power

Storing carbon in buildings

February 4, 2025 By EarthWise Leave a Comment

According to a new study by researchers at the University of California, Davis and Stanford University, construction materials used in buildings have the potential to lock away billions of tons of carbon dioxide. The study, published in Science, shows that storing CO2 in buildings could be a major contributor to efforts to reduce greenhouse gas emissions.

Overall efforts in carbon sequestration take carbon dioxide – either as it’s being produced or once it’s already in the atmosphere – and store it away. Storing it might involve injecting it into underground caverns or deep in the ocean. Alternatively, storing it might involve converting it into a stable form using chemical reactions. These various strategies involve both practical challenges and potential environmental risks.

The new study suggests that many materials that are already produced in large quantities have the potential to store carbon dioxide. These include concrete, asphalt, plastics, wood, and brick. More than 30 billion tons of these materials are produced worldwide every year.

Ways to accomplish carbon storage include adding biochar into concrete, using artificial rocks loaded with carbon as concrete and asphalt aggregates, plastic and asphalt binders based on biomass instead of petroleum, and including biomass fiber into bricks.

The largest potential is using carbonated aggregates to make concrete. Concrete is by far the world’s most popular building material with more than 20 billion tons being produced each year.

The feedstocks for these ways to store carbon in building materials are mostly low-value waste materials, so the economics of implementing these carbon sequestering strategies are likely to be quite favorable.

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Storing Carbon in Buildings Could Help Address Climate Change

Photo, posted October 19, 2022, courtesy of Alexandre Prevot via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

A big year for battery storage

January 29, 2025 By EarthWise Leave a Comment

A decade ago, the ability of utilities to store large amounts of electricity in batteries was basically nonexistent. In the past several years, growth in battery storage systems has exploded. As of the end of November, the US had about 24 gigawatt-hours of storage capacity in place. This is 71% more than just a year ago. Nearly half of the battery storage in the US is located in California. Texas, Arizona, and Nevada are also leaders in deploying battery storage.

Battery storage allows solar and wind generating plants to keep operating when there is reduced demand for their output and have the electricity that they produce be available later when demand rises. Storing this excess electricity essentially extends the hours of the day when clean energy can be used.

Equally important, the existence of battery storage reduces the need for peaker plants, the fossil-fueled power plants that only turn on at times of peak demand, such as during hot afternoons.

There are 1,000 peaker plants in the US and they are generally heavily polluting, inefficient, and expensive to operate. Some 63 million people live within a three-mile radius of one of them and are exposed to harmful pollutants like nitrogen oxides and sulfur dioxide. Peaker plants also release more greenhouse gases than other power plants do for every unit of electricity they generate.

Many battery storage facilities are co-located with, or otherwise support, solar energy plants. The amount of solar energy in the US is growing rapidly and surpassed the 100-gigawatt mark in 2024. As solar power continues to expand, so will battery energy storage.

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Battery projects soared again in 2024

Photo, posted August 3, 2024, courtesy of the Bureau of Ocean Energy Management via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Energy storage with iron-air batteries

January 24, 2025 By EarthWise Leave a Comment

The Cambridge Energy Storage Project in Cambridge, Minnesota will be the first commercial deployment of iron-air battery technology. Developed by startup company Form Energy, the battery system will provide 1.5 MW and 150 MWh of multi-day energy storage.

Iron-air batteries are based on the principle of reversible rusting. When discharging, the battery releases energy by breathing in oxygen from the air and converting iron metal to rust. When charging, the battery takes up electrical current that converts rust back into iron and breathes out oxygen.

An individual iron-air battery module is about the size of a washer/dryer set and contains about 50 individual cells filled with a water-based, non-flammable electrolyte. For a utility-scale system like that being built in Cambridge, modules are grouped together in enclosures and hundreds of enclosures grouped together in megawatt-scale power blocks. A one-megawatt low-density system would take up about half an acre of land. High-density systems would be capable of producing more than 3 MW per acre.

The technology has lower costs compared to lithium-ion battery technology but may be best suited as complementary with it since lithium-ion is primarily used for short-duration energy storage while air-iron can store energy for several days.

The system is expected to be operational by late 2025. Great River Energy, the operator of the system, plans to conduct a multi-year study to evaluate the system’s performance and potential for broader development.

