First measurements of p11B fusion in a magnetically confined plasma

R M Magee; K Ogawa; T Tajima; I Allfrey; H Gota; P McCarroll; S Ohdachi; M Isobe; S Kamio; V Klumper; H Nuga; M Shoji; S Ziaei; M W Binderbauer; M Osakabe

doi:10.1038/s41467-023-36655-1

First measurements of p¹¹B fusion in a magnetically confined plasma

Nat Commun. 2023 Feb 21;14(1):955. doi: 10.1038/s41467-023-36655-1.

Authors

R M Magee¹, K Ogawa², T Tajima^{3

4}, I Allfrey³, H Gota³, P McCarroll³, S Ohdachi², M Isobe², S Kamio^{3

4}, V Klumper^{3

4}, H Nuga², M Shoji², S Ziaei³, M W Binderbauer³, M Osakabe²

Affiliations

¹ TAE Technologies, Inc., Foothill Ranch, CA, USA. RMagee@TAE.com.
² National Institute for Fusion Science, Toki, Japan.
³ TAE Technologies, Inc., Foothill Ranch, CA, USA.
⁴ University of California-Irvine, Irvine, CA, USA.

Abstract

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 in the magnetically-confined, thermonuclear plasma environment. Here we report clear experimental measurements supported by simulation of p¹¹B fusion with high-energy neutral beams and boron powder injection in a high-temperature fusion plasma (the Large Helical Device) that have resulted in diagnostically significant levels of alpha particle emission. The injection of boron powder into the plasma edge results in boron accumulation in the core. Three 2 MW, 160 kV hydrogen neutral beam injectors create a large population of well-confined, high -energy protons to react with the boron plasma. The fusion products, MeV alpha particles, are measured with a custom designed particle detector which gives a fusion rate in very good relative agreement with calculations of the global rate. This is the first such realization of p¹¹B fusion in a magnetically confined plasma.