technologies

Fake Meat And Climate | Earth Wise

March 10, 2023 By EarthWise 1 Comment

Investors have poured billions of dollars into efforts to replace animal proteins with plant-based substitutes or even laboratory-grown animal cells. Replacing meats with these products is certainly a favorable development for the climate, but it is not likely to offset livestock agriculture’s climate and land use impacts anytime soon.

According to research at Stanford University, even optimistic estimates are that only something like 5% of dietary protein will come from these technologies by 2030. That just isn’t fast enough to put a real dent in the food-related emissions problem.

Stanford environmental scientist David Lobell suggests that there should be much more focus on reducing emissions of animal-based systems. There really hasn’t been much effort in this area because it is only recently that the climate impact of animal agriculture has been a topic of public concern. One problem is that it is difficult for investors to monetize investments in approaches for lowering animal agriculture emissions. These might include alternative feeds or supplements or vaccinations that inhibit methane-producing microorganisms in animals’ digestive systems.

Another approach to the problem is changing the mix of animal proteins in people’s diets. Chicken and pork are half as bad as dairy per pound of protein, and about one-tenth as bad as beef, in terms of emissions.

Dairy is a major issue. There has been quite a lot of progress in increasing the use of dairy-free milk, but over the past 40 years, Americans have cut their consumption of milk in half but doubled their consumption of cheese. Progress in dairy-free cheese has not been anywhere near as successful as that of dairy-free milk. But new products are entering the marketplace all the time.

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Is fake meat a real solution? Stanford expert explains

Photo, posted June 17, 2019, courtesy of Christolph Scholz via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

An Iron-Air Battery Plant | Earth Wise

February 9, 2023 By EarthWise Leave a Comment

Lithium-ion batteries are the standard energy source for electric vehicles, and they are also the dominant technology for storing energy in the electric grid. However, they are not the only game in town. There are other battery technologies that have various potential advantages over lithium-ion and some of them are getting the chance to show what they can do.

One is the iron-air battery. Unlike lithium-ion batteries that require expensive and strategically challenging materials like lithium, cobalt, nickel, and graphite, iron-air batteries make use of one of the most common elements in the earth’s crust.

Iron-air batteries operate on a principle known as “reversible rusting”. When discharging, the battery takes in oxygen from the air and converts iron into rust. While charging, electrical current converts rust back into iron and the battery releases oxygen. Batteries consist of a slab of iron, a water-based electrolyte, and a membrane that feeds a controlled stream of air into the battery.

A Massachusetts-based company called Form Energy is building a $760 million iron-air battery storage facility in the city of Weirton in West Virginia. Investment financing along with a $290 million government incentive package is paying for the facility.

The facility is designed to address the need for long-duration energy storage and will be capable of storing electricity for 100 hours at competitive prices. The battery modules will be about the size of a side-by-side washer/dryer and will contain a stack of 50 3-foot-tall cells. Such batteries are too big and heavy for use in cars but will be cheaper and higher-capacity than equivalent lithium-ion battery systems.

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Form Energy selects West Virginia for its first iron-air battery plant

Photo credit: Form Energy

Earth Wise is a production of WAMC Northeast Public Radio

The Energy Storage Boom | Earth Wise

November 25, 2021 By EarthWise Leave a Comment

Global energy storage deployment is increasing at a very rapid pace. According to recent industry forecasts, there will be 12.4 gigawatts of new energy storage capacity online in 2021 breaking the previous annual record of 4.9 gigawatts set last year.

To understand these numbers, the world only reached 1 gigawatt of new capacity in a year for the first time in 2016. Five years later, 1 gigawatt represents a good month.

Industry projections are that new global storage capacity will increase each year, reaching 70 gigawatts by 2030.

Almost all of this new storage capacity is in the form of batteries and most of that is lithium-ion batteries. The largest battery storage facility in the world – the Manatee Energy Storage Center in Florida – is scheduled to be completed before the end of this year. But there are other battery technologies that offer promise and there are other storage technologies apart from batteries.

