<=== observer ===>
"MMORRIS",\
"Morris, M.",\
"UCLA",\
"Dept. of Astronomy-156205",\
"",\
"8979 Math-Scien",\
"",\
"Los Angeles, CA",\
"USA",\
"1  310 8253320",\
"1  310 2062096",\
"morris@osprey.astro.ucla.edu"

<=== proposal ===>
"GCMETAL", 1, 2,\
{"abundances",\
"HII regions"},\
{"H.J. Habing",\
"Leiden Observatory",\
"P.O. Box 9513",\
"2300 RA Leiden",\
"The Netherlands",\
"E.F. van Dishoeck",\
"Leiden Observatory",\
"P.O. Box 9513",\
"2300 RA Leiden",\
"The Netherlands"}

<=== title ===>
THE METALLICITY OF GALACTIC CENTER GAS

<=== abstract ===>
SCIENTIFIC ABSTRACT

Galactic evolution models lead us to believe that the interstellar 
gas occupying the central few hundred parsecs of the Galaxy has probably 
undergone a relatively large amount of nuclear processing in stars.  This 
is supported by observations of highly unusual isotopic abundance ratios 
of molecular lines there, indicative of an enhanced abundance of nuclear 
burning products via both primary and secondary processes.

However, the metallicity of the galactic center region is only crudely
determined at present, and there is essentially no unambiguous information on
how the metallicity varies with radius in the inner few hundred parsecs.  A
few measures have been made of mid-IR lines of Ar and Ne, and of the far-IR
fine structure lines of [N III] and [O III], and these suggest a metallicity
enhancement of about a factor of two, but the treatment of the abundances of
unobserved ionization states is  quite uncertain. Stars near the galactic
center provide some relevant clues - the peak metallicity of K giants in
Baade's window is about twice the solar value, though there is a broad range. 
In sum, the metallicity of the galactic center is poorly known, and yet we
cannot understand this environment well without knowing it.  The metallicity
is needed to 1) constrain models of galactic evolution, 2) model the heating,
cooling, and chemistry of the interstellar medium near the galactic center, 3)
use molecular lines to derive cloud masses, and 4) understand how metallicity
may affect the IMF in the star formation process.

In order to determine accurate abundance ratios and to establish the
galactic center metallicity and its dependence on galactocentric radius
with some reliability, we propose to use the SWS and LWS on ISO for 
a total of 2.9 hours to observe the accessible ionization states of H 
(alpha lines at 4.05 & 7.45 microns), N (NII at 121.9 and NIII at 57.4 
microns), O (OIII at 51.8 & 88.4 microns and OIV at 25.9 microns), Ne 
(NeII at 12.8 and NeIII at 15.6 & 36.0 microns) and Ar (ArII at 6.99 
and ArIII at 8.99 & 21.8 microns) in 5 HII regions in the inner 0.5
degrees of the Galaxy.  These observations will be used with
existing radio continuum data to construct models for the
temperature, density, and radiation field within each HII region so that
all ionization states will be represented in the models. Ar and Ne have
been chosen as probes of the heavy element abundance because they are 
likely to be negligibly depleted onto grains.  In addition, the Pf-alpha 
line of H at 7.45 mu is included for direct comparison with the Ar 
lines and to provide an estimate of the H column density for comparison 
with those derived from radio continuum data. Br-alpha is included in 
order to constrain the mid-IR extinction by comparison with Pf-alpha.

The HII regions chosen for study are all relatively isolated and
their structures are all reasonably well understood from radio 
observations.  All are very strong sources of near- and
far-infrared radiation. On the basis of existing velocity information,
mapping observations, and clues from absorption line studies, one can be
confident that these objects are close to the galactic center, rather
than being fortuitously superimposed. They have a spread of
galactocentric distances, so that any sharp metallicity gradients near
the nucleus might be probed.  Sgr B2 and Sgr A are not on our list, but
the spectral surveys of Sgr B2 and Sgr A West to be undertaken in the
core program can also be used as measures of the metallicity at 0 and
about 100 pc, respectively.

In case of the Sagittarius hole, the objects will not be visible, and no time
will be allocated to this proposal. The available time will in that case shift
to the proposal "Large Scale Shocks in the Galactic and Other Regions" to map
the H2O distribution in IC 443.

OBSERVATION SUMMARY

We propose to observe the fine structure lines of N II, N III, O III, O IV, Ar
II, Ar III, Ne II, Ne III and recombination lines of H I in 5 H II regions in
the Galactic Center region. Because the continuum is strong, we will use the
Fabry-Perot wherever feasible in order to distinguish the lines (SWS AOT07,
LWS AOT04). The remaining lines will be done with the SWS grating, AOT02. The
requested S/N is 50-100 on the continuum for the grating and 10-20 on the line
for the FP. The integration times would typically be 80s for each line in each
source. Concatenation of the SWS AOT2 and AOT7 observations is required in
order to have the same orientation of the slit on the source. It is
recommended for the LWS observations in order to save overhead for slewing.


<=== scientific_justification ===>

Autumn launch

TEAM: top 40%  second 30%  last 30%
SWS :     0.          0.        0.
LWS :     0.          0.        0.
CAM :     0.          0.        0.
PHT :     0.          0.        0.
SOT :     0.          0.        0.
THE :     0.          0.        0.
JLP :     0.          0.        0.
HJH :  4196.       4196.     2098.
AFM :     0.          0.        0.
MOH :     0.          0.        0.

