storage

Energy storage in New York isn’t easy

September 19, 2025 By EarthWise Leave a Comment

The state of New York has the ambitious goal of having 70% of its electricity come from renewable sources in 2030 and a 100% zero-emission electric grid by 2040. Meeting these goals is becoming increasingly unlikely as the state faces multiple challenges including local opposition to projects, rising inflation, and the termination of offshore wind projects.

Solar and wind power are key elements of New York’s renewable plans, and both require battery energy storage so that excess energy can be saved when there is plentiful sun and wind so that there will be power available when nature hasn’t cooperated.

There are now over 6,000 battery storage projects in the state, mostly relatively small in magnitude. Currently, the state has a storage capacity of about 445 megawatts, enough to power roughly 300,000-400,000 homes. The state has a goal of having 6 gigawatts of storage by 2030, more than a dozen times more than exists today.

Most of New York’s electricity demand is downstate, in and below the Hudson Valley. Real estate is limited and expensive and there is lots of opposition to big energy projects in the region.

However, installing the actual battery systems themselves can be one of the easier parts of the process. Obtaining permits from state and local authorities, buying or leasing land, negotiating with grid operators, completing environmental reviews, overcoming local opposition, and especially, connecting to the electric grid, are all challenging and very time consuming.

Meeting the state’s energy storage goals is not easy.

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Figuring Out a Battery Storage System to Fit New York’s Wind and Solar Ambitions Has Not Been Easy

Photo courtesy of NineDot Energy.

Earth Wise is a production of WAMC Northeast Public Radio

Deconstructing buildings

July 24, 2025 By EarthWise Leave a Comment

An estimated 30 million tons of wood waste from construction and demolition in the U.S. ends up in landfills each year. A growing number of cities have launched initiatives to reuse the wood instead. It is a strategy to reduce carbon emissions, cut waste, and shift towards a circular economy.

For a long time, salvaged wood was a niche pursuit by people who valued the fine grain and enduring quality of older wood. Reclaimed old-growth lumber offers character and strength. These people pursued construction that uses wood with a story – timber recovered from historic structures, collapsing barns, and other demolished buildings.

Now, there are multiple companies in the business of salvaging wood from buildings. Cities and businesses are embracing the use of reclaimed materials. Ordinances in cities like Portland, Oregon, Boulder, Colorado, and San Antonio, Texas require older buildings to be taken apart for repurposing their materials. Palo Alto, California has banned demolition completely.

Portland was the first U.S. city to require old residential homes to be deconstructed. After a decade, contractors have deconstructed more than 650 homes in the city, salvaging 2,000 tons of reusable wood.

Using reclaimed wood in local buildings stores carbon and reduces emissions by avoiding the need to cut new trees, process materials, and ship them long distances.

Deconstructing buildings is not a widely available skill. Contractors have to be trained on how to dismantle buildings piece by piece. But there is now a national registry of deconstruction trainers and a network of practitioners.

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Deconstructing Buildings: The Quest for New Life for Old Wood

Photo, posted May 16, 2018, courtesy of Alexandre Prevot via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Record forest loss

July 3, 2025 By EarthWise Leave a Comment

The world lost a record amount of forests last year. The biggest factor for the unprecedented losses were wildfires that raged around the world.

According to the annual update by the University of Maryland and the World Resources Institute, pristine rainforests alone lost 17 million acres, which was nearly twice as much as in the previous year. Overall, the world lost the equivalent of 18 soccer fields of forested land every minute last year.

Over time, agriculture has been the primary cause of forest losses, but last year, for the first time since record-keeping began, fires were the leading cause, accounting for nearly half of all the destruction.

With respect to the climate, wildfires emitted over 4 billion tons of greenhouse gasses, which is more than four times the amount generated by air travel in 2023.

Land clearing for agriculture, cattle farming, and other purposes was by no means in decline last year. In fact, it rose by 14%, which was the sharpest increase in almost a decade. This trend could permanently transform critical natural areas, unleashing large amounts of carbon, intensifying climate change, and fueling even more extreme fires.

Forests are a major contributor to the natural storing of carbon dioxide. Intact tropical forests are especially effective at storing carbon.