Pumped hydroelectric storage is long established technology that still represents the largest amount of storage capacity in the world with more than 181 GW of capacity. There is not much room for expansion of pumped hydro, which is limited to specific locations. But it will be years before battery storage catches up to this total.

The United States and China have a large majority of energy storage capacity and projections are that the two countries will still have nearly three-quarters of the world’s total capacity in 2030.

With the ongoing rapid expansion of wind and solar power, the need for energy storage continues to grow and is the driving force for the energy storage boom. It is not clear how it will all shake out, but energy storage is going to be a big deal from now on.

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Inside Clean Energy: Taking Stock of the Energy Storage Boom Happening Right Now

Photo, posted March 15, 2013, courtesy of Portland General Electric via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio.

Major Funding For Novel Energy Storage | Earth Wise

October 21, 2021 By EarthWise Leave a Comment

The accelerating adoption of wind and solar energy is driving a growing interest in energy storage technologies. An electric grid dominated by intermittent power sources will need large-scale energy storage. Grid-scale energy storage is expected to increase at least 10 times over the next decade and this will require nearly $300 billion in investments over that time period.

Much of the effort in energy storage has focused on battery storage. But there are other storage technologies that are attracting attention and investment.

Energy Vault is a Swiss-based company specializing in gravity and kinetic energy-based energy storage. Their technology uses a multi-headed crane to store energy generated by renewable sources by stacking heavy blocks made of composite material into a tower, capturing potential energy from the elevation gain of the blocks. To produce electricity, the crane lowers the blocks to the ground, driving generators in the process. The company has just raised $100 million in funding from investors.

Malta, Inc. is an energy storage company based in Cambridge, Massachusetts that is developing an electro-thermal energy storage system. Energy generated from renewable (or other) sources drives a heat pump to create thermal energy producing both hot and cold reservoirs. The heat is then stored in molten salt while the cold is stored in a chilled liquid. To generate electricity, the temperature difference between the two reservoirs is used to drive a heat engine. Malta has recently raised $60 million in new funding including significant support from Chevron Energy Ventures.

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Energy Vault Raises $100 Million In Series C Funding

Chevron backs long-duration thermal energy storage developer Malta

Photo, posted October 16, 2019, courtesy of Jonathan Cutrer via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio.

Small-Scale Climate Solutions | Earth Wise

May 18, 2020 By EarthWise Leave a Comment

In order to meet international climate targets, we need to cut greenhouse gas emissions in half over the next decade and reach net-zero by mid-century. Achieving this will require unprecedented and rapid changes in how energy is supplied, distributed and used.

Researchers at several European universities collected data on a wide variety of energy technologies at different scales and tested how well they performed in accomplishing an accelerated low-carbon transformation.

Large-scale, costly, non-divisible or so-called lumpy technologies, such as utility-scale generation, nuclear power, carbon capture and storage, high-speed transportation, and whole-building retrofits are often seen as the most effective way to achieve emission-reduction goals. A key finding of their study is that low-carbon technologies that are smaller scale and can be mass deployed are more likely to enable a faster transition to net-zero emissions.

So-called granular options include solar panels, electricity storage batteries, heat pumps, smart thermostats, electric bikes, and ride-share services. These options scale not by becoming larger but by replicating.

Small-scale options are quicker to deploy, their technologies have shorter lifespans and are less complex, so innovations and improvements can be brought to market more rapidly. They are also more widely accessible and help create more jobs, giving governments a sound basis for strengthening climate policies.

However, smaller-scale technologies are not a panacea. There are no small-scale replacements for industrial plants and other kinds of major infrastructure, but in many different contexts, they can outperform larger-scale alternatives as a means of accelerating the low-carbon transformation.

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Smaller scale solutions needed for rapid progress towards emissions targets

Photo, posted April 8, 2019, courtesy of the City of St Pete via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio.

An Incentive For Carbon Capture | Earth Wise

April 1, 2020 By EarthWise Leave a Comment

Convincing industries to reduce their carbon dioxide emissions has not been easy. Many approaches have been debated, including carbon taxes, carbon tax-and-trade schemes, and passing a giant Green New Deal. Most economists agree that putting a price on carbon is likely to be the most effective approach.

