"The most toxic and dangerous type of radioactive waste created by the nuclear industry"
This is waste generated by nuclear power plants called 'high-level radioactive waste' (HLW), also known as 'spent' or 'irradiated' fuel. This waste contains plutonium, uranium, strontium, and cesium; and will be radioactive for millions of years.
It is not like the waste currently stored at the Waste Isolation Pilot Project (WIPP) or any other waste site that exists today in the U.S.: it is far worse.
Two companies are proposing to build waste facilities near Carlsbad and Hobbs for the most toxic and dangerous type of radioactive waste created by the nuclear industry.
Holtec International is working with the Eddy-Lea Energy Alliance, LLC (ELEA) to apply for a license to build a Consolidated Interim Storage (CIS) facility approximately halfway between Carlsbad and Hobbs, and 16 miles north of WIPP.
The Nuclear Regulatory Commission (NRC) has declared the Holtec/ELEA application complete, NRC initiated a public comment period with 60 days for public comment. Note that transport of this waste poses risks to the environment and all life located near transportation routes.
Holtec proposal:
New CIS facility to store 100,000 metric tons of HLRW, with the potential to increase to 120,000 metric tons for 120 years
Shallow sub-surface burial system
New Mexicans and Texans are fighting the attempted licensing of these two proposed CIS facilities - Waste Control Specialists near Andrews, Texas and Eddy Lee/Holtec International east of Carlsbad, New Mexico.
These sites and any transport to these sites are not only dangerous but environmentally unjust. These sites present clear examples of environmental racism.
New Mexico's demographic is largely Latino. There are many communities of color, especially in the southern part of the state where the sites are being proposed. People of color would be disproportionately affected if the Eddy Lee/Holtec CIS site were licensed and constructed.
New Mexico and Texas do not consent to either proposed CIS facility and are fighting to avoid the environmental injustice and the unnecessary shipment of irradiated high-level nuclear waste through their communities.
Hardened On-Site Storage (HOSS) is a community-based concept that aims to protect the public from the threats posed by the current vulnerable storage of commercial irradiated fuel.
History
For decades, high level radioactive waste has accumulated at reactor sites and continues to do so as nuclear reactors generate more waste. Without a credible plan to permanently isolate it, storage pools, where irradiated nuclear waste is currently stored until it becomes less hot, have been tightly packed and re-racked to accommodate all the waste.
Unfortunately, the pools and dry casks have no robust containment. If the cooling pumps stopped operating or the water in the pools drained out, temperatures would quickly increase, as happened in Fukushima Japan, and could result in a similar disaster.
Current dry cask storage at reactor sites (pictured above) is extremely vulnerable. There is often nothing more than a chain-link fence and a short distance that separates the highly radioactive waste containers and public access.
Establishing interim hardened on-site storage (HOSS) is a top priority. Hardened on-site storage allows waste generators to store high level waste as close to the site of generation as possible, thereby exposing fewer people to radiation, as safely as possible.
Rather than storing dozens of vulnerable dry-casks next to each other in the open air, the HOSS Principles established by concerned citizens mandate:
Irradiated fuel must be stored as safely as possible as close to the site of generation as possible;
HOSS facilities must not be regarded as a permanent waste solution, and thus should not be constructed underground and the waste must be retrievable;
The facility must have real-time radiation and heat monitoring for early detection of problems with containers;
The overall objective of HOSS should be that the amount of releases projected in even severe attacks should be low enough that the storage system would be unattractive as a terrorist target;
Placement of individual canisters that makes detection difficult from outside the site boundary.
Hardened On-Site Storage (HOSS) is supported by organizations in all 50 states. The Principles of Securing Nuclear Waste at Nuclear Reactor Sites are posted here. It would provide better security at reactor sites with robust dry storage and community oversight, including real-time monitoring of heat and radiation. HOSS is rooted in values of community protection and environmental justice and will provide increased protection from human or natural disasters, like terrorist attacks and earthquakes
HOSS facilities are not permanent waste solutions, and therefore should not be constructed deep underground as the waste must be retrievable. However, they are a workable solution that will allow us to explore scientifically sound, and socially and environmentally just long-term management systems.
Nuclear Power Has No Place in a Green Energy uture
Because of: Time Delay, Success of Renewables, Huge Costs, Dangers, Weapons Connection, and Wastes
from Yahoo News, 21 Oct 21, ”…….Practical concerns also temper enthusiasm for a nuclear future. The next generation of reactors, heralded as a game changer by supporters, still haven’t been proven in the real world. Even if those technologies are as revolutionary as advertised, skeptics say it could take decades before they make a real difference in the global energy grid — too long if the worst outcomes of climate change are to be avoided.
