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Visits

Visits

1. Testing the mantle plume hypothesis: an IODP effort to drill into .. [223]
2. Elemental carbon record of paleofire history on the Chinese Loess .. [181]
3. Yaochong Mo deposit, a low-F porphyry Mo deposit from the Qinling-.. [178]
4. The enrichment of heavy iron isotopes in authigenic pyrite as a po.. [174]
5. The Subduction Factory: Geochemical perspectives [170]
6. The formation of the Late Cretaceous Xishan Sn-W deposit, South Ch.. [169]
7. Combined zircon and cassiterite U-Pb dating of the Piaotang granit.. [168]
8. Nanosecond laser ablation tandem inductively coupled plasma mass a.. [167]
9. Genesis of the Gaosong Sn-Cu deposit, Gejiu district, SW China: Co.. [166]
10. Major transition of continental basalts in the Early Cretaceous: I.. [165]
11. Mantle Source and Magmatic Evolution of the Dying Spreading Ridge .. [164]
12. Influence of pyroxene and spinel on the kinetics of peridotite ser.. [161]
13. Early Cretaceous high-Mg adakites associated with Cu-Au mineraliza.. [155]
14. The formation of Luoboling porphyry Cu-Mo deposit: Constraints fro.. [152]
15. Source of ore-forming fluids of the Yangshan gold field, western Q.. [151]
16. Oxygen fugacity and porphyry mineralization: A zircon perspective .. [150]
17. Early Cretaceous adakite from the Atlas porphyry Cu-Au deposit in .. [147]
18. Carbonated mantle domains at the base of the Earth's transition zo.. [145]
19. Global atmospheric oxygen variations recorded by Th/U systematics .. [145]
20. Penetration of Bomb C-14 Into the Deepest Ocean Trench [143]
21. Geochronological and geochemical constraints on the formation of C.. [143]
22. Composition comparison of Zhejiang Longquan celadon and its imitat.. [139]
23. Geological characteristics and geochronology of the Takht-e-Gonbad.. [134]
24. In situ elemental and Sr-O isotopic studies on apatite from the Xu.. [134]
25. Calcium Isotopic Compositions of Normal Mid-Ocean Ridge Basalts Fr.. [133]
26. Origins of two types of serpentinites from the Qinling orogenic be.. [132]
27. The formation of the South China Sea resulted from the closure of .. [131]
28. The genesis of early Carboniferous adakitic rocks at the southern .. [130]
29. Late Cretaceous granitic magmatism and mineralization in the Yingw.. [130]
30. Mid-Late Cretaceous igneous activity in South China: the Qianjia e.. [129]
31. Evolution of serpentinite from seafloor hydration to subduction zo.. [129]
32. Geochemical and Geochronological Constraints on the Origin and Emp.. [127]
33. Constraints on the origin of adakites and porphyry Cu-Mo mineraliz.. [126]
34. Calcium isotopic fractionation during plate subduction: Constraint.. [126]
35. Palaeoarchaean materials in the Tibetan Plateau indicated by zirco.. [125]
36. Geochemical constraints on genesis of Paleoproterozoic A-type gran.. [124]
37. Investigation of an oceanic plateau formation and rifting initiati.. [123]
38. Thermodynamic and Elastic Properties of Magnesite at Mantle Condit.. [122]
39. Geochemistry of I- and A-type granites of the Qingyang-Jiuhuashan .. [122]
40. Melt-Fluxed Melting of the Heterogeneously Mixed Lower Arc Crust: .. [121]
41. The formation of the giant Bayan Obo REE-Nb-Fe deposit, North Chin.. [119]
42. Iron isotopic composition of supra-subduction zone ophiolitic peri.. [119]
43. Genesis of tin-dominant polymetallic deposits in the Dachang distr.. [116]
44. Origin of Early Cretaceous Guandian adakitic pluton in central eas.. [114]
45. Crystal fractionation of granitic magma during its non-transport p.. [113]
46. Formation of A-type granites in the Lower Yangtze River Belt: A pe.. [113]
47. A 20 m.y. long-lived successive mineralization in the giant Dahuta.. [113]
48. Mineral paragenesis, fluid inclusions, H-O isotopes and ore-formin.. [113]
49. Early Cretaceous adakitic rocks in the Anqing region, southeastern.. [110]
