Clean Planet's Quantum Hydrogen is Building a New Energy Future in Japan Through LENR
Exploring the safe, high-density energy breakthrough poised to transform industrial heating and accelerate global decarbonization.
The world faces escalating challenges driven by climate change and the finite nature of fossil fuels. This pressing global imperative has intensified the quest for clean, sustainable, and abundant energy solutions, setting the stage for the urgent exploration of novel energy technologies. Among the most intriguing, yet historically controversial, contenders in this pursuit are Low Energy Nuclear Reactions (LENR), often historically referred to as "cold fusion." This report delves into the fascinating world of LENR, examining its origins, current state of research and development, and the promising role of companies like Clean Planet in shaping its future. Recent advancements are shifting LENR from the fringes of scientific inquiry to the precipice of commercial viability, signaling a potential paradigm shift in global energy production.
The Underlying Science of Electroweak Interactions and Condensed Matter Physics
The prevailing understanding suggests that LENR involves neutron-based electroweak interactions, distinguishing it from the strong-force interactions that govern fission and hot fusion. Electroweak interaction is a unified description of electromagnetism and the weak interaction, which merge at extremely high temperatures but are also theorized to play a role in specific condensed matter environments.
A significant historical barrier to the broader acceptance of LENR was the absence of a coherent, widely accepted theoretical framework to explain how nuclear reactions could occur at low energies without the expected high-energy byproducts. However, the explicit focus on "neutron-based electroweak interactions" and the intensive research into "condensed matter" and "nanomaterials engineering" indicate a notable evolution in the field. This shift moves beyond vague "cold fusion" claims to a more specific, physics-based hypothesis. This developing theoretical understanding provides a much-needed scientific anchor, making LENR research more amenable to mainstream scientific scrutiny. This scientific anchoring is pivotal for accelerating its validation and potential commercialization, transforming the discussion from merely observing unexplained phenomena to developing a deeper understanding of the underlying physical mechanisms.
Current research is intensely focused on nanomaterials engineering, recognizing the critical role of condensed matter in optimizing reaction conditions and enhancing energy output. The unique properties of nanomaterials, such as increased surface area and quantum effects, are believed to facilitate hydrogen penetration and interaction, which are crucial for observing LENR phenomena.
Clean Planet is Pioneering Quantum Hydrogen Energy (QHe)
A Post-Fukushima Imperative
Clean Planet, a Japanese company, stands at the forefront of LENR commercialization efforts. The company's inception was deeply influenced by the 2011 Fukushima nuclear disaster, an event that profoundly underscored the urgent need for safer and more sustainable energy solutions. Driven by this imperative, CEO Hideki Yoshino founded Clean Planet with a vision to develop Quantum Hydrogen Energy (QHe) technology, a novel approach to clean energy rooted in LENR principles. The company's foundational philosophy emphasizes a global reliance on green energy, extending even to potential applications in outer space.
The Science Behind QHe Technology
Clean Planet's QHe technology is a heat-generating process based on hydrogen quantum diffusion.10 This process involves heating a small amount of hydrogen saturated within a nano-sized nickel-based composite material. The reaction generates substantial heat, boasting an energy density more than 10,000 times greater than that of natural gas. This remarkable efficiency implies that less than 10 grams of hydrogen could potentially fulfill a household's monthly electricity and heat requirements. A compelling experiment conducted by Clean Planet demonstrated continuous excess heat generation for an impressive 589 days, initiated solely by an initial hydrogen saturation.
A critical aspect of QHe technology is its operating temperature. Unlike traditional hot fusion, which demands temperatures in the millions of degrees Celsius, QHe technology operates at significantly lower temperatures, typically between 500°C and 1,000°C. This lower operating range, coupled with the "quantum hydrogen diffusion" mechanism and "electron-mediated effects" , suggests a pathway to overcome the Coulomb barrier without requiring extreme conditions. This inherently implies a fundamentally safer and more manageable nuclear process, reducing the need for exotic materials and complex containment, thereby potentially lowering both capital and operational costs. The long-duration, continuous heat generation observed further underscores the stability and practical potential of the reaction.
