Charles E. Knapp scite author profile

In order to maximize the K-line radiation from imploding gas puff loads driven by high current, pulsed power generators such as the DECADE Module 2 (DM2), initial puff diameters of 5-10 cm are required to provide implosion times of 200-300 ns. To date, such implosions have been found to produce lower-than-predicted yields. Lack of uniformity in the initial current flow through the neutral gas is offered as one of the possible reasons. If so, sufficient pre-ionization of the gas should mitigate this problem.A uv source was designed to pre-ionize a 7-cm diameter argon gas puff to be employed on the DM2 generator at Primex Physics International Company. The source is a 19-cm diameter cylinder consisting of two flashboards bent into semi-circles. The flashboard plasma is directed toward the axis of the cylinder which is co-linear with the axis of the gas nozzle. The plane of the flashboard is located 18 cm from the nozzle exit so that the ionizing uv is emitted at 60-80" angles and promptly illuminates the gas while the flashboard plasma arrives at the PRS load region about 4 ps later. The pre-ionization is measured absolutely using a high-sensitivity interferometer with which we can discriminate between phase shifts due to neutral argon and those due to free electrons as a function of space and time. Pre-ionization levels in the I-10% range were measured near the outer edge of the DM2 nozzle rendering this outer layer sufficiently conductive to carry the DM2 current.In addition to the DM2 application, it is anticipated that a version of this uv pre-ionization scheme will be utilized on neon gas puffs driven by the NRL Hawk generator.An innovative fusion scheme, embodying the principles of magnetized target fusion (MTF), in which the initial magnetized target and a plasma liner containing a cold fuel layer are introduced into the reactor vessel in a stand-off manner, is discussed. Two compact toroids containing fusionable materials are introduced into a spherical reactor target chamber in a diametrically opposing maimer. Embedded in the compact toroids are force-free magnetic fields in Woltjer-Wells-Taylor's state of minimum energy, which are known experimentally to be extraordinarily stable. They collide in the center to form an initial magnetized target plasma. A spherical distribution of plasma jets are then launched fiom the periphery of the vessel, coalescing to form a converging spherical plasma liner. On impact with the central plasma, the plasma liner sends a shock wave through it, shock heating it to some elevated temperature (above 100 eV) which sets the initial adiabat for subsequent compression. The high temperature immediately raises the electrical conductivity of the plasma to the extent that it traps the magnetic flux inside the central plasma. The central plasma is further compressed by the plasma liner and heated nearly adiabatically to conditions for thermonuclear burn, the magnetic flux being compressed with it. The thermal loss rate, greatly reduced by the high magnetic fields, are sufficiently lo...

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Possible energy gain for a plasma-liner-driven magneto-inertial fusion concept

Knapp

Kirkpatrick

2014

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A one dimensional parameter study of a Magneto-Inertial Fusion (MIF) concept indicates that significant gain may be achievable. This concept uses a dynamically formed plasma shell with inwardly directed momentum to drive a magnetized fuel to ignition, which in turn partially burns an intermediate layer of unmagnetized fuel. The concept is referred to as Plasma Jet MIF or PJMIF. The results of an Adaptive Mesh Refinement (AMR) Eulerian code (Crestone) are compared to those of a Lagrangian code (LASNEX). These are the first published results using the Crestone and LASNEX codes on the PJMIF concept

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An implicit Smooth Particle Hydrodynamic code

Knapp

2000

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Analysis Of The Boeing FEL Mirror Measurements

Knapp

Viswanathan

Appert

1989

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Charles E. Knapp

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An embodiment of the magnetized target fusion concept in a spherical geometry with stand-off drivers

Possible energy gain for a plasma-liner-driven magneto-inertial fusion concept

An implicit Smooth Particle Hydrodynamic code

Analysis Of The Boeing FEL Mirror Measurements

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