Spring launch

TEAM: top 40%  second 30%  last 30%
SWS :     0.          0.        0.
LWS :     0.          0.        0.
CAM :     0.          0.        0.
PHT :     0.          0.        0.
SOT :     0.          0.        0.
THE :     0.          0.        0.
JLP :     0.          0.        0.
HJH :     0.          0.        0.
AFM :     0.          0.        0.
MOH :     0.          0.        0.


	   Table 1: Sources Selected for Abundance Determinations
		    ===============================================


    Name              R.A.(1950)       Dec(1950)             References
_____________________________________________________________________________

G-0.02-0.07 (A)     17h 42m 41.5s     -28d 58' 20"        Goss et al. 1985
						   Yusef-Zadeh & Morris 1987a
						    Yusef-Zadeh et al. 1989

G0.18-0.04          17  43  05.0      -28  47  00  Yusef-Zadeh & Morris 1987b
						    Serabyn and Guesten 1991

H5                  17  42  27.9      -28  52  18  Yusef-Zadeh & Morris 1987a
							    Glass 1988
							Morris et al. 1992

Sgr C               17  41  24.5      -29  26  40           Liszt 1985

G0.5-0.0 (Sgr B1)   17  43  53.0      -28  30  12    Odenwald and Fazio 1984
						     Seiradakis et al. 1989,
						     and references therein
________________________________________________________________________________


		    Table 2: Lines to be Observed
			     ====================

================================================================================
					   Continuum Fluxes (Jy) in aperture*
				     ___________________________________________

Element  ion             wavelength   G-0.02    G0.18     H5     SgrC     G0.5
________________________________________________________________________________
   H     HI (Br-alpha)   4.05 (SWS)     0.06     0.04    0.03    0.03     0.03
	    (Pf-alpha)   7.45 (SWS)     5.0      4.3     3.4     2.2      0.5

   Ne    NeII           12.8  (SWS)     6.8      7.1     7.0     3.6      3.0

	 NeIII          15.6  (SWS)     9.9     10.5    10.7     5.2      5.0
			36.0  (SWS)   106.     101.     98.     44.      59.
   Ar    ArII            6.99 (SWS)     1.4      1.2     0.9     0.7      0.4

	 ArIII           8.99 (SWS)     3.3      3.2     2.8     1.7      1.0
			21.8  (SWS)    30.      30.     31.     10.5     12.8

    O    OIII           51.8  (LWS)   2.9E3    2.6E3    2.6E3   2.0E3    2.3E3
			88.4  (LWS)   3.6E3    2.8E3    2.6E3   3.5E3    3.7E3

	  OIV           25.9  (SWS)    50.      49.     50.     16.      21.

    N     NII          121.9  (LWS)   3.0E3    4.9E3    5.4E3   2.8E3    3.2E3

	 NIII           57.4  (LWS)   3.1E3    2.6E3    2.7E3   2.4E3    2.7E3
________________________________________________________________________________

* IRAS fluxes saturated in 60 and 100 micron bands in all sources, so the LWS
  and longer-wavelength SWS fluxes are underestimates of the true fluxes.


<=== autumn_launch_targets ===>

 1, "SWS02", 1., "N", "G-0.02-0.07     ", 17.71153, -28.97222, 1950, 0., 0.,  1072,  2
 2, "SWS07", 1., "N", "G-0.02-0.07     ", 17.71153, -28.97222, 1950, 0., 0.,   646,  3
 3, "LWS04", 1., "N", "G-0.02-0.07     ", 17.71153, -28.97222, 1950, 0., 0.,   380,  0
 4, "SWS02", 2., "N", "G0.18-0.04      ", 17.71806, -28.78333, 1950, 0., 0.,  1072,  5
 5, "SWS07", 2., "N", "G0.18-0.04      ", 17.71806, -28.78333, 1950, 0., 0.,   646,  6
 6, "LWS04", 2., "N", "G0.18-0.04      ", 17.71806, -28.78333, 1950, 0., 0.,   380,  0
 7, "SWS02", 1., "N", "H5              ", 17.70775, -28.87167, 1950, 0., 0.,  1072,  8
 8, "SWS07", 1., "N", "H5              ", 17.70775, -28.87167, 1950, 0., 0.,   646,  9
 9, "LWS04", 1., "N", "H5              ", 17.70775, -28.87167, 1950, 0., 0.,   380,  0
10, "SWS02", 2., "N", "SgrC            ", 17.69014, -29.44444, 1950, 0., 0.,  1072, 11
11, "SWS07", 2., "N", "SgrC            ", 17.69014, -29.44444, 1950, 0., 0.,   646, 12
12, "LWS04", 2., "N", "SgrC            ", 17.69014, -29.44444, 1950, 0., 0.,   380,  0
13, "SWS02", 3., "N", "SgrB1           ", 17.73139, -28.50333, 1950, 0., 0.,  1072, 14
14, "SWS07", 3., "N", "SgrB1           ", 17.73139, -28.50333, 1950, 0., 0.,   646, 15
15, "LWS04", 3., "N", "SgrB1           ", 17.73139, -28.50333, 1950, 0., 0.,   380,  0

<=== spring_launch_targets ===>