Brazil has the largest area of tropical forest and it accounted for 42% of all tropical primary forest loss in 2024. Fires fueled by the worst drought on record caused two thirds of that loss, more than a sixfold increase over the previous year.

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Global Forest Loss Hit a Record Last Year as Fires Raged

Photo, posted September 12, 2024, courtesy of the USDA Forest Service via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Sun powered carbon capture

June 30, 2025 By EarthWise Leave a Comment

As the world struggles to implement technologies and find the political will to reduce carbon emissions, there are also ongoing efforts to find ways to capture carbon from emitting sources and from the atmosphere itself. After capturing carbon dioxide, there is then the need to safely store it or make use of it.

Current methods for capturing and then releasing carbon dioxide are expensive and energy intensive. In fact, some methods even require the use of fossil fuels. Recently, researchers at Cornell University have developed a method for capturing carbon dioxide that is powered by sunlight.

The Cornell method mimics the mechanisms that plants use to store carbon which involves using sunlight to make a reactive enol molecule that grabs carbon dioxide.

Existing chemical-based carbon capture techniques make use of amines, which are organic ammonia-derived compounds that react selectively with carbon dioxide. But amines are not stable in the presence of oxygen and don’t last, which necessitates the energy-intensive production of more and more amines.

The Cornell method uses the same method that the plant enzyme RuBisCo uses in photosynthesis. It is based on an inexpensive sorbent material that is capable of a high rate of carbon capture.

The researchers tested the system using flue samples from Cornell’s Combined Heat and Power Building, an on-campus power plant that burns natural gas. The system was successful in isolating carbon dioxide.

Ultimately, they would like to stage the reaction on what looks like a solar panel, but one that would capture carbon instead of generating electricity.

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In a first, system uses sunlight to power carbon capture

Photo, posted August 8, 2015, courtesy of Holly Victoria Norval via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Nature: An important climate ally

June 10, 2025 By EarthWise Leave a Comment

Nature is often seen as a victim of climate change, but it’s also one of the most powerful tools we have to fight it. Natural ecosystems, such as forests, wetlands, grasslands, oceans, and soils, absorb and store massive amounts of carbon dioxide. These ecosystems not only help reduce the concentration of greenhouse gases in the atmosphere, but they also regulate temperatures and provide buffers against extreme weather.

One of the most effective strategies for mitigating climate change is simply protecting and restoring these natural areas. For example, mangrove forests – those coastal wetlands filled with tangled, salt-tolerant trees – sequester carbon at high rates and help protect coastal communities from storm surges and rising seas. Peatlands – another type of wetland – store more carbon than all the world’s forests combined – despite only covering 3% of Earth’s land surface. Global restoration efforts are underway, from replanting mangroves in Southeast Asia to rewetting degraded peatlands in Europe.

Creating urban green spaces like parks and community gardens, restoring forests through native tree plantings, and adopting sustainable agricultural practices like cover cropping and agroforestry are all proven to be low-cost, high-impact climate solutions.

While nature-based solutions are gaining recognition, they remain critically underfunded, according to a recent United Nations report. Closing this gap is essential to unlocking nature’s full climate potential.

Investing in nature isn’t just about preserving Earth’s natural beauty. It’s a practical strategy for building a more resilient and sustainable future.

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Mangrove forests and rising seas

Financing Nature-based Solutions for a better future

Finding peatlands

The Importance Of Urban Green Spaces

Photo, posted October 23, 2011, courtesy of the Everglades National Park / NPS via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Feeding the future

June 9, 2025 By EarthWise Leave a Comment

Climate change is already affecting the yields of major staple crops around the world, and researchers warn that the impacts will become more severe over time. Rising temperatures, shifting rainfall patterns, and more frequent extreme weather events are disrupting growing seasons and reducing agricultural productivity.

Addressing these growing threats requires rethinking how we grow, distribute, and consume food. To kick off Climate Solutions Week, we wanted to examine some solutions that could make food systems more resilient, sustainable, and adaptable to our rapidly changing environment.

One solution is Climate-Smart Agriculture, which blends traditional practices with modern techniques to boost productivity while reducing greenhouse gas emissions. Methods like zero tillage, intercropping, and crop diversification could improve soil health, conserve water, and help farms withstand climate extremes.