But there is already in place an adjustment to the US tax code that is more of a carrot than a stick. It is a tax credit that is designed to make capturing CO2 a financial winner for a number of high-emitting industries. The credit, called 45Q, was enacted in February 2018.

The 45Q credit earns industrial manufacturers $50 per metric ton of CO2 stored permanently or $35 per ton if the CO2 is put to use. An earlier credit for capturing carbon dioxide was limited to only $20 per metric ton and was capped at 75 million tons. Some large fossil fuel companies did make use of the earlier credit.

The new version does not have a cap, but to qualify, companies need to start constructing carbon-capture facilities within 7 years and have 12 years to claim their money.

Companies with emission-intensive operations are busy figuring out how to take advantage of the credit. These include cement makers, steel and power plants, corn ethanol producers, and ammonia plants.

Because the credit mandates that companies start constructing their carbon-capture facilities within seven years, most companies will tend to rely on mature technologies. But the tax credit should also drive demand for next-generation carbon-capture technologies, of which there are many under development. Saving lots of money on taxes is likely to lure US companies to capture carbon dioxide.

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45Q, the tax credit that’s luring US companies to capture CO2

Photo, posted October 2, 2014, courtesy of Sask Power via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio.

Stretchable Batteries | Earth Wise

February 28, 2020 By EarthWise Leave a Comment

Wearable technology is an ever-increasing part of our world. Fitness trackers have become commonplace for people of all ages. Smart watches perform a growing range of functions. There are wearable health monitoring systems of many types for assisted living, elderly patients, and people with specific health problems. Virtual reality headsets are increasingly popular and there is now even smart technology footwear that is integrated with smartphones and mapping software.

The adoption of wearable electronics has so far been limited by their need to derive power from relatively bulky, rigid batteries that reduce comfort and even may present safety hazards related to chemical leakage or combustion. To date, there has not been a power source that can stretch and bend the way our bodies do, which would enable electronic designs that people can comfortably wear.

Researchers at Stanford have recently announced the development of a soft and stretchable battery that relies on a special type of plastic to store power more safely than the flammable formulations used in conventional batteries today.

The lithium ion batteries in our phones, computers, cameras and electric cars already make use of plastic electrolytes. These polymer electrolytes are in the form of flowable gels. The Stanford researchers developed a new polymer that is solid and stretchable rather than gooey and potentially leaky. But it still carries an electric charge and maintains a constant power output even when squeezed, folded or stretched to nearly twice its original length.

The prototype battery is thumbnail-sized and stores only about half as much energy for its size as a conventional battery. But the researchers are working to increase both the size and the energy density of the battery.

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A new stretchable battery can power wearable electronics

Photo, posted November 28, 2016, courtesy of Timo Newton-Syms via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio.

Turning CO2 Into Rock

January 6, 2020 By EarthWise Leave a Comment

As the world continues to struggle to find ways to reduce carbon emissions, there is increasing attention being paid to so-called negative emission technologies (NET), which remove and permanently sequester carbon dioxide from the atmosphere.

The University of Victoria in British Columbia has brought together an international team of experts to explore the possibilities of permanently and safely sequestering CO2 as rock beneath the ocean floor. The Solid Carbon Project seeks to extract carbon dioxide directly from the air and then, using deep-ocean technology powered by offshore solar and wind energy, inject it into sub-seafloor basalt, where it would mineralize into solid carbonate rock.

When CO2 is injected into porous basalt, a type of volcanic rock, it reacts relatively quickly with minerals to form solid carbonate, thereby permanently removing it from the atmosphere. Because 90% of the planet’s basalt is located beneath the ocean floor, the deep ocean is the place to do this kind of carbon sequestration.

The team includes experts in ocean science, carbon mineralization, renewable energy, engineering design, and oil-and-gas drilling/injection operations. Other experts are focusing on the social and legal implications of the NET technology.

