Fact-checked by Grok 2 weeks ago

Generation IV reactor

Generation IV (Gen IV) nuclear reactors are an advanced class of reactor designs aimed at providing sustainable, safe, and economically viable energy production for the and beyond. These reactors build on the technologies of earlier generations by incorporating innovative features such as closed fuel cycles, higher thermal efficiencies, and enhanced safety mechanisms to minimize waste, reduce proliferation risks, and support diverse applications including , , and industrial heat. Developed collaboratively through the Generation IV International Forum (), an international partnership established in 2001 involving thirteen member countries plus the , Gen IV systems target commercial deployment around 2030 while addressing global energy challenges like and resource scarcity, with the first such reactor, China's , achieving commercial operation in 2023. The signed a new in 2025 to ensure continued international cooperation. The GIF's development framework is guided by eight technology goals categorized into sustainability, economics, safety and reliability, and proliferation resistance and physical protection. For sustainability, Gen IV reactors seek to utilize more efficiently—potentially breeding more fuel than they consume through fast-neutron spectra—and minimize long-lived by spent fuel in closed cycles. Economically, they aim for capital and operational costs competitive with plants, with simplified designs to reduce construction times and needs. Safety enhancements include inherent features like systems that prevent meltdowns without human intervention, while proliferation resistance is achieved through advanced fuel forms and reprocessing methods that deter weapon-usable material extraction. These goals were formalized in the GIF's 2002 , which has been updated periodically based on ongoing research involving over 100 international experts. From an initial evaluation of 130 reactor concepts, the selected six promising systems for focused research and development: the Gas-Cooled Fast Reactor (GFR), Lead-Cooled Fast Reactor (LFR), Molten Salt Reactor (MSR), Sodium-Cooled Fast Reactor (), Supercritical Water-Cooled Reactor (SCWR), and Very High Temperature Reactor (VHTR). The GFR and LFR employ fast neutron spectra with or lead coolants for high efficiency and waste transmutation; the MSR uses molten salts as both fuel and coolant for flexible operation at high temperatures; the leverages sodium cooling with a proven history in prototypes for breeding ; the SCWR operates at supercritical pressures akin to advanced light-water reactors but with superior efficiency; and the VHTR achieves outlet temperatures up to 950°C using coolant, enabling of and process heat for applications like or . This diverse portfolio allows Gen IV reactors to adapt to varying national energy needs, with prototypes and demonstrations advancing through international projects coordinated by the 's technical secretariat at the .

Introduction

Definition and Objectives

Generation IV reactors represent a class of advanced nuclear reactor technologies designed to succeed Generation III and III+ reactors, with deployment targeted around 2030 or later. These systems emphasize improvements in , , and reliability, as well as proliferation resistance and physical protection, as defined by the Generation IV International Forum (). Unlike earlier generations, Generation IV reactors incorporate innovative designs that support closed fuel cycles to recycle nuclear materials, potentially enabling multi-purpose applications such as , , and high-temperature industrial process heat. The GIF has established four broad areas encompassing eight specific technology goals for Generation IV systems. In the area of , the objectives include significantly enhancing fuel utilization—potentially reducing requirements by a factor of 100 compared to once-through cycles—and minimizing the volume and radiotoxicity of nuclear waste through advanced reprocessing and in a closed cycle. For , the goals focus on achieving lifecycle costs competitive with other sources, supported by features like modular , longer operational lifetimes exceeding 60 years (potentially up to 100 years or more), and reduced capital investment through factory fabrication. Safety and reliability objectives aim to produce inherently safer reactors with passive safety systems that minimize the need for active intervention, aiming for a very low core damage frequency, further enhancing the safety levels already achieved by Generation III+ reactors such as the , and rates above 90%. Proliferation resistance seeks to minimize the production of weapons-usable materials like separated , while physical protection emphasizes robust designs that withstand external threats such as impacts or , integrating safeguards from the outset. These goals collectively position Generation IV reactors as versatile, long-term solutions for global energy needs beyond traditional electricity production.

Historical Context and Evolution

The development of nuclear reactors has progressed through distinct generations, each building on prior technologies to address evolving needs in energy production, safety, and resource utilization. Generation I reactors, pioneered in the 1950s and 1960s, were primarily prototypes and early power plants designed to demonstrate fission-based electricity generation, such as the Shippingport Atomic Power Station in the United States, which operated from 1957 to 1982. These systems laid the groundwork but were limited by experimental designs and low operational efficiencies. Generation II reactors, deployed commercially from the 1970s through the 1990s, represented the first widespread adoption of light-water reactors like pressurized water reactors (PWRs) and boiling water reactors (BWRs), featuring basic safety systems and achieving grid-scale power output. Generation III and III+ designs, emerging in the 1990s and continuing into the present, introduced evolutionary improvements such as enhanced fuel performance and passive safety features, exemplified by the AP1000 reactor, which incorporates gravity-driven cooling to mitigate accident risks without active intervention. The push toward Generation IV reactors was driven by critical lessons from major accidents and broader global challenges in energy supply and environmental sustainability. The 1979 Three Mile Island partial meltdown in the United States exposed vulnerabilities in operator interfaces and cooling systems, prompting regulatory overhauls that underscored the need for inherently safer designs. The 1986 in the highlighted flaws in reactor control and containment, resulting in widespread radioactive release and reinforcing international demands for proliferation-resistant and accident-tolerant technologies. Similarly, the 2011 Fukushima Daiichi crisis, triggered by a overwhelming backup systems, emphasized the importance of resilience against external hazards like natural disasters. Concurrently, post-1990s concerns over escalating global energy demands and —driven by rising from fossil fuels—spurred interest in advanced nuclear options capable of providing low-carbon, reliable baseload power to support . Early concepts for IV reactors originated from U.S. Department of Energy () advanced nuclear research programs in the , which explored innovative fuel cycles and reactor types to overcome limitations in waste management and resource efficiency. These efforts culminated in the formalization of IV goals through collaborative international initiatives, focusing on systems that could operate more sustainably than predecessors. In terms of evolutionary metrics, IV designs target a significant extension of resources; while II reactors, using once-through fuel cycles, support roughly 200 years of supply from identified reserves at current consumption rates, IV closed cycles—particularly in fast reactors—can increase utilization by up to 60 times, effectively multiplying the resource base. Additionally, improvements from the approximately 33% of II light-water reactors to over 45% in select IV concepts, such as high-temperature gas-cooled systems, enable greater electricity output per unit of heat generated. In January 2025, the signed a new to continue its international collaboration on IV systems.

Generation IV International Forum

Formation and Organizational Structure

The Generation IV International Forum (GIF) was initiated by the U.S. Department of Energy in 2000 and formally established in July 2001 through the signing of its charter by nine founding members: , , , , , the Republic of Korea, , the , and the . This framework was created to coordinate international (R&D) on advanced systems, addressing global energy needs while enhancing safety, sustainability, and economic viability. As of 2025, following Russia's exclusion, the includes 12 member countries—, , , , , , , the Republic of Korea, , , the , and the —along with , representing the 27 member states, for a total of 13 members. Membership decisions require unanimous approval from existing members, based on a prospective member's nuclear program and capacity to contribute to collaborative efforts. The GIF's organizational structure is designed to facilitate high-level decision-making and technical coordination. At the apex is the Policy Group, comprising senior representatives at the ministerial or equivalent level from each member, which sets strategic priorities and approves major initiatives. Supporting this is the , led by a , which manages day-to-day operations and R&D oversight through the —a body of that monitors progress and advises on . Specialized panels, including System Steering Committees for each of the six Generation IV reactor systems, provide focused guidance on technology-specific development. The secretariat, hosted by the OECD Nuclear Energy Agency (NEA) in , , handles administrative support, including coordination of meetings and documentation. Funding and collaboration are central to the GIF's operations, achieved through joint R&D projects governed by system arrangements that promote secure technology sharing and protections among members. These arrangements enable pooled resources for shared experiments, data exchange, and prototype development, with members contributing based on their expertise and national programs. Since inception, the forum has supported over 100 collaborative projects, including Euratom-co-funded initiatives totaling around 95 efforts with approximately €500 million in investments. The GIF has evolved significantly since 2001, expanding its scope to incorporate industry partners via the Senior Industry Advisory Panel, which provides strategic input from private sector executives, and welcoming observers from international bodies like the (IAEA). This growth reflects a shift toward broader and practical deployment considerations. A key focus has been on harmonized regulations, addressed through working groups like the Risk and Safety Working Group, to align standards across borders. In 2025, the adoption of a new , effective , ensured the forum's continuity and adaptability amid geopolitical changes, including the exclusion of from active participation.

