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Showing posts with label #EVNVIRONMENT. Show all posts
Showing posts with label #EVNVIRONMENT. Show all posts

Wednesday, June 2, 2021

The International Commission on Irrigation and Drainage (ICID)

 The International Commission on Irrigation and Drainage (ICID)



The International Commission on Irrigation and Drainage (ICID), established in 1950 is a leading scientific, technical, international not-for-profit, non-governmental organization. ICID is a professional network of experts from across the world in the field of irrigation, drainage, and flood management. The main mission is to promote ‘Sustainable agriculture water management’ to achieve ‘Water secure world free of poverty and hunger through sustainable rural development’.

 

ICID is a knowledge sharing platform dedicated to issues that covers the entire spectrum of agricultural water management practices ranging from rainfed agriculture to supplemental irrigation, land drainage, deficit irrigation to full irrigation, etc. In addition, drainage of agricultural lands forms the core theme of commission’s activities. Floods and drought; the two extremes of increasingly variable climate as a result of potential climate change, also form the focus of activities.


ICID has more than half-a-century of experience in the transfer of water management technology and in the handling of related issues. Building on its past experience, accomplishments, and the comprehensive water management framework, ICID strives to promote programs to enhance sustainable development of irrigated agriculture. ICID has been involved in the global discussions leading to Agenda 21, World Water Vision, and World Water Forums etc., which have become the focal point of several of its technical activities.

In recognition of its significant contribution to the programs and objectives of International Year of Peace proclaimed by the UN General Assembly, on 15 September 1987 ICID was designated as a Peace Messenger by the UN Secretary General.




Wednesday, May 26, 2021

SOLID WASTE MANAGMENT: CONVERTING WASTE MENACE INTO A WINDOW OF OPPORTUNITY

 SOLID WASTE MANAGMENT: 

CONVERTING WASTE MENACE INTO A 

WINDOW OF OPPORTUNITY

#Environment #Pollution 


https://upscthingsforyou.blogspot.com/2021/05/solid-waste-managment-converting-waste.html?m=1



WHY THIS TOPIC? 

Millions of tonnes of garbage is getting accumulated in every 

possible open space in and around cities and towns and also 

in water bodies across India. The launch of  #Swachh Bharat with ranking of Indian cities has highlighted the importance 

of waste management but it requires more collaborative and 

citizen driven initiatives to comprehensively deal with this 

accumulating monster impacting the quality of life and 

environment around us. 

INTRODUCTION 

Waste management rules in India are based on the principles 

of "sustainable development", "precaution" and "polluter 

pays". These principles mandate municipalities and 

commercial establishments to act in an environmentally 

accountable and responsible manner—restoring balance, if 

their actions disrupt it. The increase in waste generation as a 

by-product of economic development has led to various 

subordinate legislations for regulating the manner of disposal 

and dealing with generated waste are made under the 

umbrella law of Environment Protection Act, 1986 (EPA). 

Specific forms of waste are the subject matter of separate 

rules and require separate compliances, mostly in the nature 

of authorisations, maintenance of records and adequate 

disposal mechanisms. 

With rapid urbanisation, the country is facing massive waste 

management challenge. Barely a quarter of the 1.43 lakh MT 

of garbage generated every day in Indian cities gets 

processed. The remaining three-quarters are dumped in the 

open. Solid Waste Management (SWM) is one among the 

basic essential services provided by municipal authorities in 

the country to keep urban centres clean. However, almost all 

municipal authorities deposit solid waste at a dumpyard 

within or outside the city haphazardly. Experts believe that 

India is following a flawed system of waste disposal and 

management. 

Health and safety and environmental risks are a major 

concern. The workers as well as the waste pickers are not 

provided with proper health and safety equipment like boots 

and gloves. The working conditions are unhygienic, the 

chance of transfer of infection is high and because of this if a 

worker gets sick he loses his wages. The workers are also not 

provided with medical insurance. The environmental risk is 

also high because the landfill sites are not maintained 

properly and the leachate gets leaked into the underground 

water. 

https://upscthingsforyou.blogspot.com/2021/05/solid-waste-managment-converting-waste.html?m=1


MAIN BODY 

Sources and types of solid waste: Residential:-the residence 

might be single family or multiple family dwellers the types of 

waste they produce are paper, food wastes , cardboard , 

leather, yard wastes, textiles, glass, special wastes, metals, 

plastics , ashes, wood and household hazardous wastes

ustrial: – industries produce ashes, food wastes, 

packaging, special wastes, housekeeping wastes, construction 

and demolition materials and hazardous wastes. 

