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Vard research project shows feasibility of nuclear-powered DP vessels

Study, called NuProShip II, confirmed that, with validated assumptions and supplier data, nuclear-powered DP vessels are achievable.

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Vard research project shows feasibility of nuclear-powered DP vessels

VARD, a subsidiary of the Fincantieri Group, on Monday (26 January) presented results of the research and innovation project NuProShip II. 

NuProShip II marked a significant milestone in the development of sustainable marine technology, exploring the integration of small 4th generation nuclear reactors into specialised offshore vessels.

The groundbreaking project NuProShip II, short for “Nuclear Propulsion in merchant Shipping” demonstrated the technical feasibility of nuclear-powered dynamically positioned (DP) vessels, researching the possibility of nuclear reactors contributing to efficiency, reliability, and environmental responsibility for the maritime industry.

VARD, the Norwegian subsidiary of the Fincantieri Group, has recently finalised one of their main contributions to the NuProShip II project; the development of a concept design for a nuclear-powered construction vessel based on an existing VARD reference concept. The study investigates the feasibility of integrating a helium gas-cooled nuclear reactor as the primary power source and evaluates its implications for vessel layout, safety, and overall system performance. 

The case study is led by Vard Design and conducted in close cooperation with DNV, Emerald Nuclear, Vard Electro, offshore ship owner Island Offshore, and the project leader and our long-term research & innovation partner Norwegian University of Science and Technology (NTNU).

The NuProShip II project proves that the technology on nuclear-powered ships is moving forward, and that VARD – as a part of the Fincantieri Group, and together with the partners in the project – are frontrunners in finding the best solutions through tangible innovation.

The study confirmed that, with validated assumptions and supplier data, nuclear-powered DP vessels are achievable. The integration aligns with the high redundancy required for DP2 power architecture, with possibility to also adapt to DP3 requirements, enhancing operational safety and reliability.

By leveraging advanced reactor concepts, NuProShip II offers the potential for removal of greenhouse gas emissions and extended operations. The project also explores innovative energy storage solutions, such as super-critical CO₂ turbines and thermal battery systems, which could provide power balancing alternatives to conventional electrical batteries.

NuProShip II aims to set new standards for radiological safety and risk management in commercial shipping.

The project will be concluded in 2026 and followed by the SFI SAINT (Sustainable Applied and Industrialised Nuclear Technology) – centre for research-based innovation led by NTNU, where VARD will be one of the key partners.

The national center has received NOK 96 million in funding from the Research Council of Norway to research maritime nuclear technology. In-kind contributions from industry, including Vard, amount to about NOK 200 million. The center will operate for eight years starting in January 2026.

 

Photo credit: Vard
Published: 30 January, 2026

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LR: Rotterdam study sets out pathway for nuclear-powered commercial ship port calls

New joint study has found that existing port safety and risk-management frameworks could provide a credible starting point for assessing nuclear-powered ship calls within a major European port environment.

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RESIZED Shaah Shahidh on Unsplash

A new joint study using the Port of Rotterdam as a case study has found that existing port safety and risk-management frameworks could provide a credible starting point for assessing nuclear-powered commercial ship calls within a major European port environment, according to Lloyd’s Register (LR) on Thursday (11 June). 

The desktop study, Enabling Nuclear-Powered Feeder Ships: A Joint Development Project on Port Call Feasibility and Regulatory Pathways, carried out through a joint development project involving LR, the Port of Rotterdam Authority, CORE POWER and A.P. Moller – Maersk, sets out the questions that ports, regulators and industry would need to answer in order to assess nuclear-powered vessels in a structured and responsible way. 

It also identified further work that would be required before routine operation could be contemplated, including regulatory alignment, emergency preparedness, security, liability and public engagement.

Its publication comes at a time of growing pressure on the shipping industry to identify even more scalable zero-emission technologies capable of meeting increasingly demanding decarbonisation requirements while preserving operational reliability, endurance and flexibility.

The report argued that maritime nuclear propulsion should be evaluated as part of the wider discussion around shipping decarbonisation, energy resilience and long-term industrial competitiveness.

While much of the current EU policy discussion has focused on alternative fuels such as hydrogen, ammonia and e-fuels, the report notes that segments of global shipping may ultimately require additional propulsion solutions capable of supporting endurance, reliability and operational flexibility at scale.

The Port of Rotterdam participated as a case study because it provides a real-world European port environment through which to examine how emerging energy and shipping technologies could interact with existing port safety frameworks, operations and regulatory processes.

Importantly, the study concluded that existing risk-based port safety frameworks already familiar to European ports could provide a credible starting point for assessing nuclear-powered vessels, provided nuclear-specific safety, security and operational considerations are systematically integrated and supported by appropriate national and international guidance.

The findings suggested that the real challenge for future maritime nuclear propulsion is likely to centre on regulatory alignment, governance, integration between nuclear and maritime safety regimes, and public and institutional preparedness.

