49th Annual Meeting of the Division of Plasma Physics
Volume 52, Number 11
Monday–Friday, November 12–16, 2007;
Orlando, Florida
Session NI2: MHD, Strongly Coupled and Low Temperature Plasmas
9:30 AM–12:30 PM,
Wednesday, November 14, 2007
Rosen Centre Hotel
Room: Salon 3/4
Chair: Phil Efthimion, PPPL, Princeton University
Abstract ID: BAPS.2007.DPP.NI2.4
Abstract: NI2.00004 : Modeling Nuclear Fusion with an Ultracold Nonneutral Plasma*
11:00 AM–11:30 AM
Preview Abstract
Abstract
Author:
Daniel H.E. Dubin
(Univ. of California, San Diego)
In the hot dense interiors of stars and giant planets, nuclear
fusion reactions
are predicted to occur at rates that are greatly enhanced
compared to
rates at low densities.
The enhancement is caused by plasma screening
of the repulsive Coulomb potential between nuclei,
which increases the probability of the close collisions that are
responsible for
fusion.\footnote{E. E. Salpeter and H. van Horn, {\it Astrophys.
J.} {\bf 155}, 183 (1969).}
This screening enhancement is a small but measurable effect in the
Sun;\footnote{J. N. Bachall L.S.Brown, A.Gruzinov, and R. F.
Sawyer., {\it A\&A} {\bf 383}, 291-295 (2002).}
and is predicted to be much larger in dense objects such as white
dwarf
stars and giant planet interiors where the plasma is strongly
coupled
(i.e., where the Debye screening length is smaller than the mean
interparticle spacing).
However, these strongly enhanced fusion reaction rates have never
been
definitively observed in the laboratory.
This talk discusses a method for observing the enhancement
using an analogy between nuclear energy and cyclotron energy
in a cold nonneutral plasma in a strong magnetic field.
In such a plasma, the cyclotron frequency is higher
than other dynamical frequencies, so the kinetic energy
of cyclotron motion is an adiabatic invariant. This energy
is not shared with other degrees of freedom except through
close collisions that break the invariant and couple the cyclotron
motion to the other degrees of freedom. Thus, the cyclotron
energy of an ion,
like nuclear energy, can be considered to be an internal degree
of freedom
that is accessible only via close collisions. Furthermore, the rate
of release of cyclotron energy is enhanced through plasma
screening by
precisely the same factor as that for the release of nuclear energy,
because both processes rely on the same plasma screening of
close collisions.\footnote{D. Dubin, {\it Phys. Rev. Lett.} {\bf
94}, 025002 (2005);
M. J. Jensen, T. Hasegawa, J. J. Bollinger, and D.H.E. Dubin,
{\it Phys. Rev. Lett.} {\bf 94}, 025001 (2005).}
Simulations and experiments measuring
large screening enhancements in strongly-coupled plasmas
will be discussed, along with the possibility of exciting and
studying
``burn fronts.''
*Supported by NSF/DOE grant PHY-0613740 and NSF grant PHY-0354979.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2007.DPP.NI2.4