Compressive hydrodynamic fluctuations amplify fusion power in plasmas via hydrodynamic, two-temperature, and kinetic mechanisms, often exceeding the gain from using the same energy for heating.
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Applies direct-adjoint eigenmode analysis and biorthogonal decomposition to quantify how a reacting base state modifies Kelvin-Helmholtz instability receptivity in a compressible temporal mixing layer.
EnVar assimilation of wall-pressure data from seven sensors is required to accurately predict separation onset and downstream pressures in Mach 6 cone-flare DNS, while upstream sensors alone are insufficient.
citing papers explorer
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Fusion-power amplification by compressive hydrodynamic fluctuations
Compressive hydrodynamic fluctuations amplify fusion power in plasmas via hydrodynamic, two-temperature, and kinetic mechanisms, often exceeding the gain from using the same energy for heating.
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Receptivity and Biorthogonal Decomposition in a Reacting Temporal Mixing Layer
Applies direct-adjoint eigenmode analysis and biorthogonal decomposition to quantify how a reacting base state modifies Kelvin-Helmholtz instability receptivity in a compressible temporal mixing layer.
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Assimilation of wall-pressure measurements in direct numerical simulations of high-speed flow over a cone-flare geometry
EnVar assimilation of wall-pressure data from seven sensors is required to accurately predict separation onset and downstream pressures in Mach 6 cone-flare DNS, while upstream sensors alone are insufficient.