New look on nuclear energy
Superior electrical power
- Massive energy in a single plant
- Small in size for near-load location
- Flexible load-following power for grid system stability
- A scalable power plant for high impact deployment
Simplifies green transition
- Works on its own
- Supports intermittent wind and solar
- Replaces gas and coal power backup
- Unburdens hydroRelieves power grid buildout pressure
- A slimmer power system fit for purpose
Supreme strategic autonomy
- No uranium dependence
- Minimum mineral dependence
- Thorium abundance
- A losing game shifts to a winning
Sustainability for real
Disruptive nuclear technology
Thorkraft reactors are not experimental. The molten salt concept has been tested and validated across decades of research. What we've done is take that proven foundation and engineer it for the world that needs it now.
Inherently safer and simpler
Nuclear safety has traditionally depended on human intervention and external factors; passive safety systems remove these variables from the risk equation.
Cleaner and less waste.
Thorium generates significantly fewer long-lived isotopes compared to uranium, reducing the radioactive legacy for future generations. This advantage has been scientifically validated but remains underutilized in commercial reactors.
Proven concept. Verified design. Unique reactor.
Thorium produces substantially fewer long-lived isotopes than uranium, thereby reducing the radioactive legacy for future generations—a demonstrable advantage that has been scientifically validated yet remains largely unexploited in commercial reactors.
From reluctance to advancement.
The power to turn nuclear reluctance into sovereign advancement

Where French expertise meets Norwegian Thorium
Development in France, a world-leading nuclear nation
France has long been a leader in nuclear technology, boasting a comprehensive nuclear value chain that spans research, development, and regulatory excellence. This expertise is now being applied to thorium molten salt reactors, which promise a cleaner and more sustainable future for nuclear energy. By leveraging its advanced infrastructure and skilled workforce, France is well-positioned to drive innovation in this field, setting new standards for safety and efficiency.
Exceptional opportunity and strategic fit for Norway
Norway stands at a pivotal moment in its energy history. With its oil and gas sectors in decline, the country possesses vast thorium reserves and the financial resources necessary to drive a strategic transformation. This presents a unique opportunity for Norway to transition from traditional energy sources to innovative, sustainable solutions, positioning itself as a leader in the global energy landscape.
Norway, comfortably numb?
Norway's heavy reliance on its oil and gas sectors has led to an overabundance of capital without a clear direction for future investments.
This lack of urgency and vision for diversification leaves the country in need of strategic guidance to wisely allocate its resources towards sustainable and innovative energy solutions.
Thorkraft will keep Norway an important energy supplier for millenias to come.
Against the Norwegian current
A development project carried forward by two independent Norwegians
...doing the opposite of what Norway tells innovators to do
not renewables, not conventional nuclear, just...
New support
Nuclear energy has featured prominently in recent Norwegian public discourse, garnering increasing support across society. However, political and regulatory authorities remain appropriately cautious, given that conventional nuclear power generates radioactive waste requiring secure geological disposal for up to 100,000 years. It is indeed prudent to avoid hasty decisions that impose legacy obligations stretching so far into the future.
Our mission
At Thorkraft, we are developing a thorium-based molten salt reactor (MSR) that produces a significantly cleaner waste profile, thereby reducing the requisite storage period to between 300 and 500 years. Furthermore, this reactor is capable of utilizing existing nuclear waste as fuel. By transmuting these long-lived isotopes, the resulting byproducts are remarkably cleaner and possess drastically shorter half-lives. Concurrently, a single such power plant has the capacity to meet the baseload energy demands of an entire region. The fundamental concept is scientifically proven, the design has been rigorously verified, and the reactor technology is uniquely positioned to solve these systemic challenges.

Europe recognises what's next
European investors are building tomorrow's infrastructure with unprecedented ambition and vision. Thorkraft cordially invites you to lead the way, joining a growing community of forward-thinking pioneers who are shaping the future of sustainable development across the continent.

Get in touch
We welcome inquiries from partners, investors, and those who share our vision.
Questions
Everything you need to know about thorium reactors and Thorkraft's technology.
Thorium is three times more abundant than uranium and exists in deposits across every continent. Our molten salt reactors unlock this potential without the geopolitical constraints that have defined energy security for decades.
Safety is engineered into the design itself. Passive systems work without human intervention or external power, and the reactor naturally shuts down if temperatures rise. This represents a fundamental departure from conventional nuclear architecture.
Thorium produces significantly less waste than uranium, with storage requirements measured in centuries rather than millennia. The waste profile is cleaner and far more manageable for future generations.
Yes. Smaller footprints and simpler construction mean reactors can be deployed where conventional plants are impractical. This flexibility is essential for meeting global energy demand without expanding fossil fuel dependence.
We are advancing through development and regulatory pathways now. The timeline depends on partnerships, investment, and regulatory approval, but the technology is proven and ready for deployment.
Molten salt reactors operate at higher temperatures than conventional designs, extracting more energy from less fuel. The chemistry is proven. The engineering is sound. What remains is deployment at scale.
Thorium is three times more abundant than uranium and distributed across every continent, eliminating the geopolitical vulnerabilities that have constrained energy security for decades. Our reactors unlock this potential without compromise. The reserves alone span centuries of operation.
Safety is engineered into the architecture itself. Passive systems function without human intervention or external power, and the reactor naturally shuts down if temperatures rise. This represents a departure from conventional nuclear design that matters.
Thorium produces significantly less waste than uranium, with storage requirements measured in centuries rather than millennia. The waste profile is cleaner and far more manageable for the generations that follow us.
We are advancing through development and regulatory pathways now, with timelines shaped by partnerships, investment, and approval processes. The technology is proven. The question is execution.