Expanding the production of highly nutritious and climate resilient food crops – like millet, sorghum, teff, quinoa, chickpeas, and tepary beans – will also have an important role to play. At the same time, reducing food waste through better storage, labeling, and surplus food re-use could help meet demand without increasing production pressure.

Agriculture is the largest user of freshwater globally, and climate change is intensifying water shortages. Farmers will need to transition to water-efficient farming practices, including drip irrigation, rainwater harvesting, and the reuse of treated wastewater.

Together, these solutions could help revolutionize the global food system to both feed a growing population and help protect the planet.

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Climate-smart agriculture

Water for Prosperity and Peace

A Food For The Future

Photo, posted October 16, 2011, courtesy of Alliance of Bioversity International and CIAT via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

A green battery from industrial waste

February 11, 2025 By EarthWise Leave a Comment

Flow batteries are rechargeable batteries in which liquid electrolytes flow through one or more chemical cells from one or more tanks. The electrolytes are redox pairs, that is, chemical compounds that can reversibly undergo reduction and oxidation reactions. The most common redox electrolytes include elements like vanadium, chromium, iron, zinc, and bromine. Flow batteries can provide large amounts of both electrical power and stored energy based on the size of the electrolyte tanks. As a result, they can be scaled up far more readily than other battery technologies.

Flow batteries are safe, stable, long-lasting, and their electrolytes can easily be refilled. They have significant potential for use in utility-scale storage for renewable energy systems.

Researchers at Northwestern University have developed a redox flow battery based on an organic industrial-scale waste product. The material – triphenylphosphine oxide or TPPO – is produced in the thousands of tons each year. It is byproduct of producing a variety of substances including some vitamins, pharmaceuticals, agrochemicals, and other bulk chemicals. For the most part, TPPO is of little use and must be carefully discarded.

The current market for redox flow batteries is very small but is expected to grow over time as the need for utility-scale energy storage continues to expand. A battery technology based on a waste material that is already produced in high volume and that must otherwise be disposed of with caution would have significant advantages.

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Green battery discovery turns trash into treasure

Photo, posted January 12, 2015, courtesy of California Energy Commission via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

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

Growing safer potatoes

January 15, 2025 By EarthWise Leave a Comment

We are often advised to avoid eating green areas on potatoes. The green comes from chlorophyll that occurs naturally when potatoes are exposed to light. It is harmless but when it is there, it can be accompanied by a natural toxin – a substance called solanine, which is a steroidal glycoalkaloid or SGA. Sunlight can produce solanine as well as chlorophyll. Solanine is produced by plants to protect them from insects.

Solanine is bitter tasting so one is unlikely to consume much of it. But consuming enough of it can lead to gastrointestinal complications like diarrhea, abdominal pain, vomiting, and sweating.

Researchers at the University of California Riverside have discovered a way to eliminate toxic compounds from potatoes, making them safer to eat and easier to store. They have identified a key genetic mechanism in the production of SGAs. They found a specific protein that controls the production and believe it will be possible to control where and when SGAs are produced. Thus, it may be possible to have SGAs present in the leaves of potato plants, thereby protecting them from insects, while having none in the potatoes themselves. By limiting SGAs to non-edible parts of plants, they can be safer and more versatile plants. For example, modified potatoes could be stored in sunny places without worry and would always be safe to eat.

Plants have evolved ingenious ways to balance growth, reproduction, and defense. Our growing understanding of these mechanisms can allow people to redesign crops to meet modern needs, increase food safety, and reduce food waste.

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Growing safer spuds: Removing toxins from potatoes

Photo, posted October 14, 2013, courtesy of Elton Morris 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

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

Mangrove forests and rising seas

December 6, 2024 By EarthWise Leave a Comment

Mangrove forests play a vital role in the health of our planet. They protect coastal regions by acting as natural barriers against storms, erosion, and flooding. The intricate root systems of mangrove forests, which allow the trees to handle the daily rise and fall of tides, also serve as biodiversity hotspots, attracting fish and other species seeking food and shelter from predators.

But mangrove forests around the world are under increasing threat from deforestation, coastal development, and climate change. In fact, according to a new study led by researchers from Northumbria University in England, the mangrove trees in the Maldives are actually drowning.

The research, which was recently published in the journal Scientific Reports, found that sea levels around the Maldives rose more than 1.18 inches per year from 2017 to 2020. An unusually intense climate phenomenon, known as the Indian Ocean Dipole, occurred toward the end of this period, causing warmer sea surface temperatures and an increase in sea level in the Western Indian Ocean.

While mangrove forests can naturally keep pace with gradually rising seas, this rate of sea level rise was too fast. The rising sea level meant that seawater effectively flooded mangrove forests, causing many trees to lose their resilience and die. Some islands in the Maldives have lost more than half of their mangrove cover since 2020.

Since mangrove forests also store massive amounts of carbon, the research team fears that the loss of mangrove forests could release large amounts of carbon, further accelerating climate change.

The researchers warn that the findings in the Maldives could have implications for coastal ecosystems around the world.

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“Drowning” mangrove forests in Maldives signal global coastal threat

Photo, posted February 11, 2015, courtesy of Alessandro Caproni via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

The bloated carbon footprint of LNG

November 15, 2024 By EarthWise Leave a Comment

According to the U.S. Department of Energy, the United States is the world’s largest producer of natural gas. In fact, natural gas supplies approximately one third of the United States’ primary energy consumption, most of which is used to heat buildings and to generate electricity. While most natural gas is delivered in its gaseous form in this country, the demand for natural gas in international markets has given rise to the use of natural gas in a liquified form.

Liquified natural gas (LNG) is natural gas that has been cooled to a liquid state, at about -260° Fahrenheit, for easier storage and transportation. The volume of natural gas in its liquid state is about 600 times smaller than its volume in its gaseous state, which makes it possible to transport it to places pipelines do not reach.

Liquified natural gas is considered a clean fossil fuel because burning it produces less emissions than coal and oil. However, according to a new study by researchers from Cornell University, LNG imported from the U.S. actually has a larger climate impact than any other fossil fuel—including coal – once processing and shipping are taken into account.

The study, which was recently published in the journal Energy Science & Engineering, found that LNG leaves a greenhouse gas footprint that is 33% worse than coal when emissions are analyzed over a 20-year time frame.

According to the research team, there is no need for LNG as an interim energy source because the transition requires massive infrastructure expenditures. Instead, those financial resources should be used to “build a fossil-fuel-free future as rapidly as possible.”

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Liquefied natural gas carbon footprint is worse than coal

Photo, posted November 17, 2017, courtesy of Colin Baird via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

How much energy storage is needed?

November 11, 2024 By EarthWise Leave a Comment

Energy storage is a critical aspect of modern energy systems as they move towards heavy dependence on renewable sources such as solar and wind that don’t produce energy at the same rate all the time. Excess energy generated by solar power needs to be stored for when the sun isn’t shining; excess wind energy needs to be stored for when the wind isn’t blowing. But how much storage capacity does the energy system need to have?

Researchers at North Carolina State University have developed a model that can be used to project what a system’s storage needs would be if it were to shift entirely to renewable sources.

The model accounts for how energy production from renewable sources would change during different times of day and different times of the year. For example, there is much more solar energy generation in the summer when the days are longer, and it is sunny more often.

There is also the issue of short-term vs. long-term energy storage. Short-term energy storage does not refer to how long a storage device can store the energy. It refers to how long it can provide power at its rated level.

The study focused on Italy’s energy system, which has suffered in recent years because it had difficulties in obtaining natural gas from Russia due to the invasion of Ukraine.

As the world moves increasingly towards renewable power sources, energy systems need to be able to account for the variability of those sources. The new model offers policymakers critical information for use in energy system planning.

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Model Projects Energy Storage Needs for Fossil Fuel-Free Energy System

Photo, posted October 28, 2016, courtesy of Daxis via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Svalbard is melting

September 10, 2024 By EarthWise Leave a Comment

Svalbard is a Norwegian archipelago between mainland Norway and the North Pole. It is one of the world’s northernmost inhabited areas and is a popular attraction for tourists. Svalbard is famous for rugged, remote terrain of glaciers and frozen tundra sheltering polar bears, Svalbard reindeer, and Arctic foxes. The Northern Lights are visible during winter, and its summer features the “midnight sun”—sunlight 24 hours a day. It is the home of the Svalbard Global Seed Vault, which provides safe, free, and long-term storage of seed duplicates from all gene banks and nations around the world.

Over half of Svalbard’s land area is covered with ice and accounts for about 6% of the planet’s glaciated area outside of Greenland and Antarctica. But Svalbard is also one of the fastest-warming places on Earth.

It has suffered extreme episodes of melting this summer, brought on by exceptionally high air temperatures. In late July and early August, temperatures hovered around 7 degrees Fahrenheit above average for this part of the Arctic Circle, causing snow and ice to rapidly melt.

According to scientists, Svalbard’s ice caps broke their all-time record for daily surface melt on July 23rd, shedding nearly half a foot of water equivalent that day, a rate five times larger than normal.

On August 11th, the high temperature in Longyearbyen, Svalbard’s capital city, reached 68 degrees, the highest August temperature on record and 4 degrees above the previous monthly record. Svalbard experienced its warmest summer on record in 2023.

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Svalbard Melts

Photo, posted September 21, 2016, courtesy of Christopher Michel via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Better wood for storing carbon

August 29, 2024 By EarthWise Leave a Comment

Scientists have discovered a new type of wood that is highly efficient at storing carbon. A comprehensive survey of the microscopic structure of the wood from many species of trees revealed that there is a type of wood that is neither softwood, such as pine and conifers, or hardwood, such as oak, ash, and birch.

The scientists from Cambridge University and Jagiellonian University in Poland analyzed some of the world’s most iconic trees using electron microscopy to survey their microscopic structure.

They found that tulip trees, which are related to magnolias and can grow over 100 feet tall, have a unique type of wood. The trees, which diverged from magnolias far back to a time when atmospheric CO2 concentrations were low, grow very tall and very quickly. These features were an adaptation to those conditions and result in the ability to store larger concentrations of carbon to compensate based on their microstructure. The elementary units of wood are known as macrofibrils, and tulip trees have much larger macrofibrils than hardwoods but smaller than those of softwoods. This unusual intermediate structure makes the trees highly effective at carbon storage.

Based on the research, it may be the case that tulip trees will end up being useful for carbon capture plantations – tree plantings specifically for the purpose of mitigating the effects of climate change. Some east Asian countries are already using various tulip tree species in plantations for locking in carbon. This was based on their large size and rapid growth, but it turns out that their novel wood structure may be the most compelling reason to use them.

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Scientists discover entirely new wood type that could be highly efficient at carbon storage

Photo, posted March 3, 2021, courtesy of Thomas Quine via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

A giant solar plus storage facility

August 23, 2024 By EarthWise Leave a Comment

One of the country’s largest co-located solar and battery energy storage projects is now fully operational. The Gemini Solar+Storage project is located in Clark County, Nevada, about 30 minutes outside of Las Vegas.

The project’s 1.8 million solar panels can generate up to 690 megawatts of electricity, which is enough to supply about 10% of Nevada’s peak demand. The facility is co-located with 380 megawatts of 4-hour battery storage, which is enough to supply Nevadans with 1,400 MWh of power after sundown.

The project makes use of a unique storage configuration that allows the storage system to be charged directly from the solar panels, resulting in increased efficiency and maximizing the capture and storage of solar energy.

The project has minimized the environmental impacts to the nearly 5,000-acre site. Primergy, the project developer, took measures to leave vegetation in place, installed solar panels to follow the ground’s natural contours, and reduced the overall footprint by more than 20% through careful design. The project created 1,300 union and prevailing wage jobs and contributed $483 million to Nevada’s economy.

Solar facilities are increasingly co-located with battery storage plants. There is a huge project in Kern County California that includes 1.9 million solar panels capable of generating 875 megawatts of solar power and storing 3,287 megawatt-hours of energy. The deserts of the southwest are prime locations for such facilities.

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The house always wins: Massive Gemini solar + storage outside of Las Vegas reaches commercial operations

Photo courtesy of Quinbrook Infrastructure Partners.

Earth Wise is a production of WAMC Northeast Public Radio