50. Protoliths and tectonic implications of the newly discovered Trias.. [110]
51. Recycling of subducted carbonates: Formation of the Taohuala Mount.. [108]
52. Petrogenesis and metallogenic implications of Late Mesozoic intrus.. [106]
53. Insights into the origin of coexisting A(1)- and A(2)-type granite.. [100]
54. Newly discovered Late Triassic Baqing eclogite in central Tibet in.. [99]
55. Rhenium enrichment in the northwest Pacific arc [98]
56. Early cretaceous transformation from Pacific to Neo-Tethys subduct.. [98]
57. Marine Carbonate Component in the Mantle Beneath the Southeastern .. [96]
58. Jurassic and Cretaceous (Yanshannian) tectonics, magmatism and met.. [94]
59. Influence of pH on Molecular Hydrogen (H-2) Generation and Reactio.. [94]
60. Statistical analysis on secular records of igneous geochemistry: I.. [93]
61. Fluids, Metals, and Mineral/Ore Deposits [84]
62. MORB-like delta Fe-56 values unveil the effect of subduction on th.. [83]
63. Geochemistry of subducted metabasites exhumed from the Mariana for.. [80]
64. Boron, arsenic and antimony recycling in subduction zones: New ins.. [74]
65. Basalt derived from highly refractory mantle sources during early .. [74]
66. Multiple element mapping and in-situ S isotopes of Au-carrying pyr.. [69]
67. The Caroline Ridge fault system and implications for the bending-r.. [69]
68. Three late-Mesozoic fluorite deposit belts in southeast China and .. [66]
69. Diachronous subduction of the Proto-Tethys Ocean along the norther.. [64]
70. Plume-ridge interaction induced migration of the Hawaiian-Emperor .. [64]
71. Sun WD and Li CY. 2020. The geochemical behavior and mineralizatio.. [63]
72. Plate convergence in the Indo-Pacific region [63]
73. Occurrence of Halogenated Organic Pollutants in Hadal Trenches of .. [60]
74. New insights into Cryogenian arc granitoids hosting Th-U mineraliz.. [55]
75. Coupled Fe-S isotope composition of sulfide chimneys dominated by .. [54]
76. Zinc isotopic systematics of the South China Sea basalts and impli.. [53]
77. Gold and sulfur sources of the Taipingdong Carlin-type gold deposi.. [52]
78. The formation of the giant Huayangchuan U-Nb deposit associated wi.. [52]
79. Water in coesite: Incorporation mechanism and operation condition,.. [52]
80. Discovery of supercritical carbon dioxide in a hydrothermal system [51]
81. Traces of the 1997 Indonesian Wildfires in the Marine Environment .. [50]
82. Geochemistry of sulfide minerals from skarn Cu (Au) deposits in th.. [49]
83. Late Cambrian tonalite-trondhjemite association in the eastern seg.. [48]
84. Late Cambrian tonalite-trondhjemite association in the eastern seg.. [47]
85. Analogous diagenetic conditions of dark enclave and its host grani.. [46]
86. Geochemistry of pyrite from stratabound massive sulfide deposits, .. [46]
87. Petrogenesis of Early Cretaceous adakites in Tongguanshan Cu-Au po.. [46]
88. Extremely light K in subducted low -T altered oceanic crust: Impli.. [45]
89. The synchronic Cenozoic subduction initiations in the west Pacific.. [45]
90. Petrogenesis and tectonic implications of cambrian Nb-enriched I- .. [44]
91. Plate subduction, oxygen fugacity, and mineralization [42]
92. Progress of the researches on Kamchatka Arc magmatism [42]
93. Thermodynamic properties of ruthenium (IV) chloride complex and th.. [42]
94. Transition of subduction-related magmatism from slab melting to de.. [40]
95. Lithium systematics in global arc magmas and the importance of cru.. [40]
96. Calcium isotopic signatures of depleted mid-ocean ridge basalts fr.. [39]
97. Significant delta Ca-44/40 variations between carbonate- and clay-.. [37]
98. Iron Isotope Behavior During Melt-Peridotite Interaction in Supra-.. [37]
99. Effect of pressure on the kinetics of peridotite serpentinization [37]
100. The mobility of platinum-group elements in the hydrothermal fluids [35]