INTRODUCTION.Since discovery of apparent carbonate carbon in Naldala [1], significant evidence has accumulated for occurrence of volatile compounds in shergotfites and nakhlites. Gooding and Muenow [2] showed that at least one shergottite (EETA79001) contains substantial sulfur in a highly oxidized form and that the oxidation must have occured on the shergottite parent planet. Burgess et al. [3] also found oxidized sulfur in ALHA77005, Shergotty, Nakhla, and Chassigny. Kerridge [4] reported carbon and deuterium of apparent pre-terrestrial origin in Shergotty and Lafayette (a nakhlite). In addition, discrete grains of salt minerals have been documented in EETA79001 and Nakhla [5][6][7]. Here we present final results from our study of volatile compounds [8] in three shergottites, one naldalite, and three eucrite control samples. SAMPLES AND METHODS. Antarctic meteorites included Allan Hills specimens ALHA77005 (shergottite) and ALHA81001 (eucrite), as well as Elephant Moraine specimens EETA79001 (shergottite; lithologies A, B, and C), and EETA79004 (eucrite). A Pasamonte eucrite specimen (USNM-897) was obtained from the U. S. National Museum and a Nakhla specimen (BMNH-1911,369) from the British Museum (Natural History). A Shergotty specimen (GSI-179) was sub-divided from material allocated by the Geological Survey of India to Duke [9]. Samples from the exterior (0-0_5-era depth, including fusion crust) and interior (> 1-cm depth) of each meteorite were individually analyzed so that terrestrial weathering and contamination could be recognized and not misinterpreted as parent-body effects. Each sample (20-80 rag) was pyrolyzed by continuous heating to 1500 K at 5-6 K/rain under 10-7 torr vacuum in a Knudsen cell fitted with a high-purity aluminum oxide liner. Evolved gases were analyzed by a quadrupole mass spectrometer that was continuously scanned over m/e = 2-100 to simultaneously measure abundances of H20, CO 2, CO, SO2, S2, H2S, HCI, C1, and hydrocarbons. RESULTS. WATER. For interior samples of shergottites, H20-release profiles and total water concentrations (< 0.1%), are not obviously correlated with similar data for other volatile species. A typical H20-release profile consists of a single broad peak at 350-700 K that suggests desorption of loosely bound water. Although Nakhla was previously suspected to contain hydrous phases [7,10,11], its measured water content was less than anticipated and its H20-release profile was similar to those of shergottites. As discussed below for chlorine, however, it is possible that much of Nakhla's indigenous water reacted to form HCI during pyrolysis. Therefore, the actual water content of Nakhla may be significantly higher than the 0.007% measured as evolved H20. Kerridge [4] reported a total of 13.3 ppm H in Shergotty and 58.3 ppm H in the nakhlite, Lafayette, but discarded as terrestrial contamination all gases extracted at < 723 IC Judging from our results for Nakhla, however, HCI evolution (and, by inference, water loss) begins at < 700 K in nakhlites. Therefore, it...