The technology utilizes readily available and cost-effective materials such as light hydrogen and base metals like nickel and copper, further enhancing its practical appeal. Clean Planet's QHe system is designed with modularity and scalability in mind, capable of delivering industrial-scale heat up to 1,000°C, making it adaptable for various applications.
Rigorous Validation and Academic Collaboration
Clean Planet's foundational research (Phase One: 2012-2018) involved establishing a Joint Research Center with Tohoku University in 2015. This collaboration was explicitly formed to study Condensed Matter Nuclear Reaction (CMNR), aiming to obtain basic data on anomalous heat generation and nuclear transmutation phenomena. A significant milestone was the participation in the NEDO project (2015-2017), a national initiative that rigorously confirmed excess heat generation and reproducibility using various nanopowder materials (nickel, copper, and zirconium). This phase successfully validated the fundamental methodology of QHe.
The strategy of deep, long-term collaboration with a reputable academic institution like Tohoku University, coupled with participation in a national project that confirmed reproducibility, directly addresses the historical criticisms regarding a perceived lack of reproducibility and independent validation that plagued early "cold fusion" claims. Professor Yasuhiro Iwamura of Tohoku University (who later moved to Yokohama City University in 2025) has extensively published on anomalous heat generation from nano-structured multilayer metal composites and hydrogen gas in peer-reviewed journals like the Japanese Journal of Applied Physics (March 2024). His work, often co-authored with Emeritus Professor Jirohta Kasagi, consistently reports energy releases at nuclear levels (e.g., >10 keV/H atom) that cannot be explained by chemical reactions, with no harmful gamma rays or neutrons observed. The replication of heat generation methodology in a new laboratory near Tokyo, even with materials sourced from different providers, further demonstrates reproducibility. This systematic approach, confirming excess heat generation and reproducibility, moves LENR closer to mainstream scientific acceptance by directly confronting past skepticism.
From Prototype to Mass Production
Clean Planet has meticulously structured its development and commercialization efforts into distinct phases :
Phase One (2012-2018): Basic Research at Academic Institutions. This foundational phase involved establishing a Joint Research Center with Tohoku University in 2015 and participating in the NEDO project (2015-2017), which rigorously confirmed excess heat generation and reproducibility using various nanopowder materials.
Phase Two (2019-2021): Preparation for Commercialization. During this period, Clean Planet focused on developing diverse prototypes for commercial applications. A crucial achievement was the successful replication of the heat generation methodology in a new laboratory near Tokyo, even with materials sourced from different providers. Strategic partnerships were forged with prominent companies, including Mitsubishi Estate, Miura (a leading Japanese industrial boiler manufacturer), and a major Japanese electric power company, laying the groundwork for product development.
Phase Three (2022-Present): Completion of Prototype. Clean Planet is currently in this critical phase, concentrating on the design, testing, and completion of a prototype for industrial boilers. A key collaboration is with Miura Co., Ltd., to develop a pilot industrial boiler aiming for a substantial output capacity of 600 kilowatts, capable of generating one ton of steam per hour. The company is also actively building partnerships with industries such as steel, chemical, and agriculture to explore and develop customized energy solutions.
Phase Four (2025-): Completion of Product and Testing for Mass Production. The upcoming phase anticipates prototype production at a pilot plant in Kawasaki by 2028-2030, aiming to establish a mass production system. Clean Planet plans to expand its patent portfolio, particularly in production processes, and finalize product designs tailored for the agriculture, chemical, steel, and power industries.
Phase Five: Start of Production at Plant #JP001. This phase marks the commencement of sales to the Japanese market, with products specifically designed for the agriculture, chemical, steel, and power sectors.
Phase Six: Start of Mass Production. The final phase envisions mass production and international market expansion, with applications extending to residential use and marine vessels.
