Tom Neiser scite author profile

Tom Neiser

3Publications

29Citation Statements Received

280Citation Statements Given

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196

258

Affiliations

General Atomics (United States), University of California, Los Angeles, Oak Ridge Associated Universities

Publications

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Gyrokinetic GENE simulations of DIII-D near-edge L-mode plasmas

Neiser

Jenko

Carter

et al. 2019

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We present gyrokinetic simulations with the GENE code addressing the near-edge region of an L-mode discharge in the DIII-D tokamak. At radial position ρ = 0.80, we find that radial ion transport is nonlinearly quenched by a strong poloidal zonal flow with a clear Dimits shift. Simulations with the ion temperature gradient increased by ∼ 40% above the nominal value give electron and ion heat fluxes that are in simultaneous agreement with the experiment. This gradient increase is within the uncertainty of the Charge Exchange Recombination (CER) diagnostic measurements at the 1.6σ level. Multi-scale simulations are carried out with realistic mass ratio and geometry for the first time in the near-edge. These suggest that highly unstable ion temperature gradient driven modes of the flux-matched ion-scale simulations strongly suppress electron-scale transport, such that ion-scale simulations are sufficient at this location. At radial position ρ = 0.90, simulations reproduce the total experimentally inferred heat flux with the inclusion of E × B shear effects and with an increase in the electron temperature gradient by ∼ 25%. This gradient increase is compatible with the experimental uncertainty in the measured electron temperature via Thomson scattering. These results are consistent with previous findings that gyrokinetic simulations are able to reproduce the experimental heat fluxes of near-edge L-mode plasmas by varying input parameters within their experimental uncertainties.

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DIII-D research advancing the physics basis for optimizing the tokamak approach to fusion energy

et al. 2022

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DIII-D physics research addresses critical challenges for the operation of ITER and the next generation of fusion energy devices. This is done through a focus on innovations to provide solutions for high performance long pulse operation, coupled with fundamental plasma physics understanding and model validation, to drive scenario development by integrating high performance core and boundary plasmas. Substantial increases in off-axis current drive efficiency from an innovative top launch system for EC power, and in pressure broadening for Alfven eigenmode control from a co-/counter-I p steerable off-axis neutral beam, all improve the prospects for optimization of future long pulse/steady state high performance tokamak operation. Fundamental studies into the modes that drive the evolution of the pedestal pressure profile and electron vs ion heat flux validate predictive models of pedestal recovery after ELMs. Understanding the physics mechanisms of ELM control and density pumpout by 3D magnetic perturbation fields leads to confident predictions for ITER and future devices. Validated modeling of high-Z shattered pellet injection for disruption mitigation, runaway electron dissipation, and techniques for disruption prediction and avoidance including machine learning, give confidence in handling disruptivity for future devices. For the non-nuclear phase of ITER, two actuators are identified to lower the L–H threshold power in hydrogen plasmas. With this physics understanding and suite of capabilities, a high poloidal beta optimized-core scenario with an internal transport barrier that projects nearly to Q = 10 in ITER at ∼8 MA was coupled to a detached divertor, and a near super H-mode optimized-pedestal scenario with co-I p beam injection was coupled to a radiative divertor. The hybrid core scenario was achieved directly, without the need for anomalous current diffusion, using off-axis current drive actuators. Also, a controller to assess proximity to stability limits and regulate β N in the ITER baseline scenario, based on plasma response to probing 3D fields, was demonstrated. Finally, innovative tokamak operation using a negative triangularity shape showed many attractive features for future pilot plant operation.

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Fermi Degenerate Antineutrino Star Model of Dark Energy

Neiser

2020

Advances in Astronomy

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When the Large Hadron Collider resumes operations in 2021, several experiments will directly measure the motion of antihydrogen in free fall for the first time. Our current understanding of the universe is not yet fully prepared for the possibility that antimatter has negative gravitational mass. This paper proposes a model of cosmology, where the state of high energy density of the big bang is created by the collapse of an antineutrino star that has exceeded its Chandrasekhar limit. To allow the first neutrino stars and antineutrino stars to form naturally from an initial quantum vacuum state, it helps to assume that antimatter has negative gravitational mass. This assumption may also be helpful to identify dark energy. The degenerate remnant of an antineutrino star can today have an average mass density that is similar to the dark energy density of the ΛCDM model. When in hydrostatic equilibrium, this antineutrino star remnant can emit isothermal cosmic microwave background radiation and accelerate matter radially. This model and the ΛCDM model are in similar quantitative agreement with supernova distance measurements. Therefore, this model is useful as a purely academic exercise and as preparation for possible future discoveries.

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Tom Neiser

Gyrokinetic GENE simulations of DIII-D near-edge L-mode plasmas

DIII-D research advancing the physics basis for optimizing the tokamak approach to fusion energy

Fermi Degenerate Antineutrino Star Model of Dark Energy

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