Peridotites chondrite-normalized patterns

Chondrite-normalized REE patterns. With regard to chondrite-normalized REE distributions in whole rocks, the tectonically emplaced and abyssal peridotites may be subdivided in six main groups ... 

Figure 23 Chondrite-normalized abundances of REEs in representative harzburgites from the Oman ophiolite (symbols—whole-rock analyses), compared with numerical experiments of partial melting performed with the Plate Model of Vemieres et al. (1997), after Godard et al. (2000) (reproduced by permission of Elsevier from Earth Planet. Set Lett. 2000, 180, 133-148). Top melting without (a) and with (b) melt infiltration. Model (a) simulates continuous melting (Langmuir et al., 1977 Johnson and Dick, 1992), whereas in model (b) the molten peridotites are percolated by a melt of fixed, N-MORB composition. Model (b) is, therefore, comparable to the open-system melting model of Ozawa and Shimizu (1995). The numbers indicate olivine proportions (in percent) in residual peridotites. Bolder lines indicate the REE patterns of the less refractory peridotites. In model (a), the most refractory peridotite (76% olivine) is produced after 21.1% melt extraction. In model (b), the ratio of infiltrated melt to peridotite increases with melting degree, from 0.02 to 0.19. Bottom modification of the calculated REE patterns residual peridotites due to the presence of equilibrium, trapped melt. Models (c) and (d) show the effect of trapped melt on the most refractory peridotites of models (a) and (b), respectively. Bolder lines indicate the composition of residual peridotites without trapped melt. Numbers indicate the proportion of trapped melt (in percent). Model parameters...

Figure 15 Illustration of the effects of host-rock contamination on whole-rock REE geochemistry. Chondrite-normalized REE patterns of measured whole-rock peridotites compared with REE abundances calculated from modal data plus mineral compositions. Also compared are mixtures of calculated whole-rock and kimberlite for each diagram. Two specimens, (a) and (b) are high-r and low-T garnet Iherzolites from Somerset Island, Nunuvut (Canada) (after Schmidberger and Erancis, 2001).

Figure 17 Summary fields of chondrite-normalized REE patterns for whole-rock peridotites and cUnopyroxenes for peridotite xenoliths. Noncratonic whole-rock peridotites are either LREE-depleted (type lA least common) or LREE-enriched (type IB most common). Data sources from Stosch and Seek (1980), Stosch and Lugmair (1986), Menzies et al (1985). Clinopyroxenes from these rocks also show LREE enrichment or depletion. Cratonic peridotite whole rocks are ubiquitously LREE-enriched. Low-T (granular) suite show greater LREE/HREE compared to high-T (sheared) suite and this is reflected in the more LREE-enriched clinopyroxene compositions in the low-T suite. Data sources from Shimizu (1975), Nixon et al. (1981), and Irvine (2002). Low-T whole-rock suite includes 19 samples...

Fig. 6. Chondrite-normalized PGE patterns of whole-rock peridotites from the Jericho kimberlite. Northern Slave Craton and for Kaapvaal peridotites. Data from Table 1. Normalizing values taken from McDonald et al. (1995).

The chemical diversity of mantle pyroxenites is also patent from REE variations. Figure 26 shows the chondrite-normalized REE patterns of representative pyroxenites from orogenic peridotite massifs in Eastern Pyrenees (Lherz and Freychi-nede) and the Betico-Rifean Belt (Ronda and Beni Bousera). These rocks show variable REE distributions, but some relationships are observed between the structural and/or mineralogical types of pyroxenites and the REE patterns ... 

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