Optical and ion energy spectroscopy of laser-produced plasmas
Abstract
The work described in this thesis relates to the
problem of observing population inversions in laserproduced
plasmas, and to the associated problem of interpreting
optically thick line intensities.
In Part I we examine the conditions under which
population inversions appropriate to soft X-ray transitions
can occur in rapidly recombining plasmas, with particular
reference to hydrogen-like transitions in a laser-produced
carbon plasma. Computations have been performed for quasisteady
state inversions between excited states of hydrogenlike
ions, as well as for inversions with respect to the
ground state. The effect of Lyman a self-absorption in
reducing population inversions between quantum states
n = 2 and 3 is examined in some detail.
The emergent intensities of optically thick lines
from an expanding plasma, such as a laser-produced plasma, are
affected by the differential Doppler effect associated with
ion streaming. As a first step in investigating this
effect we have measured (in Part II) the velocity spectra
of the streaming ions. A plasma was produced by focusing
the pulse (4 ns duration) from a Neodymium laser onto a
carbon target (power density in the range 3 x 10¹⁵ to
1.3 x 10¹⁶ Wm⁻² ) in vacuum. A 45° parallel plate electrostatic
analyzer was built to record the energy spectra of
the streaming ions. Space charge effects within the
analyzer are examined quantitatively. Ion velocity spectra,
deduced from the energy spectra and covering the range
1-5 x 10⁵ ms⁻¹ , are reported for C³⁺ , C⁴⁺ , C⁵⁺ and C⁶⁺ .
The role of recombination in forming these spectra is
discussed.
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