The study of electron density and temperature diagnostics of solar plasmas
using emission lines was first extensively reviewed by Gabriel & Jordan
(1972), with more recent work including that of Feldman et al.
(1992), Dwivedi (1994) and Mason & Monsignori Fossi
(1994). A common procedure
involves searching for intensity ratios which are sensitive to electron
density (
) and/or electron temperature (
). In the present
paper we consider the case of the MgVI ion which has five
fine-structure levels in the ground configuration, each of which is
sensitive to electron density values relevant to the solar transition
region. Therefore, although lines of MgVI are relatively weak in
the solar spectrum, some of the line ratios are potentially very useful
for electron density/temperature diagnostics in different solar phenomena
such as the quiet-Sun, active regions and solar flares (Bhatia &
Mason 1980; Raju & Gupta 1993).
| Orbital |  |  |  | Orbital |
| | |
| 1s | 75.47140 | 1 | 11.69120 |  | 44.75401 | 1 | 3.14288 |
| 4.96191 | 1 | 19.81840 | -440.48331 | 2 | 3.19387 | ||
| 0.10120 | 2 | 5.30819 | 1104.09003 | 3 | 3.19394 | ||
| 13.81971 | 2 | 9.99860 | -1038.47746 | 4 | 3.60095 | ||
| 0.00039 | 2 | 4.07241 | |||||
| 2p | 25.22256 | 2 | 4.44405 | ||||
| 2s | -21.53204 | 1 | 11.69120 | 21.80006 | 2 | 7.10836 | |
| -0.71817 | 1 | 19.81840 | 10.49715 | 2 | 3.64321 | ||
| 19.64494 | 2 | 5.30819 | 4.90313 | 2 | 14.97880 | ||
| -51.70492 | 2 | 9.99860 | |||||
| 33.51006 | 2 | 4.07241 |  | 49.25869 | 2 | 2.52065 | |
| -117.35998 | 3 | 3.18186 | |||||
| 3s | 9.86858 | 1 | 9.50846 | ||||
| -23.25848 | 2 | 3.67081 |  | 74.19637 | 3 | 4.38082 | |
| 10.98560 | 3 | 2.34889 | |||||
|
|
At present there is a paucity of atomic data available for the
electron-impact excitation of the MgVI ion. An early
calculation by Saraph et al. (1969) produced LS collision
strengths for transitions among the 2s22p
S
,
2D and 2P levels using the exact resonance
distorted wave method. Only a limited number of incident electron
energies were considered in this work which makes the Maxwellian
averaging necessary to produce the astrophysically important effective
collision strengths impossible. Davis et al. (1976) presented results for
electron-impact excitation rate coefficients for a few selected transitions
(2s22pS
- 2s2p
P
,
2s22p
P - 2s2p
P
)
in MgVI. The calculations were carried out in the distorted wave
approximation with exchange when required. Many of the rate coefficients
produced by this work were expressed in terms of a simple two parameter
fit. The most elaborate calculation to date was performed by Bhatia &
Mason (1980), again utilizing the distorted wave method. They evaluated
fine-structure collision strengths for transitions among the
2s22p3 and 2s2p4 levels in MgVI. The data, however,
were presented for only three incident electron energies (10, 15, 20 Ryd.)
and the effective collision strengths required for many astrophysical and
plasma applications were not evaluated.
Clearly there is a need for a large and sophisticated close-coupling calculation to evaluate for the first time accurate effective collision strengths for the electron-impact excitation of MgVI. The purpose of the present work is to perform the most elaborate evaluation to date which (a) includes a large number of target eigenstates in the wavefunction representation of the MgVI ion; (b) incorporates channel coupling and configuration-interaction effects by the inclusion of higher-lying levels; (c) produces collision strengths at a very fine mesh of incident electron energies to properly resolve the autoionizing resonances in the collision cross sections, which are known to significantly enhance the resulting effective collision strengths, and finally (d) to produce the astrophysically important fine-structure effective collision strengths over a wide range of electron temperatures.
) of the radial wavefunctions
as indicated in Eq. (1)