Oklo says engaging with Nuclear Regulatory Commission in readiness assessment.. read more..

Nuclear Philippines effort moves forward some more

The potential future of the Philippines adapting nuclear power that will generate clean and abundant energy for the needs of the people and businesses moved a few more steps forward thanks to two key meetings involving the group of President Ferdinand “Bongbong” Marcos, Jr., and notable energy firms, according to a news article by the Philippine News Agency (PNA). This is the latest in the Marcos…

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one thing i have not thoroughly expanded upon about nuclear policy is supply chain fragility.

the united states did not have enough fissile material to drop a third bomb on japan. enriching more uranium required the construction of refineries at an industrial scale, and producing plutonium required the contruction of reactors in a practically unprecedented infrastructure project (atoms for peace). sl1 was completely unclassified, nuclear car batteries and airplanes were promised and nuclear mutant gardens produced over 2200 novel cultivars. atoms for peace was a coordinated tranche of propaganda designed to convince the public that a limitless energy utopia was just around the corner if we only built out the reactors to produce the plutonium that would make the arsenal. after it was produced, all of these great visions of the future quietly withered away, and would have revealed themselves as lies all along if anybody had been paying attention.

the nuclear deterrent is expiring. we are currently engaged in subcritical testing in nevada to identify what portion of the arsenal could theoretically still function. in order to make any new warheads at scale, we would need to rebuild a number of reactors comparable to the number that has been decommissioned since the cold war.

we no longer have the manufacturing capability to undertake an infrastructure project of this scale. we can't even cobble together the funding to greenlight a single power plant. gates' nuscale just lost intermountain west, we can't even cobble together funding for six small modular research reactors. given no action, the bombs will become duds, and we will not be able to produce any more.

i would give it maybe 40 years at most, realistically more like 20 (an insufficient amount of time for an infrastructure project of this scale), before the united states loses its capability to defend itself, a "right" it never had.

which is why we're doing "atoms for peace 2" now.

it's still a lie.

the people who are going to have to ultimately end this -- in one way or another, disarmament, abandonment, or detonation -- are alive today. it's us. nobody else is coming to save us.

NuScale Power Corporation (SMR) Stock Plunges 25% Amid DeepSeek AI Concerns and Reevaluation of AI-Driven Energy Demand

Yahoo! Finance, Ghazal Ahmed, Thu, January 30, 2025  We recently published an article titled These 29 AI Electricity, Infrastructure Stocks Are Crashing Due to DeepSeek News. In this article, we are going to take a look at where NuScale Power Corporation (NYSE:SMR) stands against the other AI stocks. Investors are pulling back from the artificial intelligence trade. Previously, a report by the…

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How NuScale SMR Technology Supports Digital Transformation and AI Energy Demands

Better Energy Stock: QuantumScape vs. NuScale Power

Micro Nuclear Reactors (MNRs) Market

Micro Nuclear Reactors (MNRs) Market Size, Share, Trends: NuScale Power Leads

Rising Demand for Sustainable Solutions Drives Market Growth

Market Overview:

The global Micro Nuclear Reactors (MNRs) market is expected to develop at a 15.7% CAGR between 2024 and 2031. North America is likely to dominate the market, owing to rising investments in sophisticated nuclear technologies and favourable government regulations. Rising energy consumption, a growing emphasis on sustainable energy solutions, and increased use of MNRs in remote areas and industrial applications are among the key metrics.

The MNR market is expanding rapidly due to the growing demand for reliable, clean, and flexible power sources. Rapid urbanisation, industrialisation, and the desire for decarbonisation are boosting MNR use across a variety of sectors. The technology's capacity to supply baseload power with minimum environmental impact is gaining traction in both developed and emerging nations.

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Market Trends:

One major trend in the MNR market is the growing interest in small modular reactors (SMRs) for distributed power generation and grid stability. These tiny nuclear reactors provide various benefits, including shorter construction timeframes, lower capital costs, and enhanced safety measures. Advances in reactor design, like those by NuScale Power, are supporting this trend by improving passive safety mechanisms and increasing fuel efficiency.