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Minnesota co-op breaks ground on multi-day energy storage project

Photo courtesy of Form Energy.

Earth Wise is a production of WAMC Northeast Public Radio

Investing in carbon capture

January 22, 2025 By EarthWise Leave a Comment

The interests of billionaires seldom seem to coincide with our own. In fact, they often seem to be quite the opposite. But there are a number of billionaires who are trying to help the world combat climate change. Yes, they want to make money doing it, but doing it is nevertheless in everyone’s interest.

A group headed by Bill Gates that included some of the wealthiest people from around the world met last summer in London to evaluate companies working to mitigate the effects of climate change. These included companies developing carbon dioxide removal technologies. Stripping carbon dioxide out of the atmosphere is an obvious way to deal with the fact that we continue to dump too much of it into the atmosphere – obvious, but extremely difficult to do at any scale that makes a difference.

Companies working on carbon capture have raised more than $5 billion since 2018. There are hundreds of companies working on it and investors include billionaires, venture capitalists, private equity firms, and major corporations. Companies like Microsoft, Google, and United Airlines have committed billions of dollars to purchase removal credits: payments to companies for removing carbon dioxide.

There are only a few dozen carbon removal facilities operational today and together they only capture a tiny fraction of the carbon dioxide humans release into the atmosphere. The hope is that such facilities will scale up in size and number so that they will make a real dent in the problem. But it will take many years at best, and the planet doesn’t have that much time. To make a difference, carbon emissions must be reduced as quickly as possible.

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The New Climate Gold Rush: Scrubbing Carbon From the Sky

Photo, posted April 19, 2020, courtesy of Greg Rubenstein via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Tourism and greenhouse gas emissions

January 17, 2025 By EarthWise Leave a Comment

Tourism is a major contributor to global greenhouse gas emissions, accounting for about 9% of the global total. Over the past 15 years, its emissions have grown more than twice as fast as those of the rest of the global economy.

Unless the tourism industry finds ways to slow down its growing emissions, those emissions will continue to increase by 3 to 4% each year, meaning that they will double every 20 years. The major drivers behind tourism’s growing emissions have been slow improvements in tourism-related technologies coupled with the rapid growth in demand.

Transportation is tourism’s main source of greenhouse gas emissions. Planes and cars generate the most carbon dioxide but there are contributions from tour buses, boat rides, ferries, and trains as well. The increasing demand for international travel has been the largest contributor to the growth of tourism-related emissions. But just as people’s homes generate emissions from energy use, so do hotels and other lodging used on vacations.

The United States, China, and India are responsible for 60% of the total increase in tourism’s carbon footprint. Generally speaking, it is the world’s wealthiest nations that have the most tourists exploring the world.

Researchers from Australia’s University of Queensland recommended several measures to slow the growth of tourism’s carbon emissions. These include reducing long-haul flights, imposing carbon dioxide taxes, setting carbon budgets, and the use of alternative transportation fuels. At the local level, tourism businesses making use of renewable energy sources and electric vehicles would help.

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Tourism leads the pack in growing carbon emissions

Photo, posted September 14, 2014, courtesy of Gary Campbell-Hall via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Battery life in electric cars

January 9, 2025 By EarthWise Leave a Comment

Most of us have lots of experience with the batteries in phones, computers, and other gadgets. Batteries don’t last forever, and we sometimes have to replace them. It’s a fact of life. These days, it’s becoming more common to drive electric cars and the fundamental principle is the same. However, the battery pack in an EV is the most expensive part of the car, so its reliability and lifespan is a greater concern.

EV batteries generally have generous warranties. In the US, EV batteries are required by federal law to be covered for at least 8 years or 100,000 miles, whichever comes first. So, the financial exposure from the battery pack is reasonably limited. Even so, EV owners would like to know that their car’s battery pack is likely to last a long time.

Battery life is generally determined by laboratory tests involving repeated charge-discharge cycles over a relatively short period of time, as opposed to those cycles being spaced out over years.

A new study by Stanford University looked at battery performance under conditions much more like what would be experienced in the real world. Cars experience frequent acceleration, braking that charges the batteries a bit, lots of stops, periods of rest, and so forth. Nothing like just charging and discharging repeatedly.