Commercial & Institutional: – they produce wood, metals, 

cardboard, glass, special wastes, Paper, food wastes, 

hazardous wastes. 

Municipal services: – landscape and tree trimmings, Street 

sweepings, general wastes from beaches, parks, and other 

recreational areas, sludge. 

The key to efficient waste management is to ensure proper 

segregation of waste at source and to ensure that the 

waste goes through different streams of recycling and 

resource recovery. Then reduced final residue is then 

deposited scientifically in sanitary landfills. Sanitary landfills 

are the ultimate means of disposal for unutilised municipal 

solid waste from waste processing facilities and other types 

of inorganic waste that cannot be reused or recycled. Major 

limitation of this method is the costly transportation of MSW 

to far away landfill sites. 

A noteworthy first step was propelling sanitation to the top of 

the policy agenda under the flagship Swachh Bharat Abhiyan 

programme. The Clean India Dashboard tracks programme 

achievements, 24x7. Almost 90 megawatts (MW) of energy is 

generated from waste-to-energy (WTE) projects. 

Nevertheless, the disproportionate focus of the programme 

on toilet construction and eliminating open defecation 

deflects attention from colossal failures in waste 

management systems. 

There has been technological advancement for processing, 

treatment and disposal of solid waste. Energy-from-waste is 

a crucial element of SWM because it reduces the volume of 

waste from disposal also helps in converting the waste into 

renewable energy and organic manure. Ideally, it falls in the 

flow chart after segregation, collection, recycling and before 

getting to the land fill. But many waste to energy plants in 

India are not operating to their full potential. 

Installation of waste-to-compost and bio-methanation 

plants would reduce the load of landfill sites. The 

biodegradable component of India’s solid waste is currently 

estimated at a little over 50 per cent. Bio-methanation is a 

solution for processing biodegradable waste which is also 

remains underexploited. It is believed that if we segregate 

biodegradable waste from the rest, it could reduce the 

challenges by half. E-waste components contain toxic 

materials and are non-biodegradable which present both 

occupational and environmental health threats including 

toxic smoke from recycling processes and leaching from e-

waste in landfill into local water tables. 

The concept of common waste treatment facility is being 

widely promoted and accepted as it uses waste as a resource 

by either using it as a co-fuel or co-raw material in 

manufacturing processes. This has led to rise of Public Private 

Partnership (PPP) models in waste management which has 

open doors for doing business in waste management. 

Bio-medical waste (management and handling) rules, 1998 

prescribe that there should be a Common Biomedical 

#Waste Treatment Facility (CBWTF) at every 150 kms in the 

country. CBWTFs have been set up and are functioning in 

cities and towns. However, establishment of functional 

CBWTF throughout the country must be ensured. Integrated 

common hazardous waste management facilities combine 

secured landfill facility, solidification/stabilisation and 

incineration to treat hazardous wastes generated by various 

industrial units. They contribute about 97.8 per cent of total 

landfill waste and 88 per cent of total incinerable hazardous 

waste generated in the country, as per an environment 

ministry report. 

Focus on 3 R’s-Reduce, Reuse, Recycle with collaborative 

participation of State and Non-state actors: It is the only 

way to save the environment from getting deteriorated. We 

are quickly running out of space and now it is important that 

all of us learn the three R’s of the environment and put it into 

practice. 

Reducing the amount of waste produced is the best way to 

help the environment. For instance buying products with 

minimum packaging, borrowing things which we do not use 

often, starting a compost bin, saving energy and water by 

turning are ways to reduce. To reduce the environment 

damage caused by cars, increase use of carpooling with 

friends, walking, taking the bus, or riding your bike instead of 

driving are the necessary steps to be taken. Same way 

salvage does for the environment. It helps to reduce the 

waste by sorting out articles of use. 

Instead of throwing away articles try to find various efficient 

ways to reuse it. For instance, replacing few things in our day 

to day life like using cloth sacks in place of plastic bags, re-

useable lunch bags without creating waste. Donating old 

clothes, toys and furniture to the needy and poor. Use writing 

paper on both sides etc. 

