TAE has spent over 20 years working to develop and distribute the cleanest, most sustainable energy source of all time. Our unique approach combines plasma physics and accelerator physics for a brand new pathway to fusion power. Read about our top breakthroughs, and browse the entire research library for over 350 posters and papers published in the world’s leading peer-reviewed journals.
February 2023 | R. Magee | Nature Communications | Paper
Proton-boron (p11B) fusion is an attractive potential energy source but technically challenging to implement. Developing techniques to realize its potential requires first developing the experimental capability to produce p11B fusion…
October 2021 | H. Gota | Nuclear Fusion | Paper
TAE Technologies, Inc. (TAE) is pursuing an alternative approach to magnetically confined fusion, which relies on field-reversed configuration (FRC) plasmas composed of mostly energetic…
March 2019 | R.M. Magee | Nature Physics | Paper
Efficiently heating a magnetically confined plasma to thermonuclear temperatures remains a central issue in fusion energy research. One well-established technique is to inject beams of neutral particles into the plasma, a process known as neutral beam injection.
February 2018 | J.A. Romero | Nature Communications | Paper
Active control of field reversed configuration (FRC) devices requires a method to determine the flux surface geometry and dynamic properties of the plasma during both transient and steady-state conditions.
November 2017 | H. Gota | Nuclear Fusion | Paper
The TAE Technologies experimental program has demonstrated reliable field-reversed configuration (FRC) formation and sustainment, driven by fast ions via high-power neutral-beam (NB) injection.
July 2017 | E. A. Baltz | Scientific Reports | Paper
TAE and Google have partnered to combine human and machine interaction to further plasma science using their “Optometrist Algorithm.”
December 2016 | L. Schmitz | Nature Communications | Paper
An economic magnetic fusion reactor favours a high ratio of plasma kinetic pressure to magnetic pressure in a well-confined, hot plasma with low thermal losses across the confining magnetic field.
May 2015 | M. Binderbauer | Physics of Plasmas | Paper
Conventional field-reversed configurations (FRCs), high-beta, prolate compact toroids embedded in poloidal magnetic fields, face notable stability and confinement concerns.
October 2019 | S. A. Galkin | APS-DPP | Poster
A current-vorticity MHD model and code have been developed for FRC plasma control applications in the C-2W device [1]. The model uses a flexible filtering…
June 2019 | C.K. Lau | Nuclear Fusion | Paper
Recent local simulations of the field-reversed configuration (FRC) have reported drift-wave stability in the core and instability in the scrape-off layer (SOL). However, experimental measurements indicate the existence of fluctuations in both FRC core and SOL, with much lower amplitude fluctuations measured in the core.
June 2019 | S.V. Putvinski | Nuclear Fusion | Paper
Fusion reactivity for the pB11 fuel has been reassessed for magnetic confinement devices. This study is based on two factors: new measurements of the fusion reaction cross-sections and an accounting of the kinetic effects that lead to the increase of the number of protons at higher energies (with respect to a pure Maxwellian).
June 2019 | T. Asai | Nuclear Fusion | Paper
Collisional merging formation of field-reversed configurations (FRCs) at super Alfvénic velocity have been successfully initiated in the FAT-CM device at Nihon University. It is experimentally evidenced that the quiescent FRC profile is formed in a self-organizational manner after distructive disturbances by the super Alfvénic collision of two translated magnetized plasmoids.
June 2019 | H. Gota | Nuclear Fusion | Paper
TAE Technologies’ research is devoted to producing high temperature, stable, long-lived field-reversed configuration (FRC) plasmas by neutral-beam injection (NBI) and edge biasing/control.
April 2019 | A.Necas | 2019 Sherwood Fusion Theory | Poster
TAE Technologies, Inc, has an active fusion plasma research program centered around the FRC (Field Reversed Configuration) magnetic topology and the existing C-2W (aka Norman) experiment.
April 2019 | J. Bao | Physics of Plasmas | Paper
Global properties of drift waves in the beam driven FRC, the C2-U device, in which the cen- tral FRC and its SOL plasma are connected with the formation sections and divertors.
April 12, 2019 | T. Tajima | Paper
We introduce a method of transmutation of spent radioactive nuclei in a liquid molten salt solution with fusion neutrons through a series of energy enhancements from accelerated deuterons via fusion to fission. This method is a part of the partitioning & transmutation (P&T) approach for the disposal of spent nuclear fuel where P&T enables the reduction of duration and volume of the spent nuclear fuel storage.
April 2019 | M. Navarro | Fusion Science and Technology | Paper
Our recent studies have shown that graphene can act as a resistant layer against plasma exposure and ion bombardment.
March 2019 | R.M. Magee | Nature Physics | Paper
Efficiently heating a magnetically confined plasma to thermonuclear temperatures remains a central issue in fusion energy research. One well-established technique is to inject beams of neutral particles into the plasma, a process known as neutral beam injection.
October 2018 | T. Roche | APS-DPP | Poster
The experimental goals of the C-2W program are to demonstrate the ability to heat and maintain a field-reversed configuration (FRC) plasma to a total temperature of several keV for a period of 30 ms.
October 2018 | B. Scott Nicks | APS-DPP | Poster
Beam-driven ion-Bernstein mode seen theoretically, exhibits wakefield character that creates similar large fast ion tail and fusion enhancement
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