Geochemical Characteristics of Mafic Rocks from the Xinlin Ophiolite, NE China

Located in the northern part of the Xinlin–Xiguitu suture zone,geochemistry and geochronology of the Xinlin ophiolite provide a unique opportunity to determine the the evolution of the eastern Xing’an–Mongolian Orogenic Belt.The Xinlin ophiolite was initially constrained roughly 21.5 km southeast of the Xinlin town by the First Regional Geological Survey Party of Heilongjiang Province.Subsequent work has shown that the mafic and ultramafic rocks in the adjacent Tayuan town was congenetic with the Xinlin ophiolite(Fig.1).Over the past three years we have conducted a series of studies to the Xinlin ophiolite with the aim to better understand its characteristic and tectonic implications.The present work is is to provide our preliminary geochemical data of the mafic rocks of the Xinlin ophiolite and possible'congenetic'mafic rocks in the Tayuan town.The mafic rocks of the Xinlin ophiolite including the gabbro,diabase and metabasalt show flat REE pattern[(La/Yb)N=0.68~1.58]and no Eu anomalies,which are transitional between normal and enriched mid-ocean ridge basalts(N-MORB and E-MORB).They also exhibit flat patterns from Ba to Yb in the trace elements spider diagram,which lie between those of typical E-MORB and N-MORB but closer to the former.The mafic rocks in the Tayuan town consist mainly of hornblende gabbro with alkaline affinity and are characterized by enriched in light rare earth elements and large ion lithophile elements,depleted in heavy rare earthelements and high field strength elements(Fig.2).The obvious differences in the geochemical characteristics indicate that the mafic rocks in the Tayuan town may not be cogenetic with those of the Xinlin ophiolite.This was further corroborated by their different formation time.Our zircon U–Pb dating indicates that the gabbro in the Tayuan town was emplaced during the late Carboniferous(~310 Ma;Fig.3),significantly younger than the recently reported U–Pb ages for the mafic rocks of the Xinlin ophiolite(~510 Ma;Feng,2015).Therefore,the two units appear as independent bodies and their origin and tectonic implication need to be further examined.

Geochemical Characteristics of the Tayuan Volcanic Rocks in the Daxinganling Metallogenic Belt

1 Introduction Daxinganling region is one of the most important nonferrous metal metallogenetic province(Wu et al.,2011;Li et al.,2014).The northern Daxinganling was a geological blank area in China formerly(Li et al.,2017).However,the region has a huge resource potential.Forty metal deposits have been found in the area recently,with

Geochemical characteristics and geological significance of picritic rocks in Permian Tiaohu Formation from Santanghu Basin, Xinjiang, NW China

1 Introduction Santanghu Basin is located between the Armantai and Karamaili suture zone,at the junction of the Siberia,Kazakhstan and Tarim plates(Chen and Jahn,2004;Xiao et al.,2008).As an important part of the Central Asian

Geochemical Characteristics of the Source Rocks in Mesozoic Yanchang Formation,Central Ordos Basin

The shale of Yanchang Formation in Upper Triassic is the most important source rock for the Mesozoic petroleum reserviors in Ordos Basin. Chang 7 and Chang 4＋5 members are the major source rock formation. Source rock samples, obtained from 22 cored wells in central Ordos Basin, were geochemically analyzed to determine the organic matter abundance, kerogen type and thermal maturity. Total organic carbon values ranged from 0.36% to 19.10%, 8.09% on average, in- dicating a good source rock potential. In this area, the shale is mature, as indicated by vitrinite re- flectance values. RockoEval data revealed that the samples are dominated by type II kerogen. Com- pare the Chang 7 and Chang 4＋5 members, which suggests that the Chang 7 shale has higher TOC, especially the highest lower Chang 7 members. The abundance of organic matter of Chang 4＋5 and Chang 7 members is both richest in southeast basin. The kerogen type of Chang 4＋5 and upper Chang 7 members is type II~, the counterpart of middle and lower Chang 7 member is type I. During the burial history, the total hydrocarbon-generating quantity of Chang 7 member is much more than that of Chang 4＋5 members.