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Landfills 101: Everything You Need to Know

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27 May, 2024

This post was originally published on Eco Watch

Quick Key Facts

What Is a Landfill? 

A school adjoins the Dandora landfill, the biggest dumpsite in East Africa and the destination of solid waste generated by Nairobi, Kenya, on Feb. 23, 2023. It was declared full in 1996 but is still operating and many people go there to find plastic, food or clothes they can sell. Simone Boccaccio / SOPA Images / LightRocket via Getty Images

Most of us barely have to think about our trash. We throw it in a bin, take the bag to the curb, then the garbage truck comes and takes it away. Pretty quickly, our waste becomes invisible to us, but it has to end up somewhere. 

Waste comes from many different streams — households, industrial settings, workplaces, medical facilities, etc. — and our current system for trash and garbage disposal primarily entails burying it underground. In the U.S., waste generated by homes and businesses is most commonly sent to landfills: huge repositories in the earth to be filled with trash and covered over. The first modern sanitary landfill was created in California in 1937, but the practice became more widely adapted in the 1960s and 70s as waste production rose, and municipalities sought ways to limit unsanitary waste disposal. In 1976, the Resource Conservation and Recovery Act was passed and created requirements for landfills to protect surrounding environments. Now, there are more than 2,600 landfills for municipal solid waste (MSW) in the U.S., a waste category that encompasses things like wood, paper, textiles, furniture, glass, plastic, some electronics and more. 

Why Do We Have Landfills? 

The Calabasas landfill in Los Angeles County, California on Jan. 22, 2008. Gary Friedman / Los Angeles Times via Getty Images

We generate huge amounts of waste and we’re only creating more. Single-use plastics and highly wasteful industries like fast fashion have become ubiquitous in practically every area of our lives. Trash generation has more than tripled since the 1960s, resulting in a current average of 4.9 pounds of MSW generated per person per day. With 11.2 billion tons of MSW produced every year, we need somewhere to put it, and landfills provide that solution. 

Our increased waste is also tied to population growth and urbanization. The more the population grows, the greater our demand for manufactured products and materials, and the more we depend on landfills. According to the World Bank, global waste generation is expected to increase by 73% from 2020 levels by 2050. 

The U.S. in particular generates a great deal of waste. Despite making up only 4% of the global population, the U.S. is responsible for 12% of the planet’s trash. It has historically exported its waste to other countries to handle, but in recent years, China, Malaysia, Thailand and Vietnam have put bans in place on imported waste, further increasing the need for domestic repositories for trash, such as landfills. 

While some waste can get recovered or recycled — and some of it is burned — the majority is sent to landfills. In 2018, 69 million tons of MWS was recycled and 25 million tons was composted, which amounts to about 32.1% of all MWS. About 3 million tons was combusted, leaving 146 million tons — half of the total — to be sent to landfills. In the absence of large-scale municipal recycling and composting programs, waste is thrown away when it could have been diverted to other streams. Our recycling system, however, isn’t perfect either — ultimately, only 9% of plastics gets recycled. With bans on our junk being imported to other countries to deal with — leaving about 19,000 shipping containers worth of plastic recycling with nowhere to go every month — much of this waste is being sent to domestic landfills instead.

Are There Different Types of Landfills? 

U.S. Environmental Protection Agency

Different types of landfills exist for different types of waste, as categorized by the EPA. All are supposed to meet nationwide criteria established under the Resource Conservation and Recovery Act (RCRA), which sets forth requirements for landfills in the absence of state programs including location restrictions, requirements for liners and toxin collection/removal systems, and required operating practices.

Solid Waste Landfills 

Heavy machinery spreads garbage at the King County Cedar Hills Regional Landfill facilities, a municipal solid waste landfill near Maple Valley, Washington on Oct. 5, 2023. Wolfgang Kaehler / LightRocket via Getty Images

Municipal Solid Waste Landfills (MSWLFs) are primarily for the waste that’s generated in our homes, schools, hospitals and businesses, as well as some nonhazardous materials from industry and construction. There are about 2,600 MSWLFs in the U.S., managed by the individual states they reside in. MSW is usually brought to transfer stations in municipalities, then transported on large, long-distance trucks to MSWLs. 