The Kawasaki Pilot Plant: Scaling for Industrial Impact
Clean Planet explicitly plans to build a pilot plant in Kawasaki by 2028 to 2030. This facility is crucial for establishing a mass production system for their QHe-powered industrial heating devices. The selection of Kawasaki for the pilot plant is a strategic decision, aligning with the city's broader initiatives in hydrogen-related businesses and decarbonization solutions. This suggests that Clean Planet is strategically positioning itself within an existing industrial ecosystem that supports advanced energy technologies. This alignment can facilitate supply chain development, access to skilled labor, and potential synergies with other industrial players in the region, thereby accelerating their path to mass production by 2030. It also implies that the local government and industrial partners in Kawasaki are receptive to, and potentially supportive of, such innovative energy projects. While other companies like Asahi Kasei are also building hydrogen pilot plants in Kawasaki , Clean Planet's specific goal is for QHe industrial heating.
Transforming Industries With QHe's Diverse Applications and Key Partnerships
Clean Planet is developing a prototype industrial boiler powered by QHe, with a potential output of 600 kilowatts, capable of generating one ton of steam per hour. These modular units are designed for integration into existing industrial infrastructure. QHe-powered heat modules are applicable to a wide range of sectors, including power generation, manufacturing factories, steel and chemical industries, agriculture, direct air capture, and water desalination.
The detailed commercialization roadmap, particularly the focus on industrial heating (a 600kW boiler producing one ton of steam per hour) and partnerships with established industrial players like Miura Co., Ltd., indicates a pragmatic, market-driven approach. Instead of aiming for immediate grid-scale electricity, Clean Planet is targeting a specific, high-demand industrial niche: process heat. This sector accounts for a large portion of industrial energy use, and focusing on it reduces the complexity and regulatory hurdles often associated with grid integration. The substantial grant of 1 billion yen (about $6.7 million) from the Tokyo Metropolitan Government's Innovation Promotion Project for Achieving Zero Emission Tokyo further de-risks their development. This funding provides crucial capital and a strong signal of governmental confidence and support for their technology as a key component of "Zero Emission Tokyo." This combination of targeted application, industry collaboration, and government backing significantly enhances the probability of successful commercialization.
Safety, Sustainability, and Strategic Patents
A paramount concern in any nuclear technology is safety. Clean Planet emphasizes that despite QHe being a nuclear reaction, it does not produce harmful radiation, presenting a safer alternative to conventional nuclear processes. This aligns with claims from other LENR developers. The reaction can be precisely controlled and easily halted by cooling the system below 500°C. Furthermore, overheating can disrupt the nanostructure of the metals, effectively stopping the reaction, thus providing an inherent safety mechanism. These explicit claims of "no harmful radiation" and inherent safety mechanisms (e.g., stopping the reaction by cooling below 500°C, self-termination upon overheating) are critical for public acceptance and regulatory approval, especially given the public's apprehension towards traditional nuclear energy. These features directly address the primary safety concerns associated with nuclear technologies.
Clean Planet has strategically built an extensive patent portfolio since 2013, with 272 patents filed and 113 granted across 23 countries. These patents cover a broad spectrum of innovations, including the core Quantum Hydrogen Energy heat generation, reaction control mechanisms, production of nano-sized reactant materials, and various heat-utilizing applications. The extensive and global patent portfolio demonstrates a sophisticated commercial strategy to protect intellectual property, secure market dominance, and attract further investment by establishing a strong competitive barrier. This dual focus on safety and intellectual property protection is essential for navigating the complex regulatory and commercial landscape of novel energy technologies.
The Evolving LENR Industry Landscape
Renewed Global Research and Significant Funding Influx
The broader LENR landscape is experiencing a significant revitalization, marked by increased research and development activities and a notable shift in funding. Governments and academic institutions are re-evaluating the potential of LENR, as evidenced by the U.S. Department of Energy's (DOE) allocation of $10 million in February 2023 to eight projects dedicated to assessing the viability of LENR for the United Sates. This substantial investment signals a growing openness to exploring this once-marginalized field.
