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.
January 2017 | GOTA Hiroshi | The Journal of the Japan Society of Plasma Science and Nuclear Fusion Research | Paper
TAE Technologies is one of the companies that conduct fusion research in the entrepreneurial approach. It is often asked why and how such research in the large scale and long range may be carried out based on private funds. English version included.
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.
November 2016 | J. Romero | APS-DPP | Presentation
Method to infer the FRC separatrix geometry and axial stability properties of the equilibrium developed. Tested with equilibrium code simulations
November 2016 | Artem Smirnov | CAARI | Presentation
Neutral beam-driven field reversed configuration offers reactor advantages.
October 2016 | M. Beall | APS-DPP | Poster
Upgraded interferometer/polarimeter on center plane of machine to provide high resolution density and magnetic field information.
October 2016 | I. Allfrey | APS-DPP | Poster
Fusion plasmas require long lifetimes and high temperatures, both of which are limited by particle loss, among other factors.
October 2016 | Dima Osin | APS-DPP | Poster
C-2U is a macroscopically stable, high-performance field-reversed configuration (HPF), where high plasma temperatures with significant fast-ion population and record lifetimes were achieved.
October 2016 | L. Steinhauer | APS-DPP | Poster
The C-2U facility at TAE Technologies creates an advanced, beam-driven FRC with large ion orbits. The plasma is sustained for > 5ms.
October 2016 | Francesco Checcerini | APS-DPP | Poster
The goal of TAE’s experiments is to sustain through the of use of neutral beam heating and edge biasing an advanced beam-driven FRC for many milliseconds, i.e., well beyond the growth times of common instabilities.
October 2016 | Nathan Bolte | APS-DPP | Poster
In the TAE Technologies C-2U experiment, advanced beam-driven field-reversed configuration (FRC) plasmas were sustained via tangential neutral beam injection.
October 2016 | R. Clary | APS-DPP | Poster
C-2U is an advanced beam-driven FRC experiment. Dynamics of fast particles (hydrogen) are critical to plasma (deuterium) performance.
October 2016 | T. Roche | APS-DPP | Poster
Complete radial profiles of plasma parameters are essential in understanding plasma dynamics.
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