thermal evolution and the age of the as- phalt. Retreat of the glacier since 1945 (fig. 3) may be one of the reasons that the as- phalt-bearing amygdales were found. Oth- erwise, weathering would most likely have masked the outcrop and definitely spoiled the low resistant asphaltic petroleum. The petrological study of the asphalt-bearing lava shows the lava matrix to be quite dense, while large vesicles and primary fractures are quite common. Chemical analyses of this lava as well as the under- lying and overlying lavas are presented in Table 1. The petroleum seems to have penetrated the lava via fractures, occa- sionally to become trapped in half-empty amygdales. Study of the secondary mineralization indicates that three hydrothermal episodes may be distinguished. The first one began during burial, and involved low tempera- ture hydrothermal alteration products (siderite, opaline silica, zeolite, smectite, calcite, celadonite and limonite). The temperature at formation is estimated to have been 40-80°C (Table 2). Small ves- icles and primary fractures are more or less filled by these early-forming minerals, while the larger amygdales and some sec- ondary veins, are lined by some of them. The larger amygdales were precipitated in a second hydrothermal episode, when high-temperature effluent, saturated with respect to calcite and quartz, flowed into cooler fissures between the volcanoes. The cooling resulted in widespread precipitation of calcite, silica minerals (agate, quartz and jasper), pyrite and pos- sibly tridymite. Unsuccessful attempts were made to nreasure the homogeniza- tion temperature in fluid inclusions in quartz and calcite. The lack of inclusions may imply slow crystallization during growth of both the calcite and the quartz. The water temperature is estimated to have been between 80-120°C. The palaeo- surface during the second hydrothermal episode is believed to liave been only about 300-500 m above the asphalt-bear- ing lava. This is deduced from the absence of calcite above 600 m altitude as well as a 5 degree tilting unconformity as mapped by Torfason (1979). Later both the central volcanoes dis- cussed were buried by an approximately 1 km thick lava succession. During burial, regional zeolitization was superimposed on the earlier hydrothermal alteration. The maximum depth to the asphalt-bear- ing lava during this time may have been nearly 1.5 km. The asphaltic petroleum may have formed during this time, from lignite beds. The asphalt was thus, along with quartz, deposited during a third hydrothermal episode. The asphaltic petroleum occurs in two ways in the amygdales. Either it fills the space between quartz crystals (fig. 5) or it occurs as spherical bodies on the floor of the amygdales, usually covered with fine grained rock crystal (front page and fig. 6). The asphalt spheres range between 2 and 8 mm in diameter. The result of liq- uid-solid chromatography of two asphalt samples are shown in Table 3. Non-hydro- carbons and aromatic hydrocarbons are the major constituents. Figs. 7A and B show the results of the gas chromato- graphic analysis of one asphalt sample. The dominance of aliphatic hydrocarbons with odd numbers over even indicates that the source is of terrestrial origin. The iso- prenoid hydrocarbons, pristine and phy- tane, which are derived from biological precursors, are also present. The aromatic hydrocarbons form a complex mixture, as illustrated in Fig. 7B. The sulfur content of one asphalt sample was determined as being 0.9 wt. %. As mentioned previously, the asphalt was deposited during the third hydrother- mal episode, which may have been gener- ated by intrusive activity. The emplace- ment of the igneous sheet in the lignite may be part of that igneous phase, the age of which is uncertain. Calculation of the cooling time of the sheet is presented in table 4, assuming thernral conduction. It appears to have taken about 3 years for the sheet to cool down to 115°C, which ntay be considered the oil generation 187

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