As the energy transition accelerates, global demand for REEs is set to surge, raising major concerns around supply chain stability and geopolitical risks.
Magnet REEs Demand Set to Triple as EVs and Wind Power Take Off
A McKinsey report reveals that global demand for magnetic rare earth elements is projected to triple—from 59 kilotons in 2022 to 176 kilotons by 2035. This sharp rise is driven by booming electric vehicle adoption and the rapid expansion of wind power projects.
Neodymium (Nd) and praseodymium (Pr) form the core of REE magnets, while dysprosium (Dy) and terbium (Tb) are added to enhance performance in extreme conditions. Although magnetic REEs make up only 30% of REE volume, they account for over 80% of market value.
The demand surge is outpacing efforts to substitute REEs with copper coil magnets. Without sufficient supply, the world could face a 60-kiloton shortage by 2035—roughly 30% of projected demand.
The energy transition will likely lead to a surge in demand for magnetic
rare earth elements, with market balance tied to mining quotas in China

China’s REE Dominance: A Double-Edged Sword
China currently controls over 60% of global REE mining and more than 80% of refining. This dominance in the REE supply chain poses a major challenge for other countries. Light REE mining and refining are expected to remain concentrated in China through 2035 unless other regions ramp up production significantly.
Heavy REEs, critical for wind turbines, EVs, and robotics, are mostly mined in the Asia-Pacific region but still primarily processed in China. As a result, countries worldwide are scrambling to develop local REE supply chains. But even with rising investments, most current pipelines are unlikely to meet near-term demand.
Trade Tensions Trigger Rare Earth Supply Shocks
In April 2025, Beijing imposed export restrictions on several rare earth products in response to U.S. tariffs and tech restrictions. This caused rare earth magnet exports to the U.S. to plummet, disrupting global supply chains and forcing automakers outside China to partially suspend production.
However, following new trade agreements in June, shipments rebounded sharply. Reuters reported that China’s exports of rare earth magnets to the U.S. jumped 660% month-over-month in June to 353 metric tons. Yet, global export levels remained 38% lower compared to the same month in 2024, showing the lingering effects of supply disruption.

America’s Untapped Rare Earth Potential Could Shift Global Dynamics
The U.S. Geological Survey (USGS) estimates that the United States has 3.6 million tons of measured and indicated rare earth resources. They are primarily in California, Alaska, Wyoming, and Texas. Canada boasts an even larger potential, with more than 14 million tons of identified REE resources, spread across Ontario, Quebec, and the Northwest Territories.
The only active rare earth mine in the U.S. is located at Mountain Pass, California, operated by MP Materials. In 2024, it produced approximately 45,000 tons of REO (rare earth oxide) concentrate, valued at $260 million. However, the ore is still mostly shipped to China for final processing, highlighting a critical gap in domestic refining capacity.
In southeastern U.S. states like Georgia and North Carolina, monazite—a phosphate mineral rich in rare earths—is being recovered as a byproduct from heavy mineral sands. Companies like Energy Fuels and Ucore Rare Metals are exploring new separation facilities and pilot-scale processing plants to close the refining gap and build end-to-end domestic REE supply chains.
Meanwhile, Canada has over 20 advanced rare earth projects in development, with several aiming to become commercial by the late 2020s. Notably, Vital Metals began small-scale production at its Nechalacho project in the Northwest Territories in 2021. Also Appia Rare Earths & Uranium Corp. is advancing its Alces Lake project in Saskatchewan.
Together, these efforts mark a strategic push by North America to reduce dependency on China. However, challenges remain, including long permitting timelines, environmental review hurdles, and the high cost of separating and refining REEs domestically.
World Mine Production and Reserves

Rare Earth Market Forecast: Strong Growth, High Volatility
According to Mordor Intelligence, the global rare earth metals market is expected to grow from 196.63 kilotons in 2025 to 260.36 kilotons by 2030, at a 5.8% CAGR. The magnet application segment will lead this growth with a forecasted CAGR of 8.02%, thanks to the rising demand for NdFeB magnets in EV motors and wind turbines.

Despite the promising outlook, market volatility is expected to persist through 2025. As manufacturers adapt, many are redesigning products to minimize REE use where possible, while governments are providing financial support. Since 2020, the U.S. Department of Defense has committed over $439 million to strengthen domestic REE supply chains.
Securing the Future: Time to Diversify the REE Supply Chain
The race is on to reduce global reliance on China for rare earths. Countries must invest in domestic mining, develop recycling infrastructure, and support technological innovation to ensure a steady, sustainable supply of REEs. Regulatory reforms and international collaboration will be key to overcoming bottlenecks.