Renewable energy technologies can be enough on their own
“The drawbacks to nuclear are compounded by the burgeoning success of renewables — both solar and wind are getting cheaper and more efficient, year after year. There is also a growing realisation that a combination of renewables, smart storage, energy efficiency and more flexible grids can now be delivered at scale and at speed — anywhere in the world.” — Jonathon Porritt, Guardian
The world doesn’t have time to wait for next-gen nuclear
“When it comes to averting the imminent effects of climate change, even the cutting edge of nuclear technology will prove to be too little, too late. Put simply, given the economic trends in existing plants and those under construction, nuclear power cannot positively impact climate change in the next ten years or more.” — Allison Macfarlane, Foreign Affairs
A major ramp-up in nuclear technologies isn’t economically feasible
“While nuclear power may have once been cheaper than wind or solar, the economics have since changed dramatically. Nuclear power plants are very expensive to build and the economics of nuclear power are getting steadily worse. By contrast, renewables continue to come down in price.” — Ian Lowe, Conversation
There’s no way to guarantee that nuclear plants will be safe
“People around the world have witnessed the Three Mile Island, Chernobyl and Fukushima accidents. It is more than enough to believe that a safe nuclear power plant is nothing but a myth.” — Jang Daul, Korea Times
More nuclear power could lead to more nuclear weapons
“Some nations — India and Pakistan, and in all probability Israel — became nuclear powers after originally seeking nuclear technology for research or to develop nuclear power. … This is important: The technology used to turn on lights or charge mobile phones shouldn’t need to involve national or international defence apparatus.” — Editorial, Nature
Nuclear waste is still a major problem
“Nuclear waste lasts for hundreds of thousands of years before they are half-decayed. Our United States government — perhaps the longest continuous government in the world — is only 232 years old. Who will be around to manage uranium wastes?” — David Ross, Courier-Journal
LANL’s Central Mission: Los Alamos Lab officials have recently claimed that LANL has moved away from primarily nuclear weapons to “national security”, but what truly remains as the Labs central mission? Here’s the answer from one of its own documents:
LANL’s “Central Mission”- Presented at: RPI Nuclear Data 2011 Symposium for Criticality Safety and Reactor Applications (PDF) 4/27/11
Click the image to view and download this large printable map of DOE sites, commercial reactors, nuclear waste dumps, nuclear transportation routes, surface waters near sites and transport routes, and underlying aquifers. This map was prepared by Deborah Reade for the Alliance for Nuclear Accountability.
Nuclear Watch Interactive Map – U.S. Nuclear Weapons Complex
Waste Lands: America’s Forgotten Nuclear Legacy
The Wall St. Journal has compiled a searchable database of contaminated sites across the US. (view)
Related WSJ report: https://www.wsj.com
Others who support the project worry about its incomplete financial support. All but one council member that day voted to continue Idaho Fall’s 5 MW commitment. But two voiced direct concern over the project not having full subscriptions. Council member Jim Francis was the sole nay vote.
“If this project works out, it’ll be great. I just wish there was a slight bit more security,” he told the Post Register in a phone interview.
A project to build a first-of-its-kind nuclear reactor in eastern Idaho has been significantly downsized.
The initial plan for the Carbon-Free Power Project was to build 12 interconnected miniature nuclear reactor modules to produce a total of 600 megawatts. It would be the first small modular reactor in the United States. After the company tasked with manufacturing the plants said it could make the reactors more power-efficient, planners reduced the project down to six module reactors that could produce 462 MW total.
“After a lot of due diligence and discussions with members, it was decided a 6-module plant producing 462 MW would be just the right size for (Utah Associated Municipal Power Systems) members and outside utilities that want to join,” said LaVarr Webb, UAMPS spokesman.
The decision was made in late June, Webb said.
The project between UAMPS and Portland-based reactor producer NuScale received $1.4 billion from the U.S. Department of Energy last year. The reactor is planned to be built on the DOE’s 890-square mile desert site west of Idaho Falls at Idaho National Laboratory. The plant is expected to be running by 2029.
“A 6-module plant allows us to get to full subscription faster, but we would have reached full subscription regardless,” Webb said of the project’s ability to achieve full financial commitment from partners. “Before joining a next-generation, first-of-a-kind nuclear plant, utilities obviously want to be certain the plant is feasible and will be built. Now that we have made significant progress, including a large cost-share award from the Department of Energy, and NuScale has received design approval from the (Nuclear Regulatory Commission), we’re seeing more and more utilities express interest in the plant.”
So far, Webb said 28 participants have committed to a total of 103 MW. But, he said, “all are currently evaluating whether to increase or decrease” their commitments. He also said “a number of utilities outside of UAMPS are considering” making a commitment.