Technology Roadmap and Goals

The Generation IV International Forum (GIF) published its initial Technology Roadmap in 2002, outlining a strategic plan for the research, development, and deployment of six advanced systems aimed at meeting global energy needs by 2030. This document was updated in 2014 to reflect progress, incorporate lessons from events like , and adjust timelines due to evolving national priorities and technical challenges, extending demonstration efforts beyond initial targets for some systems. The roadmap structures development into three overlapping phases: viability (focused on feasibility and proof-of-principle by around 2010), performance (optimization and conceptual design by around 2020), and demonstration (prototype testing leading to commercialization post-2030), with earlier low-temperature prototypes targeted pre-2025 for select systems like the (SFR) and very-high-temperature reactor (VHTR). R&D priorities under the roadmap emphasize cross-cutting areas such as advanced fuels (e.g., high-burnup metallic and nitride fuels), materials resistant to extreme temperatures and corrosion, and enhanced safety features including passive cooling systems, with an estimated investment of hundreds of millions of USD across these domains. System-specific arrangements guide targeted efforts, such as the SFR arrangement established in 2006, which coordinates international work on sodium coolant technology, severe accident mitigation, and actinide recycling to support closed fuel cycles. These priorities integrate GIF's core goals, including verifiable sustainability metrics like multiplying uranium resource utilization by a factor of 100 through breeding and recycling, thereby extending fuel supplies for at least 100 years at increased exploitation rates, and minimizing long-term waste radiotoxicity to levels requiring isolation for under 1,000 years. Proliferation resistance is embedded via safeguards on reprocessing, such as low-decontamination recycling and denatured fuels, alongside real-time monitoring and international standards developed in collaboration with the International Atomic Energy Agency (IAEA). International cooperation, enabled by GIF's multinational membership, relies on Memoranda of Understanding (MOUs) and system arrangements to share resources and facilities, avoiding duplication and accelerating progress. For instance, MOUs facilitate access to shared fuel fabrication capabilities in for advanced oxide and metallic fuels, while testing infrastructure in , such as the High-Temperature Test Reactor (HTTR) and sodium loops, supports validation of high-temperature materials and coolant behaviors for VHTR and SFR systems. This collaborative framework, involving over 13 member countries, ensures equitable contributions to cross-border R&D while aligning with global nuclear non-proliferation norms.

Thermal Spectrum Reactors

Very-High-Temperature Reactor (VHTR)

The Very-High-Temperature Reactor (VHTR) is a thermal-spectrum design within the Generation IV framework, characterized by its use of as a and as a moderator to achieve high operating temperatures suitable for applications. The core operates with a thermal neutron spectrum, featuring an outlet temperature of 900–1000°C, which enables efficient heat transfer for both and non-electric uses. Fuel configurations include prismatic blocks or pebble-bed forms, typically employing tri-structural isotropic (TRISO) particles encapsulated in for enhanced product retention under high temperatures. This design builds on the properties of 's thermal inertia and 's chemical inertness, allowing the reactor to maintain structural integrity during transients. A primary advantage of the VHTR lies in its potential for high up to 50%, surpassing traditional light-water reactors due to the elevated helium outlet temperatures that optimize turbines. Beyond power production, the VHTR supports for through thermochemical water-splitting cycles, such as the sulfur-iodine process, which leverages the reactor's heat output to achieve efficiencies up to 50% without . Additionally, it provides process heat for industrial sectors like petrochemical refining and , reducing reliance on fossil fuels and enabling low-carbon alternatives at temperatures above 850°C. The inert nature of helium coolant eliminates risks of oxidation or corrosion in the core, as it remains stable and non-reactive even at extreme temperatures, contrasting with water-based systems. Safety is further enhanced by passive decay heat removal mechanisms, relying on natural circulation of helium, conduction through graphite, and radiation to external structures, without the need for active pumps or external power during accidents. This approach ensures core temperatures remain below fuel damage thresholds, providing a robust defense-in-depth strategy. Development of the VHTR draws from Generation III high-temperature gas-cooled reactors, notably China's demonstration plant, which achieved criticality in 2021 and entered commercial operation in December 2023 with two 250 MWt modules. The (GIF) has targeted a VHTR prototype for deployment in the 2020s, focusing on international collaboration for fuel qualification and , though progress has faced delays due to regulatory and materials challenges. Ongoing research emphasizes scaling to larger units while validating high-temperature components for sustained operation.

Molten Salt Reactor (MSR)

The (MSR) is a Generation IV design that utilizes molten salts as both carrier and , enabling flexible cycles and high-temperature operation. In this configuration, such as or is dissolved directly in the , which circulates through the reactor core, facilitating continuous processing and inherent safety characteristics. MSRs can operate in thermal, epithermal, or fast neutron spectra, depending on the design, with thermal and epithermal variants often incorporating moderators to slow neutrons. Core features of MSRs include the use of molten or salts as the primary medium, with common compositions such as LiF-BeF₂ (FLiBe) or LiF-ThF₄-UF₄ for designs, and mixtures like NaCl-UCl₃ for fast-spectrum applications. These salts dissolve the salts at low , typically near atmospheric levels, and support operating s ranging from 600°C to 800°C, which enhance for or process heat applications. For instance, the conceptual Fast Reactor (MSFR) targets a mean of around 750°C, while -based designs like the (TMSR-LF1) operate between 630°C and 650°C. A key advantage of MSRs is the capability for online fuel reprocessing, where products can be continuously removed through methods like sparging or chemical , allowing the reactor to maintain high fuel utilization and breed without shutdowns. This process supports extended operation and minimizes waste accumulation. is further enhanced by low-pressure operation, which reduces the risk of pressure-related accidents, and passive features such as freeze plugs—solidified barriers that melt during overheating to drain the fuel into subcritical storage tanks for natural cooling. These mechanisms provide a large coefficient of reactivity and long response times to transients, contributing to robust profiles. MSR variants include thermal breeders that leverage the thorium-uranium cycle, where is converted to in a graphite-moderated , enabling high breeding ratios with reduced long-lived waste compared to uranium- cycles. Designs like the Molten Salt (MSBR) exemplify this approach, using an initial fissile inventory of or to initiate the cycle. Additionally, MSRs offer potential for burning actinides, such as transuranics from spent fuel, in fast-spectrum configurations like the MOSART concept, which can transmute over 12 tons of minor actinides per gigawatt-thermal over 50 years. The thorium-uranium cycle, in particular, aids waste reduction by producing fewer higher actinides. Despite these benefits, MSRs face significant challenges, including corrosion of structural materials by the aggressive molten salts at high temperatures, necessitating advanced alloys like Hastelloy N or Hastelloy GH3535 with precise redox control to mitigate degradation. In thermal designs, graphite moderators must withstand radiation damage and salt permeation, limiting component lifespan to around 4-5 years in some concepts due to issues like helium production and fission product ingress. Ongoing research under the Generation IV International Forum addresses these through material testing and salt chemistry optimization. Development of MSRs draws from historical experiments like the in the 1960s, with recent progress led by China's , a 2 MWth thorium-based prototype that achieved criticality in October 2023, demonstrated online refueling without shutdown in April 2025, and successfully converted thorium to uranium fuel in November 2025. The Generation IV International Forum coordinates international efforts focusing on thermal and fast-spectrum test reactors anticipated in the 2020s, addressing materials and fuel processing challenges for commercial deployment.