Recycling Rare Earths
Given long mine development timelines and environmental concerns, recycling offers a fast-track solution to strengthen REE supply chains. By recovering REEs from used electronics, industrial equipment, and EV motors, countries can reduce import dependence and close supply gaps.
While large-scale recycling systems are still developing, they represent a sustainable and cost-effective way to boost local supply, especially for high-value magnets.
As the energy transition speeds up, rare earth elements are essential. In the future, ensuring resilient supply chains will be critical to advancing clean energy, digital technology, and national security.
The post Rare Earth Demand to Triple by 2035: Can the U.S. Catch Up with China? appeared first on Carbon Credits.
Carbon Footprint
McKibben opts for a small-tent climate movement
A few months ago I went to a climate change forum at the Center for Brooklyn History. The panel I attended, “Confronting Climate Change: Understanding Deniers,” featured the prominent climate activist, Bill McKibben.
Bill McKibben. Courtesy https://billmckibben.com/.
I was curious to hear McKibben’s take on climate change deniers. I don’t regard the true deniers as a big problem – they’re only 11-15% of our country, according to most polls. Rather, I wondered if McKibben would label as “climate deniers” people who agree that climate change is a significant problem but disagree with his framing and his proposed solutions. I have worked for decades on energy and climate matters as an energy lawyer. Now, more than ever, I believe that to address climate change we need to build a big tent.
In the Q&A I tested where McKibben is on this by asking if he would label as a climate denier someone who subscribes to the main tenets of climate change science yet holds that natural gas has a role to play as a bridge fuel. (Our exchange starts at 1:12:45 of the video.)
This could have been a chance for McKibben to make clear that such a view isn’t climate denialism, even if he feels it’s misguided. But he punted, saying “I don’t care whether they’re deniers or not.” For good measure, he threw in his long-standing refrain that swapping coal for natural gas makes climate change worse, despite coal’s far higher carbon content per unit of energy.
674-MW methane-powered generating station, Salem, MA.
As you can hear in the recording, McKibben’s claim that gas is worse than coal draws on the work of Cornell scientist Robert Howarth. Yet McKibben didn’t mention that Howarth’s work is controversial and disputed by many scientists. The crux of the dispute is whether methane’s impact on warming should be measured with a 20-year or 100-year time frame.
Methane is a relatively short-lived greenhouse gas, with a lifetime of around 10 years, versus the 100-year life applicable to carbon dioxide. But each ton of methane is far more potent while in the atmosphere, trapping roughly 100 times as much heat as a ton of CO2. These cross-cutting facts about atmospheric methane — shorter life but greater potency than CO2 — have resulted in two opposing camps: one insisting on a 20-year timeframe for greenhouse gas accounting, the other adhering to the established 100-year frame. This matters because with a 20-year timeframe, generating electricity with natural gas (which, chemically speaking, is essentially all methane) is more damaging to climate than coal-fired electricity.
McKibben blew past this dispute. To hear him at the Center for Brooklyn History, one would have no inkling that there’s an active disagreement over which timeframe to use, that there are staunch climate activists who favor the 100-year time frame, and that the Intergovernmental Panel on Climate Change (IPCC) generally uses the 100-year timeframe.
McKibben’s latest (2025) book. Published by W.W. Norton & Company.
McKibben also insisted that a discussion about natural gas’s potential role in mitigating climate change as a replacement for coal is irrelevant because solar “is now our cheapest resource.” McKibben’s claim, of course, suffuses “Here Comes the Sun,” his 2025 book that extols solar power as the cheapest solution for all of our energy needs. But this too is questionable, because it’s based on cost comparisons between solar farms and natural gas power plants (or nuclear power plants) that fail to consider that electricity supply and delivery is a complex system of wires and plants rather than individual power plants. Based on his remarks, McKibben is choosing to ignore studies such as the comprehensive 2025 report from the Clean Air Task Force that concluded that plant-level cost comparison “is a good metric to track historical technology cost evolution [but] is not an appropriate tool to use in the context of long-term planning and policymaking for deep decarbonization.” And the task force is not alone in finding that when electricity is treated as a system, solar loses its place as the cheapest low-carbon resource.
The dogmatism McKibben displayed at the Brooklyn meeting was unfortunate. We’re in a time when efforts to combat climate change are in retreat. A unified front is required to turn the tide. Instead of doubling down on absolutist positions, activists like McKibben who seem convinced that the solution to climate change is all-renewables, end of discussion, should be seeking common ground with others who want climate action but believe that nuclear power and natural gas must also play a role.
NYC Climate March, Sept 17, 2023. Photo: C. Komanoff.
