著者
砂川 一郎 堀田 修三 沢田 秀穂
出版者
宝石学会(日本)
雑誌
宝石学会誌 (ISSN:03855090)
巻号頁・発行日
vol.10, no.1, pp.3-35, 1983

Diamonds have been found occassionally in the tails of dressing of stream tin deposits in Phuke, Phangnga and Takua Pa Areas, South Thailand. From a geological point of view, the occurrence of diamond in Thailand implies unique and important meanings, since in Thailand kimberlites have not been found so far and there is no continental shield (craton) area in which most diamonds and kimberlites of the world have been found. In spite of this importance, no detailed studies on diamond crystals from Thailand have been made so far, although there have been four reports on their occurrences. In the present study, detailed surface microtopographic observations have been made of 15 diamond crystals, which were collected during the past 20 years by a gem dealer in Phangnga at a tin deposit in a small island, Dog Mai, off Phangnga and Phuket, South Thailand. Crystals are colourless, pale yellow, pale green and pale brown in colour, from 0.1 to over 0.7 ct in weight, and are very much rounded, showing rounded octahedral, tetrahedral, hexa-octahedral, dodecahedroidal and elongated dodecahedroidal morphologies (Fig. 3, 4, Table 1). The rounded morphology indicates that the crystals have suffered severe dissolution, most probably during the ascension of crystals in kimberlite magma, not during the transportation on the Earth's surface. Surface microtopographs representing various degrees of dissolution have been observed, which include rounded hexa-octahedral and dod-ecahedroidal faces (Fig. 12-16), circular disk depressions, often superimposed, and similar necklace-like patterns (Fig. 16-19), net work patterns (Fig. 20), all of which appear on rounded surfaces, and trigons appearing on flat {111} faces. Among these, trigons attract a particular attention. On the (111) faces of one of these crystals, all varieties of trigon morphologies are observed (Fig. 23, 25), which include trigons having opposite orientation to the triangle of the octahedral face (negative trigon, NT type), truncated NT (NT' type), hexagon (H type), and those having the same orientation as the triangle of the octahedral face (positive type, PT type), and truncated PT (PT' type). Both point-bottomed (P type) and flat-bottomed (F type) trigons are seen in a ratio of ca. 24 : 1. Trigons so far observed on {111} faces of natural diamond crystals are exclusively NT type and its deviation, and neither PT type trigons nor co-existence of both PT and NT types have been reported. Recent experimental studies have shown that trigons are etch pits and their orientations and morphologies change depending on temperature and oxygen fugacity (Fig. 21). Therefore, the co-existence of both PT and NT types on one octahedral face observed in the present study is very unique and suggests a rather peculiar condition under which diamonds from Thailand have experienced dissolution. The distributions of different types (Table 2), sizes (Table 3, Fig.26), and inclination angles of side faces (Table 4, Fig. 28) of ca. 8000 trigons occurring on flat table area and narrow terrace area on one (111) face are measured. The results are analysed, using a concept of surface reconstruction model proposed for Si etch pits by van Enckevort and Giling (1978) (Fig. 31, 33,34) and phase diagram of orientations of trigons (Fg. 21) by Yamaoka et al. (1980). Based on this analysis, the dissolution history of the crystal is suggested, in which the effect of change of oxygen fugacity is stressed (Fig.35). It is suggested that diamonds in Thailand came from kimberlite magma, whose chemistry was slightly different from that of kimberlites in other localities. This is in harmony with geological peculiarity of diamond occurrence in Thailand.
著者
和田 浩爾
出版者
宝石学会(日本)
雑誌
宝石学会誌 (ISSN:03855090)
巻号頁・発行日
vol.10, no.4, pp.3-11, 1983

The spectral characteristics of pearls produced by the different species of marine and freshwater bivalved molluscs were examined by Jewel Color Duble-beam Spectrophotometer. The color of pearls appeared to arise from (1) the interference of the light reflected at the external face of pearls and also at each of the boundaries between the crystal layers consisting of the nacre, (2) the absorbing material of light in the nacre, and (3) the dark organic material contained in pearls. The interference color observed in pearls is variable according to the size, shape, orientation and ordering of crystallites in the crystal layers and exhibits the characteristic iridescence of silver white to pink. The spectrophotometric reflectances of the iridescence were similar to each other between the pearls produced by Pinctada maxima, Pinctada margaritifera and Pteria penguin. We will notice that the major absorbing material is the pigment secreted by the epithelial cells of the pearl sac derived from the mantle epithelium. The color impression of pearls was closely connected with the characteristic pigment in the different species of bivalves, e. g. yellow for Pinctada fucata and P. maxima, black for P. margaritifera, brown for P. penguin, orange pink for Hyriopsis schlegeli, and violet pink for Anodonta calypigos. In the black pearls of P. margaritifera and the brown pearls of P. penguin, the reflection curves had respectively the special absorption bands, probably caused by the characteristic pigment contained in each pearl. The color impression of pearls including the dark organic material was dark and pale blue, and did not differ between the different species of bivalves in the spectrophotometric reflectance. The organic material seems to be composed of anomalous secretions and debris of cells.
著者
林 政彦
出版者
宝石学会(日本)
雑誌
宝石学会誌 (ISSN:03855090)
巻号頁・発行日
vol.20, no.1, pp.99-110, 1999

従来から使われている鑑別手段では判断が難しい宝石については,新しい分析技術の開発あるいは従来の方法の応用によって,その鑑別を可能にすることが必要である。そこで,今日は現在広く使われているEDS,軟X線による透過像,FT-IRなどの分析機器を用い,現在流通している宝石の鑑別に成功した例をいくつか紹介する。今後はこのようなハイテク機器が宝石の研究に貢献するであろう。