Supercritical Water-Cooled Reactor (SCWR)

The Supercritical Water-Cooled Reactor (SCWR) is a Generation IV thermal-spectrum reactor concept that utilizes light as both coolant and moderator under supercritical conditions, operating above the critical point of at 374°C and 22.1 . Core designs can employ either a pressure-tube configuration, with individual fuel channels for , or a pressure-vessel setup analogous to conventional light water reactors (LWRs), housing multiple assemblies within a single vessel. Typical operating parameters include inlet temperatures of 280–350°C, outlet temperatures of 500–625°C, and pressures around 25 , enabling a direct once-through cycle that eliminates the need for steam generators and reduces system complexity. Fuel assemblies, often using (UO₂) or advanced options like uranium (UC), are arranged in bundles—such as 43-element strings in pressure-tube variants—with heated lengths of approximately 5–6 meters to achieve thermal powers of 2,300–3,000 MWth and electric outputs up to 1,200 MWe. This design offers evolutionary advantages over existing LWRs by leveraging established water-based technologies while achieving higher thermal efficiencies of 44–48%, compared to 33% in typical LWRs, due to the elevated outlet temperatures and single-phase properties that avoid crises and enhance . The simplified balance-of-plant reduces capital costs and operational complexity, aligning with Generation IV economic goals through improved fuel utilization and compatibility with existing LWR fuel cycles, potentially extending burnups to 40–50 GWd/tU. Additionally, the absence of phase change in the core streamlines turbine integration with supercritical fossil plant experience, promoting higher overall plant efficiency up to 51% in optimized cycles. Safety in SCWRs is enhanced by passive features inherent to the design, including natural circulation for removal via isolation condensers and feedwater tanks, as well as negative reactivity —such as a Doppler of -2.5 pcm/°C—that provide inherent against power excursions. The pressure-tube variant benefits from a heavy-water moderator acting as a , while pressure-vessel designs incorporate thermal sleeves to protect the vessel from high temperatures, limiting core damage frequencies to moderate levels through robust overpressure protection and compact structures. Fuel compatibility with LWR standards further supports safety by minimizing risks and easing transition from current fleets. Variants of the SCWR primarily focus on thermal-spectrum operation but include adaptations like CANDU-style pressure-tube reactors using CANFLEX bundles for enhanced neutron economy, and PWR-style pressure-vessel designs with 25x25 fuel assemblies for scalability. While the core technology remains thermal, conceptual extensions to fast-spectrum versions, such as Japan's Super FR, explore burning for waste , though these are secondary to the primary thermal designs pursued internationally.

Fast Spectrum Reactors

Gas-Cooled Fast Reactor (GFR)

The Gas-Cooled Fast Reactor (GFR) is a designed as a high-temperature, helium-cooled that operates without a to enable efficient breeding and . It aims to achieve outlet temperatures of 800–850°C at a primary of approximately 7 , facilitating high thermal efficiency for and potential industrial applications such as . The core employs advanced , typically mixed uranium-plutonium ((U,Pu)C) or , arranged in hexagonal assemblies with annular pins clad in () composites to withstand extreme conditions. Key advantages of the GFR include its potential for a high breeding ratio approaching or exceeding 1.0, enabling a closed fuel cycle that recycles plutonium and minor actinides to minimize long-lived radioactive waste through transmutation. Unlike liquid metal-cooled systems, the use of inert helium as coolant eliminates risks of chemical reactivity with air or water, reducing corrosion and enhancing operational safety while allowing transparent gas for better in-core inspection. This design supports high fuel burnup targets, such as 5% fissions per initial metal atom, promoting resource efficiency and sustainability in nuclear energy production. For safety, the GFR typically incorporates a direct power conversion system using as the , which simplifies the design and improves efficiency at high temperatures. Decay heat removal relies on robust systems, including potential passive mechanisms via natural circulation or dedicated loops with blowers, to prevent overheating during accidents like loss of ; for instance, one atmosphere of can remove up to 2% of (about 12 MWth for a 600 MWth ) with minimal blower power. These features contribute to by avoiding failures common in water-cooled reactors. Despite these benefits, the GFR faces significant challenges, particularly the high and cladding temperatures—up to 1,450°C for and 1,000°C for cladding under normal operation, rising to 2,000°C in accidents—which necessitate advanced materials like SiC-SiC composites qualified for and fission product retention up to 1,600°C. The low thermal inertia of the helium-cooled core also demands innovative strategies for transient management, such as enhanced removal to mitigate rapid heating after loss. As of 2025, the GFR is in the viability phase of development, with readiness levels advanced beyond early stages for key components; ongoing focuses on qualification and materials, supported by projects such as the European 75 MWth experimental reactor (targeting operation around 2035) and General Atomics' EM2 500 MWth design (aiming for deployment by 2032).

Sodium-Cooled Fast Reactor (SFR)

The (SFR) is a Generation IV fast spectrum reactor that uses liquid sodium as the primary to achieve high and support a closed fuel cycle for sustainable production. It employs either a pool-type design, where the core, primary pumps, and heat exchangers are integrated within a large sodium pool for enhanced natural circulation, or a loop-type configuration with separate external loops for flow, allowing for modular construction and easier maintenance. Operating at outlet temperatures of 500–550°C and near of approximately 1 atm, the SFR enables high power densities while minimizing material stresses. Fuels typically include mixed uranium-plutonium oxide (MOX) or metallic alloys such as uranium-plutonium-minor actinide-zirconium, which facilitate efficient and of nuclear materials. A key advantage of the SFR lies in its technological maturity, derived from decades of operational experience with prototypes that have accumulated over 400 reactor-years worldwide. Notable examples include the Phénix reactor in , a 250 MWe pool-type SFR that operated successfully from 1973 to 2009, demonstrating reliable power generation and fuel performance, and the BN-350 in , a 150 MWe loop-type unit that ran from 1972 to 1999 while also supporting . These prototypes have validated the SFR's ability to achieve breeding ratios of 1.0–1.2, enabling the recycling of from spent fuel to extend resources and minimize long-lived waste. As of 2025, the fleet has expanded with Russia's BN-800 (789 MWe) operational since 2016 and India's PFBR (500 MWe) completing fuel loading in 2024, while the U.S. Natrium project (345 MWe) advanced to groundbreaking in 2024. Safety in SFRs is enhanced by inherent passive mechanisms, including negative reactivity feedback from the thermal expansion of and sodium coolant, which reduces reactivity during temperature increases and prevents power excursions. The liquid sodium provides a large inertia and a wide margin to boiling, contributing to a long response time for removal via natural circulation, while an inert cover gas system prevents chemical reactions and contains potential sodium leaks. Extensive testing on prototypes like Phénix and BN-350 has confirmed these features, showing no core damage in simulated severe accidents and supporting Generation IV goals for accident-tolerant designs. SFR fuel variants balance safety and performance: oxide fuels like MOX offer superior thermal stability and higher melting points for enhanced during transients, making them suitable for larger 500–1500 plants with aqueous reprocessing. In contrast, metallic fuels provide higher actinide burning efficiency and burnups up to 200 GWd/MTHM, supporting ratios above 1.0 in compact 150–500 modular designs, though they necessitate pyrometallurgical integrated on-site. These options allow SFRs to adapt to diverse deployment scales while advancing waste reduction objectives.