The study identifies several key findings:

  • Existing port safety and risk-management frameworks provide a credible starting point for the assessment of nuclear-powered commercial vessels within the defined case study scenario.
  • Further work is needed on regulatory alignment, governance coordination, nuclear-specific safety and security, emergency preparedness, liability and insurance, operational integration and public engagement before routine commercial operation could be contemplated.
  • Current IMO provisions relating to nuclear-powered ships were developed for an earlier era and require modernisation to support any future civil commercial nuclear propulsion pathway.
  • Current European maritime decarbonisation discussions remain heavily focused on alternative fuels, with comparatively limited consideration of high-density, zero-emission propulsion systems capable of supporting long-range and high-utilisation shipping operations.
  • Major ports and maritime Member States may play an important role in shaping how nuclear propulsion is assessed and potentially integrated into future shipping strategies.

 

Photo credit: Shaah Shahidh on Unsplash
Published: 16 June, 2026

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South Korean-led nuclear car carrier design secures LR backing

LR is working with HHI, KSOE, Hyundai Glovis, G- Marine Service and KAERI on a joint development project exploring an advanced small modular reactor (SMR) installation on a PCTC.

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South Korean-led nuclear car carrier design secures LR backing

Classification society Lloyd’s Register (LR) on Tuesday (2 June) said it has teamed up with South Korean shipbuilding, marine services and nuclear research organisations to advance the development of a nuclear‑assisted car carrier concept. 

LR is working with Hyundai Heavy Industries, Korea Shipbuilding & Offshore Engineering (KSOE), Hyundai Glovis, G- Marine Service and the Korea Atomic Energy Research Institute (KAERI) on a joint development project (JDP) exploring an advanced small modular reactor (SMR) installation on a pure car and truck carrier (PCTC). 

The study focused on how a Molten Salt Reactor (MSR) could be physically and operationally integrated into a large vehicle carrier. Work examined the internal arrangement and segregation of the reactor system, shielding requirements, and the impact on cargo deck layout and vehicle capacity, alongside stability and trim implications linked to the reactor’s weight and positioning. 

The partners also assessed propulsion system configuration and power delivery, as well as operational flexibility compared with conventionally fuelled PCTCs, where trade routes and port calls can be tightly constrained. 

A key focus of the project has been safety. LR led hazard identification (HAZID) and preliminary risk assessment work, focusing on containment, onboard safety systems and potential operability constraints tied to nuclear technology at sea. 

The partners will mark the project milestone with an Approval in Principle (AiP) granting ceremony on 2 June at the LR stand during Posidonia 2026. 

Sung-Gu Park, President – North East Asia, Lloyd’s Register, said: “While nuclear propulsion is still at an early stage of development, this project shows the importance of building technical understanding now to support future progress. 

“Establishing feasibility at concept stage is a valuable step forward, particularly in areas such as cargo optimisation, vessel stability and integrated safety design.” 

Hong-Ryeul Ryu, CTO and Senior Executive Vice President at HD HHI, said: “With global environmental regulations becoming increasingly stringent and no definitive net-zero fuel yet available, SMR-powered ships can serve as a highly effective alternative, representing a pioneering next-generation maritime technology capable of complying with GHG emission regulations while allowing lifetime operation without refuelling, and HD HHI will remain at the forefront of sustainable maritime technology development.”

 

Photo credit: Lloyd’s Register
Published: 4 June, 2026

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ABS and HD Hyundai team up on nuclear-powered electric propulsion systems for boxships

Agreement forms a framework to assess the technical feasibility of a nuclear-powered electric propulsion system specific to a 16K TEU container ship.

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ABS and HD Hyundai team up on nuclear-powered electric propulsion systems for boxships

Classification society ABS on Monday (9 March) said it signed a joint development project (JDP) for the conceptual design of a nuclear-powered electric propulsion system with HD Korea Shipbuilding & Offshore Engineering (HD KSOE) and HD Hyundai Samho Heavy Industries (HD HSHI).

The agreement forms a framework to assess the technical feasibility of a nuclear-powered electric propulsion system specific to a 16K TEU container ship.

“This project represents an important step in exploring the potential of a nuclear-powered electric propulsion system for container vessels. By combining HD Hyundai’s shipbuilding expertise with ABS’ deep engineering experience in maritime safety, we aim to evaluate technologies that can support safer, more efficient and lower-emission operations for the next generation of propulsion solutions,” said Matthew Mueller, ABS Vice President, North Pacific Business Development.

Kwon Byung-hun, Head of the Electrification Center at HD KSOE, said: “In response to the growing demand for eco-friendly ships, we are continuously pursuing the development of electric propulsion systems using nuclear energy—a carbon-free energy source. We will expand our R&D efforts to strengthen our technological competitiveness in nuclear-linked electric propulsion.”

Under the agreement, HD KSOE and HD HSHI will develop the basic design, electrical component specifications and arrangement plans for a nuclear-powered electric propulsion system tailored for container ships.

 

Photo credit: ABS
Published: 10 March, 2026

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