Economics may play a stronger role than fear in steering nuclear power toward a slow decline.
“The pace of nuclear technologies’ progress could also be a factor in clean-energy strategies turning away from such power generation. Small modular reactors, along with other experimental designs, are not expected to begin commercial operations (or even testing) until the 2030s at the earliest, according to the DOE. This suggests that small reactors are unlikely to make a meaningful difference in reducing carbon emissions within the next 20 years. And at that point, they will have to compete in a future energy landscape that has been transformed even further by cheaper renewables and energy-storage technologies.”
“One imagines that solar will be more ingrained and cheaper, wind may be more ingrained and cheaper, the offshore wind will be developed, maybe batteries will be better developed, and storage will be better developed,” says Allison Macfarlane, who was chair of the NRC in 2012–2014. “That’s the market nuclear will have to compete in.”
Nuclear power faces a wobbly future 10 years after an earthquake and tsunami triggered a triple reactor meltdown at the Fukushima Daiichi plant in Japan. But the industry’s unstable footing has less to do with the Fukushima accident—and more to do with how a natural gas glut and the rise of renewable power have transformed the global energy landscape.
Fukushima has certainly left its mark on the nuclear industry. When the Tohoku earthquake and tsunami occurred on March 11, 2011, there were 54 nuclear reactors in Japan. Since then about a third of them have been permanently shut down, and only nine have resumed operation.
“In Japan, [the accident is] still an outsize event,” says Edwin Lyman, director of nuclear power safety at the Union of Concerned Scientists. “It not only had direct and indirect environmental consequences that they’re still dealing with—and a price tag of hundreds of billions of dollars to clean it up—but also it shattered the confidence of the Japanese people in nuclear power, which the authorities had always assured them was totally safe.”
Additionally, the accident spurred regulatory reviews of nuclear power worldwide and accelerated a preexisting plan in Germany to completely phase out nuclear power by the end of 2022. Other countries, including Spain, Belgium and Switzerland, are in the process of doing so within the next 14 years.
The nuclear energy industry has had a fraught year. Well…I mean, haven’t we all…But still, it’s pleasantly surprising to see such a looming giant begin to wither and fall. The nuclear power industry is failing, as evidenced not only by the alarming reports of fraud, corruption, and other fiascos that occurred at multiple nuclear facilities over the course of 2020, but also by the numbers that prove renewables are simply better for ALL of our futures – not just the nuclear business moguls our taxpayer dollars so generously continue to bail out.
Nuclear power is often promoted as one of the best ways to reduce our reliance on fossil fuels to generate the electricity we need, but new research suggests that going all-in on renewables such as wind and solar might be a better approach to seriously reducing the levels of carbon dioxide in the atmosphere.
Based on an analysis of 123 countries over a quarter of a century, the adoption of nuclear power did not achieve the significant reduction in national carbon emissions that renewables did – and in some developing nations, nuclear programmes actually pushed carbon emissions higher.
The study also finds that nuclear power and renewable power don’t mix well when they’re tried together: they tend to crowd each other out, locking in energy infrastructure that’s specific to their mode of power production.
Given nuclear isn’t exactly zero carbon, it risks setting nations on a path of relatively higher emissions than if they went straight to renewables.
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“If countries want to lower emissions as substantially, rapidly and cost-effectively as possible, they should prioritize support for renewables, rather than nuclear power.”
That’s the finding of new analysis of 123 countries over 25 years by the University of Sussex Business School and the ISM International School of Management which reveals that nuclear energy programs around the world tend not to deliver sufficient carbon emission reductions and so should not be considered an effective low carbon energy source.
Researchers found that unlike renewables, countries around the world with larger scale national nuclear attachments do not tend to show significantly lower carbon emissions—and in poorer countries nuclear programs actually tend to associate with relatively higher emissions.
“Most of the effects of the law at the heart of a $60 million Statehouse bribery scandal are set to take effect Jan. 1. The law generally creates or expands consumer-fueled subsidies for legacy nuclear and coal-fired power plants in Ohio and offsets those costs by rolling back and eliminating existing surcharges designed to create markets for renewable sources like wind and solar and reduce energy consumption overall.”
COLUMBUS — EDP Renewables North America, the world’s fourth-largest wind developer, invested more than $700 million into projects in Paulding and Hardin counties when Ohio first rolled out the red carpet.
But more recent signals from the state — including last year’s passage of the $1 billion bailout of two nuclear plants — have convinced the company to look elsewhere for its future investments.
“HB 6 created a false dichotomy — that Ohio must sacrifice a clean-energy future at the expense of its energy past,” Erin Bowser, EDP’s director of project management, on Wednesday told a House of Representatives select committee now considering repealing House Bill 6.