Lead-Cooled Fast Reactor (LFR)

The (LFR) is a Generation IV fast-spectrum that employs molten lead or lead-bismuth eutectic (LBE) as the primary to achieve high efficiency in actinide transmutation and power generation. The core operates with a fast , utilizing fuels such as mixed oxide (MOX), nitride (UN), or nitride (PuN) in wire-wrapped fuel pins arranged in a , which provides spacing and enhances while minimizing flow resistance. inlet and outlet temperatures typically range from 400–480°C, with potential extension to 550°C using , enabling high for production or generation. Natural circulation of the dense supports passive removal, reducing reliance on mechanical pumps. Key advantages of the LFR stem from the coolant's physical properties, including its high boiling point—1743°C for lead and 1670°C for LBE—which permits low-pressure operation and eliminates boiling risks under normal or transient conditions, providing a substantial safety margin over water-cooled designs. The inherent negative void coefficient ensures that coolant voiding leads to reduced reactivity, promoting self-stabilization during accidents. These attributes make the LFR well-suited for compact, modular systems ranging from 20–180 "battery" units with 15–20 year fuel lifespans to larger 1400 plants, supporting closed fuel cycles for and waste minimization. Safety in LFRs is enhanced by the coolant's chemical inertness, as lead does not react exothermically with air, water, or structural materials, thereby avoiding hydrogen generation or fires in breach scenarios. Passive shutdown and cooling rely on natural convection and the coolant's high heat capacity—40% greater than sodium—allowing prolonged operation without external power, while a guard vessel preserves coolant inventory. In hypothetical core damage events, the molten corium would float atop the denser lead, halting fission and facilitating containment. LFR designs vary by coolant: pure lead is favored for sustained commercial use due to its abundance, high stability, and absence of radiological byproducts, though its higher melting point (327°C) requires careful freeze protection. In contrast, LBE (melting point 125°C) enables lower-temperature startups but produces polonium-210 through bismuth neutron activation, necessitating shielding and purification systems to manage alpha-emitter hazards. These variants build on over 80 reactor-years of operational experience from historical naval prototypes. As of 2025, notable progress includes Russia's BREST-OD-300 (300 MWe) under construction since 2021, with key component installations ongoing, and European initiatives such as the ALFRED 300 MWth demonstrator and Belgium's MYRRHA 100 MWth accelerator-driven LFR in development stages.

Development Timeline

Key Historical Milestones

The was formally established in as an to advance the research and development of next-generation systems, building on initial U.S. Department of Energy initiatives from 2000. The , outlining the goals for sustainable, safe, and economical nuclear technologies, was signed on July 28, , by founding members including , , , , , , , the , and the . In December 2002, after evaluating over 130 reactor concepts proposed by international experts, the GIF selected six systems for focused development: the gas-cooled fast reactor (GFR), lead-cooled fast reactor (LFR), molten salt reactor (MSR), sodium-cooled fast reactor (SFR), supercritical water-cooled reactor (SCWR), and very-high-temperature reactor (VHTR). This selection, detailed in the initial , prioritized designs addressing , , , and proliferation resistance. From 2005 to 2010, the progressed through the signing of initial system arrangements to coordinate R&D collaborations, with the and VHTR among the first to formalize partnerships involving multiple member countries for shared experiments and design assessments. Concurrently, the launched the European Sustainable Nuclear Industrial Initiative (ESNII) in to demonstrate fast reactor technologies with closed fuel cycles, emphasizing sodium- and lead-cooled systems in alignment with GIF priorities. Throughout the 2010s, prototype construction marked tangible advancements in Gen IV concepts; China poured first concrete for the HTR-PM demonstration high-temperature gas-cooled reactor in December 2012, serving as a Gen III+ precursor to VHTR technology and reaching initial grid connection in December 2021. In Russia, construction of the MBIR multipurpose sodium-cooled fast research reactor began in September 2015 at the RIAR site in Dimitrovgrad, aimed at testing fuels and materials for fast spectrum systems to replace the aging BOR-60 facility. In 2020, the GIF's annual report highlighted an updated technology roadmap amid global disruptions from the , which delayed collaborative meetings and experimental timelines while reaffirming progress toward deployment goals. That same year, the U.S. Department of Energy initiated the Advanced Reactor Demonstration Program (ARDP) with $30 million in 2020 funding for risk-reduction activities, including projects on reactors (such as Kairos Power's fluoride salt-cooled design) and very-high-temperature reactor concepts (like X-energy's Xe-100 pebble-bed system).

Current Status and Future Projections

As of November 2025, Generation IV reactor technologies remain primarily in research, development, and pre-licensing phases, with no commercial-scale units operational worldwide. International efforts under the Generation IV International Forum (GIF) continue to advance prototypes, such as molten salt reactors in the United States targeting initial deployment by 2026 and China's thorium-based molten salt reactor scheduled for operation by 2029, though timelines for gas-cooled fast reactors (GFR) and very-high-temperature reactors (VHTR) have faced delays due to technical and funding hurdles. Projections for commercial deployment of Generation IV systems span 2030 to 2040, depending on reactor type and regional progress. In the United States, the Department of Energy's Reactor Pilot Program, launched in 2025, has selected 11 advanced reactor projects—including several Generation IV concepts—for accelerated testing and licensing, aiming to achieve criticality in at least three by 2026 to support broader rollout. In , the lead-cooled fast reactor (LFR) accelerator-driven system has Phase 1 () underway since 2024, with construction of the full reactor projected to begin after 2033 and commissioning scheduled for 2036, serving as a key demonstrator for LFR technology. Key challenges delaying these timelines include the need for regulatory to streamline licensing across borders and vulnerabilities in the supply chain, exacerbated by the ongoing crisis which has disrupted production and isotope supplies since . Geopolitical tensions have heightened risks to sourcing, prompting efforts to diversify supplies and build domestic enrichment capacity in Western nations. An optimistic outlook envisions Generation IV reactors contributing up to 200 gigawatts of advanced capacity globally by 2050, particularly if high-temperature designs like VHTR enable efficient co-production to meet clean demands. Success in these areas could position Generation IV systems as a for sustainable expansion, reducing and enhancing .

Safety and Sustainability Assessment

Safety Features and Improvements

Generation IV reactors incorporate features that leverage physical properties to prevent accidents without relying on active controls or intervention. All designs exhibit coefficients of reactivity, which automatically reduce rates as temperatures rise, providing self-regulating during transients. This , combined with low-pressure operation in most systems, minimizes the risk of reactivity excursions and supports walk-away , where the reactor can achieve safe shutdown and cooldown solely through natural processes, even under design extension conditions. Passive safety systems further enhance reliability by utilizing gravity, natural convection, and conduction for removal, eliminating dependence on pumps, valves, or external power. In very high-temperature reactors (VHTR) and reactors (MSR), natural circulation of the coolant—helium in VHTR or in MSR—effectively dissipates residual heat post-shutdown, maintaining core integrity without active intervention. Fast spectrum reactors, such as sodium-cooled (), lead-cooled (LFR), and gas-cooled (GFR), employ meltdown-proof cores through metallic fuel designs that allow molten fuel to relocate axially upon melting, expanding the core geometry and inserting negative reactivity to avert recriticality or severe damage progression. These features align with Generation IV safety goals of a very low likelihood and degree of core damage, with some designs achieving core damage frequencies below $10^{-7} per reactor-year—significantly lower than the typical $10^{-4} to $10^{-5} per reactor-year targets for Generation III+ reactors—while also reducing risks like that could lead to explosions in water-moderated systems. Cross-design examples illustrate this: supercritical water-cooled reactors (SCWR) benefit from the stability of supercritical water, which lacks a crisis and enables density-driven natural circulation for heat removal. In LFRs, the lead coolant's high (approximately 1743°C) precludes formation and explosions, allowing passive natural circulation to manage even in severe scenarios. Overall, these advancements ensure no need for offsite emergency measures, as radioactive releases remain negligible. As of 2025, ongoing GIF efforts, including the 2024 Safety Design Guidelines for sodium-cooled fast reactors and the July 2025 Multinational Design Evaluation Programme (MDEP) workshop on safety, continue to refine these features through updated assessments.

