surtseyan tephra grains are very uniform in shape and typically equant. FORM PARAMETERS, DEFINITIONS AND ANALYTICAL METHODS SAMPLING PROGRAMME Samples for the analysis of form were selected with four objectives in mind. The first one was to enable comparison between eruptions in widely different physical environments (submarine, subgla- cial, subaerial). The second objective was to cover a wide chemical compositional range (basalt to rhyol- ite). Thirdly, the variation within one tephra layer was tested by analyzing four samples from a vertical section through one layer (H4), and by analyzing samples from three geographically separated locali- ties for a single tephra layer (H!). Finally a dupli- cate analysis was carried out on one of the samples to test the reproducibility of the analytical method. Table I lists the samples used in the present study. All the samples were obtained from existing collec- tions of tephra samples and no field observations were carried out. The exact location of some of the samples is not known and is not considered relevant to the present study. There are several possible sources of error in the determination of form of tephra produced in a vol- canic eruption. A single eruption may change in character with time. A sample from a single phase of such an eruption may not represent a full picture. This source of error may be minimized during sam- pling by carefully mapping the tephra bed and by observing intemal changes in structure. Secondly, the grain shape may play a part in the sorting of tephra as it is carried away from the point of erup- tion, so that the form may change with distance within the same tephra layer. If certain eruptive mechanisms, such as phreatomagmatic explosions, affect the grain shape, some effect on the transport distance may also be expected because grains pro- duced in an explosion are likely to be ejected rela- tively high up in the atmosphere, facilitating long distance transport. Finally, fresh tephra forms a relatively unstable sediment in many cases and may be easily transported and redeposited. This secon- dary process may change the original shape of the tephra, but should normally be accompanied by some rounding. No attempt was made in the present study to evaluate these possible sources of error, except for the samples from H, which was sampled at three localities, and H4 which was sampled in a vertical section. A combination of detailed field work and the study of tephra morphometry would clearly be desirable to minimize or eliminate some of the indoor and outdoor sources of error. GRAIN SIZE AND FORM All tephra samples (Table I) were divided into whole O size classes by sieving and size classes retained on 0.0 to +3.0 (yielding a size range of 0.125 to 2.0 mm) were measured in all the samples. The mean diameter of some measured grains may fall outside the upper and lower sieve class limits because of their irregular shape. The <Þ scale was defined by Krumbein (1934) and McManus (1963): O = -log2(d/d0) where d is the grain diameter in mm, d0 is the refer- ence unit (1 mm) of the dimensionless 4> scale. After sieving, 20 grains from each size class were selected randomly. Rock fragments, phenocrysts, and exceptionally coloured grains were rejected. Each grain was then mounted on an elongate glass plate with the plane of maximum projection of the grain oriented parallel to that of the glass plate. This plane contains the long (L) and intermediate (I) axes while the short axis (S, measuring the grain thick- ness) is perpendicular to the glass plane. The length of the 3 axes was measured under a binocular micro- scope employing a 90° rotation about the long axis of the glass plate to view the S axis. A duplicate analysis was carried out on one of the samples, 5838 from Snæfellsjökull. The values for the major axes of each size class were fed into a computer program which calculates various form indexes as well as their means and sta- tistical parameters, and plots form diagrams to give a visual concept of the measurements. The form 60 JÖKULL, No. 39, 1989

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