Computation of time energy gain in D-3He mixture: Energy deposited through deuterium ignition beam

Authors

  • S. N. Hosseinimotlagh Islamic Azad University of Shiraz

DOI:

https://doi.org/10.18034/apjee.v1i2.217

Keywords:

Fast Ignition, Deuteron Beam, Energy, Dynamics

Abstract

The fast ignition approach to ICF consists in first compressing the fuel to high density by a suitable driver and then creating the hot spot required for ignition by means of a second external pulse. If the ignition beam is composed of deuterons, an additional energy is delivered to the target with increased energy gain. Therefore ,in this innovative suggestion ,we consider deuterium  beams for fast ignition in D+3Hemixture and solve the dynamical  balance equations under the available  physical conditions by considering a new average reactivity formula ,then we compute the energy gain in this mixture .Our computational results show that we can get energy gain value larger than 4 at resonant temperature (200keV)of D+3Hemixture. We select D+3Hefuel, because D+3Hereaction is very attractive from a theoretical point of view since it does not produced neutrons. The D+3Hebenefits include full-lifetime materials, reduced radiation damage, less activation ,absence of tritium breeding blankets ,highly efficient direct energy conversion, easier maintenance, proliferation resistance.

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Author Biography

  • S. N. Hosseinimotlagh, Islamic Azad University of Shiraz

    Department of Physics, Colleges of Sciences, Islamic Azad University of Shiraz, Iran

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Published

2014-12-31

How to Cite

Hosseinimotlagh, S. N. . (2014). Computation of time energy gain in D-3He mixture: Energy deposited through deuterium ignition beam . Asia Pacific Journal of Energy and Environment, 1(2), 153-168. https://doi.org/10.18034/apjee.v1i2.217

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