Current research is intensely focused on:
Nanomaterials Engineering: Optimizing condensed matter environments for enhanced reaction conditions and energy output.
Reproducibility and Validation: Establishing consistent and reproducible experimental results, essential for broader scientific acceptance.
Theoretical Frameworks: Developing a comprehensive theoretical understanding of LENR mechanisms to guide future experimental designs and accelerate technological development.
Some More Key Players Driving Innovation: Brillouin Energy, Hylenr Technologies, and ENG8
Beyond Clean Planet, several other companies are actively contributing to the commercialization of LENR technology, each with unique approaches and applications. The emergence of multiple, distinct companies, each with their own technological focus and targeted applications, indicates a maturing industry. This diversification suggests that LENR is not a monolithic technology but a family of phenomena, each potentially leading to different commercial pathways. The specialization highlights strategic market entry points where the unique advantages of LENR (compactness, long duration, safety) offer distinct competitive advantages, rather than a direct head-on competition with established energy sources. This multi-pronged approach increases the overall probability of LENR's successful integration into the global energy mix.
Table 1:
LENR Technology Focus and Commericialiation Progress
ENG8’s 3rd party validation: University of Aveiro, University of Cambridge, IEP (Instituto Eletrotécnico Português)
These companies and many more are exploring a diverse range of applications for LENR, including industrial heat production, distributed power generation, and specialized industrial boilers. The promise of LENR to deliver energy without harmful emissions or radioactive waste is a powerful motivator in the global pursuit of clean energy solutions.
Economic Viability, Market Potential and A Cost-Competitive Future
Addressing the Economic Equation
The promise of LENR to deliver energy without harmful emissions or radioactive waste is a powerful motivator. Successfully commercialized in LENR could significantly impact global energy markets by offering an ultra-clean, energy-dense, and inherently safe power source.
While specific Levelized Cost of Energy (LCOE) or Levelized Cost of Heat (LCOH) for LENR technologies are still emerging, the underlying principles suggest high economic viability. LENR systems require minimal fuel input (grams of hydrogen for months/years of operation) compared to fossil fuels (thousands of pounds for hours). This drastically reduces fuel costs and supply chain complexities. The use of readily available and cost-effective materials like nickel and copper further lowers input costs compared to traditional nuclear or complex fusion reactors. The absence of radioactive waste eliminates the enormous long-term costs associated with waste management and disposal in conventional nuclear fission. The ability to operate at lower temperatures (500-1000°C) reduces engineering complexity and material stress, potentially leading to lower capital expenditures for plant construction compared to high-temperature fusion.
The global industrial heating market alone is substantial, valued at $41.5 billion in 2022 and projected to reach $72.4 billion by 2030, growing at a Compound Annual Growth Rate (CAGR) of 5.67%. This large and growing market represents a significant opportunity for LENR solutions like Clean Planet's industrial boilers. For comparison, industrial heat pumps (a clean alternative) have capital costs that make their total cost per unit heat output slightly higher than natural gas boilers, though this gap is closing with rising gas prices and falling electricity costs from renewables. LENR's potential for even lower operating costs could make it highly competitive.
Broader Economic Implications of Energy Abundance
The widespread adoption of LENR can lead to "superabundant energy," which is a fundamental driver of economic activity and closely linked to economic growth. The discussion of LENR's cost-effectiveness (minimal fuel, no radioactive waste, lower operating temperatures) and its market potential in industrial heating leads to a profound implication: a shift from an energy economy based on scarcity and finite resources to one of abundance. This is not merely about replacing one fuel with another; it is about fundamentally changing the cost structure of energy itself.