The study found that today’s EV batteries may last up to 40% longer than expected. Real-world stop-and-go driving benefits batteries more than standard test conditions.

The cost of EV batteries continues to get lower all the time and it is likely to be quite a long time before one is likely to need a new battery assuming one even keeps the car long enough.

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Existing EV batteries may last up to 40% longer than expected

Photo, posted August 27, 2021, courtesy of Ron Frazier via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Thermal batteries for heavy industry

January 3, 2025 By EarthWise Leave a Comment

Heavy industries like cement, steel, chemicals, and paper require large amounts of heat and, for the most part, that heat comes from burning fossil fuels. Other sectors of the economy have been making progress in reducing carbon emissions, but heavy industry has not found easy answers for supplying the heat it needs for manufacturing.

Researchers at MIT have developed a way to supply heat that only uses electricity, which in principle can come from carbon-free sources. The idea is to use thermal batteries. These are basically an electrically conductive equivalent of ceramic firebricks, which have been used to store heat for centuries in fireplaces and ovens.

A spinout company called Electrified Thermal Solutions has demonstrated that its firebricks can store heat efficiently for hours and release it by heating air or gas up to 3,272 degrees Fahrenheit.

The firebrick arrays are contained in insulated, off-the-shelf metal boxes. The standard system can collect and release about 5 megawatts of energy and store about 25 megawatt-hours. The thermal battery can run hotter and last longer than any other electric heating solution on the market.

Using this technology can be a way to take advantage of the low cost of electricity in off-peak hours. In the so-called wind belt in the middle of the U.S., electricity prices can even be negative at times. Using the firebrick technology – called the Joule Hive Thermal Battery – it can be possible to provide industrial heating capability at very competitive prices, and that doesn’t even factor in the positive climate impact.

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Decarbonizing heavy industry with thermal batteries

Photo, posted April 19, 2019, courtesy of Hans M. via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

A solar peaker plant

January 1, 2025 By EarthWise Leave a Comment

Peaker plants are power plants that the grid makes use of during times of particularly high electricity demand. The power they supply is typically high in cost and usually high in greenhouse gas emissions. When operating the electricity grid, power sources are generally called upon in order of marginal cost. Only when demand is very high do grid operators make use of the highest-cost assets that tend to be fossil-fueled power plants that can start and ramp up quickly.

For years, there has been the idea that solar-powered peaker plants could eventually replace the polluting fossil-fueled ones. Recently, the renewable energy developer, owner, and operator Arevon Energy began commercial operations of the Vikings Solar-plus-Storage Project in Imperial County, California. It is the first utility-scale solar peaker plant in the United States.

The plant utilizes a 157-megawatt solar array combined with 150 MW and 600 MWh of battery energy storage. It can shift low-cost daytime solar energy to higher-cost peak demand periods. The result is a lowered cost of electricity for nearly one million customers of San Diego Community Power.

The project contradicts the often-held notion that renewable energy is inherently unreliable. It can provide carbon-free electricity at specific times of critical need. Typical hybrid solar + storage plants provide electricity during daylight hours and store only excess generation in their battery systems. The Vikings project is specifically designed to shift the entirety of its generation from solar hours to the peak demand period.

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Arevon fires up the first solar + storage peaker plant in the U.S.

Photo, posted October 15, 2024, courtesy of Jay Inslee via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Neighborhood geothermal energy

December 30, 2024 By EarthWise Leave a Comment

Residential geothermal energy makes use of the constant, year-round temperature of the earth below the surface to efficiently provide both heating and cooling for a home. In the summer, the cool earth beneath a house sits at about 55 degrees and can be tapped into with a heat pump to provide cooling. In the winter, that 55-degree underground expanse provides a much warmer source of air to heat instead of the often freezing-cold air outside. Geothermal systems are appealing because they use far less energy than other sources of heating and cooling.

Using geothermal energy to heat and cool buildings is nothing new. But after years of planning and months of drilling into the ground, the first neighborhood-scale geothermal heating and cooling project has come online in Framingham, Massachusetts.

The project ties together 31 residential and five commercial buildings that share the underground infrastructure needed to heat and cool them. This sort of shared geothermal system has previously been used on college campuses and similar places, but never before across a neighborhood in the United States.