Sustainability Benefits and Waste Reduction

Generation IV reactors emphasize sustainability through advanced fuel cycles that optimize resource use and minimize environmental impacts. Closed fuel cycles, particularly in fast-spectrum designs such as sodium-cooled fast reactors (SFRs) and lead-cooled fast reactors (LFRs), enable the recycling of plutonium, uranium, and minor actinides from spent fuel, significantly extending the availability of uranium resources by up to two orders of magnitude compared to traditional once-through cycles in light-water reactors. This approach utilizes over 99% of the energy potential in natural uranium, transforming depleted uranium stockpiles into usable fuel and reducing the need for new mining. Additionally, molten salt reactors (MSRs) incorporating thorium cycles further enhance resource efficiency by leveraging the abundant thorium reserves, which are roughly three to four times more plentiful than uranium, thereby decreasing reliance on uranium mining and associated environmental disruptions. Waste management in Generation IV systems focuses on to mitigate long-term radiotoxicity. Fast reactors like gas-cooled fast reactors (GFRs) and SFRs employ neutron spectra to long-lived actinides such as and , reducing the radiotoxicity of by factors of 100 to 1,000 compared to conventional cycles, and shortening the required isolation period from over 100,000 years to as little as 500–5,000 years with multi-. In closed cycles with near-complete transuranic recycling (losses below 0.1% per pass), the resulting primarily consists of shorter-lived fission products, lowering the long-term heat load and volume destined for geological repositories by at least an . MSRs contribute by continuously processing fuel online, burning actinides without producing separated plutonium streams, which further diminishes accumulation. Beyond , Generation IV reactors support multi-use applications that enhance overall . High-temperature systems, including very high-temperature reactors (VHTRs) and MSRs operating at 700–1,000°C, enable co-generation for via thermochemical processes or , as well as seawater desalination, thereby reducing the of these energy-intensive sectors. Such versatility improves —up to 50% higher than current reactors—and repurposes excess heat, minimizing in water bodies. Proliferation resistance is integrated into Generation IV designs to support sustainable deployment. In MSRs with liquid-fueled, integrated salt , fuel remains in molten form without discrete separation of fissile materials like , eliminating the production of weapons-grade streams and enhancing safeguards through continuous online reprocessing that avoids bulk handling of pure actinides. Fast reactors similarly achieve high in the core, diluting with other isotopes and reducing the attractiveness of diverted materials for non-peaceful uses.

Ongoing Projects and Demonstrations

International Collaborative Efforts

The coordinates international research and development on Generation IV nuclear systems through system-specific arrangements that facilitate joint efforts among member countries. For the , collaborative projects involve , , and the , focusing on shared technical studies such as selection and plant concepts to advance common design principles. Similarly, the Very High Temperature Reactor (VHTR) arrangement includes on , with the and among the key signatories, alongside , the , , and , emphasizing high-temperature applications for . In , the European Sustainable Nuclear Industrial Initiative (ESNII) under the Sustainable Nuclear Energy Technology Platform (SNE-TP) has driven multinational demonstrations of technologies. The project, proposed as a key ESNII demonstrator, was terminated by the French government in 2019 due to shifting priorities, leading to a reorientation toward lead-cooled systems like the Lead Fast European Demonstrator. Complementing this, Belgium's project, a lead-bismuth-cooled accelerator-driven system, advances ESNII goals by demonstrating subcritical operation and capabilities for . The (IAEA) and (NEA) support Generation IV proliferation resistance through initiatives like the Nuclear Harmonization and Standardization Initiative (NHSI), which promotes standardized safety codes for systems such as the Supercritical Water-cooled Reactor (SCWR). Additionally, IAEA efforts on international low-enriched fuel banks enhance assured supply chains, reducing incentives for sensitive fuel cycle activities and bolstering non-proliferation in advanced reactor deployments. In 2025, renewed its commitment to collaborative R&D with the of a new on March 1, signed by ten countries and , enabling continued cross-cutting work on shared challenges across all Generation IV systems. This includes emerging explorations of technologies for reactor simulation and optimization, as highlighted in recent GIF research pitches.

National and Commercial Prototypes

In the United States, Kairos Power is advancing the Hermes demonstration reactor, a 35 MWth fluoride salt-cooled molten salt reactor designed as a low-power to validate advanced reactor technologies. The U.S. Nuclear Regulatory Commission issued a construction permit for Hermes in December 2023, with nuclear safety-related beginning in May 2025 and operations targeted for 2026 at the site in . This project emphasizes passive safety features and high-temperature operations suitable for process heat applications. TerraPower's Natrium represents a key prototype, with the U.S. issuing a favorable in October 2025 and expecting a construction permit decision by the end of the year. Planned for deployment near , with initial operations around 2030, Natrium integrates a 345 MWe sodium fast with molten salt-based to enable flexible power output. China has operationalized the , with its first 600 unit achieving grid connection in December 2023 and currently in trial operations toward commercial deployment at the Xiapu site in province. This prototype demonstrates closed fuel cycle capabilities using mixed oxide fuel, supporting China's ambitions for sustainable nuclear expansion. Complementing this, China's thorium-based liquid-fueled prototype, rated at 2 MWth, began construction in Wuwei in September 2021, achieved fuel loading in October 2023, and reached criticality in the same month, marking a milestone in thorium utilization for Generation IV systems. The reactor achieved full power operation in June 2024 and demonstrated the world's first thorium-to-uranium fuel conversion in November 2025. Additionally, the high-temperature gas-cooled , operational since December 2021 at Shidao Bay with two 250 MWth modules driving a 210 , serves as a precursor to very high-temperature reactor designs by validating TRISO fuel performance at 750°C outlet temperatures. In , the BREST-OD-300 demonstration, a 300 MWe prototype emphasizing and actinide burning, commenced construction in June 2021 at the site, with operations projected for 2028-2029. The MBIR multi-purpose fast , a 150 MWth sodium-cooled test bed for fuel and material irradiation, is under construction, with operations expected starting in 2028, enabling validation of fast spectrum technologies ahead of commercial deployment. India's (AHWR-300), a 300 thorium-fueled boiling light water-cooled reactor design, has prototype testing of key components such as the and vertical ongoing through the 2020s at the . In , GE Hitachi Nuclear Energy's ARC-100 , a 100 small , entered pre-licensing engagement with the Canadian Nuclear Safety Commission in 2023, with regulatory submissions advancing toward a 2025 construction permit application. On the commercial front, Terrestrial Energy's (IMSR), a 195 MWe graphite-moderated design using clean coolant, is progressing through U.S. pre-application activities initiated in 2019, with a combined application targeted for submission in 2025. X-energy's Xe-100, a 80 MWe per module relying on TRISO fuel, has secured U.S. Department of Energy funding under the Advanced Reactor Demonstration Program, including $80 million in 2020 for development, with a construction permit application submitted in March 2025 for a four-unit deployment at Dow's Seadrift facility in .

Technological Challenges

Advanced Materials Development

Advanced materials for Generation IV reactors must endure operational demands exceeding those of previous generations, including service lives greater than 60 years, neutron fluences up to 4 × 10^{23} n/cm² (E > 0.1 MeV), and temperatures ranging from 400°C to 1000°C. These requirements stem from the need for enhanced structural integrity in high-flux, high-temperature environments to support long-term reactor operation and efficiency. Key materials under development include oxide dispersion strengthened (ODS) steels for cladding applications, typically featuring 9-12% with fine oxide dispersoids such as Y₂O₃ or TiO₂ to provide exceptional resistance at elevated temperatures. These alloys, exemplified by compositions like 12YWT or 14YWT, exhibit superior properties under stress, with rupture lifetimes exceeding 10,000 hours at 700°C and 100 . For very high-temperature gas-cooled reactors (VHTR) and gas-cooled fast reactors (GFR), fiber-reinforced (SiC/SiC) composites serve as core structural materials, offering thermal stability up to 1600°C and low absorption due to their isotropic . These composites are particularly suited for fuel cladding in VHTR and GFR designs, where they maintain dimensional stability in or inert gas coolants. Radiation effects pose significant challenges, including void swelling in metallic alloys and dimensional changes in ceramics, which are mitigated in ODS steels through dispersoid pinning of dislocations, limiting swelling to less than 5% at doses up to displacements per atom (dpa). In fast-spectrum fuels, this resistance enables extended irradiation periods of 15-20 years without excessive volumetric expansion. For SiC/SiC composites, radiation-induced point defects cause modest property degradation, but swelling becomes notable above 1000°C, necessitating optimized fiber-matrix interfaces for sustained performance. resistance is enhanced in lead- or molten salt-cooled systems via alumina-forming alloys, such as FeCrAl variants integrated into ODS steels, which develop protective oxide layers to prevent degradation in aggressive coolants. Research and development efforts are coordinated through the Generation IV International Forum (GIF), which maintains the Generation IV Materials Handbook as a centralized database of performance data for structural materials across reactor systems, including irradiation and corrosion benchmarks. In the United States, the Department of Energy's Nuclear Energy Enabling Technologies (NEET) program funds post-irradiation examination and testing of candidate materials, such as ODS steels and SiC/SiC composites, at facilities like Idaho National Laboratory to validate long-term behavior under simulated Gen IV conditions. These initiatives prioritize high-impact testing to address gaps in swelling and creep data, ensuring materials meet the stringent durability targets for deployment.