As observed, "there are no low-energy rich countries in the world", implying that cheap, abundant energy is a prerequisite for widespread prosperity. Cheaper energy translates to lower prices for goods, more abundant building materials, and improved quality of life. It could enable innovations like water-from-air condensation and vertical farming, addressing global challenges beyond just energy. Energy independence for nations and industries would be a strong possibility, allowing for redirection of resources from fuel expenditures to new capabilities and innovation. LENR's potential to provide "practically unlimited range and endurance" for applications and enable resources to be redirected from "energy-specific technical change to more general progress" suggests a ripple effect across all sectors, fostering innovation and improving global quality of life, far beyond just decarbonization. This represents a truly transformative economic proposition.
Table 2:
LENR Clean Planet (QHe) vs. Conventional Energy.
Overview of Clean Planets QHe/LENR Technology
The Path to a Clean Energy Revolution
The future of LENR appears increasingly promising. The confluence of growing governmental and academic investment , advancements in experimental reproducibility (Solid State) , and the dedicated efforts of private enterprises like Clean Planet, Brillouin Energy, Hylenr Technologies, and ENG8, to name a few leaders, suggests that LENR is emerging as a transformative force in the global energy landscape.
While challenges persist, particularly in fully elucidating the underlying physics and scaling the technology for widespread adoption, the potential for ultra-clean, energy-dense, and inherently safe power sources is a compelling driver. Regulatory frameworks will adapt to accommodate this novel technology, balancing safety with innovation. The journey from scientific anomaly to commercial viability is expected to be swift once the first LENR product goes commericial, and the persistent efforts in the LENR community offer optimism for a truly sustainable and clean planet.
The interplay of scientific progress, commercial strategy, and regulatory evolution is crucial for LENR's future. Scientific validation is attracts funding and partnerships, which in turn accelerates research and development and prototype deployment. This progress then creates pressure for regulatory bodies to accelerate frameworks for a technology that does not fit existing nuclear or chemical paradigms. Many experts within the field anticipate that 2025 will be a landmark year for LENR, potentially witnessing further technological breakthroughs and a surge in investment to commericialization. Clean Planet's roadmap, with prototype production at the Kawasaki pilot plant, represents a concrete step towards realizing this vision. These anticipated milestones are not merely arbitrary dates but represent critical inflection points where the theoretical promise is expected to translate into tangible, scalable demonstrations. This integrated perspective highlights that the "dawn of a new energy era" is not just a scientific discovery, but a complex socio-economic-technological transition that brings on fundamentally reshaping global energy systems.
References
New Energy Times. "What is LENR Research? (Definitions)." https://newenergytimes.com/v2/reports/LENR-FAQ.shtml
NUCAT Energy LLC. "Short History of LENR." http://nucat-energy.com/low-energy-nuclear-reactions/short-history/
CLEANPLANET Inc. "TECHNOLOGY." https://www.cleanplanet.co.jp/technology/ Elshaikh, Eman. "Clean Planet: Innovating the Future of Clean Energy." Solid State Fusion Discovery, June 11, 2024. Available at: https://solidstatefusion.org/2024/06/clean-planet/
U.S. Department of Energy. "U.S. Department of Energy Announces $10 Million in Funding to Projects Studying Low-Energy Nuclear Reactions." News and Insights, February 17, 2023. https://arpa-e.energy.gov/news-and-events/news-and-insights/us-department-energy-announces-10-million-funding-projects-studying-low-energy-nuclear-reactions