“But if we are truly to have a world free of the horrific threat of nuclear arms, the goal needs to be more. A world free of the other side of the nuclear coin – nuclear power –is also necessary. Radical? Yes, but consider the even more radical alternative: a world where many nations will be able to have nuclear weapons because they have nuclear technology. And the world continuing to try using carrots and sticks to try to stop nuclear proliferation — juggling on the road to nuclear catastrophe.”
Risk to the Earth from nuclear power sees the Doomsday Clock ticking ever closer to midnight, doomsday (Image via YouTube)
At the start of 2020, Bulletin of the Atomic Scientists moved its Doomsday Clock to 100 seconds to midnight — the closest to midnight, doomsday, since the clock started in 1947.
There are two gargantuan threats — the climate crisis and nuclear weapons/nuclear power.
The only realistic way to secure a future for the world without nuclear war is for the entire planet to become a nuclear-free zone — no nuclear weapons, no nuclear power. A nuclear-free Earth.
How did India get an atomic bomb in 1974? Canada supplied a reactor and the U.S. Atomic Energy Commission provided heavy water for it under the U.S. so-called “Atoms for Peace” program. From the reactor, India got the plutonium for its first nuclear weapon.
Any nation with a nuclear facility can use plutonium produced in it to construct nuclear arms.
“The nuclear industry’s position in support of spent fuel legislation is tempered by a combination of reality and priorities. While the industry regularly testifies in favor of finding a long-term solution to the spent fuel problem, the reality is that state legislative prohibitions on the construction of new nuclear reactors are meaningless, given that no new reactors are planned in the foreseeable future. It is uneconomic and/or not politically viable to build a new reactor in the United States—even one of the small modular reactors under development.”
The 92-page platform adopted at the Democratic National Convention does not include a single sentence on the issue of how to manage the more than 80,000 tons of spent nuclear fuel sitting at 70 sites in communities across the country. The Republicans adjourned without adopting any new platform for 2020, leaving their 2016 platform in place—but it also did not address the nuclear waste issue.
Ironically, political interest in addressing the spent fuel issue is decreasing at a time when the number of closed nuclear plants in the United States is increasing—and it is common practice to level the plant and leave the spent fuel behind. If the issue had been as significant a political priority today as it was in the past, it would have been included in one or both of the platforms.
In its 2004 and 2008 platforms, the Democratic Party committed to “protect Nevada and its communities from the high-level nuclear waste dump at Yucca Mountain, which has not been proven to be safe by sound science.” Republicans, in their 2012 platform, focused on how “[t]he federal government’s failure to address the storage and disposal of spent nuclear fuel has left huge bills for States and taxpayers.”
“The world nuclear industry “continues to be in stasis,” with power plants shutting down at a faster rate in western Europe and the United States, the number of operating reactor units at a 30-year low, and the few new construction projects running into “catastrophic cost overruns and schedule slippages,” according to the latest edition of the annual World Nuclear Industry Status Report (WNISR), released last week.”
U.S. Nuclear Regulatory Commission/wikimedia commons
“Some 408 nuclear reactors were in operation in 31 countries as of July 2020, a decline of nine units from mid-2019 and 30 fewer than the 2002 peak of 438,” Reuters writes, citing the report. “The slow pace of new projects coming onstream also increased the overall age of the global fleet to around 31 years.”
“Overall, in terms of the cost of power, new nuclear is clearly losing to wind and photovoltaics,” with the two renewable technologies now receiving about 10 times the investment, write Jungmin Kang, former chair of South Korea’s Nuclear Safety and Security Commission, South Korea, and Princeton University Professor Emeritus Frank von Hippel, in their foreword to the 361-page report. That meant new nuclear projects “were struggling to secure finance amid competition from renewables, with reported investment decisions for the construction of new nuclear plants at around US$31 billion in 2019,” Reuters says.
Nuclear Watch Interactive Map – U.S. Nuclear Weapons Complex
Waste Lands: America’s Forgotten Nuclear Legacy
The Wall St. Journal has compiled a searchable database of contaminated sites across the US. (view)
Related WSJ report: https://www.wsj.com
LANL’s Central Mission: Los Alamos Lab officials have recently claimed that LANL has moved away from primarily nuclear weapons to “national security”, but what truly remains as the Labs central mission? Here’s the answer from one of its own documents:
LANL’s “Central Mission”- Presented at: RPI Nuclear Data 2011 Symposium for Criticality Safety and Reactor Applications (PDF) 4/27/11
The UNT Digital Library is home to materials from UNT’s research, creative, and scholarly activities, and serves as a centralized repository for the rich collections held by UNT’s libraries, colleges, schools, and departments.