Fuel Cycle and Coolant Innovations

Generation IV reactors incorporate advanced fuel designs tailored to their specific types, enhancing , , and resource utilization. For very high-temperature reactors (VHTRs), tri-structural isotropic (TRISO) particles serve as the primary fuel form, consisting of oxycarbide kernels coated with layers of and to contain products at high temperatures up to 1600°C. These particles are embedded in pebbles or prismatic blocks, enabling a once-through fuel cycle with high . In sodium-cooled fast reactors (SFRs) and lead-cooled fast reactors (LFRs), metallic fuels based on -plutonium-zirconium (U-Pu-Zr) alloys are utilized, featuring a sodium bond between the fuel and cladding to accommodate swelling and improve during operation. For reactors (MSRs), the fuel consists of actinides such as and dissolved directly in a molten or carrier salt, like -beryllium fluoride (LiF-BeF2) or (LiCl), allowing continuous online reprocessing and through liquid fuel drainage. Coolant innovations in Generation IV designs address corrosion, neutron economy, and operational stability. Supercritical water-cooled reactors (SCWRs) employ water above its critical point (374°C, 22.1 MPa) as , requiring precise chemistry control—such as pH adjustment with or alkali additions—to mitigate in structural materials and maintain coolant purity. In LFRs, lead-bismuth eutectic (LBE) serves as the due to its high and neutronic properties, but it produces through bismuth , necessitating removal systems like alkaline extraction or getter materials such as or to capture volatile and prevent its release. Fuel cycle integration in these reactors emphasizes closed-loop processes for . Pyroprocessing, an electrochemical separation technique, is applied to fast reactors like SFRs and LFRs, where spent metallic is electrorefined in to recover over 99% of actinides for , minimizing waste and avoiding aqueous reprocessing vulnerabilities. In MSRs, the thorium cycle involves breeding from dissolved in the salt, achieving conversion ratios greater than 1 through continuous product removal and thorium feeding, which supports long-term fuel self-sufficiency. Despite these advances, challenges persist in fuel fabrication and reprocessing . TRISO particle production requires precise processes that are difficult to scale industrially without yield losses, while metallic casting demands control over in large batches. Reprocessing efficiency targets, such as 99% recovery in pyroprocessing, face hurdles from incomplete separation of fission products and salt management, complicating economic viability for commercial deployment.

