The importance of laser wavelength for driving inertial confinement fusion targets. I. Basic physics

We reinvestigate the role that laser wavelength plays in driving inertial confinement fusion (ICF) targets. Different assumptions underlie previous analytic frameworks that provide predictions for wavelength scaling of many important target parameters. These are explored and compared to radiation-hy...

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Bibliographic Details
Published in:Physics of plasmas 2023-01, Vol.30 (1)
Main Authors: Schmitt, Andrew J., Obenschain, Stephen P.
Format: Article
Language:English
Subjects:
Argon
Excimer lasers
Excimers
Glass lasers
Inertial confinement fusion
Magnetohydrodynamic stability
Neodymium lasers
Plasma physics
Wavelengths
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Summary:We reinvestigate the role that laser wavelength plays in driving inertial confinement fusion (ICF) targets. Different assumptions underlie previous analytic frameworks that provide predictions for wavelength scaling of many important target parameters. These are explored and compared to radiation-hydrodynamics simulations of laser-driven targets. We are particularly interested here in lasers with wavelengths between 0.193   μ m [wavelength of the Argon Flouride (ArF) excimer laser] and 0.527   μ m (the frequency-doubled glass Nd:glass laser). Short-wavelength drivers have significant advantages for directly driven ICF targets, which are summarized here. We show that constraints such as providing a certain pressure or avoiding laser-plasma instability thresholds allow shorter laser wavelengths to provide energy savings, pressure enhancements, and/or higher hydrodynamic efficiencies. We also consider potential disadvantages, such as increased laser imprint or exposure to the Landau–Darrieus instability. These are shown to be either minor and/or can be easily remediated.
ISSN:1070-664X
1089-7674
DOI:10.1063/5.0118080