TAE Technologies has pioneered the pursuit one of the cleanest and most economical path to providing electricity with H2-boron (also known as p-B11 or p11B), an abundant, environmentally sound fuel. The company announced, in collaboration with Japan’s National Institute for Fusion Science (NIFS), a noteworthy research advancement: the first-ever H2-boron fusion experiments in a magnetically confined fusion plasma.
In a peer-reviewed paper published by Nature Communications titled, “First measurements of p11B fusion in a magnetically confined plasma”, scientists explain the outcome of the nuclear fusion reaction of H2-boron in an experiment in NIFS’ Large Helical Device (LHD). This paper describes the experimental work of producing the conditions necessary for H2-boron fusion in the LHD plasma and TAE’s development of a detector to make measurements of the H2-boron reaction products: helium nuclei, known as alpha particles. The finding reflects years of collaborative international scientific fusion research and represents a milestone in TAE’s mission to develop commercial fusion power with H2-boron, the cleanest, most cost-competitive and most sustainable fuel cycle for fusion.
“This experiment offers us a wealth of data to work with and shows that H2-boron has a place in utility-scale fusion power. We know we can solve the physics challenge at hand and deliver a transformational new form of carbon-free energy to the world that relies on this non-radioactive, abundant fuel,” said Michl Binderbauer, CEO of TAE Technologies.
TAE is one of the world’s leading and largest private commercial fusion energy company, and this result represents an important step toward development of H2-boron fusion. In layperson’s terms, the company is one step closer to the realization of a fusion power plant that will ultimately produce clean electricity, with only helium, also known as three alpha particles, as a byproduct. These three alpha particles are the hallmark of H2-boron fusion energy, and inspired TAE’s founders to name the company Tri Alpha Energy, now TAE Technologies.
Inventing fusion reactors that produce net energy is one thing, delivering it as a reliable, grid-ready source of electricity is another. By choosing to pursue H2-boron as a fuel cycle, TAE has anticipated the true demands of commercial, daily use of fusion energy. Most fusion efforts around the world are focused on combining H2 isotopes deuterium-tritium (D-T) to use as fuel, and the donut-shaped tokamak machines commonly used in fusion concepts are limited to D-T fuel. Unlike those efforts, TAE’s compact linear design uses an advanced accelerator beam-driven field-reversed configuration (FRC) that is versatile, and can accommodate all available fusion fuel cycles, including p-B11, D-T and deuterium-helium-3 (D-He3 or D3He). This benefit will uniquely enable TAE to license its technology on the way to its goal of connecting the first H2-boron fusion power plant to the grid in the 2030s. With the FRC, TAE is advancing a modular and easy-to-maintain design that will have a compact footprint with the potential to take advantage of a more efficient magnetic confinement methodology, which will get up to 100x more power out, as compared to tokamaks.
As TAE’s colleagues at NIFS note, H2-boron is considered an advanced fusion fuel because it “enable(s) the concept of cleaner fusion reactors. This achievement is a big first step towards the realization of a fusion reactor using advanced fusion fuel.”
As the paper published in Nature Communications puts it: “While the challenges of producing the fusion core are greater for p11B than D-T, the engineering of the reactor will be far simpler. … Stated simply, the p11B path to fusion trades downstream engineering challenges for present day physics challenges. And the physics challenges can be overcome.”
The H2-boron approach is part of TAE's core vision for commercial fusion energy, born of the company’s technology co-founder Dr. Norman Rostoker’s philosophy of keeping the end in mind. This vision for truly clean, abundant, cost-competitive energy is what sets TAE apart from a growing field of fusion companies. While this reaction did not produce net energy, it demonstrates viability of aneutronic fusion and reliance on H2-boron.
TAE expects to demonstrate net energy on its next research reactor, Copernicus, around mid-decade.