The process of changing the waste and non-useable materials 

into potentially useful materials. It is the key component of 

modern waste reduction procedure. There are some 

ISO standards related to recycling such as ISO 15270:2008 for 

plastics waste and ISO 14001:2004 for environmental 

management control of recycling practice. Recycling reduces 

the consumption of raw materials and energy usage. It also 

reduces air and water pollution by reducing the need of 

conventional waste disposal. Usage of recycled materials will 

help the environment to be green again. 

CONCLUSION

Around 100 cities are set to be developed as smart cities. 

Civic bodies have to redraw long term vision in solid waste 

management and rework their strategies as per changing 

lifestyles. They should reinvent garbage management in cities 

so that we can process waste and not landfill it (with 

adequate provisioning in processing and recycling).To do this, 

households and institutions must segregate their waste at 

source so that it could be managed as a resource. The Centre 

aims to do away with landfill sites in 20 major cities. There is 

no spare land for dumping garbage, the existing ones are in a 

critical state. It is reported that almost 80 per cent of the 

waste at Delhi landfill sites could be recycled provided civic 

bodies start allowing waste managers to segregate waste at 

source and recycle it. Compost pits should be constructed in 

every locality to process organic waste. Community 

participation has a direct bearing on efficient waste 

management. Recovery of e-waste is abysmally low, we need 

to encourage recycling of e-waste on a very large scale level 

so that problem of e-waste disposal is contained.

https://upscthingsforyou.blogspot.com/2021/05/solid-waste-managment-converting-waste.html?m=1


Monday, May 24, 2021

WATER SCARCITY: IMPACT AND SOLUTIONS

 WATER SCARCITY: IMPACT AND 

SOLUTIONS 



#Environment #Conservation

WHY THIS TOPIC? 

As per the NITI Aayog report, around 60 crore people in India 

are facing water scarcity. Even Chennai, a major metropolis is 

facing the crisis and also the millennium city, Gurgaon. If this, 

continues then it is going to impact the entire country by 

2030. So, the need of the hour is wholesome state and non-

state actors participation in water conservation. 

INTRODUCTION 

Problems are huge as precious evolutionary living resources, 

natural infrastructure, are going extinct. While we 

thoughtlessly build artificial infrastructure, we forget that this 

kills natural infrastructure which took evolution aeons to 

create and cannot be engineered. We are missing the 

essential point that this is our lifeline on the planet. Forests, 

rivers, mountains, aquifers and soil are being lost at an 

alarming rate. Today, India is in the midst of a suicidal water 

crisis as urban and rural landscapes go thirsty. 

Over the years, we have seen activists, scientists and experts 

from across India working on bottom-up schemes to revive 

and rejuvenate lakes, wetlands, streams and other small 

water bodies. While these movements have brought about a 

significant change at the local level, the scale of our water 

problems is much larger. 




MAIN BODY 

Here we have two intractable issues. First, cities today are 

vast agglomerations that continue to spread, with bursting 

populations of tens of millions. They are huge parasites on 

water, food, energy and all other resources. High densities of 

our cities do not allow for water harvesting to fill the gap. 

Until now, invasive schemes like dams to service these large 

cities and the huge needs of agriculture have caused extreme 

ecological devastation. 

Second, in our global market economies, the products and 

services that are derived from natural infrastructure have 

often led to the terminal loss of the source itself. The global 

free market, and with it the scale of human intervention, now 

exceeds the scale of the planet. These resources (forests, 

mountains, floodplains and rivers) are often lost to the greed 

of governments, institutions, corporations and individuals. 

This is long-term loss for short- term gain. Natural resources 

are living evolutionary resources that are constantly renewed 

by natural cycles. Therefore, they provide us perennial value 

as long as we use them with natural wisdom and not kill them 

with exploitation — which is the order of the day. 

Groundwater plays an important role in our lives and India’s 

economy, but it is disappearing fast. There is mounting 

evidence that we are extracting more than can be naturally 

replenished. In the hard-rock aquifers of peninsular India, 

drilling 800 ft. or deeper is becoming the norm. Groundwater-

dependent towns and villages spend an increasing fraction of 

their budgets chasing the water table. Stories abound of 

farmers spending their life savings or taking loans to drill a 

borewell, but failing to find water. If we “run out” of 

groundwater, millions of people will be left without any 

means to sustain themselves. 

