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The clinopyroxenes of the Skaergaard intrusion, eastern Greenland

Published online by Cambridge University Press:  14 March 2018

I. D. Muir
I. D. Muir*
Affiliation:
Department of Mineralogy and Petrology, University of Cambridge
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Extract

During the past twenty years considerable attention has been given to the compositions of the pyroxenes from basic igneous rocks. Hess (1941) reviewed the courses of crystallization of pyroxenes from mafic magmas and drew a trend line for the lime-rich clinopyroxenes. The present investigation was undertaken primarily to determine more closely the trend in the ferroaugite region, for here Hess's trend was based on the analyses of two pyroxenes from the Skaergaard intrusion and both of these are now known to be somewhat unusual types. The Skaergaard intrusion which is a strongly fractionated gabbroic complex is Particularly suitable for this study of the ferroaugites. Fifteen new analyses have been made for this investigation and twenty-three analyses of the pyroxenes from this intrusion are now available. Using nineteen of these, new trend lines have been drawn (fig. 1) for the Skaergaard clinopyroxenes.

Type
Research Article
Information
Mineralogical magazine and journal of the Mineralogical Society , Volume 29 , Issue 214 , September 1951 , pp. 690 - 714
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1951

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References

Baeth, (T. F. W.), 1931. Pyroxen von Hiva Oa, Marquesas–Inseln und die Formel titanhaltiger Augit. Neues Jahrb. Min., Alrt. A, vol. 64, pp. 217224. [M.A. 5–219.]Google Scholar
Bowen, (X.L.), 1914. The system diopside–forsterite–silica. Amer. Journ. Sci., ser. 4, vol. 38, pp. 207–204.Google Scholar
Bowen, (X.L.), 1935. "Ferrosilite" as a natural mineral. Amer. Journ. Sci., ser. 5, vol. 30, pp. 481–494. [M.A. 6 260.]Google Scholar
Bowen, (X.L.), and Schairkk, (J.F.), 1935. The system MgO–FeO–KiO2. Amer. Journ. Sci., ser. 5, vol. 29, pp. 151–247. [M.A. 6–352.]Google Scholar
Schairek, (J.F.), and Posnjak, (E.), 1933. The system CaO–FeO–SiO2. Amer. Journ. Sci., ser. 5, vol. 20, pp. 193–284. [M.A. 5–t54.]Google Scholar
Deer, (W.A.) and Waokr, (L.R.), 1938. Two new pyroxenes included in the system clinoenstatite, clinoferrosilite, diopside, and hedenbergite. Min. Mag., vol. 25, pp. 15–22.Google Scholar
Dixon, (B.E.) and Kennedy, (W.Q.), 1933. Optically un axial titanaugite from Aberdeenshire. Zeits. Krist., vol. 36, pp. 112120. [M.A. 5–440.]Google Scholar
Edwards, (A.B.), 1942. Differentiation in the dolerites of Tasmania. Journ. Geol., vol. 50, pp. 451 480,579–610. [M.A. 9–161.]Google Scholar
Henky, (X. F. M.), 1935. Home data on the iron–rich hypersthenes. Min. Mag., vol. 24, pp. 221–220.Google Scholar
Hess, (H.H.), 1941. Pyroxenes of common mafic magmas. Amer. Min., vol. 26, pp. 515–555, 573–579. [M.A. 8–233.1Google Scholar
Hess, (H.H.), 1949. Chemical composition and optical properties of common clinopyroxenes. Amer. Min., vol. 34, pp. 621—060. [M.A. 11 15.]Google Scholar
Kennedy, (G.C.), 1949. Equilibrium between volatiles and iron oxides in igneous rocks. Amer. Journ. Sci., vol. 246, pp. 529–549. [M.A. 10–424.]Google Scholar
Kennedy, (W.Q.), 1933. Trends of differentiation in basaltic magmas. Amer. Journ. Sei., ser. 5, vol. 25, pp. 239–256.Google Scholar
Poldervaart, (A.), 1944. The petrology of the Elephants' Head dyke and the New Amalfi sheet. Trans. Roy. Soc. South Africa, vol. 30, pp. 85–119.Google Scholar
Tilley, (C.E.), 1950. Some aspects of magmatie evolution. Quart. Journ. Geol. Soc. London, vol. 106, pp. 37–61.Google Scholar
Tomita, (T.), 1934. Variations in optical properties, according to chemical composition, in the pyroxenes … Journ. Shanghai Sei. Inst., sect. 2, vol. 1, pp. 41–58. [M.A. 6–71.]Google Scholar
Tsuboi, (S.), 1932. On the course of crystallization of pyroxenes from rock–magmas. Japanese Journ. Geol. Geogr., vol. 10, pp: 67–82. [M.A. 5–219.]Google Scholar
Wageir, (L.R.) and Deer, (W.A.), 1939. Geological investigations in east Greenland, Part III. Petrology of the Skaergaard intrusion, Kangerdlugssuaq, east Greenland. Medd om Gronland, vol. 105, no. 4, pp. 1–352. [M.A. 8–27.]Google Scholar
Walker, (F.) and Poldervaart, (A.), 1949. The Karroo dolerites of the Union of South Africa. Bull. Geol. Soc. Amer., vol. 60, pp. 591–705. [M.A. 11–32.]Google Scholar
Waaren, (B.E.) and Biscoe, (J.), 1931. The crystal structure of the monoclinic pyroxenes. Zeits. Krist., vol. 80, pp. 391–401. [M.A. 5–186.]Google Scholar
Waaren, (B.E.) and Biscoe, (J.), and BRAGC, (W. L.), 1928. The structure of diopside, CaMg(SiO3)2. Zeits. Krist., vol. 69, pp. 168–193. [M.A. 4–31.]Google Scholar