The $14 million project, built by Eversource, broke ground in June 2023, and comprises 90 boreholes or wells drilled 600-700 feet underground. Approximately 135 customers are connected to the system, including low- and moderate-income customers, apartment buildings, a gas station, and a kitchen cabinet showroom.

A total of 13 states, including Massachusetts and New York, are considering pilot projects or advancing legislation that would allow gas utilities to develop networked geothermal heating and cooling.

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First-in-the-Nation Geothermal Heating and Cooling System Comes to Massachusetts

Photo, posted September 30, 2019, courtesy of Stephen D. Strowes via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Faster electric vehicle charging

December 25, 2024 By EarthWise Leave a Comment

One concern that people have in replacing gas-powered vehicles with electric vehicles is the time it takes to charge them. Charging an EV at home from an ordinary 110V electrical outlet is a slow process; installing a 220V outlet speeds things up considerably but it still can take all night to fully charge a car. The driving range of electric cars has increased over the years so that now there are many cars that can go 300 miles or more on a charge. For most people, so-called range anxiety is mostly gone. But on long road trips, charging time can be a real issue.

There are increasing numbers of high-speed chargers along or adjacent to major highways that can provide 200 miles of driving range in less than half an hour. But people want more charge, and they want it faster.

There are multiple efforts in improving EV batteries and charger technology aimed at transforming a visit to a public charger to an experience comparable to filling up at a gasoline station.

Researchers at the University of Waterloo have designed a new kind of lithium-ion battery that will be able to go from zero battery power to 80% in just 15 minutes. This technology would certainly enhance the capabilities of today’s electric cars. However, it is quite possible that other technologies that surpass this performance will emerge in the near future. There is talk across the industry of cars that can charge up in 5 or 10 minutes. There is also the prospect of many cars that can drive 500 miles on a charge. These features would address the needs or desires of all but a very small number of drivers.

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From zero to 80 per cent in just 15 minutes

Photo, posted May 7, 2022, courtesy of Sharon Hahn Darlin via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Giant batteries in the Earth

December 23, 2024 By EarthWise 1 Comment

The wind and the sun are inexhaustible sources of energy, and we are tapping into them to produce electricity at a growing rate around the world. But neither of them is always available when we need them. When the sun isn’t shining and the wind isn’t blowing, they don’t work.

An opposite problem also exists. When our energy needs are low, but it is sunny or windy, solar and wind power are all dressed up with nowhere to go. Energy storage is the answer to both of these problems. When there is excess generation, store the energy for later use. When there is need for energy and not enough is being generated, tap into the energy that is stored.

Giant banks of lithium-ion batteries are the rapidly growing form of energy storage, and they are increasingly providing resilience in the electric grid. But battery storage is short-term energy storage. Even the largest battery banks can only provide a few hours of electricity.

So, there is a real need for “long-duration energy storage” – systems that provide at least 10 hours of backup power and sometimes much more – for the grid to be fully reliable.

Pumped hydro storage, which uses water from elevated reservoirs to drive turbines, has been around for a long time. Historically, this is the largest form of energy storage in the world. Other methods include pumping compressed air into underground caverns or lifting massive blocks into elevated positions. All of these techniques use excess electricity to place things like water, air, or cement into a position where they can be used to drive electrical generators.

The grid of tomorrow will store energy in giant battery banks, but also in the ground, in reservoirs, and in large structures.

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How giant ‘batteries’ in the Earth could slash your electricity bills

Photo, posted March 21, 2024, courtesy of Sandra Uecker/USFWS via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Hydrogen-powered aviation

December 16, 2024 By EarthWise Leave a Comment

The transportation sector is responsible for about a quarter of human-generated greenhouse gas emissions. Most of the energy used by transport systems comes from fossil fuels. The transition to electric vehicles – cars, trucks, and buses – is making a real difference. However, the emissions from the aviation industry have continued to grow faster than those of other forms of transportation. There have been increased efforts to develop hydrogen-powered aircraft, but the challenges are substantial.

Hydrogen can be used for aviation both as a directly combusted fuel, or to power electric fuel cells. Its advantages are that its use produces no carbon dioxide, and, in fact, hydrogen produces more energy per pound than jet fuel.