Scientific evidence also points to over-exploitation. The 

Central Ground Water Board classifies all blocks in India 

based on the fraction of recharge that is extracted and trends 

in long-term groundwater levels. Since 2004, almost a third of 

blocks have been classified “over-exploited” or “semi-critical”. 

If we understand the problem and if the consequences are so 

severe, why are we unable to address it? The answer lies 

partly in politics, partly in the invisible nature of groundwater, 

and partly in our reliance on simple techno-economic fixes. 

Flawed regulatory structure: Electricity is supplied to 

farmers free of cost. This policy made sense when 

groundwater was abundant in the 1980s. Indeed, it helped 

millions of farmers escape poverty. But today, where 

groundwater levels have fallen hundreds of feet below the 

ground, the subsidy is actually only utilised by the richest 

farmers who can afford to drill deep. And even so, not all are 

lucky enough to strike water. Access to groundwater in hard-

rock regions has almost become a lottery. Yet in the absence 

of alternative water sources, charging farmers for electricity is 

seen as political suicide.

Groundwater is inherently difficult to monitor and control, in 

part because of its invisibility, which also perpetuates the 

illusion that each well is independent. The myth is enshrined 

in Indian groundwater law that allows landowners to extract 

as much as they want. In reality, not only is groundwater 

within an aquifer interconnected, but aquifers and rivers are 

also interconnected. So depleting groundwater means drying 

rivers. Despite this, groundwater and rivers are regulated by 

different agencies that do not properly account for the 

linkages between them, often double counting the quantum 

of the resource. 

Much of the current action on the ground is through techno-

economic fixes. These have clear benefits in terms of 

reducing pumping costs and using local aquifers instead ofbuilding big, expensive dams. But what they do not do is 

create “new” water. 

Solution can be floodplain. Research has shown that 

floodplains of rivers are exceptional aquifers where any 

withdrawal is compensated by gravity flow from a large 

surrounding area and can be used as a source of providing 

water to cities. Floodplains are formed over millions of years 

by the flooding of rivers with deposition of sand on 

riverbanks. Some floodplains, such as those of Himalayan 

rivers, contain up to 20 times more water than the virgin flow 

in rivers in a year. Since recharge is by rainfall and during late 

floods, the water quality is good. If we conserve and use the 

floodplain, it can be a self-sustaining aquifer wherein every 

year, the river and floodplain are preserved in the same 

healthy condition as the year before. 

The Delhi Palla floodplain project on the Yamuna is an 

example of this. By utilising 20 sq.km of the river length and 

running at half its capacity, it provides water to almost a 

million people daily. Piezometers and a control system have 

been installed to monitor water levels and other parameters 

through the year, to ensure sustainable withdrawal. Besides, 

it provides huge revenue to the Delhi Jal Board. 

Preserving the floodplain in a pristine condition is essential 

for this scheme to work. Land on the floodplains can be 

leased from farmers in return for a fixed income from the 

water sold to cities. The farmers can be encouraged to grow 

orchards/food forests to secure and restore the ecological 

balance of the river ecosystem. 

Currently, mineral water is brought from faraway mountain 

springs, putting huge pressure on the mountains. It is 

packaged and consumed in plastic bottles that end up in 

landfills. Forested hills are a result of evolution over millions 

of years. They are not polluted and sit on a treasure of 

underground aquifers that contain natural mineral water 

comparable to that found in a mountain spring. This is 

because the rain falls on the forest and seeps through the 

various layers of humus and cracked rock pathways, picking 

up nutrients and minerals and flows into underground 

mineral water aquifers. 

Research shows that the water in these aquifers is 

comparable to several international natural spring mineral 

waters. It also shows that if a scheme of ‘conserve and use’ is 

applied correctly, it would allow a forest (like Asola Bhatti in 

Delhi) to be sustained as a mineral water sanctuary. About 30 

sq.km of the forest could then provide enough natural 

mineral water to 5 million people in the city. The Aravalli 

forested hills can provide mineral water to all major towns of 

Rajasthan. This water can substantially improve the health of 

citizens and preserve forests at the same time. The marvel is 

that we can provide quality natural mineral water for all from 

a local forest tract for 20 times less than the market price and 

yet reap great economic returns. 

Such non-invasive, local, large-scale ‘conserve and use’ 

projects till now have not been part of our living scheme. 