References

  1. [1]
    Welcome to the Generation IV International Forum | GIF Portal
    The GIF has selected six reactor technologies for further research and development: the gas-cooled fast reactor (GFR), the lead-cooled fast reactor (LFR), the ...Six nuclear energy systems · Molten Salt Reactors (MSR) · GIF Member Area
  2. [2]
    History and Achievements of GIF | GIF Portal
    A major milestone in the development of the Generation IV International Forum was reached when ten of the forum's member countries signed the world's first ...
  3. [3]
    Portal Site Public Home - the Generation IV International Forum
    The GIF brings together 13 countries (Argentina, Australia, Brazil, Canada, China, France, Japan, Korea, Russia, South Africa, Switzerland, the United Kingdom ...
  4. [4]
    Generation IV Goals, Technologies and GIF R&D Roadmap
    Generation IV nuclear energy systems will provide sustainable energy generation that meets clean air objectives and provides long-term availability of systems ...Lead Fast Reactors (LFR) · Molten Salt Reactors (MSR) · Very High Temperature...
  5. [5]
    [PDF] A Technology Roadmap for Generation IV Nuclear Energy Systems
    There are currently 438 nuclear power plants in opera- tion around the world, producing 16% of the world's electricity—the largest share provided by any.
  6. [6]
    Nuclear Power Reactors
    Oct 1, 2025 · Generation I reactors were developed in the 1950-60s and the last one (Wylfa 1 in the UK) shut down at the end of 2015. They mostly used natural ...
  7. [7]
    Advanced Nuclear Power Reactors
    Apr 1, 2021 · Generation I reactors were developed in 1950-60s, and the last one shut down in the UK in 2015. Generation II reactors are typified by the ...
  8. [8]
    Safety of Nuclear Power Reactors - World Nuclear Association
    Feb 11, 2025 · There have been two major reactor accidents in the history of civil nuclear power – Chernobyl and Fukushima ... Even months after the Three Mile ...
  9. [9]
    https://world-nuclear.org/information-library/nuclear-fuel-cycle/nuclear-power-reactors/nuclear-power-reactors
  10. [10]
    Fast reactor can increase utilization rate of uranium resources 60-fold
    Apr 11, 2024 · By establishing a fast reactor nuclear energy system and implementing a closed fuel cycle, uranium resource recycling can be achieved, increasing the ...
  11. [11]
    Generation IV Nuclear Reactors
    Apr 30, 2024 · The aim of ESNII is to demonstrate Gen IV reactor technologies that can close the nuclear fuel cycle, provide long-term waste management solutions.
  12. [12]
    None
    Below is a merged summary of the GIF 2024 Annual Report content based on the provided segments. To retain all information in a dense and organized manner, I will use a combination of narrative text and tables in CSV format where appropriate (e.g., for member lists, funding details, and organizational structures). The response integrates all details while avoiding redundancy and ensuring clarity.
  13. [13]
    GIF Parties and Implementing Agents | GIF Portal
    How does a country become part of the Generation IV International Forum? ... Membership of a country to the Forum is decided by its present members (unanimous ...
  14. [14]
    New GIF Framework Agreement to ensure international co-operation ...
    Jan 29, 2025 · About the Generation IV International Forum (GIF). Established in 2001, GIF provides a platform for collaborative research and development on ...Missing: formation Department
  15. [15]
    [PDF] GIF Annual Report - the Generation IV International Forum
    Overall, some 95 projects co-funded by Euratom (with around EUR 350 million out of EUR 500 million) were presented. A significant number of these projects are ...
  16. [16]
    Russia excluded from Generation IV Forum
    Dec 6, 2024 · Its current membership includes 13 countries (Argentina, Australia, Brazil, Canada, China, France, Japan, Korea, Russia, South Africa, ...<|control11|><|separator|>
  17. [17]
    [PDF] Technology Roadmap Update for Generation IV Nuclear Energy ...
    Mar 14, 2014 · The Technology Roadmap (2002), defined and planned the necessary R&D and associated timelines to achieve these goals and allow deployment of ...
  18. [18]
    Sodium Fast Reactors GIF System Steering Committee | GIF Portal
    The Sodium Fast Reactor System Steering Committee (SFR SSC) was initially formed following the signing of the SFR System Arrangement in 2006 under the now ...
  19. [19]
    [PDF] GIF RDTF Final Report – January 2021
    Japan capabilities include the AtheNa facility for large scale component and system sodium test with 60MW heat capacity; the PLANDTL facility for sodium thermal ...
  20. [20]
    Very High Temperature Reactor (VHTR) | GIF Portal
    The Very High Temperature Reactor (VHTR), one of six Gen IV nuclear system candidates, is designed for electricity and heat cogeneration.<|control11|><|separator|>
  21. [21]
    [PDF] Very High Temperature Reactor (VHTR) - INL Digital Library
    Jan 31, 2003 · The VHTR reference concept is a helium-cooled, graphite moderated, thermal neutron spectrum reactor with an outlet temperature of 1000°C or ...
  22. [22]
    [PDF] Very-high-temperature reactor - the Generation IV International Forum
    High-temperature gas-cooled reactors (HTRs or. HTGRs) are helium-cooled graphite-moderated nuclear fission reactors using fully ceramic fuels.
  23. [23]
    Hydrogen production using high temperature nuclear reactors
    May 25, 2016 · A secondary high temperature heat transfer loop can provide process heat for non-electrical energy production while for the medium temperature ...
  24. [24]
    [PDF] Gas-Cooled Reactors—The importance of Their Development
    The VHTR is the only fission reactor that appears to be able to directly provide energy for high-teaperature processes operating at 850 to 1000°C, thus ...
  25. [25]
    [PDF] VERY HIGH TEMPERATURE REACTOR (VHTR) SAFETY ...
    For VHTR, the removal of decay heat does not require active cooling by the helium. Indeed, the first protective action of a VHTR responding to accident is to ...
  26. [26]
    [PDF] An Overview of Non-LWR Vessel Cooling Systems for Passive ...
    One of the key passive safety features of the VHTR is the potential for decay heat removal by a combination of natural convection and radiation across an ...
  27. [27]
    China's demonstration HTR-PM enters commercial operation
    Dec 6, 2023 · It follows a successful 168-hour demonstration run for the High Temperature Gas-Cooled Reactor - Pebble-bed Module (HTR-PM) in Shidao Bay (also ...<|control11|><|separator|>
  28. [28]
    [PDF] Status of Molten Salt Reactor Technology
    The molten salt reactor is one of the six reactor technologies selected by the Generation IV International Forum for further research and development.
  29. [29]
    Molten Salt Reactors (MSR) | GIF Portal
    Molten Salt Reactors (MSRs) are a class of nuclear fission reactors where molten salts serve as the reactor fuel, coolant, and / or moderator.
  30. [30]
    [PDF] THE MOLTEN SALT REACTOR (MSR) IN GENERATION IV - LPSC
    An MSR has a core where fuel is dissolved in molten fluoride salt. It uses fast-spectrum concepts, and the fuel salt flows freely from bottom to top.
  31. [31]
    None
    ### Summary of Supercritical Water-Cooled Reactor (SCWR) for Generation IV
  32. [32]
    [PDF] Supercritical Water Cooled Reactor (SCWR) PR&PP White Paper
    The SCWR design variants are not expected to be different from Gen III+ systems. The main objective is to protect the plant (investment) and to protect the ...
  33. [33]
    [PDF] Feasibility Study of Supercritical Light Water Cooled Reactors ... - OSTI
    The supercritical water-cooled reactor (SCWR) is one of the six reactor technologies selected for research and development under the Generation-IV program.Missing: variants | Show results with:variants
  34. [34]
    [PDF] Assessment of the Technical Maturity of Generation IV Concepts for ...
    Specific design features include containing the reactor in a sealed cartridge to avoid ... supercritical water-cooled reactor (SCWR), sodium-cooled fast reactor ( ...
  35. [35]
    Gas-Cooled Fast Reactor (GFR) | GIF Portal
    Using gas coolant without graphite in GFR systems poses several technological challenges such as rapid heating after coolant loss, hindering the High- ...
  36. [36]
    [PDF] Gas-Cooled Fast Reactor Research and Development Roadmap
    2.1 General Features. The typical GFR design features an unmoderated, helium-cooled core with a ceramic fuel that operates at high temperatures (i.e., 1,450 ...
  37. [37]
    [PDF] The GEN IV Gas Cooled Fast Reactor: Status of Studies
    GFR Key Feasibility Issues. ➢ Safety case with low thermal inertia and poor heat transfer properties of coolant. ▫ Decay Heat Removal strategy. ▫ Core Melt ...
  38. [38]
    Sodium Fast Reactor (SFR) | GIF Portal
    Among Generation IV systems, the SFR boasts the highest number of constructed reactors and the most comprehensive operational history. Employing mixed oxide or ...
  39. [39]
    [PDF] Status of Fast Reactor Research and Technology Development
    1. Liquid metal fast breeder reactors – Safety measures. 2. Nuclear power plants – Design and construction. 3. Nuclear reactors – Decommissioning.
  40. [40]
    [PDF] PHENIX AND SUPERPHENIX FEEDBACK EXPERIENCE
    Dec 1, 2017 · the french SFR reactors Phenix and Superphenix. ▫ These two books on this subject give a first idea of this experience with some ...
  41. [41]
    Lead-Cooled Fast Reactor - an overview | ScienceDirect Topics
    An important feature of the LFR is the enhanced safety ... This chapter provides a description of the important advantages, challenges and features of Generation ...
  42. [42]
    [PDF] overview of lead-cooled fast reactor (lfr) technology
    Mar 27, 2019 · LFRs have similar sustainability and safety advantages as SFRs. – Can support a closed fuel cycle for efficient resource use and waste ...
  43. [43]
    Overview and History of Lead and Lead-Bismuth Fast Reactors (LFRs)
    Apr 11, 2024 · Lead-cooled fast reactors (LFRs) are a class of nuclear reactor designs that utilize circulating molten lead (or Pb-Bi alloys) as the primary reactor coolant.<|control11|><|separator|>
  44. [44]
    https://www.nrc.gov/docs/ML1915/ML19150A577.pdf
  45. [45]
    Charter of the Generation IV International Forum -GIF
    Document Title. Charter of the Generation IV International Forum -GIF ; Country or International Organization. GIF ; Status. Expired ; Start Date. July 16, 2001.Missing: signing | Show results with:signing
  46. [46]
    [PDF] esnii | snetp
    ESNII is Europe's demonstration programme for. Fast Neutron Reactor ... □ Fast neutron reactors with closed fuel cycles for increased sus- tainability ...
  47. [47]
    Russia begins construction of MBIR
    Sep 16, 2015 · The construction licence was issued in May 2015 for a period of ten years. MBIR is expected to replace the BOR-60 fast research reactor, built ...Missing: test | Show results with:test
