all phases of energy production and electricity generation, and energy is required to extract, convey and deliver water, and to treat wastewaters prior to their return to the environment.

The Energy Department’s new report – The Water-Energy Nexus: Challenges and Opportunities – examines this interaction, and lays out several technical and operational challenges at local, regional and national scales. The report notes that water scarcity, variability and uncertainty are becoming more prevalent, potentially leading to vulnerabilities within the U.S. energy system. Changes brought on by population growth, technological advances and policy developments are increasing the urgency for informed action.

When severe drought affected more than a third of the United States in 2012, limited water availability constrained the operation of some power plants and other energy production infrastructure. When Hurricane Sandy struck that same year, we saw firsthand the major problems that arise when vital water infrastructure and facilities lose power.

And the recent boom in domestic unconventional oil and gas development, brought on by hydraulic fracturing and horizontal drilling, has added complexity to the national dialogue about the relationship between energy and water resources.

What’s more, the effects of climate change only amplify the need to manage our interdependent water and energy systems more mindfully. As the release of the third U.S. National Climate Assessment made clear last month, climate change is affecting every region of the United States and key sectors across our economy.

Even as the Energy Department is taking strong steps to cut carbon pollution and work with our international partners to build a more sustainable energy future, we must prepare for the effects of climate change we are already seeing.

The Energy Department’s longstanding leadership in modeling and technology research and development makes it uniquely suited to meet the national need for data-driven and empirical solutions to address these challenges. This report is just the beginning.

The Department of Energy looks forward to working with our partners, including other federal agencies, state and local governments, members of Congress, foreign governments, private industry, academic institutions, non-governmental organizations, and citizens, to develop and pursue a shared vision of more resilient coupled energy-water systems.

This integration and collaboration will enable more effective research, development and deployment of key technologies, harmonization of policies where warranted, shared datasets, informed decision-making, and robust public dialogue.

A key part of that dialogue is our ongoing meetings to gather public comment on the Quadrennial Energy Review (QER), a four-year process to identify key threats, risks and opportunities for U.S. energy and climate security.

 Last week in San Francisco, Dr. John Holdren — Director of the White House Office of Science and Technology Policy — led a discussion with regional stakeholders about the water-energy nexus and lessons learned that could be applied broadly across this issue area. Future opportunities to provide input to the QER process remain.

Content Courtesy: energy.gov