New Energy Times. "What is LENR Research? (Definitions)." https://newenergytimes.com/v2/reports/LENR-FAQ.shtml
U.S. Department of Energy. "U.S. Department of Energy Announces $10 Million in Funding to Projects Studying Low-Energy Nuclear Reactions." News and Insights, February 17, 2023. https://arpa-e.energy.gov/news-and-events/news-and-insights/us-department-energy-announces-10-million-funding-projects-studying-low-energy-nuclear-reactions
CLEANPLANET Inc. "TECHNOLOGY." https://www.cleanplanet.co.jp/technology/
CLEANPLANET Inc. "NEWS." https://www.cleanplanet.co.jp/news/
Researchmap.jp. "Yasuhiro Iwamura." https://researchmap.jp/CMNR?lang=en
Konica-Minolta CPP. "About the Clean Planet Program." http://cleanplanetprogram.konicaminolta.eu/en-en/about-clean-planet-program
Clean Planet Group. "Clean Planet official website." https://www.cleanplanet.com/
Clean Planet Innovations. "Our Partners."https://cleanplanetinnovations.com/our-partners/
CATF. "2025 Mid-Year Impact." https://www.catf.us/es/2025/06/2025-mid-year-impact/
Scitechdaily.com. "Earth's Secret Hydrogen Jackpot: Enough Clean Power for 170,000 Years." https://scitechdaily.com/earths-secret-hydrogen-jackpot-enough-clean-power-for-170000-years/
EPA. "About Cosmic Radiation." https://www.epa.gov/radtown/cosmic-radiation
NASA. "Planetary Protection." https://sma.nasa.gov/sma-disciplines/planetary-protection
Kawasaki. "Group Vision 2030." https://answers.khi.co.jp/en/special/visionmap2030/
Kawasaki. "CO2 Capture Technology." https://global.kawasaki.com/en/energy/equipment/co2sr/index.html
Japan Times. "Japan bets on homegrown startups to adapt to a hotter world." https://www.japantimes.co.jp/news/2025/05/29/japan/startups-carbon-reduction/
Pulse2.com. "Clean Planet: $6.7 Million Grant Received For Advancing Quantum Hydrogen Energy." https://pulse2.com/clean-planet-6-7-million-grant-received-for-advancing-quantum-hydrogen-energy/
CCE-MT.org. "Tohoku University and Clean Planet." http://www.cce-mt.org/page3/index.html
Tohoku University. "New joint research division with Clean Planet Inc." Available at: https://www.tohoku.ac.jp/en/press/news20150406_1.html
JCF. "JCF23 Abstracts." Available at: https://jcfrs.org/wordpress/wp-content/uploads/2023/03/jcf23-abstracts-updated.pdf
Energies Media. "Brillouin Energy Hydrogen Hot Tube Technology Achieves Performance Breakthroughs." https://energiesmedia.com/article/brillouin-energy-hydrogen-hot-tube-technology-achieves-performance-breakthroughs-a-revolution-in-low-cost-ultra-safe-pollution-free-energy/
Energy.gov. "Technology Commercialization Fund." https://www.energy.gov/eere/solar/technology-commercialization-fund
Hylenr.com. "About Us."https://www.hylenr.com/about-us/
Hylenr.com. "Technology." https://www.hylenr.com/technology/
YouTube. "ENG8 EnergiCell® Live Demo.”
ENG8. "Technology." https://eng8.energy/technology/
ENG8. "Validation & Testing." https://eng8.energy/category/validation-testing/
Precedence Research. "Heating and Cooling Market Size to Hit USD 369.58 Bn by 2034." https://www.precedenceresearch.com/heating-and-cooling-market
Allied Market Research. "Industrial Heating Equipment Market Research, 2032." https://www.alliedmarketresearch.com/industrial-heating-equipment-market-A08269
ESD. "LENR Briefing." https://www.esd.whs.mil/Portals/54/Documents/FOID/Reading%20Room/Science_and_Technology/16-F-1333_%20DOC_02_LENR_Briefing.pdf
Economic Times. "HYLENR's cold fusion technology unveiled in Hyderabad." https://energy.economictimes.indiatimes.com/news/renewable/hylenrs-cold-fusion-technology-unveiled-in-hyderabad-eyes-global-energy-markets/111822810
IEA. "Are renewable heating options cost-competitive with fossil fuels in the residential sector." https://www.iea.org/articles/are-renewable-heating-options-cost-competitive-with-fossil-fuels-in-the-residential-sector
Energy Innovation. "Decarbonizing Low-Temperature Industrial Heat In The U.S. Report." https://energyinnovation.org/wp-content/uploads/Decarbonizing-Low-Temperature-Industrial-Heat-In-The-U.S.-Report-2.pdf
EIA. "Electricity Generation." https://www.eia.gov/outlooks/aeo/pdf/electricity_generation.pdf Lazard.