Market Segmentation:

Light Water Reactors (LWRs) dominate the MNR market, accounting for the largest share in the reactor type segment due to their proven technology and operational experience. LWRs benefit from decades of study, development, and commercial operation in large-scale nuclear power plants, making them a popular choice for many MNR models.

Recent advances in LWR designs for MNRs have centred on increasing safety and efficiency. A top nuclear technology company recently announced a new LWR-based MNR design that includes passive safety features and better fuel technology, resulting in longer operational cycles and less waste generation. This concept has sparked widespread interest among potential clients in both the power generating and industrial sectors.

The power generation application segment is rapidly expanding, owing to rising demand for clean, baseload electricity in a variety of situations. According to recent figures, MNRs might offer up to 20% of the electricity required by isolated communities and industrial sites by 2040.

Market Key Players:

NuScale Power

Westinghouse Electric Company

Rolls-Royce

X-energy

TerraPower

General Electric Hitachi Nuclear Energy

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The US is preparing a transportable nuclear reactor for military operations. It will be the country’s first 4th generation reactor

The U.S. Department of Defense (DoD) has a plan. It intends to build a fourth-generation transportable nuclear reactor that can be used in its military campaigns. The ‘Project Pele’ is already underway and aims to design, build, and test a prototype within no more than five years. However, as expected, the DoD has help to bring it to fruition. In fact, the construction of the reactor is already underway at the Idaho National Laboratory.

The final assembly will begin in February 2026, likely when all the components for this machine will be completed. The development of the reactor is being handled by BWXT Advanced Technologies, a U.S. company specializing in nuclear energy. Although the reactor’s construction is already in progress, as mentioned, the final assembly will start in February 2026. In all likelihood, that will be the date when all the components involved in this machine are finished. An important note: other fourth-generation nuclear reactors are being developed in the U.S., such as the NuScale Small Modular Reactor (SMR), but the first to go operational is likely to be the one from ‘Project Pele’.

One of the requirements imposed by the DoD is that this reactor must be easily transportable. In fact, it wouldn’t make sense if it wasn’t, given that its purpose is to be used in military operations. Interestingly, when it’s ready, the prototype will be transported inside four containers to the Idaho National Laboratory, where it will be tested. From that point on, it will remain operational in a testing phase for at least three years to ensure it works correctly and safely.

Fourth-generation reactors shape the immediate future of nuclear energy

The physicists and engineers involved in the development of fourth-generation fission nuclear reactors are working to propose new designs that can be conceptually very different from previous generations. However, the requirements these new nuclear plants must meet are clearly defined. The first is to achieve maximum sustainability, so the fuel is used to its full potential to produce energy, minimizing the amount of radioactive waste generated and ensuring its management is as efficient as possible.

Artificial intelligence has arrived at nuclear power plants, and it’s going to change them forever

Safety and reliability must be high enough to minimize the probability of reactor core damage.

The second requirement concerns the economic investment needed to launch and maintain the nuclear power plant, which should be as low as possible so that it is comparable to the costs of other energy sources, thus reducing the financial risk. The third and final requirement is that safety and reliability must be high enough to minimize the likelihood of damage to the reactor core. Moreover, if an accident occurs, no emergency measures should be needed outside the nuclear plant’s premises.

As we’ve just seen, the demands introduced by Generation IV nuclear plants are ambitious because they aim to eliminate many of the shortcomings that have plagued previous designs. In this scenario, China is a step ahead. In fact, in January of this year, the first fourth-generation reactor in the world entered commercial operation.

It is a small modular reactor of strictly Chinese origin known as HTR-PM (High-Temperature Reactor-Pebble bed Modules). This device is characterized by using helium as a coolant and graphite as a moderator and is installed at the Shidao Bay-1 nuclear plant located in Shandong Province, China.

