ABSTRACT
The blue amphibole asbestos, crocidolite, which occurs as interbedded seams in banded ironstones of the Lower Griquatown stage of the Transvaal System in the Northern Cape Province, is the finely fibrous form of the soda-amphibole riebeckite. Despite the widespread occurrence of the Precambrian type of banded ironstones, crocidolite is a mineral of rare occurrence and is only developed to a relatively minor extent in South Afric.a, Western Australia and Central China. The composition, structure and properties of riebeckite in general and of crocidolite in particular are discussed and four new chemical analyses are given. Particular attention is paid to the mode of occurrence of fibrous riebeckite and it is suggested that the name "crocidolite" be reserved for the asbestiform riebeckite which occurs interbedded with banded ironstones. The general geology, lithology and mineralogy of Precambrian banded ironstones are described and their distribution in space and time is discussed. It is found .that no banded ironstones are known to be younger than 1000 million years. This fact is related tospecial conditions of atmosphere, surface temperature and biological development which existed duri~g the so-called Primitive Period of the Precambrian, a period which lasted from apnroximately 3000 million years to 1000 million years ago. The banded ironstones of the Transvaal System are described in some detail and seven new chemical analyses as well as trace element data are given. The genesis of banded ironstones is discussed at some length and particular attention is paid to the authigenesis of riebeckite. It is concluded that banded ironstones were deposited in seasonally fluctuating, typically "non-aggressive", fresh to brackish water lakes which were fed by sluggish, mature rivers. The solutions of iron and silica, alkaline earths and clay colloids carried by these rivers were derived from basic igneous rocks by chemical weathering in a tropical, monsoon-type climate. Recognisable detrital material is virtually absent from the banded ironstones of the Transvaal System, but it is thought that the stilpnomelane layers are aeolian deposits and that their composition gives some indication of the material which remained behind as "lateritic" soils in the source area. It is suggested that both crocidolite and riebeckite were formed by the low temperature " dehydration, in situ, of an ordered precursor which could have been a clay mineral similar in structure to attapulgite, but containing ferrous and ferric ions in the octahedral layer. This clay mineral acquired sodium by cation exchange during dry periods when the depositional lakes were enriched in sodium.
, J (2021). The Genesis of The Blue Amphibole Asbestos of The Union Of South Africa. Afribary. Retrieved from https://track.afribary.com/works/the-genesis-of-the-blue-amphibole-as-bestos-of-the-union-of-south-africa
, J.H.GENIS "The Genesis of The Blue Amphibole Asbestos of The Union Of South Africa" Afribary. Afribary, 23 Apr. 2021, https://track.afribary.com/works/the-genesis-of-the-blue-amphibole-as-bestos-of-the-union-of-south-africa. Accessed 27 Nov. 2024.
, J.H.GENIS . "The Genesis of The Blue Amphibole Asbestos of The Union Of South Africa". Afribary, Afribary, 23 Apr. 2021. Web. 27 Nov. 2024. < https://track.afribary.com/works/the-genesis-of-the-blue-amphibole-as-bestos-of-the-union-of-south-africa >.
, J.H.GENIS . "The Genesis of The Blue Amphibole Asbestos of The Union Of South Africa" Afribary (2021). Accessed November 27, 2024. https://track.afribary.com/works/the-genesis-of-the-blue-amphibole-as-bestos-of-the-union-of-south-africa