Get 20M+ Full-Text Papers For Less Than $1.50/day. Start a 14-Day Trial for You or Your Team.

Learn More →

The Earth's Lower MantleDiamond in the Lower Mantle

The Earth's Lower Mantle: Diamond in the Lower Mantle [Diamond contains mineral inclusions of all three lower-mantle associations, juvenile ultramafic, mafic and carbonatitic; it is also an accessory mineral in all these associations. While the first two associations coexist with diamond, the carbonatitic associationCarbonatitic association is a parental medium for the lower-mantle diamond. Physical and chemical characteristics of lower-mantle diamond differ from ones of lithospheric origin. Most of the lower-mantle diamonds are ‘nitrogenNitrogen-free’ Type II variety. The others are usually low-nitrogen stones with the average nitrogen aggregation rate of 94%. The high proportion of nitrogen-aggregated diamonds suggests that they had a prolonged residence in the lower mantle under high-T conditions, which resulted in an almost complete transformation of single-atomic and paired nitrogen centers into polyatomic complexes. In contrast to lithospheric diamonds, almost all analyzed lower-mantle ones (70–89%) have noticeable levels of hydrogen centers (up to 4–6 cm−1). The isotopic compositions of lower-mantle diamonds are located within a narrow range: from −5.45 to −1.26‰ δ13C VPDB, with an average value of −4.36‰ ± 2.28‰ (2σ). It may be considered as the juvenile lower-mantle carbonCarbon isotopic composition. The isotopic composition of nitrogen for lower-mantle diamonds is located within a close range, from −5.2 to −1.0‰ δ15Natm, with an average value of δ15Natm = −3.00‰ ± 2.37‰ δ15Natm. Lower-mantle diamond was formed in carbonate-oxide parental melts and fluids, which experienced fractional crystallization with the decrease of temperature and changes in the melt composition. The most important role in this process belongs to the carbonate component in the parental melt.] http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png

The Earth's Lower MantleDiamond in the Lower Mantle

Part of the Springer Geology Book Series
Kaminsky, Felix V.
The Earth's Lower Mantle — May 23, 2017
Download PDF
28 pages

Loading next page...
 
/lp/springer-journals/the-earth-s-lower-mantle-diamond-in-the-lower-mantle-nlEJEiv4oa
Publisher
Springer International Publishing
Copyright
© Springer International Publishing AG 2017
ISBN
978-3-319-55683-3
Pages
229 –257
DOI
10.1007/978-3-319-55684-0_7
Publisher site
See Chapter on Publisher Site

Abstract

[Diamond contains mineral inclusions of all three lower-mantle associations, juvenile ultramafic, mafic and carbonatitic; it is also an accessory mineral in all these associations. While the first two associations coexist with diamond, the carbonatitic associationCarbonatitic association is a parental medium for the lower-mantle diamond. Physical and chemical characteristics of lower-mantle diamond differ from ones of lithospheric origin. Most of the lower-mantle diamonds are ‘nitrogenNitrogen-free’ Type II variety. The others are usually low-nitrogen stones with the average nitrogen aggregation rate of 94%. The high proportion of nitrogen-aggregated diamonds suggests that they had a prolonged residence in the lower mantle under high-T conditions, which resulted in an almost complete transformation of single-atomic and paired nitrogen centers into polyatomic complexes. In contrast to lithospheric diamonds, almost all analyzed lower-mantle ones (70–89%) have noticeable levels of hydrogen centers (up to 4–6 cm−1). The isotopic compositions of lower-mantle diamonds are located within a narrow range: from −5.45 to −1.26‰ δ13C VPDB, with an average value of −4.36‰ ± 2.28‰ (2σ). It may be considered as the juvenile lower-mantle carbonCarbon isotopic composition. The isotopic composition of nitrogen for lower-mantle diamonds is located within a close range, from −5.2 to −1.0‰ δ15Natm, with an average value of δ15Natm = −3.00‰ ± 2.37‰ δ15Natm. Lower-mantle diamond was formed in carbonate-oxide parental melts and fluids, which experienced fractional crystallization with the decrease of temperature and changes in the melt composition. The most important role in this process belongs to the carbonate component in the parental melt.]

Published: May 23, 2017

Keywords: Electron Paramagnetic Resonance; Fractional Crystallization; Diamond Crystal; Total Nitrogen Content; Parental Medium

There are no references for this article.