Microreactors Market: Innovations Transforming Chemical Processing

 Introduction to Microreactors market

The microreactors market is gaining significant traction due to their efficiency in handling chemical reactions on a microscale, leading to faster reaction times, improved yields, and better safety. These compact systems enable continuous flow chemistry, enhancing scalability and cost-efficiency. Industries such as pharmaceuticals, chemicals, and energy are increasingly adopting microreactors to streamline production. The global demand is fueled by the need for sustainable manufacturing processes and advancements in microfluidics and nanotechnology. However, market growth faces challenges like high R&D costs and technological integration barriers.

The Microreactors Market is Valued USD 0.34 billion in 2024  and projected to reach USD 1.6 billion by 2032, growing at a CAGR of 19.00% During the Forecast period of 2024-2032. These compact, highly efficient reactors enable faster, safer, and more controllable chemical reactions compared to conventional reactors. Growing demand across industries such as pharmaceuticals, petrochemicals, and fine chemicals, coupled with rising interest in sustainable and continuous manufacturing, drives the expansion of the market. Continuous flow systems, portability, and enhanced scalability make microreactors an attractive solution in high-tech sectors.

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Major Classifications are as follows:

By Types

Pressurized Water Reactors (PWRs)

Boiling Water Reactors (BWRs)

High-Temperature Gas[1]Cooled Reactors (HTGRs)

Molten Salt Reactors (MSRs)

Fast Neutron Reactors (FNRs)

Other

By Fuel Types

Low-Enriched Uranium (LEU)

High-Assay Low Enriched Uranium (HALEU)

Thorium

Other

By Application

Remote Power Generation

Industrial Process Heat

Space Exploration

District Heating

Others

By End Users

Government and Military

Utilities and Energy Companies

Industrial and Manufacturing

Space Agencies

Key Region/Countries are Classified as Follows:

◘ North America (United States, Canada,) ◘ Latin America (Brazil, Mexico, Argentina,) ◘ Asia-Pacific (China, Japan, Korea, India, and Southeast Asia) ◘ Europe (UK,Germany,France,Italy,Spain,Russia,) ◘ The Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria, and South

Key Players of Microreactors market

Elysium Industries, X-energy, TerraPower, HolosGen, Ultra Safe Nuclear Corporation (USNC), Nuscale Power, INL - Idaho National Laboratory, Moltex Energy, Westinghouse Electric Company, Canadian Nuclear Laboratories (CNL), Starfire Energy, Seaborg Technologies, ThorCon Power, LeadCold, Kairos Power and Others.

Market Drivers in the Microreactors Market:

Efficiency in Chemical Processes: Microreactors offer superior control over reaction conditions, enhancing yield and minimizing waste.

Sustainability: The reduction in energy and resource usage makes them ideal for companies focused on green chemistry.

Pharmaceutical Growth: Increased demand for precision in pharmaceutical synthesis drives the need for advanced microreactor systems.

Market Challenges in the Microreactors Market:

High Initial Costs: The development and integration of microreactor systems can be costly for small- and medium-sized enterprises.

Limited Awareness: Many industries are unfamiliar with the benefits of microreactor technology, limiting widespread adoption.

Regulatory Issues: Complex regulatory environments in different regions can slow down market penetration.

Market Opportunities of Microreactors Market:

Pharmaceutical Industry: The growing demand for personalized medicine and batch production presents significant opportunities.

Sustainable Manufacturing: Companies looking to reduce their environmental footprint can benefit from the efficiency of microreactors.

Renewable Energy: Microreactors offer potential in biofuel and renewable energy production, contributing to the global shift towards clean energy.

Conclusion:

The microreactors market is poised for significant growth as industries seek to optimize chemical processes through efficiency, scalability, and sustainability. While there are challenges related to cost, integration, and scalability, the opportunities offered by microreactors in enhancing precision and reducing environmental impact are vast. As technology continues to evolve, the microreactors market will play a crucial role in transforming industries like pharmaceuticals, petrochemicals, and beyond, pushing them toward greener and more efficient production methods.