Climate change activists need to build a bigger tent, rather than call anyone who disagrees with their positions a climate change denier. It is striking that McKibben stuck to his guns after saying in the same talk that the most important goal for everyone right now is to help climate change realists win more House and Senate seats in this year’s midterms. As some have noted, an absolutist position on natural gas appears less likely to achieve that win and politicians are following that advice.
Will McKibben evolve? He has demonstrated that he knows how to build a national climate movement centered around issues like divestment. Given the current political situation, he should focus on building an even bigger tent by welcoming all of the 85% who believe that we need to address climate change but do not agree with his ideological positions.
Rich Miller is an energy lawyer who has worked for a variety of stakeholders and now gives walking tours in lower Manhattan on the history of electricity.
Carbon Footprint
Rebranding ‘Balcony Solar’ as ‘Guerrilla Solar’ won’t lift its climate value.
Image generated with Claude. Why have we juxtaposed a bicycle with balcony solar? Read on.
First it was Plug-In Solar. Then it was Balcony Solar. Now it’s Guerrilla Solar, at least according to Inside Climate News, which yesterday proclaimed that The ‘Guerrilla Solar’ Era Has Arrived.
“It,” of course, is Modular solar panels. They’re the hot new photovoltaic solution: cheap enough to buy at Home Depot, easy to hang or prop to catch maximum rays, and small enough to fit on a balcony (if you’ve got one) and plug into your “home grid.” But, alas, too meager a generator of electricity to be more than a bit player in decarbonizing most U.S. homes.
How do I know? I’ve done the math.
A standard, lower-end 220-watt balcony solar array will produce 337 kilowatt-hours a year, or 28 kWh a month averaged over the course of a year. That’s for a 220W unit measuring 3.5 feet by 3.5 feet. (220W x 1/1000 x 17.5% x 8760 hours per year = 337 kWh. Calculation assumes a 17.5% full-year capacity factor, which is arguably generous for New York, where I live. )
Our balcony solar mashup. Top: an install in Germany. Bottom: Home Depot advert.
A typical U.S. home consumes 10,500 kWh a year, or 28 to 29 kWh per day, says Solartech, drawing on U.S. Energy Information Administration data. That puts a home’s daily power needs on par with a balcony solar unit’s monthly output. In effect, once each month the balcony array gifts a homeowner or renter a bit more than day’s full complement of electricity. And earth’s atmosphere gets the same respite: a 3 percent reduction in carbon emissions caused by the home’s electricity usage.
(The 3 percent figure could also be calculated directly by dividing 337 kWh per year of solar production by 10,500 kWh per year to run the home. For bigger or smaller arrays, just prorate your assumed wattage by my 220W; for 440W, say, double my figures.)
Balcony Solar metrics
Why write about balcony solar if it’s so inconsequential? CTC’s mission includes puncturing would-be climate balloons before they ascend too far. In the same vein, we practice quantification to make clear what does and doesn’t move the climate needle. (More on that further below.)
The best way to depict balcony solar’s climate value is to express it in terms of tangible metrics. We’ve selected two. Both assume the basic, lower-end PV array I assumed at the top: a 3.5 foot-square array whose peak output is 220 watts.
1. It would take 50 million 220W balcony solar units (bsu’s) to restore the climate benefit we destroyed in 2020-2021 when we shut the high-performing Indian Point nuclear power plant 32 miles from Midtown Manhattan.
2. A single person cutting back their driving by a mile a day would provide the same climate benefit over the course of a year as a single 220W bsu.
(Calculations in sidebar. Now you know why we led with images of an urban dweller as cyclist and balcony solar user.)
Yes, it’s dense — as befits a sidebar. The numbers tell a story. Follow the color co-ordination.
Ponder that: It would take fifty million smallish bsu’s to level up to the fossil fuel carbon emissions that Indian Point was keeping at bay by supplying the New York City area year in and year out with abundant carbon-free power. Deploying that many balcony solar units would entail 10 bsu’s for each of the 5 million households in the MTA’s service territory. (The Metropolitan Transportation Authority provides subway, bus and commuter rail transit in the five boroughs and seven suburban counties.) Or, if those same households upgraded to 1100-watt bsu’s, collectively they would still make up only half of the lost Indian Point power.
The second comparison, involving driving, is perhaps trickier to grasp but more interesting, since it relates to people’s behavior. Living differently isn’t part of public discourse, at least not in the USA, and especially when what’s being served up is using less. But “reducing,” as we might call it (remember “Reduce, Reuse, Recycle”? or, “Insulate, then Insolate”?) is just as potent for cutting emissions as switching to renewables — even more so when the reducing means driving less, considering the multitude of benefits that accrue from diminishing cars’ imprints on our communities. Still, staying on topic: driving just one fewer mile per day brings about the same shrinkage in carbon emissions as deploying one 220W solar array.