A study by researchers at MIT looked at the prospects for hydrogen use in aircraft and what needs to be done to make it practical. The biggest issue is that the extra bulk of a hydrogen fuel tank and fuel cells in a plane would have to be offset by weight reductions elsewhere, such as reducing payload (cargo or passengers). This would mean there would need to be more flights, thereby reducing the gains made. The researchers argued that improvements in fuel cell power and more weight efficient fuel systems could eliminate the need for additional flights.

The bigger challenge is the infrastructure for generating and distributing hydrogen. There needs to be green hydrogen – hydrogen produced without carbon emissions – and the infrastructure for getting it to planes where it is needed has to also not produce substantial emissions.

The study suggests that the rollout of hydrogen-based aviation should start at locations that have favorable conditions for hydrogen production.

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Fueling greener aviation with hydrogen

Photo, posted December 20, 2016, courtesy of Dylan Agbagni via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Capturing hot carbon dioxide

December 13, 2024 By EarthWise Leave a Comment

Decarbonizing industries like steel and cement is a difficult challenge. Both involve emitting large amounts of carbon dioxide both from burning fossil fuels and from intrinsic chemical reactions taking place. A potential solution is to capture the carbon dioxide emissions and either use them or store them away. But this sort of carbon capture is not easy and can be quite expensive.

The most common method for capturing carbon dioxide emissions from industrial plants uses chemicals called liquid amines which absorb the gas. But the chemical reaction by which this occurs only works well at temperatures between 100 and 140 degrees Fahrenheit. Cement manufacturing and steelmaking plants produce exhaust that exceeds 400 degrees and other industrial processes produce exhaust as hot as 930 degrees.

Costly infrastructure is necessary to cool down these exhaust streams so that amine-based carbon capture technology can work.

Chemists at the University of California, Berkeley, have developed a porous material – a type of metal-organic framework – that can act like a sponge to capture CO2 at temperatures close to those of many industrial exhaust streams. The molecular metal hydride structures have demonstrated rapid, reversible, high-capacity capture of carbon dioxide that can be accomplished at high temperatures.

Removing carbon dioxide from industrial and power plant emissions is a key strategy for reducing greenhouse gases that are warming the Earth and altering the global climate. The captured CO2 can be used to produce value-added chemicals or can be stored underground or chemically-reacted into stable substances.

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Breakthrough in capturing ‘hot’ CO2 from industrial exhaust

Photo, posted March 3, 2010, courtesy of Eli Duke via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Artificial plants to clean indoor air

December 12, 2024 By EarthWise Leave a Comment

The average American spends about 90% of their time indoors breathing the air in our workplaces, homes, or schools. The quality of this air affects our overall health and well- being. Indoor air quality is an issue because many sources can generate toxic materials, including building materials, carpets, and more. But high levels of carbon dioxide are a health hazard themselves. Indoor CO2 levels can often be 5 to 10 times higher than the already heightened levels in the atmosphere.

Many of us make use of air purification systems, which can be expensive, cumbersome, and require frequent cleaning and filter replacements.

Researchers at Binghamton University in New York are working to develop artificial plants that consume carbon dioxide, give off oxygen, and, as a bonus, generate a little electricity. These artificial plants make use of the artificial light in the indoor environment to drive photosynthesis. They achieve a 90% reduction in carbon dioxide levels, which is far more than natural plants can achieve.

The Binghamton researchers had been working on bacteria-powered biobatteries for various applications, but they repurposed the work into a new idea for artificial plants. The artificial plants have “leaves” containing a biological solar cell and photosynthetic bacteria. Their first plant had five leaves and demonstrated promising carbon dioxide capture rates and oxygen generation. It also produced a little electricity. If its generating capacity can be improved, it might also be useful for charging cell phones or other practical applications.

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Binghamton researchers develop artificial plants that purify indoor air, generate electricity

Photo, posted October 13, 2012, courtesy of F. D. Richards via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

A better way to extract lithium

December 10, 2024 By EarthWise Leave a Comment

Lithium is the critical component in the batteries that power phones and computers, electric cars, and the systems that store energy generated by solar and wind farms. Lithium is not particularly rare, but it is difficult and often environmentally harmful to extract from where it is found.