Antonio Velardo shares: Nuclear Energy Project in Idaho Is Canceled by Ivan Penn and Brad Plumer

By Ivan Penn and Brad Plumer Technical challenges, higher costs and rising interest rates hurt the project that NuScale Power and Western utilities had developed. Published: November 8, 2023 at 06:14PM from NYT Business https://ift.tt/egs45Ov via IFTTT

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Nuclear Stocks Were Super Hot Just A Month Ago. What’s Changed?

 Oil Price, By Alex Kimani – Dec 10, 2024 However, nuclear energy stocks have lately lost momentum, mostly because the sector was seriously overheating. NuScale Power Corp. has lost more than 30% of its share price in the current month. Over the past couple of years, the nuclear energy sector has enjoyed a renaissance in the U.S. and many Western countries thanks to the global energy crisis…

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Global Commitments Bolster Romanian NuScale Nuclear Project

A venture to deploy the primary NuScale 462-MWe VOYGR-6 nuclear energy plant in Romania by 2029 has garnered a $275 million public-private funding dedication from the U.S., Japan, South Korea, and the United Arab Emirates (UAE) as a part of a worldwide infrastructure partnership. 1,178 more words Global Commitments Bolster Romanian NuScale Nuclear Project — Energy News 247- Reliable energy,…

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Small Modular Reactor (SMR) Market is Set to Exhibit 9.5% CAGR Between 2023-2030

Up from revenue of US$4.4 Bn registered in the year 2022, the global small modular reactor market is expected to reach nearly US$9 Bn by the end of 2030. The projections offered by a new study of Fairfield Market Research also suggest that the market is discovering opportunities on the back of the highly cost-intensive nature of conventional nuclear industry. An expediting shift to green energy further complements the pace of market expansion.

 Cost Benefit Against Conventional Nuclear Industry Creates Tailwinds for Market

The market will largely gain from a growing need to have some more efficient and safer system alternatives that would offer benefits in the form of affordably priced energy security. The growing decommissioning requirements in addition to the clear benefits of SMR technology in the form of performance and costs are collectively driving the growth of the global small modular reactor market landscape.

 For More Industry Insights Read: https://www.fairfieldmarketresearch.com/report/small-modular-reactor-smr-market

 PWR Category Dominates Other Small Modular Reactor Types

By type of reactors, the pressurized water reactor (PWR) category continues to lead the global small modular reactor market. The segment currently accounts for nearly 66.7% share of the overall market valuation and will most likely surge ahead of the other segments covered in the report analysis, viz., pressurized heavy water reactor (PHWR), and others. Widespread availability of PWRs when compared to the others, and their competitive price point are poised to collectively uphold the dominance of this segment in the small modular reactor market landscape throughout the period of assessment.

 End Users Seek Greater Safety, and Operational Stability

In addition to the higher operational stability, PWRs are associated with a greater safety quotient that strongly supports the market lead of PWRs in the small modular reactor market. ability. Preference for pressurized water reactors among end users is expected to remain high in the long term, suggests the research presented in the report.

 Asia Pacific Leads the Pack in SMR Space

Based on the regional analysis of the small modular reactor market, Asia Pacific is the leader region with more than 80% share of the overall revenue generation. The market here will continue to reign supreme on account of the maximum installed base capacity, indicates report. China, and India will remain the most lucrative Asian markets as shows in the report.

 Europe, and North America Turn Lucrative

Besides, Russia also is one of the global SMR hotspots, upholding attractive prospects of the European small modular reactor market. On the other hand, the US maintains the lead when it comes to R&D around the SMR technology. Canada will remain an equally important pocket on the back of its Small Modular Reactor Action Plan.