  48. [48]
    2020 GIF Annual Report - the Generation IV International Forum
    The 2020 Generation IV International Forum (GIF) Annual Report reflects significant progress in Generation IV (Gen-IV) reactor systems despite the challenges ...Missing: delays | Show results with:delays
  49. [49]
    Five advanced reactor designs get DOE risk reduction funding
    The Department of Energy today announced $30 million in initial fiscal year 2020 funding—with the expectation of more over the next seven years—for five ...
  50. [50]
    US' first liquid-fueled Gen IV nuclear reactor set for 2026 deployment
    Oct 15, 2025 · With a completed facility and key permits, the company is on track to deploy its groundbreaking Gen IV molten salt reactor by 2026.<|separator|>
  51. [51]
    Department of Energy Announces Initial Selections for New Reactor ...
    Aug 12, 2025 · DOE announced the Reactor Pilot Program in June 2025, following ... The goal of the Reactor Pilot Program is to expedite the testing of advanced ...Missing: demonstration Gen
  52. [52]
    Nuclear Power in Belgium
    Oct 2, 2025 · Construction of the Myrrha reactor itself is now expected to begin in 2026, with full operation from 2034. Public opinion. Recent polling ...
  53. [53]
    Diversifying nuclear energy supply chains - Clean Air Task Force
    Apr 25, 2025 · Key challenges in the EU's nuclear energy supply chains relate to the procurement of manufactured nuclear energy fuel. As it stands, 19 out of ...
  54. [54]
    Isotope Supply Chain at Risk from War in Ukraine - AIP.ORG
    Jul 15, 2022 · Russia's invasion of Ukraine has brought new urgency to the Department of Energy's efforts to expand US production capacity for critical isotopes.
  55. [55]
    Geopolitical risks threatening the uranium supply chain - Watt-Logic
    Jul 23, 2024 · In my final post on the uranium supply chain I look at geopolitical risks threatening the access of western countries to nuclear fuel.Missing: harmonization | Show results with:harmonization
  56. [56]
    Commercializing Advanced Nuclear Reactors Explained in Five ...
    Mar 30, 2023 · The report estimates that advanced nuclear could provide about 200 GW of additional capacity by 2050. The five charts below explain the why and how to make ...Missing: IV | Show results with:IV
  57. [57]
    [PDF] Hydrogen Production with Operating Nuclear Power Plants
    May 17, 2025 · The development of high temperature reactors capable of highly efficient power generation and hydrogen production has been emphasized by the ...
  58. [58]
    [PDF] Generation IV International Forum - GIF
    Jul 2, 2021 · This report contains integrated considerations of RSWG to achieve and demonstrate the improved safety potential of future reactor systems. It ...
  59. [59]
    [PDF] Safety Design Criteria - the Generation IV International Forum
    Sep 30, 2017 · A fast reactor, including an SFR, is characterised by the fact that its core is not in its most reactive configuration under normal operating ...Missing: variants | Show results with:variants
  60. [60]
    [PDF] Safety of Gen-IV Reactors Dr. Luca Ammirabile, Euratom, EU - GIF
    for Generation IV ... In particular, the initial design for the PSA results related to the protected loss of heat sink showed core damage frequency of 5 to 10-7 ...
  61. [61]
    Super Critical Water Reactors (SCWR) | GIF Portal
    SCWRs have higher thermodynamic efficiency than current water-cooled nuclear reactors. The SCWR is the only water-cooled reactor selected by the Generation-IV ...
  62. [62]
    Lead Fast Reactors (LFR) | GIF Portal
    Breeding ratio, about 1 (but design with BR>1 or BR<1 are proposed). How does Lead Fast Reactors meet Generation IV Criteria? Sustainability. Resources ...
  63. [63]
    [PDF] Implications of Partitioning and Transmutation in Radioactive Waste ...
    (a) A reduction of the hazard associated with spent fuel over the medium and long term (>300 years) by a significant reduction of the inventory of plutonium and ...<|separator|>
  64. [64]
    [PDF] Summary of Generation-IV Transmutation Impacts
    Jun 30, 2005 · Preliminary results suggest that a burnup of 50-60% is possible in a VHTR burner design using non-uranium (transuranics) fuel. However, ...
  65. [65]
    Proliferation Resistance and Physical Protection White Paper - 2023
    May 11, 2025 · This document represents the status of Proliferation Resistance and Physical Protection (PR&PP) characteristics for the Molten Salt Reactor designs.Missing: integral reprocessing
  66. [66]
    Selection of sodium coolant for fast reactors in the US, France and ...
    This joint paper describes and cross-compares the U.S., France and Japan selections of future nuclear reactor concepts and coolants. In the GIF framework, ...Missing: facilities | Show results with:facilities
  67. [67]
    [PDF] GIF VHTR Hydrogen Production Project Management Board
    The signatories include Canada, EU, France, Japan,. Korea and the USA. China has been an observer, waiting to join the group formally, but contributing strongly ...
  68. [68]
    France terminates ASTRID fast-neutron reactor project - IPFM Blog
    Aug 30, 2019 · France's nuclear agency, CEA, confirmed that it has terminated the program to build a prototype sodium-cooled fast-neutron reactor, known as ASTRID.Missing: ESNII cancellation EU
  69. [69]
    [PDF] ESNII Vision Paper 2022 - SNETP
    Because of the French Government's decision in 2019 to terminate the ASTRID project, a construction phase no longer appears for a sodium demonstrator in Europe.Missing: shift | Show results with:shift
  70. [70]
    [PDF] ESNII Vision Paper 2021 - SNETP
    Jun 30, 2021 · Because of the French Government's decision in 2019 to terminate the ASTRID project, a construction phase no longer appears for a sodium ...Missing: shift | Show results with:shift
  71. [71]
    MYRRHA | Myrrha
    MYRRHA is the world's first large scale Accelerator Driven System project at power levels scalable to industrial systems.Missing: lead- cooled ESNII
  72. [72]
    Shaping the Future of Gen IV Nuclear Talents - YouTube
    Oct 28, 2025 · This special webinar was streamed live on 15 October 2025, marking the 10th anniversary of the GIF Education and Training Working Group ...<|control11|><|separator|>
  73. [73]
    Kairos Power Begins Nuclear Safety-Related Construction of ...
    May 8, 2025 · Kairos Power completed the first safety-related concrete pour for a U.S. advanced reactor under an NRC construction permit on May 7, 2025.
  74. [74]
    The Natrium® Project Receives First NRC-Issued Environmental ...
    The Natrium¹ plant has achieved a key regulatory milestone – a favorable EIS from the U.S. NRC. Bellevue, WA – October 22, 2025 – TerraPower, a ...Missing: MSR | Show results with:MSR
  75. [75]
    Integral Molten Salt Reactor (IMSR) - Nuclear Regulatory Commission
    The U.S. Nuclear Regulatory Commission (NRC) is currenlty engaged in pre-application activities with Terrestrial Energy USA Inc (TEUSA) starting in October 2019 ...
  76. [76]
    Dow & X-energy's South TX Nuclear Project at Seadrift
    X-energy received $80 million in initial funding to develop a commercial four-unit Xe-100 nuclear plant and a full-scale TRISO fuel fabrication facility.Why Nuclear? · Dow And X-Energy To Deploy... · X-Energy Signs Ardp...
  77. [77]
    Dow and X|energy Submit Construction Permit Application to the ...
    Mar 31, 2025 · X-energy was selected by the DOE in 2020 to develop, license, and build an operational Xe-100 advanced SMR and TRISO-X fuel fabrication facility ...<|control11|><|separator|>
  78. [78]
    [PDF] Status Report on Structural Materials for Advanced Nuclear Systems
    Generation IV Materials Handbook. • Content description: – This handbook provides data on structural materials for Generation IV reactor systems ...<|control11|><|separator|>
  79. [79]
    Disruptive Manufacturing of Oxide Dispersion-Strengthened Steels ...
    Also, creep resistance is significantly improved, with ODS steels, showing creep rupture lifetimes exceeding 10,000 h at 700 °C under 100 MPa, making them ...
  80. [80]
    SiCf/SiC composites as core materials for Generation IV nuclear ...
    This chapter provides the current status and future works of the SiC f /SiC composite in nuclear applications for Generation IV energy systems.
  81. [81]
    [PDF] Initial Assessment of Environmental Effects on SiC/SiC composites ...
    Their high resistance to intense irradiation condition is an inherent property of the isotropic SiC crystal, which undergoes only modest property changes ( ...
  82. [82]
    Microstructure evolution and void swelling of ODS ferritic/martensitic ...
    The high resistance of ODS steels to irradiation swelling has been well-documented at high doses of irradiation [31–36]. Therefore, we adopted an irradiation ...
  83. [83]
    Generation IV Materials Handbook | GIF Portal
    Jun 11, 2025 · The Generation IV Materials Handbook is the authoritative, single, durable data source to share materials information within the Generation IV International ...Missing: radiation- ODS steels SiC/ SiC
  84. [84]
    Nuclear Energy Enabling Technologies (NEET)
    The NEET program conducts R&D to develop innovative nuclear energy technologies, including next-generation reactor and fuel cycle technologies, and supports ...Missing: IV post- irradiation
  85. [85]
    [PDF] Nuclear Energy Enabling Technologies (NEET) - INL Digital Library
    Most NEET ASI program stakeholders have substantial R&D activities focusing on the in-pile behavior of nuclear fuels and materials extending from advanced fuels.
  86. [86]
    [PDF] High Temperature Gas Cooled Reactor Fuels and Materials
    All these reactors are primarily fuelled by TRISO (tri iso-structural) coated particles. The aim however is to build future nuclear fuel cycles in concert with ...
  87. [87]
    Implications for water chemistry control in a GEN IV supercritical ...
    The SCWR can be considered a hybrid between an LWR and a fossil-fired SCW power plant. As in an LWR, any chemical species that enter the coolant from the heat ...
  88. [88]
    Investigation of polonium removal systems for lead-bismuth cooled ...
    Aug 7, 2025 · The alkaline extraction method is being investigated as a method to remove polonium (Po) from a lead-bismuth (Pb-Bi) cooled reactor.
  89. [89]
    [PDF] IAEA TECDOC SERIES
    Pyroprocessing with metal electrorefining has been successfully applied since the 1980s to treat spent metal fuels used in FFTF and EBR-II reactors for ...
  90. [90]
    [PDF] Gas-cooled Reactors and Industrial Heat Applications
    Jun 16, 2022 · ... TRISO fuel particles provides a stable and robust barrier that confines fission products within the fuel particles. This allows for long ...
  91. [91]
    (PDF) Advanced Nuclear Reactors—Challenges Related to the ...
    Oct 10, 2025 · Generation IV reactors are intended to play a significant role in reaching a fully closed cycle. At the same time, we can observe the growing ...