English

An effective electrostatic-confinement based fusion approach

Plasma Physics 2013-07-02 v1

Abstract

The paper reports a new electrostatic-confinement based fusion approach, where, a new non-equilibrium distribution function for an ion-beam, compressed by an external electric force, has been derived. This distribution function allows the system to possess appreciably low and insignificant thermal energy irrespective of the energy per particle. The spread in the energy among the particles is attributed to the collisions in presence of the external force, whereas; for equilibrium, the spreading in energy is due to the absence of the force. The reactivity for a deuterium-deuterium fusion, using the proposed distribution function, has been computed. It is shown that the fusion time is comparable to the energy confinement time, collision time and transit time of the ion for beam energy greater than 160 keV. The estimated energy gain Q (ratio of fusion power to the power consumed by the system) is around 10 for beam energy 160 keV and ion density 1018 cm-3. The energy loss due to particle scattering is estimated and is taken into consideration in the estimation of energy gain. An outline of a possible device is proposed according to the model and is not similar to conventionally used in IEC systems based on collisions of the beam with a reflex beam or with background gas or plasma.

Keywords

Cite

@article{arxiv.1307.0151,
  title  = {An effective electrostatic-confinement based fusion approach},
  author = {R. K. Paul},
  journal= {arXiv preprint arXiv:1307.0151},
  year   = {2013}
}

Comments

27 pages, 6 figures

R2 v1 2026-06-22T00:43:02.140Z