TABLE 1 Microprobe analysis of bonding material in discontinuity from tholeiite, Iceland. Age approximately 2 m. y. Point analysis. TAFLA 1. Örgreining á fylliefni úr smásprungu í íslensku póleiíti. Aldur u. p. b. 2 m. á. Punktagreining. SiO,, TiOT- AiP;i ]+/),* MgO CaO Na20 K.P MnO Total 38.44 00.00 4.23 26.94 6.22 1.67 0.18 0.17 0.52 78.37 + Ti usually less than 1.00% * Totai Fe as Fe20.j TABLE2 X-ray diffraction analyses of 3 samples of bonding material from tholeiite, Iceland. Peaks in Angstrom (Á) TAFLA 2. Röntgengreining á premur sýnum af fylliefni úr íslensku póleiíti. Toppar í Angstrom (Á) Sample Untreated Ethylene glycol treated Heated to 550°C Pretreated with Mg+2 Glycol 1 15.49 15.76 9.92 14.71 15.22 2 14.46 15.22 9.99 14.62 14.96 3 15.22 15.22 9.99 14.62 14.71 culite group (H. Kristmannsdóttir, personal communication). In the Irish rocks smectite (saponite) can be a constituent of the bonding material (Douglas 1972). The chemicai analysis is of course for the total material and it is not clear therefore to what extent either Ca or Fe is part of the clay mineral structure. On the other hand both the red and biack phases are structurally the same, according to the X-ray diffraction ana- lyses. Figure 3 (f) is a scanning eiectron micrograph of the black phase on a freshly opened discontinuity and shows small irregu- larly shaped flakes. Small microfractures can also be discerned in the same photograph. DISC.USSION Origin of the disconhnuilies The large scale open joints which form the prism surfaces have most often been explained as tension joints formed by thermal stresses set up on cooling of the lava (e. g. Spry 1961). The predominantly vertical joints have formed perpendicular to the upper and lower cooling surfaces and perpendicular to the planes of equal tensile stress. The discontinuities described in this paper are on a much smaller scale and do not seem to be genetically identical to the major joints. Their relationship to petrology indicates that they are brittle fractures originally. They seem to be mainly the result of tensile stresses although small scale shearing is not com- pletely absent. The intersection angles of 90° and 120° can be satisfactorily explained by assuming that the fractures have formed dynamically i. e. by extension according to Griffith crack theory (Griffith 1920). An ex- tending fracture runs at right angles to the tensile stress. This explains the 90° intersec- tions and aiso why some fractures bend to meet others at 90° since the tensile stress is 4 JÖKULL 31.ÁR

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