Enhancement of D-T Reaction Rate due to D-T Contact
スポンサーリンク
概要
- 論文の詳細を見る
The reaction rate that is appropriate for magnetized nonuniform plasma is numerically calculated to investigate the enhancement of the D-T reaction rate. Spatial separation of the guiding center distributions of D and T enhances the reaction rate. Cases of several guiding center configurations are investigated. The largest enhancement is obtained, when both guiding center distributions are δ-functions which are separated by a length that corresponds to the Gamow peak energy. As compared with the case of no separation of D and T, the maximum enhancing factors obtained are 2.3 for total reaction rate and 1.6 for local reaction rate. Cases of the guiding center distributions with finite widths are also investigated.
- 核融合科学研究所の論文
著者
-
Aono Osamu
Research Information Center, Institute of Plasma Physics, Nagoya University
-
Ogasawara Masatada
Research Information Center Institute Of Plasma Physics Nagoya University:faculty Of Science And Eng
-
Hitoki Shigehisa
Mitsubishi Electric Corporation
-
Hitoki Shigehisa
Research Information Center, Institute of Plasma Physics, Nagoya University
-
Aono Osamu
Research Information Center Institute Of Plasma Physics Nagoya University:department Of Physics Jich
-
Ogasawara Masatada
Research Information Center Institute Of Plasma Physics Nagoya University
-
Aono Osamu
Department of Physics, Jichi Medical School
関連論文
- Phenomenological Equations for Reacting Fluids
- Effects of Impurity Ions on the Anomalous Diffusion due to the Dissipative Trapped Ion Instability
- Relation between Weibel Instability and Magnetic Field Generating Thermal Instability
- Stabilization of Rayleigh-Taylor Instability due to the Spontaneous Magnetic Field in Laser Produced Plasma
- Unified Theory of Relaxations in Plasmas
- Enhancement of D-T Reaction Rate in Nonuniform Magnetoplasma
- Enhancement of D-T Reaction Rate due to D-T Contact
- Effects of Nuclear Fusion Reaction on Diffusion and Thermal Conduction in a Magnetoplasma
- Quantum Effects on the Temperature Relaxation in Plasmas
- Rotation of a Magnetic Field
- Trapped-Ion Anomalous Diffusion Coefficient on the Basis of Single Mode Saturation
- Numerical Investigation of Saturation Mechanism of the Dissipative Trapped Ion Instability
- Mixing Length Hypothesis in the Dissipative Trapped Ion Instability
- Heat Flux in the Presence of Shifting Cold and Hot Electron Maxwellian Distributions