"Lazard's LCOEPlus June 2024." https://www.lazard.com/media/xemfey0k/lazards-lcoeplus-june-2024-_vf.pdf
APS. "Quantum Mechanical Theory of Hydrogen Diffusion." https://link.aps.org/doi/10.1103/PhysRevLett.37.146
ICCF26.org. "ICCF26 Abstracts." https://iccf26.org/img_common/abstract/iccf26_abstract.pdf
Wikipedia. "Cold fusion." https://en.wikipedia.org/wiki/Cold_fusion
MDPI.com. "CSPth Central Tower can be combined with a fuel-based system." https://www.mdpi.com/1996-1073/15/22/8528
ResearchGate. "Levelized Cost of Solar Thermal System for Process Heating Applications in the Tropics." https://www.researchgate.net/publication/322782169_Levelized_Cost_of_Solar_Thermal_System_for_Process_Heating_Applications_in_the_Tropics NASA.
"Economic Impact of Cheap Abundant Energy LENR." https://ntrs.nasa.gov/api/citations/20150000549/downloads/20150000549.pdf
Brookings.edu. "The economic impacts of clean power." https://www.brookings.edu/articles/the-economic-impacts-of-clean-power/
Frontiers in Materials. "Current Scientific Consensus on LENR Academic Review 2023 2024 2025." Available at: https://www.frontiersin.org/journals/materials/articles/10.3389/fmats.2024.1500487/full
LENR-CANR.org. "Current Status of the Coherent Correlated States for Explanation of LENR." https://lenr-canr.org/wordpress/?page_id=3009
World Nuclear Report. "Power-Play-The-Economics-Of-Nuclear-Vs-Renewables." https://www.worldnuclearreport.org/Power-Play-The-Economics-Of-Nuclear-Vs-Renewables
NASA. "Comparative evaluation of solar, fission, fusion, and fossil energy resources, part 3." https://ntrs.nasa.gov/citations/19740014477
MDPI.com. "Combining the concepts of energy security and sustainable energy consumption.https://www.mdpi.com/1996-1073/16/3/1390
Asahi Kasei. "Asahi Kasei starts operation of multi-module hydrogen pilot plant in Kawasaki." https://www.businesswire.com/news/home/20240514748940/en/Asahi-Kasei-starts-operation-of-multi-module-hydrogen-pilot-plant-in-Kawasaki
ResearchGate. "The Launch of a New Plan on Condensed Matter Nuclear Science at Tohoku University." https://www.researchgate.net/publication/386410694_The_Launch_of_a_New_Plan_on_Condensed_Matter_Nuclear_Science_at_Tohoku_University
LENR-CANR.org. "An Approach to the Nuclear Reactions in the Chemical Lattice." https://lenr-canr.org/acrobat/StormsEanapproach.pdf
LENR-CANR.org. "J. Condensed Matter Nucl. Sci. 39 (2025) 1–436." https://lenr-canr.org/acrobat/BiberianJPjcondensedzl.pdf
LENR-CANR.org. "Anomalous Heat Effect from Deuterium-Loaded Palladium." https://lenr-canr.org/acrobat/BiberianJPjcondensedn.pdf
ResearchGate. "Anomalous heat generation that cannot be explained by known chemical reactions produced by nano-structured multilayer metal composites and hydrogen gas." https://www.researchgate.net/publication/386410694_The_Launch_of_a_New_Plan_on_Condensed_Matter_Nuclear_Science_at_Tohoku_University
JCF. "JCF20 Abstracts." Available at: https://jcfrs.org/JCF20/jcf20-abstracts.pdf
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