 Leaders in SMR Industry

GE, Mitsubishi Heavy Industries, Ltd., China National Nuclear Corporation, General Atomics, Rolls Royce, Nuclear Power Corporation of India Limited (NPCIL), Bechtel Corporation, Korea Electric Power Corporation, Holtec International, NuScale Power, LLC., BWX Technologies Inc.

 Get Sample Copy of Report at https://www.fairfieldmarketresearch.com/report/small-modular-reactor-smr-market/request-sample

 About Us

Fairfield Market Research is a UK-based market research provider. Fairfield offers a wide spectrum of services, ranging from customized reports to consulting solutions. With a strong European footprint, Fairfield operates globally and helps businesses navigate through business cycles, with quick responses and multi-pronged approaches. The company values an eye for insightful take on global matters, ably backed by a team of exceptionally experienced researchers. With a strong repository of syndicated market research reports that are continuously published & updated to ensure the ever-changing needs of customers are met with absolute promptness.

NextEra Energy CEO Says NuScale Energy's Business Model Isn't Worthwhile

NuScale’s small nuclear reactor is first to get US safety approval

One hope buoying nuclear energy advocates has been the promise of “small modular reactor” designs. By dividing a nuclear facility into an array of smaller reactors, they can largely be manufactured in a factory and then dropped into place, saving us from having to build a complex, possibly one-of-a-kind behemoth on site. That could be a big deal for nuclear’s persistent financial problems, while also enabling some design features that further improve safety.

On Friday, the first small modular reactor received a design certification from the US Nuclear Regulatory Commission, meaning that it meets safety requirements and could be chosen by future projects seeking licensing and approval.

The design comes from NuScale, a company birthed from research at Oregon State University that has received some substantial Department of Energy funding. It’s a 76-foot-tall, 15-foot-wide steel cylinder (23 meters by 5 meters) capable of producing 50 megawatts of electricity. (The company also has a 60-megawatt iteration teed up.) They envision a plant employing up to 12 of these reactors in a large pool like those used in current nuclear plants.

Huge (pun intended)! Making a standard design constructed off-site will lead to huge cost benefits for licensing, construction, operation, and maintenance of future nuclear plants.

NuScale has more details on their website but the goal is that power plant facilities house 12 self-contained reactors that can provide "154 MWe to a mission critical facility micro-grid for 12 years without new fuel following a catastrophic loss of offsite grid and transportation infrastructure."

They estimate the cost of production for the n-th plant to be in the range "approximately $40/MWh to $65/MWh" and their first project has a contractual cap on costs at $58/MWh, all of which is price-competitive with large, established reactors like Diablo Canyon, though their small plant footprint generates a tenth of the electricity output.

They also support air-cooled designs, "which can reduce plant water consumption to as little as 1.1 gal/MWh" and the "high-temperature heat can be directly used to produce hydrogen through electrolysis, thus reducing efficiency losses". "Hydrogen produced by a NuScale HTSE system is forecasted to be cost competitive with high capacity factor renewable hydrogen cost estimates while also providing continuous, controlled hydrogen production."

Used fuel will be stored on-site:

NuScale reactor building and VOYGR plant design incorporates a proven safe, secure and effective used fuel management system. A stainless steel lined concrete pool holds used fuel for at least 5 years under 60 feet of water. The used fuel is protected both by the ground and the Seismic Category 1 reinforced concrete reactor building designed to withstand an aircraft impact, and a variety of natural and man-made phenomena.

After cooling in the spent fuel pool, spent fuel is placed into certified casks, steel containers with concrete shells, on site of the plant. The NRC Waste Confidence Rule states that this is a safe and acceptable way to store used fuel for an interim period at the plant up to 100 years. The NuScale's standard facility design includes an area for the dry storage of all of the spent fuel for the 60-year life of the VOYGR plant.

The plant also supports recycled fuel, or mixed uranium-plutonium oxide (MOX) fuel, helping to reduce nuclear waste.