INTRODUCTION The alteration and the overall mineralogy of the hydrothermally altered basaltic rocks in a 1750 m deep section through the Reykjanes geothermal area has been described in a pre- vious paper (Tómasson and Kristmannsdóttir, 1972). In Fig. 1 the distribution of clay minerals with depth in three of these drillholes is shown. The clay minerals formed were by X-ray identi- fication found to be smectites in the uppermost cooler parts (at rock temperature below 200 °C) and chlorites in the lower part of the section. An intermediate zone of randomly mixed-layer smectite/chlorite minerals bridges the two main zones (in the temperature interval 200—270 °C). Normal non-swelling chlorite is found beneath this depth, but the swelling chlorite is found together with it to the deepest levels reached by drilling. In Table 1 is shown the classification of the clay minerals from X- ray diffraction analyses. The mixed-layer min- erals of chlorite and smectite are irregularly interstratified and their diffraction peaks are often broad and without a distinct maxima. The swelling chlorites are divided into four main types, but minerals showing intermediate characteristics have been found. The thermally instable chlorite 3 and chlorite 5 were classified mainly on basis of their swelling abilities being similar to the two thermally stable types and their occurrence together with them. The struc- ture of those swelling, chlorite like minerals and their relation to the other clay minerals was uncertain after the first study by X-ray diffraction methods. Optical observations suggest that the clay minerals are all Fe-rich. The optical properties of the mixed-layer minerals and the swelling chlorites are mostly rather similar but very variable from one sample to another. No clear correlation between microscopic observation and results from X-ray diffraction analyses could be obtained for those minerals. Due to these features it was suggested that a process of gradual and continuous chloritiza- tion of the smectites did happen by increasing temperature without any major chemical re- arrangement of the silicate layers themselves. The aim of the present study was to investigate the clay minerals, mainly the mixed-layer minerals and swelling chlorites by differential thermal analysis and infrared spectroscopic methods and to find out whether these features changed abruptly or gradually and study their relations to the smectite and normal chlorite minerals. A main difficulty in preparing the samples for this study was to obtain nearly pure clay mineral fractions from the rock. Some of the clay mineral types occur only together with one or two of the other types. In some cases a mixture of two or three minerals was there- fore obtained in the clay fraction. A sample containing only one single clay mineral, and large enough for the differential thermal ana- lyser was obtained of the smectite, a mixed- layer smectite/chlorite mineral and the swelling chlorite of group 2 (see Table 1). A sample of nearly pure swelling chlorite 5 was also pre- pared. All the samples contained small quanti- ties of non clay minerals, mainly plagioclase, calcite, quartz and opaques. The quantity of the non clay minerals was in most samples 1— 5%. The purity of the samples was checked by X-ray diffraction scanning. RESULTS OF THE DIFFERENTIAL THERMAL ANALYSIS (DTA) In Fig. 2 are shown some characteristic DTA patterns of the samples. A striking feature is the similarity of the curves for swelling chlorite and the mixed-layer minerals. Mixtures of smectite and swelling chlorite, mixed-layer minerals and swelling chlorite also show closely similar patterns. The main peaks appear at practically the same temperatures in all instances, only their relative intensities are different. The differ- ential thermal analyses show that the “chlori- tic” minerals all contain structural bound water in varying degree. A rather strong and well defined dehydroxylation peak occurs at 590—600 °C. An endothermic peak at about 830 °C, which is probably due to dehydration of the mica layer, has lower intensity than the dehydroxylation peak, but is quite well defined. It is followed immediately by an exothermic peak at about 860 °C. The DTA curves for the chloritic minerals are quite similar to curves of “corrensite” (Mackenzie, 1957a). The similarity JÖKULL 26. ÁR 31

Síða 1
Síða 2
Síða 3
Síða 4
Síða 5
Síða 6
Síða 7
Síða 8
Síða 9
Síða 10
Síða 11
Síða 12
Síða 13
Síða 14
Síða 15
Síða 16
Síða 17
Síða 18
Síða 19
Síða 20
Síða 21
Síða 22
Síða 23
Síða 24
Síða 25
Síða 26
Síða 27
Síða 28
Síða 29
Síða 30
Síða 31
Síða 32
Síða 33
Síða 34
Síða 35
Síða 36
Síða 37
Síða 38
Síða 39
Síða 40
Síða 41
Síða 42
Síða 43
Síða 44
Síða 45
Síða 46
Síða 47
Síða 48
Síða 49
Síða 50
Síða 51
Síða 52
Síða 53
Síða 54
Síða 55
Síða 56
Síða 57
Síða 58
Síða 59
Síða 60
Síða 61
Síða 62
Síða 63
Síða 64
Síða 65
Síða 66
Síða 67
Síða 68
Síða 69
Síða 70
Síða 71
Síða 72
Síða 73
Síða 74
Síða 75
Síða 76
Síða 77
Síða 78
Síða 79
Síða 80
Síða 81
Síða 82
Síða 83
Síða 84
Síða 85
Síða 86
Síða 87
Síða 88
Síða 89
Síða 90
Síða 91
Síða 92
Síða 93
Síða 94
Síða 95
Síða 96
Síða 97
Síða 98
Síða 99
Síða 100
Síða 101
Síða 102
Síða 103
Síða 104