A new class of Fusion Reactor

Our novel multi-state fusion reactors are the result of a quarter-century of engineering design, over 15 years of combined runtime and the latest understanding of stellar physics.

Unlocking orders of magnitude higher performance

Our systems produce two distinct fusion reactions in parallel with a single power input; fusion occurs in both the plasma and the solid-state lattice. We call this novel reactor design Multi-State Fusion.

Through harnessing our latest understanding of stellar physics, we have already demonstrated the ability to increase the total fusion rate of our reactors by over an order of magnitude. This is achieved by improving upon a TRL 9 reactor architecture by using proprietary methods to introduce fusion fuel into the solid plasma-facing internal components; TRL 6.

By utilising lattice confinement fusion (LCF), a process validated by NASA in 2021, our reactor design achieves solid-state fuel densities 400 million times higher than those achievable in the plasma.

We do more with less

Our reactor design benefits from an electron-screened environment within the core, thereby reducing the energy required to overcome the coulomb barrier between particles. This reduces the required temperatures to induce fusion by several million degrees, allowing for significantly higher performance in a compact form factor.

Solid state fuel densities 400 million times higher than in our sun

Unparalleled performance in a compact system

By utilising lattice confinement fusion (LCF), a process validated by NASA in 2021, our reactor design achieves significantly higher solid-state fuel densities than those achievable in plasma.

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From Theory to Real World Applications

Over the years, Astral Neutronics has steadily advanced its Multi-State Fusion (MSF) technology, turning groundbreaking theory into a solution that delivers the promise of fusion already today.

2020

Theory & Simulations

The first Multi-State fusion reactor is theorised, and detailed simulations and design analysis of combining LCF and IEC technologies indicate a significant performance gain.

2021

First Prototype

Our first prototype reactor, built in the UK, demonstrated a 36% increase in reactor performance with limited fusion fuel enrichment in the solid state.

2022

Second Round of Prototypes

The second round of prototypes, tested in partnership with the University of Bristol, yielded in excess of an order of magnitude increase in fusion performance. This allows us to confidently produce greater than 100 billion DT fusions per second within a compact commercial architecture.

2023

Verified Performance

Third round of prototypes being tested at Astral's facility in the UK with members from external independent institutions verifying fusion performance. This allows us to confidently produce greater than 1 trillion DT fusions per second within a commercial architecture. The performance is highly relevant to our approach to decentralized medical isotope production.

2024 forward

A wide range of applications and capabilities

As we progress the fusion rate of our technology, aiming to exceed 10 trillion DT fusions per second per system, we unlock a wide range of applications and capabilities, such as large-scale medical isotope production, fusion neutron materials damage testing, transmutation of existing nuclear waste stores, space applications, hybrid fusion-fission power systems, and beyond.

Unlock the power of multi-state fusion

Contact us to learn how you can work with us and get access to our reliable and high-performance compact fusion reactors and isotope production for your organisation.