What Balcony Solar boosters are really saying
To be fair, our friends at Inside Climate News and, yes, The New York Times appear to be trying to modulate their balcony solar enthusiasm.
ICN‘s Dan Gearino, whom we cited up front, said he looked to Germany, the birthplace of balcony solar, to see if the units made sense for U.S. households. His takeaway: “It may make more sense financially to spend the cost of plug-in solar on insulation, air sealing or other basic measures to reduce energy use.” Hooray: insulate before you insolate.
Gearino helpfully interviewed renewables guru (and U.S. emigré) Craig Morris, who currently heads Germany’s plug-in solar trade association, Bundesverband Steckersolar. To Morris, balcony solar’s main advantages are that it provides power without taking up land, and that it affords people a way to “become participants in the transition to clean energy.” Behold, guerrilla solar. That, in turn, bolsters “the political consensus that supports the transition.” But Morris also made clear that widespread adoption of plug-in solar would only meet “about 2 percent of Germany’s electricity demand.”
Morris’s “about 2 percent” feels right for Germany. But not for the U.S., where widespread adoption of virtually any individual carbon alternative seems forever out of reach, and where the energy pie is so much larger — think giant fridges, freezers for beer, steroidal homes bursting with piles of powered toys, not to mention industrial and institutional electricity use that Morris correctly excluded from his figure.
Don’t forget to micro-dose. NYT headline + image for David Wallace-Wells’ guest essay (see text). Image by Rui Pu.
Both Gearino and Morris seem more measured than climate journalist Robinson Meyer, founding editor of Heatmap and frequent contributor to The Times, where he wrote about balcony solar in mid-June.
“New zero-carbon power kits will allow Americans to make their own energy choices,” declares the callout to the print version of Meyer’s NYT guest essay, The Tiny Solar Panel That Could Change America. (The even more expansive print headline invites us to “Forget Roofs. Backyard Solar Is the Next Frontier.”)
Wallace-Wells is of two minds. He calls balcony solar “a small way that apartment- and condo-dwelling Americans can take ownership of their energy choices and cut down their pollution on the margins.” No quarrel there, thanks to his qualifiers “small” and “on the margins.” Earlier, though, he opines that balcony solar units “have the potential to change how Americans understand and consume energy,” But read further and you’ll again see Wallace-Wells cautioning that “Balcony solar will play one small role in [the] drama” of transiting to the new world of clean, abundant energy.
Any such caveats are welcome these days, amid widespread solar hoopla. Still, it doesn’t seem to be in Wallace-Wells’ toolkit — or that of Inside Climate News and other mainstream climate journalists — to tutor their audiences as to the true limits of balcony solar and other panaceas. Just like it wasn’t in their field of vision a decade ago to lay out the true stakes of shutting Indian Point as Riverkeeper was singing its siren song.
What’s Next for NY Balcony Solar
Meantime, as Canary Media reported recently (and helpfully), New Yorkers concerned with climate and affordability are waiting for NY Gov. Kathy Hochul to sign the recently passed SUNNY (Solar Up Now New York) Act legalizing balcony and other plug-in solar. It would be head-spinning (and politically suicidal) if she didn’t, given near-universal support ranging from Con Edison to DSA Assembly Member Emily Gallagher, who told Canary Media, “This is the most popular bill I’ve [ever] worked on.”
My guess is that Hochul is waiting for the right moment, and perhaps the right “package,” that can advance and not undercut her push to launch five large new nuclear power plants around the state — one to be built by the public New York Power Authority, the others to be constructed and operated privately. A little bit of math, a la what we offered here a la Indian Point, might help her out.
The governor also must manage the veritable hot potato of her deferred implementation of the landmark 2019 Community Leadership and Climate Protection Act. She might do well to consider jettisoning the act’s unwieldy cap-and-invest centerpiece in favor of a straight-up carbon tax (with the revenues distributed pro rata to the state’s households) in its place. That, far more than balcony (or guerrilla) solar, could blow open the door to the “innovations and technologies we cannot yet imagine” that Wallace-Wells fantasized about in his Times essay.
Carbon Footprint
The new SBTi Corporate Net-Zero Standard: what it means for business
On 11 June 2026, the Science Based Targets initiative (SBTi) published the most substantial revision of its flagship corporate framework since its introduction. The SBTi Corporate Net-Zero Standard Version 2.0 takes effect on 1 February 2027 and reshapes the way companies approach their net-zero targets.
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