Researchers used the Omega Laser Facility at the Rochester’s Laboratory for Laser Energetics to make highly detailed measurements of laser-heated plasmas. Credit: University photo / J. Adam Fenster
New research from the University of Rochester will enhance the accuracy of computer models used in simulations of laser-driven implosions. The research, published in the journal Nature Physics, addresses one of the challenges in scientists’ longstanding quest to achieve fusion.
In laser-driven inertial confinement fusion (ICF) experiments, such as the experiments conducted at the University of Rochester’s Laboratory for Laser Energetics (LLE), short beams consisting of intense pulses of light—pulses lasting mere billionths of a second—deliver energy to heat and compress a target of hydrogen fuel cells. Ideally, this process would release more energy than was used to heat the system.
Laser-driven ICF experiments require that many laser beams propagate through a plasma—a hot soup of free moving electrons and ions—to deposit their radiation energy precisely at their intended target. But, as the beams do so, they interact with the plasma in ways that can complicate the intended result.
“ICF necessarily generates environments in which many laser beams overlap in a hot plasma surrounding the target, and it has been recognized for many years that the laser beams can interact and exchange energy,” says David Turnbull, an LLE scientist and the first author of the paper.
To accurately model this interaction, scientists need to know exactly how the energy from the laser beam interacts with the plasma. While researchers have offered theories about the ways in which laser beams alter a plasma, none has ever before been demonstrated experimentally.
Now, researchers at the LLE, along with their colleagues at Lawrence Livermore National Laboratory in California and the Centre National de la Recherche Scientifique in France, have directly demonstrated for the first time how laser beams modify the conditions of the underlying plasma, in turn affecting the transfer of energy in fusion experiments.
“The results are a great demonstration of the innovation at the Laboratory and the importance of building a solid understanding of laser-plasma instabilities for the national fusion program,” says Michael Campbell, the director of the LLE.
USING SUPERCOMPUTERS TO MODEL FUSION
Researchers often use supercomputers to study the implosions involved in fusion experiments. It is important, therefore, that these computer models accurately depict the physical processes involved, including the exchange of energy from the laser beams to the plasma and eventually to the target.
For the past decade, researchers have used computer models describing the mutual laser beam interaction involved in laser-driven fusion experiments. However, the models have generally assumed that the energy from the laser beams interacts in a type of equilibrium known as Maxwellian distribution—an equilibrium one would expect in the exchange when no lasers are present.
“But, of course, lasers are present,” says Dustin Froula, a senior scientist at the LLE.
Froula notes that scientists predicted almost 40 years ago that lasers alter the underlying plasma conditions in important ways. In 1980, a theory was presented that predicted these non-Maxwellian distribution functions in laser plasmas due to the preferential heating of slow electrons by the laser beams. In subsequent years, Rochester graduate Bedros Afeyan ’89 (Ph.D.) predicted that the effect of these non-Maxwellian electron distribution functions would change how laser energy is transferred between beams.
But lacking experimental evidence to verify that prediction, researchers did not account for it in their simulations.
Turnbull, Froula, and physics and astronomy graduate student Avram Milder conducted experiments at the Omega Laser Facility at the LLE to make highly detailed measurements of the laser-heated plasmas. The results of these experiments show for the first time that the distribution of electron energies in a plasma is affected by their interaction with the laser radiation and can no longer be accurately described by prevailing models.
The new research not only validates a longstanding theory, but it also shows that laser-plasma interaction strongly modifies the transfer of energy.
“New inline models that better account for the underlying plasma conditions are currently under development, which should improve the predictive capability of integrated implosion simulations,” Turnbull says.
David Turnbull et al, Impact of the Langdon effect on crossed-beam energy transfer, Nature Physics (2019). DOI: 10.1038/s41567-019-0725-z
When laser beams meet plasma: New data addresses gap in fusion research (2019, December 2)
retrieved 3 December 2019
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