Laser-enhanced nuclear fusion in the multiphoton regime
POSTER
Abstract
Quantum tunneling between fusing nuclei is considered in the presence of a sinusoidal time-varying
external field. The associated nonclassical equation of motion is treated using a Floquet/Volkov (FV)
analysis as well as a Kramers-Henneberger (KH) analysis, which are both compared against a first-
principles numerical solution of Crank-Nicolson (CN) type. Numerical validation of the FV formula
justifies its use in analytical estimates of laser-enhanced reaction rates, while the KH formula fails
to reproduce the predictions of the other methods. For a Deuterium–Tritium (DT) plasma at a
temperature of 1 keV, calculations suggest that significant enhancement of fusion reactivity requires
field strengths on the order of 10^15–10^16 V/m and photon energies on the order of 1 keV. The
enhancement effect is more sensitive to increases in field strength at lower photon energies.
external field. The associated nonclassical equation of motion is treated using a Floquet/Volkov (FV)
analysis as well as a Kramers-Henneberger (KH) analysis, which are both compared against a first-
principles numerical solution of Crank-Nicolson (CN) type. Numerical validation of the FV formula
justifies its use in analytical estimates of laser-enhanced reaction rates, while the KH formula fails
to reproduce the predictions of the other methods. For a Deuterium–Tritium (DT) plasma at a
temperature of 1 keV, calculations suggest that significant enhancement of fusion reactivity requires
field strengths on the order of 10^15–10^16 V/m and photon energies on the order of 1 keV. The
enhancement effect is more sensitive to increases in field strength at lower photon energies.
*DOE Office of Science, Fusion EnergyScience under FWP 100182, as well as from the NationalScience Foundation MPS AGEP Graduate Research Sup-plement.
Presenters
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Martin L Lindsey
- Stanford University