On a fusion chain reaction via suprathermal ions in high-density H-11B plasma

The B-11(p,3 alpha) fusion reaction is particularly attractive for energy production purposes because of its aneutronic character and the absence of radioactive species among reactants and products. Its exploitation in the thermonuclear regime, however, appears to be prohibitive due to the low reactivity of the H-B-11 fuel at temperatures up to 100 keV. A fusion chain sustained by elastic collisions between the alpha particles and fuel ions, this way scattered to suprathermal energies, has been proposed as a possible route to overcome this limitation. Based on a simple model, this work investigates the reproduction process in an infinite, non-degenerate H-B-11 plasma, in a wide range of densities and temperatures which are of interest for laser-driven experiments (10(24)less than or similar to ne less than or similar to 10(28) cm(-3), Te less than or similar to 100 keV Ti similar to 1 keV). In particular, cross section data for the alpha-p scattering which include the nuclear interaction have been used. The multiplication factor, k infinity, increases markedly with electron temperature and less significantly with plasma density. However, even at the highest temperature and density considered, and despite a more than twofold increase by the inclusion of the nuclear scattering, k(infinity) turns out to be of the order of 10(-2) only. In general, values of k(infinity) very close to 1 are needed in a confined scheme to enhance the suprathermal-to-thermonuclear energy yield by factors of up to 10(3) or 10(4).

Automated summary

The study explores the potential of the B-11(p,3 alpha) fusion reaction in thermonuclear reactions, finding that elastic collisions are necessary to increase reactivity and overcome temperature limitations. Results show that even at high temperatures and densities, the multiplication factor remains low, limiting the energy yield.