Bioreactor landfills also fall under this category, and are used for degrading organic waste quickly. In these landfills, liquids are added to help bacteria break the waste down using either aerobic or anaerobic techniques. 

The Yolo County Landfill Bioreactor in California was built to accelerate the decomposition of waste and produce renewable energy in 5 to 10 years. Yolo County

Industrial Waste Landfills are used for commercial and institutional waste. For example, Construction and Demolition Debris Landfills are repositories for heavy and bulky materials like wood, concrete, drywall, salvaged components of buildings like plumbing and windows, metal and glass generated during construction and demolition of roads, bridges and buildings. This accounts for a large amount of waste in the U.S. — in 2018, 600 million tons of C&D debris were generated, which is more than twice the amount of MSW. Demolition itself accounts for 90% of all C&D waste. 

The former 38-acre Ascon Landfill operated from 1938 to 1984, taking much of its waste from oil drilling operations and construction debris, pictured in Huntington Beach, California on May 30, 2019. Allen J. Schaben / Los Angeles Times via Getty Images

Coal Combustion Residual Landfills fall under the Industrial Waste category too, housing the nearly 130 million tons of coal ash generated every year from the burning of coal in power plants. After a large coal ash spill in Tennessee in 2008 flooded 300 acres of land and got into two rivers, the EPA established that these materials must be disposed of in such landfills. 

Thousands of tons of coal fly ash deposited in an unlined landfill in Chester, West Virginia on Sept. 10, 2008. The fly ash originates from the coal-fired 2460 MW Bruce Mansfield Power Plant in Shippingport, Pennsylvania. Fly ash contains toxic heavy metals including arsenic, selenium, mercury, cadmium, chromium and lead. Robert Nickelsberg / Getty Images

Hazardous Waste Landfills

Hazardous Waste landfills are exactly what they sound like: repositories for only hazardous waste that is flammable, toxic or chemically reactive, including things like household cleaners, chemical waste, paint and aerosols. These types of landfills are the most regulated by the EPA, and are monitored even after their closure for toxic leachate.

The Environmental Restoration Disposal Facility at the Hanford Nuclear Reservation near Richland, Washington on June 30, 2005. The landfill holds discarded contaminated soil, building materials and debris from cleanup work following Hanford’s decades as a plutonium production complex since the 1940s. Jeff T. Green / Getty Images

Open Dump Landfills 

Residents living near the Chiquita Canyon Landfill in Castaic, California say it should be closed due to odors, contamination and health risks, pictured on Nov. 22, 2023. Myung J. Chun / Los Angeles Times via Getty Images

When we talk about landfills, we’re typically referring to “sanitary landfills” — that is, municipal landfills that are regulated and controlled. However, open dump landfills are common in many areas of the Global South, and are used by about 70% of countries for disposing MSW. Without municipal waste disposal programs, these dumps are where trash often ends up. 

Because these landfills typically aren’t regulated or controlled, they’re more likely to cause fires, attract pests and pollute the surrounding area. The toxic gases they produce are also not contained, so methane is released into the nearby environment. Water contamination is a primary problem around open dump landfills. Without groundwater monitoring systems in place, toxins make their way into groundwater and nearby drinking water, which has the potential to transmit infection and disease.

Basic Components and Operations of a Landfill 

Open dumping is illegal in the U.S., and landfills must follow certain design and operation guidelines as established under the Resource Conservation and Recovery Act (RCRA), although they’re created and managed state-by-state. 

The major components of sanitary landfills include the following:

  • Leachate collection system. Leachate is the liquid that percolates through the landfill, picking up toxins as it moves. Once it reaches the bottom of the landfill, it’s collected by perforated tubes and pumped out into a collection area, and then a holding pond where it’s treated to remove the harmful toxins. 
  • Plastic liner system (or “composite liner”). The liner — created from a layer of compacted clay and specific types of plastic — is meant to keep the landfill completely sealed so groundwater and soil aren’t contaminated by leachate.
To reduce the formation of liquids, gases and dust, geomembrane waterproofing is used in municipal solid waste landfills like this one in Italy pictured on Aug. 20, 2023. It acts as a barrier between covered material and the surrounding space to prevent the spread of pollutant leachate. Marco Scataglini / UCG / Universal Images Group via Getty Images
  • Cells are the areas where trash is dumped and compacted, allowing landfills to be filled in a segmented manner. Every day, waste is tipped into the active cell, which gets mechanically compacted. Layers of soil are laid down to cover the trash at intervals, and help to prevent odor. When the cell becomes full, another one is started.
  • Stormwater drainage systems collect the rainwater that lands on the landfill, move it to drainage ditches, and then to collection ponds. 
  • Methane collection systems are needed to collect the methane — a potent greenhouse gas — that forms during the decomposition of organic waste. Landfills are among the largest sources of methane in the U.S., and collection systems prevent it from being released into the air. Wells, pipes and pumps collect the methane, where it’s then piped to a facility that processes it and removes impurities. From there, the refined methane can be distributed for such uses as vehicle fuel and electricity. About 500 MSW landfills collect methane for energy in this way.

The Pioneer Crossing Landfill in Berks County, Pennsylvania uses methane gas, a byproduct of the decomposition of waste, to produce electricity for the local utility company. J.P. Mascaro & Sons

  • Environmental monitoring systems monitor the groundwater, storm water, and gas around landfills. Pipes go down into the groundwater to find whether they’ve become warmer or more acidic, which could mean that leachate is escaping and getting into the landfill’s surrounding environment.
  • The Cap seals the top of the landfill. Usually, a layer of compacted soil or clay is put down, then layers of fabric and plastic before a 2-foot layer of soil (sometimes followed by more inches of topsoil) is put down so vegetation can grow on top of it.

How Does Waste Act Inside a Landfill?

Waste acts much differently inside a landfill than it would in your trash can, or when merely left out in the open. Different types of waste also act differently, posing unique problems depending on their makeup. 

Organic Waste 

What’s so bad about putting food in a landfill? It’ll just break down eventually, right? Not exactly.

Food is the largest category of landfilled material, according to the EPA, accounting for about 24%. The dark, anaerobic — that is, oxygen-free — environment of a landfill means that the insects and microorganisms needed to properly break down these materials aren’t present. Decomposition thus happens much, much slower, and releases a lot of methane as a byproduct. In a landfill, it can take decades for food to break down completely. By some estimates, a head of lettuce won’t completely decompose for 25 years. In other cases, food may not decompose at all. 

Piles of discarded fruit at the Shelford Landfill, Recycling & Composting Centre near Canterbury, England on Aug. 23, 2007. Peter Macdiarmid / Getty Images

Plastics

In landfills, most polymers and plastics remain “unchanged,” according to a 2022 study. Abundant evidence shows that plastic never really degrades, but rather breaks down into smaller and smaller pieces, eventually creating microplastics. The forces and environmental conditions of landfills — like gas, the pH of leachate, high salinity, temperature fluctuation, high pressure, etc. — can cause plastics to fragment into microplastics that can then be transported out of landfills in leachate and pollute nearby areas. Microplastic abundance in landfill refuse is between 20,000 and 91,000 items/kg — higher than the concentration in sewage sludge and agricultural soil. Therefore, when you throw a piece of plastic in a bag of landfill-bound trash, that doesn’t guarantee it’ll remain sealed off from the environment forever. 

Energy Recovery in Landfills 

The McCarty Road Landfill in Houston, one of the largest waste disposal facilities in Texas, reclaims methane produced in the landfill to power generators and make renewable natural gas, pictured on May 31, 2022. Brett Coomer / Houston Chronicle via Getty Images

Sometimes after a landfill is capped, the gases that form within it over time are vented out for energy recovery efforts. These gases can be used to generate electricity or as medium-Btu fuel, and have uses for vehicle fuel, pipeline gas, industrial and institutional buildings, and creating electricity for the grid. They’re recovered using a series of wells and vacuum systems that direct it to a collection area, after which it’s processed and can then be used. About 68% of all landfill gas (LFG) projects is for generating electricity, and 16% is used to offset another fuel, like fracked gas and coal. Another 16% is used to make renewable natural gas (RNG), a high-Btu gas that can be used instead of fossil natural gas. 

Why Are Landfills a Problem? 

On the surface, landfills seem like a logical solution to our waste — if we have nowhere else to put it, why not bury it? Landfills do, however, present serious and potentially life-threatening risks to nearby communities and the environment.

Location 

A plastic liner covers a portion of the Fresh Kills Landfill on the New York City borough of Staten Island, formerly the largest landfill in the world, on June 30, 1995. James Leynse / Corbis via Getty Images

Federal and state regulations mandate where landfills can be built, placing restrictions on building near wetlands or flood zones without certain performance standards in place. In some states, they can’t be put near bodies of water at all. But many landfills are poorly managed, leaving them susceptible to environmental conditions and leading to pollution. Landfills are also associated with poorer quality of life when placed near residential communities, discussed further in the next section. 

Residents of North Bellport, New York say the nearby Brookhaven Town recycling and landfill facility releases toxic emissions and odors, pictured on April 25, 2023. Steve Pfost / Newsday RM via Getty Images

Soil Pollution 

Like water moving through coffee grounds, rainwater moving through landfills becomes saturated with the toxins inside the trash, eventually reaching the bottom as leachate. Some of this liquid does get collected by the leachate collection system, but if there are any holes in the lining, it can easily escape into the surrounding environment. Nearby soil is destroyed by the toxic chemicals, impacting the ability of plants to grow there and threatening the biodiversity of the area. 

Workers cover potential airborne debris and gases on a portion of the West Lake Landfill in St. Louis, Missouri on June 1, 2017. The site was an unlined mixed-waste landfill whose contents included illegally dumped radioactive waste. It’s also an EPA Superfund cleanup site. Linda Davidson / The Washington Post via Getty Images

Air Pollution 

Air quality also suffers around landfills. Particulates, dust and other air pollutants can escape from landfills. Vinyl chloride, ethyl benzene and toluene, are just some of the hazardous air pollutants emitted from MSW landfills. Respiratory problems — among other adverse health conditions — have been linked to landfill-related air pollution. 

The largest and oldest open-air dump in Argentina is Lujan in Buenos Aires, pictured on March 1, 2024. For 60 years, millions of tons of municipal waste have accumulated in the landfill, which overlooks a lagoon with a rich variety of flora and fauna. The landfill continues to leak leachate as well as toxic gases and smoke into the environment, the surrounding water tables and lagoons. Luciano Gonzalez / Anadolu via Getty Images

Water Pollution 

When landfill leakages occur and leachate gets into groundwater, it becomes contaminated with toxins in industry and household waste, as well as electronics, which contain mercury, cadmium and lead. Ammonia is often in leachate, and produces nitrate. High concentrations of nitrate in ecosystems causes eutrophication, a process by which a high nutrient concentration in water leads to an explosion of plant life and algal growth, creating “dead zones” devoid of oxygen. Besides ammonia, leachate can also transport bacteria and heavy metals into groundwater, potentially contaminating drinking water. 

A large covering that will eventually stretch over a 30-acre area to better suppress odors and emissions from an underground landfill fire at Chiquita Canyon Landfill in Castaic, California on Feb. 22, 2024. Environmental regulators found elevated levels of cancer-causing benzene in the polluted water spilling onto the surface of the landfill. Allen J. Schaben / Los Angeles Times via Getty Images

Landfill Gas and Greenhouse Gases 

Landfill gas (LFG), formed from the breakdown of organic waste inside the landfill, is mostly methane and CO2 (90-98%), but also contains nitrogen, oxygen, ammonia, hydrogen, and sulfides, among others. Its makeup depends on the specific conditions and age of the landfill, as well as temperature and water content, but some landfills can produce gas for up to 50 years. 

Methane is a primary cause for concern in LFG, formed from the slow decomposition of organic matter in the airtight, anaerobic conditions of the landfill. Landfills are the third largest source of methane emissions in the U.S., and for a greenhouse gas that’s 25% more potent than CO2, this has major implications for global climate change. Methane is also highly flammable. In March 2022, a massive fire started at a landfill site outside of Delhi, India, releasing toxins into the air. The fire, unfortunately, came right on the heels of an analysis stating that New Delhi was already the most polluted capital in the world

Workers use backhoe loaders to move the waste at the biggest landfill in Delhi, India on July 28, 2020. Amarjeet Kumar Singh / SOPA Images / LightRocket via Getty Images

Besides its climate-warming components, landfill gases can also get into structures near the landfill. They come up through the soil in a process called “soil vapor intrusion,” collecting in poorly-ventilated areas and polluting the indoor air of nearby buildings.  

Human Health 

People wearing protective masks hold banners with pictures of polluted areas during a demonstration by Comitato Stop Biocidio (Stop to Biocide Committee) highlighting environmental problems of the Campania Region such as illegal landfills, the burning of toxic waste and the consequent growth of tumors among the population, in Naples, Campania, Italy on June 6, 2020. Manuela Ricci / KONTROLAB / LightRocket via Getty Images

These gases, pollutants and toxins impact the health of people who live near landfills. Open or poorly-managed landfills can lead to drinking water contamination, thereby transmitting diseases and causing infection. Documented adverse health outcomes include higher risk of cancer and birth defects in infants. Trichloroethylene (TCE) is just one carcinogen associated with leachate, entering the soil and groundwater near landfills. Ammonia and hydrogen sulfide are also harmful to humans and can cause coughing, difficulty breathing, and trigger asthma, headaches, nausea, and irritation in the eyes, nose and throat. For those who live near waste lagoons of landfills, adverse health outcomes are an especially serious problem. 

Why Are Landfills an Environmental Justice Issue?

It has long been the case that landfills are constructed more often near communities of color and low-income neighborhoods. A 1983 study conducted by Congress’s Government Accountability Office found that in eight southeastern states, 75% of hazardous waste landfill sites were located in communities that were primarily Black, Latine and low-income. This puts marginalized communities at greater health risk. The proximity of landfills to housing also keeps property values low, which can make it hard for residents to sell their property and escape the health hazards. 

What Can We Do? 

Minimize Waste

In the simplest terms, to reduce our dependence on landfills, we need to reduce our waste. Diverting our waste through recycling and composting can keep waste out of landfills, as can just using less stuff altogether. 

The recycling system in the U.S. is far from perfect. Due to a combination of many factors — including the un-recyclability of many materials, poor waste systems and lack of recycling systems in some areas — only about 9% of plastic actually gets recycled. However, when done properly, taking part in recycling programs keeps these materials out of landfills. Composting at home or through municipal programs is another important step, and is possible no matter where you live. An estimated 8-10% of yearly GHG emissions are associated with unconsumed food, and 30-40% of our national food supply is wasted every year. Composting keeps that organic waste from entering landfills in the first place, where it’ll decompose and produce methane. 

Because construction and demolition are huge sources of landfill waste, it’s also crucial that we reduce their waste materials by preserving existing buildings rather than constructing new ones, or by reusing and repurposing existing materials. 

Green waste decomposes at a composting facility at the Frank R. Bowerman Landfill in Irvine, California on Nov. 2, 2022. Paul Bersebach / MediaNews Group / Orange County Register via Getty Images

Legislative Action

Many of these solutions might seem like they’re out of our hands. How are we as individual people supposed to create a better global recycling system? How are we supposed to redistribute construction materials so they aren’t wasted? We can stop using single-use plastics on our own, but how can we make that change on a larger scale? How can we as individuals create a more just and sustainable MSW system?

Voting isn’t a silver bullet for all of our problems, but it’s an important tool we have in bringing about change. Vote for local and federal legislators who have platforms based on environmental action and justice, including the implementation of sustainable integrated waste management on a larger scale. Better-managed and engineered facilities for waste that meet environmental requirements and aren’t placed in sensitive areas is an important step. New York City — where residential composting is now mandatory – is one success story, and shows how large-scale composting solutions can be implemented by people in power. There are models for other ways of handling our waste. In Sweden, for example, 0% of MSW ends up in landfills, due in part to good recycling infrastructure and biological treatment of waste.

Coming up with other uses for the land that landfills occupy has been another topic of conversation. Many landfills in the U.S. have been identified as promising locations for solar farms, and many have already been built, using that land to create clean, renewable energy. 

The Hickory Ridge Landfill near Atlanta, Georgia opened in 2011 as the world’s largest landfill solar energy cap, including 10 acres of solar panels generating enough electricity to power 224 homes. Jeff Greenberg / Education Images / Universal Images Group via Getty Images

Takeaway

Landfills aren’t merely dumping grounds for our trash, but rather are complex, regulated structures with many components. Soil, air, and water pollution is just one set of issues associated with landfills, along with greenhouse gas emissions, injustices on nearby communities, and steep costs to human health. Creating a more just and sustainable system of waste management that minimizes our reliance on landfills — and makes the landfills we do have better-engineered, better-managed, and better-monitored – will be an effort that incorporates both personal action and large-scale legislation, and changes in how we view and handle waste in our culture.

The Puente Hills Park project in Industry, California involves re-landscaping what had been a vast landfill into a recreation/wilderness area. The landfill closed in 2013 after operating for 56 years. Pictured on June 28, 2023. Myung J. Chun / Los Angeles Times via Getty Images

The post Landfills 101: Everything You Need to Know appeared first on EcoWatch.

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Insurance sector digs into impact of mandatory climate reporting

Insurance sector digs into impact of mandatory climate reporting

Businesses are being encouraged to prepare for the impact of mandatory climate disclosure in Australia.

Earlier this year, the federal government passed amendments to the Corporations Act 2001 (Cth) and the Australian Securities and Investments Commission Act 2001 (Cth), resulting in mandatory climate reporting for larger businesses in Australia.

The issue was examined during a recent address to members of the Underwriting Agencies Council, with particular attention paid to how the new legislation will affect the insurance sector.

Speaking at the event, Prateek Vijayvergia, Xceedance Business Leader – Key Accounts, Australia and New Zealand, said that while 75% of ASX 200 companies were committed to or already performing climate reporting, the number fell to 10.5% for broader ASX companies.

“There’s a lot more awareness and commitment and urgency that we see in the Australian market now and this is not limited only to the insurance business, but for all larger Australian businesses,” he said.

“Although this is all good, there is a gap in climate-related reporting among ASX-listed entities, and the depth and the quantification.”

Joining Vijayvergia in the discussion was Sharanjit Paddam, Principal – Climate Analytics at Finity Consulting, who said that from 31 December 2025, in addition to an Annual Report, large companies will need to submit a Sustainability Report — what Paddam referred to as “the home for ESG disclosures”.

Four pillars underpin the disclosure standards — governance, strategy, risk management, and metrics and targets. Paddam emphasised that the devil is in the detail.

“You not only have to disclose the financial impacts on your balance sheet today and your income statement today, but also in the short-, medium- and long-term future,” he said.

“They (ASIC and APRA) want hard numbers to be put in the accounts about how climate change is financially going to affect the operations of the company.”

Paddam explained: “At the heart of the disclosure is really what are the financial impacts of climate change on your company, investors, customers and shareholders; to understand that and to allocate capital and make investment decisions informed by how climate change might affect your business.”

Paddam added that companies need to consider their own impact on climate change.

“The world is changing in disclosures in a very big way over the next few years, and companies are going to have to think about not just accounting for their financial outcomes, but also their climate outcomes,” he said.

“These are mandatory standards — this is locked in, and it will be required to happen over the next few years, and it is intended that these standards will change the economy and they will drive changes throughout the way we do business.”

A particular challenge will be the reporting of Scope 3 emissions — those indirectly generated by the activities of an organisation — due to lack of data, methodology and resources.

“What’s really helping all of us is the advancement in technology so there are better ways of collecting information and data around emissions,” Vijayvergia said.

“And also, to then slice and dice that information so it can be used to make a plan around climate risk.

“It’s becoming more comprehensive and almost integral to the overall reporting that’s happening for an organisation.”

Organisations impacted by these legislative changes include those that produce accounts under the Corporations Act and meet any two of the following criteria: consolidated assets more than $25m; consolidated revenue more than $50m; or 100 or more employees.

Paddam said the new requirements would capture some of the larger underwriting agencies and brokers.

“It’s an opportunity to look at the services that you are providing and how good a partner you are for your insurance provider, or as a distributor of insurance products, to see where you could uplift your services in this respect,” he advised.

“The things we insure, the things we invest in, are all intended to change as a result of these disclosures, and getting your heads around that quicker and faster than your competition is very important.”

Image credit: iStock.com/pcess609

Accessible Data Makes Renewable Energy Projects Possible Worldwide

Accessible Data Makes Renewable Energy Projects Possible Worldwide

Accessible Data Makes Renewable Energy Projects Possible Worldwide
jschoshinski
Thu, 11/14/2024 – 18:52

High fidelity, publicly available data is essential for mobilizing clean energy investment and informing renewable energy policy and deployment decisions, but access to this data is a critical barrier for many countries aiming to develop and optimize their clean energy resources. Recognizing the importance of tools that offer accessible data to inform renewable energy planning and deployment, the USAID-National Renewable Energy Laboratory (NREL) Partnership developed the Renewable Energy (RE) Data Explorer. RE Data Explorer is a publicly available geospatial analysis tool that provides free global renewable energy resource data to inform policy, investment, and deployment decisions for solar, wind, and other energy resources. 
Two of the thematic days at COP29 are focused on energy and science, technology, innovation, and digitalization. RE Data Explorer is a great example of how digital technologies can play a role in promoting clean energy and addressing the climate crisis. The tool also delivers on the commitment USAID made at COP28 to make investments that will “support technical assistance programs and partnerships to strengthen subnational climate preparedness.”
The use of USAID-NREL public data in Tanzania, available on RE Data Explorer, offers a direct example of the impact of accessible data on the implementation of renewable energy projects. Tanzania is working to accelerate the deployment of renewable energy and decarbonize its grid, aiming for 30-35 percent emissions reduction by 2030. A major challenge to pursuing this goal is the lack of reliable, long-term renewable energy resource data for project planning.
NextGen Solar, a private sector partner of USAID Power Africa, used USAID-NREL data specific to Tanzania to support the development of its renewable energy projects in the country. The company, which specializes in building and operating utility-scale solar photovoltaic (PV) power plants in sub-Saharan Africa and small island nations, utilized USAID-NREL public data to develop the world’s largest PV-hybrid solar mini grid in rural Kigoma, Tanzania. USAID-NREL public data enabled NextGen Solar to perform technical feasibility studies to forecast electricity generation in an area previously lacking reliable, affordable power. Thanks to this reliable data and analysis, NextGen Solar was able to mobilize $6 million in investment to build the plant. This 5-megawatt (MW) plant has now been in commercial operation for over 3.5 years and supplies electricity to over 65,000 homes, the region’s largest hospital, and three schools. It has also helped the Government of Tanzania save an estimated $2.2 million annually while reducing carbon emissions and demonstrating the viability of utility-scale solar power to sub-Saharan Africa.
The application of USAID-NREL public data in Ukraine is  another example of how open data can drive the mobilization of clean energy projects. Planners and developers in Ukraine are looking to incorporate more renewable energy, particularly wind and solar, as the country rebuilds its grid and searches for new means to become less dependent on foreign resources. Like Tanzania, a barrier for Ukraine was the lack of accessible, high-quality data on its wind and solar output capabilities. USAID-NREL is helping Ukraine overcome this barrier through new high-resolution solar time series data accessible on RE Data Explorer, which will help Ukraine meet the needs of stakeholders in the energy sector across the national government, academia, and private industry.
“[USAID-NREL public data] really helps with planning and understanding where the resources are—where it is most cost effective to build distributed resources that will help to decentralize the grid.”
NREL’s Ukraine program lead, Ilya Chernyakhovskiy

To better understand the broad impact of RE Data Explorer, a 2024 NREL survey gathered insights from respondents on how they applied this data in real-world scenarios. Overall, respondents reported evaluating and planning over 111,000 MWs of solar and wind projects, with a potential investment of over $6.5 billion. End-users also reported over 1,600 MWs of solar and wind energy with over $1 billion  in investment that has been approved and financed. For context, according to the Solar Energy Industries Association (SEIA), 1,600 MWs would power approximately 275,200 average U.S. homes and 111,000 MWs would power approximately 19.1 million.
One particular real-world example provided by the survey came from a respondent from climate tech startup Ureca who shared that their company pursued a .3MW solar project in Mongolia that was approved and financed. Ureca’s project “focuses on small PV systems for households in Mongolia that currently use raw coal for heating.” This initiative, called Coal-to-Solar, is now helping low-income families transition from coal to renewable energy in Ulaanbaatar, Mongolia—the coldest capital in the world—as part of a Just Energy Transition pilot aimed at reducing reliance on coal.
The outcomes of these projects also highlight how USAID and NREL are working together to implement USAID’s 2022-2030 Climate Strategy. In accordance with the plan’s strategic objective, “Targeted Direct Action: Accelerate and scale targeted climate actions,” projects informed by USAID-NREL public data in Tanzania, Ukraine, and Mongolia employed context-sensitive approaches to “support climate change mitigation and adaptation efforts in critical geographies, [and] mobilize increased finance.” Furthermore, USAID and NREL’s work focused on accessible data supported Intermediate Result 1.1 in the plan, which aims to “catalyze urgent mitigation (emissions reductions and sequestration) from energy, land use, and other key sources.” 
From accelerating Tanzania’s clean energy transition, to aiding Ukraine’s rebuilding efforts, to enabling clean energy projects across the world, USAID-NREL public data is helping users and local communities reduce greenhouse gas emissions, promote sustainable development, and pave the way for a cleaner, more resilient future. 
For more information about RE Data Explorer, watch this video. To learn more about how high-resolution solar data is enabling energy expansion across two continents, read this NREL article.

Teaser Text
USAID-NREL’s RE Data Explorer is a great example of how digital technologies can play a role in promoting clean energy and addressing the climate crisis.

Publish Date
Thu, 11/14/2024 – 12:00

Author(s)

Emily Kolm

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Blog Type
Blog Post

Strategic Objective

Mitigation

Region

Global

Topic

Emissions
Low Emission Development
Climate Policy
Climate Strategy
Climate Strategy Implementation
Digital technology
Energy
Clean or Renewable Energy
Grid Integration
Geospatial
Locally-Led Development
Mitigation
Partnership
Rural

Country

Tanzania
Ukraine

Sectors

Energy

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World Water Film Festival Opens in New York, Aims to Inspire

World Water Film Festival Opens in New York, Aims to Inspire

Right now across the U.S., drought persists, particularly in the northeast, where wildfires are burning because of the dry conditions. At the same time, some communities are still recovering from the catastrophic effects of hurricane season and the wind and water mash-up they wrought. In either case, water – both as a source of life […]
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