They change the relationship between nature, water and 

cities. They differ in scale from the small, community-driven 

projects of check dams, water harvesting and lakes and can 

service large populations. Unlike large-scale dams, these 

projects work with nature rather than against it. They can be 

used around the globe. If we were to recognise the true value 

of our natural infrastructure and ‘conserve and use’ our 

evolutionary resources with the help of science, it would 

secure the future for humanity and the natural world. 

Further, boosting recharge through rainwater harvesting 

structures such as small check dams is a popular measure. 

Another technological solution is to improve efficiency 

through subsidised drip irrigation or energy-saving pumps. 

CONCLUSION

The way forward is comprehensive water budgeting, 

simultaneously in each watershed and the river basin as a 

whole. Water budgets at the watershed level will inform 

communities about how much water they have, so it can be 

equitably shared within communities. Water budgets for the 

river basin will inform communities how much must be left 

for downstream users, ensuring that water resources are 

allocated between communities fairly and transparently. 

Given the zero-sum nature of the game and the impossibility 

of creating “new” water, it is likely that we cannot restore the 

water balance in severely depleted regions without painful 

cuts in water use. However, there are some glimmers of 

hope. Water users everywhere are worried about the 

disappearing resource and willing to engage. The trick lies in 

combining technology (low-water-use crops, xeriscaping) and 

economic incentives that reduce actual water use (“cash-for-

blue” schemes) without reducing productivity or quality of 

life. This needs a strong water governance system based on 

awareness building, science and a commitment to fairness 

and sustainability.


Thursday, May 6, 2021

FOREST FIRE


FOREST FIRE





  Forest fire, can be described as any uncontrolled and non-prescribed combustion or burning of plants in a natural setting such as a forest, grassland, brush land or tundra, which consumes the natural fuels and spreads based on environmental conditions (e.g., wind, topography). Wildfire can be incited by human actions, such as land clearing, extreme drought or in rare cases by lightning .

There are three conditions that need to be in order for a wildfire to burn: fuel, oxygen, and a heat source. Fuel is any flammable material surrounding a fire, including trees, grasses, brush, even homes. Air supplies the oxygen a fire needs to burn. Heat sources help spark the wildfire and bring fuel to temperatures hot enough to ignite. Lightning, burning campfires or cigarettes, hot winds, and even the sun can all provide sufficient heat to spark a wildfire .

If we talk about INDIA 

At least 5,291 forest fires were recorded in Odisha between February 22 and March 1, 2021 - the highest in the country for the same period – according to the Forest Survey of India (FSI). Telangana recorded the second-highest fires in the country at 1,527 during the same period, followed by MadhyaPradesh (1,507) and Andhra Pradesh (1,292),according to FSI data.

The Global Wildland Fire Network Bulletin published by the Global Fire Monitoring Center presents the most recent data regarding consequences of wildfire: in 2017, 36 fires in protected areas were recorded in 19 countries burning more than 196000 hectares worldwide.

Wildfire plays a mixed role for (ecology)and economy since some ecosystems depend on natural fires to maintaining their dynamics, biodiversity and productivity. However, every year, wildfires burn millions of hectares of forest woodlands and other vegetation, causing the loss of many human and animal lives and an immense economic damage, both in terms of resources destroyed and the costs of suppression. There are also impacts on society and the environment, such as damage to human health from smoke, loss of biological diversity, release of  greenhouse gases, damage to recreational values and infrastructure .

Most fires are caused by people. The list of human motivations include land clearing and other agricultural activities, maintenance of grasslands for livestock management, extraction of non-wood forest products, industrial development, resettlement, hunting, negligence and arson. Only in very remote areas of Canada and the Russian Federation lightning is a major cause of fires .

There are three basic types of wildfires:

  • Crown fires burn trees up their entire length to the top. These are the most intense and dangerous wildland fires.
  • Surface fires burn only surface litter and duff. These are the easiest fires to put out and cause the least damage to the forest.
  • Ground fires (sometimes called underground or subsurface fires) occur in deep accumulations of humus, peat and similar dead vegetation that become dry enough to burn. These fires move very slowly, but can become difficult to fully put out, or suppress     




  • Positive  impact of forest forest FIRE

           a) Cleaning up forests of dead and decaying matter                     and  help forests to regenerate
    • b) Maintaining ecosystem balance by removing diseased plants and harmful insects
    • c) help in reviving dormant seeds of many species
    •  d) help supress invasive species
    • e) controlled fires can help prevent and reduce the impact of large fires.