Traditional ore sources are increasingly difficult and expensive to mine. The largest known deposits of lithium are in natural brines – the salty water found in geothermal environments. These brines also contain other ions like sodium, potassium, magnesium, and calcium, and efficiently separating out the lithium is extremely challenging.

Traditional separation techniques consume large amounts of energy and produce chemical waste, particularly hazardous chlorine gas. These techniques typically suffer from poor selectivity; that is, the process is interfered with by the other ions present in natural brines.

A team of researchers at Rice University has developed a three-chamber electrochemical reactor that improves the selectivity and efficiency of lithium extraction from brines. The middle chamber of the reactor contains a specialized membrane that acts as a barrier to chloride ions, preventing them from getting to the electrode area where they can form chlorine gas.

The new reactor has achieved a lithium purity rate of 97.5%, which means the setup can effectively separate lithium from other ions in the brine and allow the production of high-quality lithium hydroxide, the key material for battery manufacturing.

The Rice University reactor design has the potential to be a game changer for lithium extraction from geothermal brines.

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‘Game changer’ in lithium extraction: Rice researchers develop novel electrochemical reactor

Photo, posted October 21, 2023, courtesy of Simaron via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

The race for fusion power

December 9, 2024 By EarthWise Leave a Comment

The sun is powered by fusion energy. Hydrogen atoms fuse together into helium atoms, liberating vast amounts of energy in the process. Our understanding of this process emerged early in the 20th century and by the 1950s, research efforts were underway trying to replicate the process on Earth. If it could be done, fusion would be a source of almost unlimited clean energy. But there has been a cynical saying going around for half a century: fusion power is the energy source of the future, and it always will be.

However, in recent years, there has been progress in developing fusion power. Extraordinarily expensive and colossal machines have produced fusion energy albeit consuming more energy than they make. However, for a brief moment in 2022, a fusion reactor at Lawrence Livermore National Laboratory did produce more energy than it took to run the machine.

Despite the less than encouraging history, there are now multiple start-up companies dedicated to developing fusion energy and they are optimistic that there will be significant progress over the next few years.

One such company, Commonwealth Fusion Systems, located 40 miles northwest of Boston, is building a fusion reactor called SPARC, that they claim will be producing net energy in 2027. They say that their next machine, called ARC, will generate electricity for paying customers in the early 2030s.

A handful of other companies, including Type One Energy, Thea Energy, Realta Fusion, Zap Energy, General Fusion, and Helion Energy are also pursuing fusion reactor designs and also expect to have machines running over the next 5 to 10 years.

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The Quest to Build a Star on Earth

Photo, posted April 21, 2015, courtesy of John Spiri via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Limiting global warming

December 4, 2024 By EarthWise Leave a Comment

A pressing question from the recently concluded 29th annual United Nations Climate Change Conference in Azerbaijan is how to transition away from fossil fuels and speed up climate mitigation in line with the 1.5 °C global warming target.

Keeping global average temperatures below 1.5 °C above pre-industrial levels is crucial to avoid the most severe impacts of climate change, including extreme weather, rising seas, biodiversity loss, and disruptions to food and water security.

According to a new study by researchers from Stockholm University, Chalmers University of Technology, and Uppsala University in Sweden, it is still possible to limit global warming to 1.5 °C. But the study found that the United States, the European Union, and 16 other countries will have to exceed their own current targets in order to achieve this global goal.

The study, which was recently published in the journal Nature Communications, introduced an “additional carbon accountability” indicator, which quantifies countries’ responsibility for mitigation and carbon dioxide removal in addition to achieving their own targets.

The study identified 18 countries that should be accountable for increasing their ambitions to stay within their equal per capita share of the global carbon budget for 1.5 °C. Additional carbon accountability is highest for the United States and China, and highest per capita for the United Arab Emirates, Russia, Saudi Arabia, and the U.S.

Failure to limit global warming risks catastrophic impacts of climate change.

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COP29: Possible to limit climate change to 1.5°C – if EU and 17 other countries go beyond their own targets

Photo, posted December 27, 2015, courtesy of Gerry Machen via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Mining extinct volcanoes

December 2, 2024 By EarthWise Leave a Comment

Rare earth elements are a group of 17 elements that are used to improve the performance, efficiency, and durability of a wide range of products. More than 200 products across a diverse set of applications make use of rare earth elements. Although the amount of rare earth used in a particular product may not be very much of its weight, volume, or monetary value, it may often be necessary for the device even to function. Rare earth elements react with other elements to form compounds that are essential because of their specific chemical behaviors.