Over the next four years, the Solid Carbon Project will assess the integration of multiple existing technologies that will be needed to successfully develop this kind of carbon storage. One of these is the direct air capture technology itself, which will need to be adapted to a renewable energy-powered offshore platform. The best outcome technologies explored by the project will be selected for a real-world demonstration at Ocean Networks Canada’s observatory site, 9,000 feet underwater in the Cascadia Basin, off the coast of British Columbia.

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A rock-solid solution for CO2

Photo courtesy of the University of Victoria.

Earth Wise is a production of WAMC Northeast Public Radio.

Lots Of Renewable Energy Jobs

August 16, 2019 By EarthWise Leave a Comment

According to the International Renewable Energy Agency, there were 11 million people employed in renewable energy worldwide in 2018. This compares with 10.3 million in 2017. So roughly three-quarters of a million new jobs were added last year. As more and more countries manufacture, trade and install renewable energy technologies, renewables jobs continue to reach new high levels.

The geographic footprint of renewable energy jobs is changing. Until now, renewable energy industries have remained relatively concentrated in a handful of major markets such as China, the US, and the European Union. But more recently, East and Southeast Asian countries have emerged alongside China as key exporters of solar technology. Malaysia, Thailand, and Vietnam were responsible for a greater share of growth in renewables last year. Overall, Asia has a 60% share of renewable energy jobs worldwide.

Beyond climate goals, low-carbon economic growth has become a driver for renewables technology. Renewables deliver on all the major elements of sustainable development: environmental, economic and social.

The solar photovoltaic industry continues to be the most dynamic renewable enterprise. It accounts for a third of the renewable energy workforce with more than three million jobs.

Biofuel jobs were up by 6% to over 2 million. Wind power supports 1.2 million jobs, with onshore projects predominant. But the offshore wind segment is gaining traction. Hydropower is still the largest installed capacity of all renewables but is now only expanding slowly. The hydropower sector employs 2.1 million people directly, three-quarters in operations and maintenance.

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Renewable energy market employs 11 million in 2018 – IRENA

Photo, posted January 11, 2012, courtesy of the Oregon Department of Transportation via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio.

Energy Trends For A New Year

January 15, 2019 By EarthWise Leave a Comment

With a new year upon us, there are several energy trends to watch out for.

The most important one is that the fundamental shift toward slow-carbon technologies is continuing. This shift is taking place despite diminishing government policy support and even active government efforts to thwart it. There is just too much momentum to stand in the way of low-carbon energy technologies.

Analysts at Bloomberg New Energy Finance estimate that over the next 30 years over 11 trillion dollars will be invested in energy power generation and power storage assets with 85% of it aimed at zero-carbon emission. Dramatic reductions in green energy costs have resulted in legitimate cost competition between zero carbon sources of energy and fossil fuel generation.

In the coming year, battery technology will continue to play a growing role both as a storage medium for energy generated by sun and wind and for powering vehicles.

Another trend is that the world’s wealthiest economies are learning to grow without growing the demand for electricity. This is important in the battle to reduce overall emissions.

Another key issue is addressing the energy needs of people who have no meaningful access to it and there are around 1.5 billion people in that category. Emerging technologies based on solar power, wind energy, microgrids and other innovations mean that traditional power grids that remain out of reach to these people are not necessary. There is the potential to address those needs without contributing to climate change.

The world is struggling to deal with the growing problem of the changing climate, but there are trends that provide at least some hope that we can move in the right direction.

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Top 3 clean energy trends to watch out for in 2019

Photo, posted April 5, 2013, courtesy of Flickr.

Earth Wise is a production of WAMC Northeast Public Radio.

The Earliest Overshoot Day Ever

October 11, 2018 By EarthWise Leave a Comment

Earth Overshoot Day marks the date when humankind’s demand for ecological resources and services in a given year exceeds what our planet can regenerate in that year. The deficit for the remainder of the year means we are liquidating stocks of ecological resources and accumulating waste, primarily carbon dioxide in the atmosphere.