Rare earth elements are not actually rare; in fact, they are fairly common. But they are mostly not found in their pure form and are generally difficult to refine. China accounts for more than 90% of global production of rare earth elements and this represents a strategic problem for the rest of the world.

New research by scientists from the Australian National University has found that some extinct volcanoes, which have not erupted for thousands or even millions of years, may be rich sources of rare earth elements. Furthermore, those elements may be easier to extract than the ones from other sources because the iron-rich magma that formed the volcanoes could be up to 100 times more efficient at concentrating rare-earths than magma found in active volcanoes today.

The clean tech industry uses rare earths for wind turbines, solar panels, and electric cars. The demand for rare earths may grow fivefold by the end of this decade. Relying on just one country for the world’s supply is a major concern. There are ancient volcanoes all over the planet and they may represent a solution to a global problem.

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Extinct Volcanoes Could Be Source of Key Metals Needed for Clean Tech

Photo, posted June 6, 2020, courtesy of Dennis Jarvis via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Electric vehicles and health

November 29, 2024 By EarthWise Leave a Comment

Much of the discussion about the benefits of electric vehicles centers about the climate impact of not burning fossil fuels as well as about reduced operating costs. A new study by the University of Toronto looked at the health benefits of large-scale adoption of electric vehicles.

The Toronto researchers used computer simulations to show that widespread electrification of the U.S. vehicle fleet when coupled with significant use of renewable energy to power the fleet could result in health benefits worth between $84 and $188 billion dollars by 2050. Expressing these benefits in dollar terms is a way to quantify those benefits, but clearly what is most important is people’s health.

Carbon dioxide coming out of tailpipes is what is most harmful to the climate, but there is much more than CO2 vehicle exhaust. There are many air pollutants that have a significant, quantifiable impact on human health. These include nitrogen oxides, sulfur oxides, and small particles known as PM2.5.

The study simulated levels of air pollution across the United States under various scenarios of adoption of EVs and the use of renewable energy. The simulations clearly showed that the combination of widespread use of electric vehicles and the greening of the power grid would result in huge cumulative public health benefits. But these benefits will take time to accrue. The internal combustion vehicles being sold today will still be on the roads for many years and will continue to spread pollution everywhere there are roads.

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New research reveals how large-scale adoption of electric vehicles can improve air quality and human health

Photo, posted May 7, 2020, courtesy of Mark Vletter via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Carbon levies for shipping

November 27, 2024 By EarthWise Leave a Comment

The global shipping industry is responsible for 90 percent of world trade. The ships crossing the world’s oceans emit nearly 3% of the global greenhouse gas emissions caused by human activity that are contributing to climate change. Among the effects of climate change are sea level rise, which is threatening the very existence of small island nations.

One such nation is Tuvalu, which is a group of islands in the South Pacific. Tuvalu has a total landmass of just 10 square miles, and sea level there is rising 1.5 times faster than the global average. Predictions are that within 50 to 100 years, low-lying islands like those of Tuvalu could be fully submerged by the ocean.

Representatives from six Pacific Island states and a growing number of Caribbean nations known as the 6Pac+ Alliance are urgently calling upon the International Marine Organization to enact a mandatory universal levy of $150 per ton of shipping emissions from large commercial vessels.

Most marine vessels typically run on highly polluting heavy fuel oil. Burning really filthy fuel is the cheapest way to cross the oceans. There are alternatives including entirely carbon-free technologies, but they will be expensive to implement and utilize. The cost of shipping would undoubtedly go up and be especially felt by small island nations and in developing countries where most food is imported.

The idea behind putting a price on ships’ carbon emissions is to both provide a financial incentive for the shipping industry to reduce its emissions and provide revenue for countries that incur costs from dealing with rising seas.

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Pacific and Caribbean Island Nations Call for the First Universal Carbon Levy on International Shipping Emissions

Photo, posted November 23, 2006, courtesy of Stefan Lins via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio