Paleoclimate, provenance, and tectonic setting of the First Member of the Paleogene Shahejie Formation in the southern slope of Huanghekou Sag
-
摘要:
碎屑沉积岩的主微量元素记录了丰富的地球化学信息,可用于古气候、物源及构造背景的恢复。通过对黄河口凹陷南斜坡古近系沙河街组一段(沙一段,E1s1)碎屑沉积岩元素地球化学分析,探讨了沙一段沉积时期古气候、物源及构造背景。Th/Sc-Zr/Sc图解和成分变异指数(ICV)表明,研究区沙一段物源为母岩风化后的首次沉积,成分成熟度较高;校正后的化学蚀变指数(CIAcorr)和钾长石蚀变指数(PIA)表明沙一段物源经历了中等程度的风化作用,沙一段沉积时期气候温暖湿润;主、微量和稀土元素显示,沙一段物源主要表现为上地壳来源长英质火成岩的特征,具有明显的负Eu异常,主要来源于前寒武纪花岗岩类岩石和少量中基性混合物源;物源区具有活动大陆边缘和大陆岛弧的构造背景,较为复杂的构造背景与西太平洋板块向东亚大陆俯冲有关。
Abstract:The major and trace elements in clastic sedimentary rocks record abundant geochemical information, and can be used to reconstruct paleoclimate, provenance, and tectonic setting. Geochemical analysis of inorganic element in clastic sedimentary rocks of the first member of the Paleogene Shahejie Formation (E1s1) in the southern slope of Huanghekou Sag was conducted, and the paleoclimate, provenance and tectonic setting of the Es1 were discussed. Th/Sc-Zr/Sc diagram and index of compositional variability (ICV) indicate that the source of the Es1 in the study area was the first deposition unit after weathering of the parent rocks, and the compositional maturity was relatively high. The corrected chemical index of alteration (CIAcorr) and plagioclase index of alteration (PIA) indicate that the source of the Es1 underwent moderate weathering, and the sedimentary period was warm and humid paleoclimatic conditions. Major, trace, and rare earth elements show that the provenance of Es1 is characterized by upper crust derived felsic igneous rocks, featuring obvious negative Eu anomaly, and the materials of provenance was mainly derived from Precambrian granitoids and some intermediate-basic mixture sources. The tectonic background of the provenance area was active continental margin and continental island arc. The complex tectonic background was related to the subduction of the Western Pacific plate to the East Asian continent.
-
Key words:
- provenance /
- paleoclimate /
- tectonic setting /
- the First Member of Shahejie Formation /
- Huanghekou Sag
-
-
表 1 沙一段主量元素含量及相关参数
Table 1. Content of major elements and related parameters of the E1s1
岩性 样品编号 主量元素/% 烧失量/% 主量元素相关参数 SiO2 Al2O3 Fe2O3T MgO CaO Na2O K2O MnO TiO2 P2O5 FeO Fe2O3 ICV CIAcorr PIA K2O/
Na2OSiO2/
Al2O3F1 F2 F3 F4 泥岩 B-2 53.62 21.56 6.28 1.69 0.316 1.02 5.1 0.041 0.871 0.079 2.5 3.78 9.32 0.71 80.31 88.60 5.00 2.49 0.02 1.22 0.72 0.02 B-3 56.75 19.78 6.07 1.29 0.398 2.18 4.46 0.08 1.01 0.057 3.37 2.7 7.84 0.78 72.67 78.18 2.05 2.87 0.46 2.48 1.12 −0.42 B-7 60.79 20.44 3.21 1.13 0.369 2.11 4.64 0.039 0.951 0.064 2.1 1.11 6.19 0.61 73.63 79.45 2.20 2.97 −1.53 3.44 2.76 0.70 B-11 54.45 21.53 5.19 1.57 0.687 2.04 4.84 0.072 1.14 0.095 3.42 1.77 8.24 0.72 73.13 78.82 2.37 2.53 −0.17 3.12 1.85 0.72 C-1 60.52 16.49 5.99 2.19 0.673 1.61 3.42 0.076 0.766 0.106 3.74 2.25 8.11 0.89 72.16 77.94 2.12 3.67 −1.50 −1.36 −0.02 0.66 C-2 59.23 16.85 6.3 2.3 0.719 1.5 3.51 0.078 0.772 0.102 3.62 2.68 8.54 0.90 72.76 78.71 2.34 3.52 −1.31 −1.54 −0.22 0.68 C-3 59 17.07 6.18 2.31 0.731 1.48 3.52 0.078 0.77 0.101 3.55 2.63 8.64 0.88 72.95 79.01 2.38 3.46 −1.28 −1.51 −0.21 0.72 C-4 59.42 16.69 6.29 2.39 0.795 1.49 3.44 0.078 0.759 0.106 3.61 2.68 8.47 0.91 72.23 78.07 2.31 3.56 −1.42 −1.76 −0.30 0.81 C-5 58.27 17.07 5.9 2.46 0.999 1.34 3.45 0.071 0.779 0.101 3.38 2.52 9.52 0.88 72.05 77.92 2.57 3.41 −1.52 −1.78 −0.16 1.20 C-6 44.71 14.93 6.13 2.35 3.59 0.774 2.79 0.11 0.593 0.377 3.01 3.12 23.62 1.09 75.18 63.32 3.60 2.99 1.83 −1.90 −1.92 0.54 泥质粉砂岩 A-1 63.62 17.62 4.41 0.788 0.52 2.19 3.08 0.048 0.746 0.097 2.14 2.27 6.79 0.67 70.69 76.80 1.41 3.61 0.80 1.11 −0.21 −1.57 A-2 61.98 17.07 5.4 1.21 0.565 1.99 3.35 0.097 0.882 0.083 4.01 1.39 7.36 0.79 70.95 76.62 1.68 3.63 −0.08 0.51 0.10 −0.67 A-3 65.02 16.54 4.37 0.978 0.493 2.13 3.38 0.064 0.792 0.077 2.72 1.65 6.08 0.74 70.13 75.34 1.59 3.93 −0.84 1.12 0.99 −0.66 A-4 66.74 13.43 3.59 1.26 2.46 2.56 2.55 0.095 0.468 0.063 2.59 1 6.66 0.97 54.08 55.56 1.00 4.97 −0.66 0.98 1.04 −0.85 B-1 62.97 15.8 5.7 1.14 0.58 2.2 3.73 0.109 0.807 0.07 3.79 1.91 6.77 0.90 68.47 72.30 1.70 3.99 −0.83 1.26 1.22 −0.83 B-4 64.36 17.82 3.51 0.826 0.411 2.6 4.04 0.044 0.839 0.058 1.91 1.6 5.46 0.69 69.06 73.35 1.55 3.61 −1.27 3.28 2.71 −0.21 B-5 63.03 17.72 4.01 1.07 0.429 2.23 4.08 0.088 0.913 0.071 2.84 1.17 6.24 0.72 70.88 75.67 1.83 3.56 −1.63 2.46 2.47 0.30 B-6 64.43 17.58 3.5 0.999 0.4 2.32 4.04 0.06 0.897 0.069 2.54 0.96 5.7 0.69 70.45 75.10 1.74 3.66 −1.96 2.66 2.82 0.42 B-8 61.43 19.36 3.62 1.07 0.699 2.07 4.23 0.049 0.892 0.069 2.31 1.31 6.44 0.65 71.37 76.62 2.04 3.17 −0.94 2.79 2.11 0.24 B-9 61.28 17.82 4.58 1.32 0.555 2.1 4.26 0.085 0.866 0.079 3.25 1.33 6.93 0.77 70.97 75.55 2.03 3.44 −1.58 2.18 2.31 0.37 B-10 63.02 17.95 3.57 1.2 0.687 2.23 4.23 0.044 0.886 0.082 2.29 1.28 6.06 0.72 69.67 73.90 1.90 3.51 −2.04 2.74 2.96 0.75 B-11 60.8 17.78 4.78 1.26 0.504 2.14 4.23 0.107 0.942 0.08 3.63 1.15 7 0.79 71.04 75.67 1.98 3.42 −1.44 2.26 2.26 0.36 砂岩 B-12 68.32 12.11 1.76 1.11 3.97 3.27 3.01 0.044 0.246 0.071 1.55 0.21 5.94 1.11 46.60 41.60 0.92 5.64 −1.62 3.90 5.14 −0.19 B-13 69.24 14.25 1.45 0.888 2.04 3.33 3.35 0.022 0.338 0.061 1.19 0.26 4.64 0.80 53.84 54.02 1.01 4.86 −2.06 4.04 4.66 −0.38 
下载: 导出CSV
表 2 沙一段微量及稀土元素含量及相关参数
Table 2. Contents of trace and rare earth elements and related parameters in the E1s1
岩性 样品编号 微量元素/10−6 微量元素相关参数 稀土元素/10−6 稀土元素相关参数 Sc V Cr Co Ni Cu Zn Rb Sr Ba Th U Zr Hf Zr/Sc Th/Sc La/Th La/Sc Co/Th La Ce Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb Lu ∑REE
/10−6L/H La/Yb GdN/
YbNδEu 泥岩 B-2 17.8 120 128 19 41.6 33.5 117 221 268 1570 15.5 2.73 141 4.24 7.92 0.87 3.39 2.95 1.23 52.5 99 11.4 42.4 6.42 1.32 5.65 0.866 4.38 0.824 2.58 0.423 2.54 0.373 230.68 12.08 20.67 1.79 0.66 B-3 16.9 115 160 14 24 54.4 162 146 291 1482 14.6 3.14 160 4.8 9.47 0.86 3.95 3.41 0.96 57.7 100 12.4 46 6.94 1.33 5.86 0.953 4.82 0.88 2.93 0.509 3.27 0.494 244.09 11.38 17.65 1.45 0.62 B-7 14.6 109 149 16.9 30.4 51.7 189 171 307 1458 15.1 2.55 145 4.79 9.93 1.03 3.40 3.51 1.12 51.3 91.9 11.1 40.2 6.22 1.21 4.92 0.782 4.11 0.725 2.58 0.457 2.73 0.393 218.63 12.09 18.79 1.45 0.65 B-11 17.3 119 160 13.8 29.3 33.6 108 169 314 1660 15.9 2.38 169 5.72 9.77 0.92 3.72 3.42 0.87 59.1 107 12.6 43.5 6.6 1.56 6.11 0.902 4.78 0.877 3.04 0.469 3.05 0.495 250.08 11.68 19.38 1.62 0.74 C-1 13.3 91.3 120 16.9 35.3 28.4 94.7 135 339 872 12 1.88 125 3.52 9.40 0.90 3.81 3.44 1.41 45.7 88.3 10.5 36.8 5.95 1.43 5.5 0.865 4.53 0.762 2.69 0.394 2.29 0.363 206.07 10.85 19.96 1.94 0.75 C-2 15.3 100 123 18.6 39.7 29.2 98.6 144 322 849 13 2.02 129 3.78 8.43 0.85 3.87 3.29 1.43 50.3 95.7 11 40.1 6.85 1.5 5.48 0.872 4.68 0.911 2.53 0.389 2.4 0.413 223.13 11.62 20.96 1.84 0.73 C-3 14 104 110 16.9 35.8 29.4 99.1 134 323 811 12.6 1.98 120 3.64 8.57 0.90 3.95 3.56 1.34 49.8 92.6 10.5 38.2 6.25 1.45 5.73 0.882 4.65 0.889 2.67 0.403 2.45 0.398 216.87 11.00 20.33 1.89 0.73 C-4 15 95.3 122 16.5 36.6 30.4 87.8 144 359 827 11.9 2.03 130 3.65 8.67 0.79 4.26 3.38 1.39 50.7 97.7 11 40.4 6.77 1.42 5.69 0.896 4.81 0.796 2.64 0.403 2.68 0.374 226.28 11.37 18.92 1.71 0.68 C-5 14.8 91.7 114 12.3 28.8 31.8 102 146 355 815 12.6 2.42 132 3.77 8.92 0.85 4.40 3.74 0.98 55.4 105 11.9 44.1 7.49 1.65 6.55 0.976 5.2 0.898 2.87 0.381 2.58 0.436 245.43 11.34 21.47 2.05 0.70 C-6 15.5 196 106 27.7 63.6 87.1 200 117 475 728 12.5 7.17 121 3.22 7.81 0.81 3.92 3.16 2.22 49 96.6 10.8 42.7 7.47 1.48 6.14 1.07 5.62 1.13 3.34 0.466 2.93 0.478 229.22 9.83 16.72 1.69 0.65 泥质粉砂岩 A-1 11 85.9 159 17.3 42.8 44.5 178 98.7 472 893 10.6 2.58 123 3.97 11.18 0.96 4.22 4.06 1.63 44.7 84.2 11.4 39.7 7.14 1.78 6.17 0.892 4.43 0.844 2.67 0.385 2.37 0.339 207.02 10.44 18.86 2.10 0.80 A-2 12.9 85.5 152 18.6 34.8 53 183 119 365 920 12.6 2.61 138 4.58 10.70 0.98 4.09 3.99 1.48 51.5 90.7 11.3 41.6 6.08 1.4 5.43 0.873 4.31 0.855 2.7 0.459 2.73 0.408 220.35 11.40 18.86 1.61 0.73 A-3 9.79 78.1 129 14.9 33.3 24.7 102 111 371 1053 11.6 2.57 133 4.06 13.59 1.18 4.19 4.96 1.28 48.6 86.7 10.2 38.4 6.15 1.14 4.96 0.869 4.28 0.737 2.34 0.393 2.27 0.36 207.40 11.80 21.41 1.76 0.61 A-4 11.7 61.9 130 8.72 22.8 37.7 140 74.2 432 860 7.21 1.88 86.5 2.58 7.39 0.62 4.48 2.76 1.21 32.3 55.1 7.14 27 4.64 1.14 4.1 0.702 3.43 0.666 1.94 0.314 1.89 0.29 140.65 9.55 17.09 1.75 0.78 B-1 12.9 74.7 140 18.5 32.2 25 71.5 118 273 1153 10.5 3.37 135 4.33 10.47 0.81 4.17 3.40 1.76 43.8 78.8 9.82 33.8 5.5 1.15 4.8 0.769 4.24 0.871 2.83 0.446 2.67 0.436 189.93 10.13 16.40 1.45 0.67 B-4 10.8 82.6 139 11.4 23.9 50.4 153 123 312 1374 11.5 2.72 136 4.27 12.59 1.06 4.40 4.69 0.99 50.6 87 10.6 37.6 6.17 1.23 5.14 0.772 4.29 0.808 2.54 0.431 2.94 0.436 210.56 11.13 17.21 1.41 0.65 B-5 13 107 136 17 30.8 56.6 177 132 288 1333 12.2 2.55 138 4.34 10.62 0.94 4.27 4.01 1.39 52.1 92.4 11.4 38.9 6.13 1.34 5.63 0.858 4.32 0.909 2.93 0.445 2.56 0.454 220.38 11.17 20.35 1.77 0.69 B-6 12.1 87.5 151 17.5 33.5 55.6 189 143 343 1485 12.2 2.66 147 4.3 12.15 1.01 4.49 4.53 1.43 54.8 97.7 11.4 42 6.76 1.44 5.42 0.838 4.44 0.801 2.62 0.42 2.88 0.436 231.96 11.99 19.03 1.52 0.70 B-8 13.3 88.1 194 10.6 21.1 28.3 110 142 309 1381 12.6 2.66 132 4.49 9.92 0.95 3.92 3.71 0.84 49.4 88.2 10.1 35.5 5.26 0.994 4.44 0.691 3.67 0.743 2.44 0.398 2.68 0.403 204.92 12.25 18.43 1.34 0.61 B-9 14.2 71.7 138 20.9 36.4 30.8 108 151 301 1322 12.1 2.27 130 3.77 9.15 0.85 4.21 3.58 1.73 50.9 91 10.6 39.1 6.73 1.25 5.11 0.842 4.78 0.822 2.6 0.398 2.58 0.405 217.12 11.38 19.73 1.60 0.63 B-10 12 89.3 164 13.4 28.1 28 89.7 139 304 1296 12.2 2.24 146 4.26 12.17 1.02 4.31 4.38 1.10 52.6 90.8 10.4 39.3 6.27 1.17 5.07 0.755 3.93 0.719 2.4 0.396 2.62 0.412 216.84 12.30 20.08 1.56 0.62 B-11 14.6 100 154 20.2 37.3 32.6 93.3 148 296 1273 13.6 2.46 132 3.6 9.04 0.93 3.85 3.58 1.49 52.3 98 11.2 43.8 6.42 1.26 5.78 0.966 4.76 0.857 2.86 0.451 2.84 0.422 231.92 11.25 18.42 1.64 0.62 砂岩 B-12 4.14 28.8 157 4.54 12.3 4.88 20.9 77 371 1068 4.38 1.3 42.8 1.25 10.34 1.06 5.25 5.56 1.04 23 41.5 4.86 18.4 3.19 0.705 2.56 0.441 2.15 0.434 1.32 0.173 1.27 0.179 100.18 10.75 18.11 1.63 0.73 B-13 4.41 38.3 152 4.08 9.46 6.78 28.6 81.6 342 1158 4.95 1.32 62.4 1.74 14.15 1.12 5.68 6.37 0.82 28.1 46 5.72 20.8 3.43 0.753 2.87 0.431 2.25 0.412 1.28 0.192 1.28 0.192 113.71 11.77 21.95 1.81 0.71
下载: 导出CSV
表 3 研究区沙一段碎屑沉积岩与不同构造背景沉积盆地杂砂岩的REE特征对比
Table 3. Comparison in REE characteristics between clastic sedimentary rocks in E1s1 and greywacke of sedimentary basins in different tectonic settings
构造背景 源区类型 La/10−6 Ce/10−6 ∑REE/10−6 L/H La/ Yb LaN/YbN δEu 大洋岛弧 未切割的岩浆弧 8(1.7) 19(3.7) 58(10) 3.8(0.9) 4.2(1.3) 2.8(0.9) 1.04(0.11) 大陆岛弧 切割的岩浆弧 27(4.5) 59(8.2) l46(20) 7.7(1.7) 11(3.6) 7.5(2.5) 0.79(0.13) 活动大陆边缘 上隆的基底 37 78 186 9.1 12.5 8.5 0.6 被动大陆边缘 克拉通内部构造高地 39 85 210 8.5 15.9 10.8 0.56 泥岩平均值 52.15 97.38 229.05 11.32 19.48 13.14 0.69 矫正后泥岩 43.46 81.15 190.88 泥质粉砂岩平均值 48.63 86.72 208.25 11.23 18.82 12.69 0.68 矫正后泥质粉砂岩 40.53 72.27 173.54 砂岩平均值 25.55 43.75 106.95 11.26 20.03 13.51 0.72 注:括号内数值为标准偏差,构造背景的数据引自文献[49]。
下载: 导出CSV
-
[1] ARMSTRONG-ALTRIN J S,MACHAIN-CASTILLO M L,ROSALES-HOZ L,et al. Provenance and depositional history of continental slope sediments in the Southwestern Gulf of Mexico unraveled by geochemical analysis[J]. Continental Shelf Research,2015,95:15-26. doi: 10.1016/j.csr.2015.01.003
[2] BHATIA M R. Plate tectonics and geochemical composition of sandstones[J]. The Journal of Geology,1983,91(6):611-627. doi: 10.1086/628815
[3] 邵磊,刘志伟,朱伟林. 陆源碎屑岩地球化学在盆地分析中的应用[J]. 地学前缘,2000,7(3):297-304.
[4] 李乐,姚光庆,刘永河,等. 塘沽地区沙河街组下部含云质泥岩主微量元素地球化学特征及地质意义[J]. 地球科学(中国地质大学学报),2015,40(9):1480-1496.
[5] MCLENNAN S M,HEMMING S,MCDANIEL D K,et al. Geochemical approaches to sedimentation,provenance,and tectonics[J]. Special Papers-Geological Society of America,1993,284:21-40.
[6] CULLERS R L. The controls on the major and trace element variation of shales,siltstones,and sandstones of Pennsylvanian-Permian age from uplifted continental blocks in Colorado to platform sediment in Kansas,USA[J]. Geochimica et Cosmochimica Acta,1994,58(22):4955-4972. doi: 10.1016/0016-7037(94)90224-0
[7] CULLERS R L. The controls on the major-and trace-element evolution of shales,siltstones and sandstones of Ordovician to tertiary age in the Wet Mountains region,Colorado,U. S. A.[J]. Chemical Geology,1995,123(1):107-131.
[8] 杜晓峰,加东辉,王启明,等. 盆内局部物源体系及其油气勘探意义:以渤海海域古近系为例[J]. 中国海上油气,2017,29(4):19-27.
[9] 陈延芳,杜晓峰,王清斌,等. 渤海黄河口东洼古地貌对沉积相的控制作用[J]. 石油地质与工程,2020,34(3):20-23.
[10] 李森. 渤海湾盆地黄河口凹陷古近系混积岩“源-汇-岩-储”一体化优质储层预测[D]. 北京: 中国地质大学, 2020. DOI: 10.27492/d.cnki.gzdzu.2020.000042.
[11] 王改卫,张海义,郭轩,等. 黄河口凹陷古近系地层结构新认识与勘探潜力评价[J]. 油气地质与采收率,2020,27(5):1-12. doi: 10.13673/j.cnki.cn37-1359/te.2020.05.001
[12] 周晓光,黄晓波,马正武,等. 渤海海域莱北低凸起隐性“逆冲物源”发育特征及地质意义[J]. 西安石油大学学报(自然科学版),2020,35(4):26-29,46.
[13] 付兆辉,秦伟军,李敏. 渤海湾盆地垦东凸起构造演化及对沉积的控制作用[J]. 石油地质与工程,2011,25(4):7-10. doi: 10.3969/j.issn.1673-8217.2011.04.003
[14] 朱红涛,刘依梦,王永利,等. 渤海湾盆地黄河口凹陷BZ34-9区带火山岩三维刻画及火山喷发期次[J]. 地球科学(中国地质大学学报),2014,39(9):1309-1316.
[15] 王昕,柴永波,姚佳,等. 渤中34构造古近系受玄武岩控制砂岩储层成岩相展布特征及发育模式[J]. 中国海上油气,2017,29(2):9-17.
[16] 薛永安,杨海风,徐长贵. 渤海海域黄河口凹陷斜坡带差异控藏作用及油气富集规律[J]. 中国石油勘探,2016,21(4):65-74.
[17] 张新涛, 周心怀, 牛成民, 等黄河口凹陷古近纪构造坡折带对沉积体系的控制[J]. 地质论评, 2014, 60(2): 332-338.
[18] 姚佳,王昕,王清斌,等. 黄河口凹陷BZ34区古近系沙一二段储集层成岩相与有利储层预测[J]. 现代地质,2016,30(6):1339-1347.
[19] 赵振华. 微量元素地球化学原理[M]. 北京: 科学出版社, 2016.
[20] TAYLOR S R,MCLENNAN S M. The continental crust:its composition and evolution[J]. The Journal of Geology,1985,94(4):57-72.
[21] BOYNTON W V. Cosmochemistry of the rare earth elements: meteorite studies[M]//HENDERSON P. Rare Earth Element Geochemistry. Am-sterdam: Elsevier, 1984: 63-114.
[22] HERRON M M. Geochemical classification of terrigenous sands and shales from core or log data[J]. Journal of Sedimentary Research,1988,58(5):820-829.
[23] WEDEPOHL K H. Handbook of Geochemistry[M]. Berlin: Springer, 1969: 59-60.
[24] WOLLAST R,CHOU L. Surface reactions during the early stages of weathering of albite[J]. Geochimica et Cosmochimica Acta,1992,56(8):3113-3121. doi: 10.1016/0016-7037(92)90292-Q
[25] NESBITT H W,YOUNG G M. Early Proterozoic climates and plate motions inferred from major element chemistry of lutites[J]. Nature,1982,299(5885):715-717. doi: 10.1038/299715a0
[26] PANAHI A,YOUNG G M,RAINBIRD R H. Behavior of major and trace elements (including REE) during Paleoproterozoic pedogenesis and diagenetic alteration of an Archean granite near Ville Marie,Québec,Canada[J]. Geochimica et Cosmochimica Acta,2000,64(13):2199-2220. doi: 10.1016/S0016-7037(99)00420-2
[27] FEDO C M,NESBITT H W,YOUNG G M. Unraveling the effects of potassium metasomatism in sedimentary rocks and paleosols,with implications for paleoweathering conditions and provenance[J]. Geology,1995,23(10):921-924. doi: 10.1130/0091-7613(1995)023<0921:UTEOPM>2.3.CO;2
[28] 郭望,张卫刚,李玉宏,等. 柴北缘大煤沟组七段页岩地球化学特征对中侏罗世晚期物源及风化作用的指示及意义[J]. 沉积学报,2020,38(3):676-686.
[29] JIAN X,GUAN P,ZHANG W,et al. Geochemistry of Mesozoic and Cenozoic sediments in the northern Qaidam Basin,northeastern Tibetan Plateau:implications for provenance and weathering[J]. Chemical Geology,2013,360:74-88.
[30] ARMSTRONG-ALTRIN J S,LEE Y I,VERMA S P,et al. Geochemistry of sandstones from the upper Miocene Kudankulam Formation,Southern India:implications for provenance,weathering,and tectonic setting[J]. Journal of Sedimentary Research,2004,74(2):285-297. doi: 10.1306/082803740285
[31] 徐小涛,邵龙义. 利用泥质岩化学蚀变指数分析物源区风化程度时的限制因素[J]. 古地理学报,2018,20(3):515-522.
[32] COX R,LOWE D R,CULLERS R L. The influence of sediment recycling and basement composition on evolution of mudrock chemistry in the southwestern United States[J]. Geochimica et Cosmochimica Acta,1995,59(14):2919-2940. doi: 10.1016/0016-7037(95)00185-9
[33] 冯连君,储雪蕾,张启锐,等. 化学蚀变指数(CIA)及其在新元古代碎屑岩中的应用[J]. 地学前缘,2003,10(4):539-544.
[34] ROSER B P,KORSCH R J. Provenance signatures of sandstone-mudstone suites determined using discriminant function analysis of major-element data[J]. Chemical geology,1988,67(1/2):119-139.
[35] SHAW D M. A review of K-Rb fractionation trends by covariance analysis[J]. Geochimica et Cosmochimica Acta,1968,32(6):573-601. doi: 10.1016/0016-7037(68)90050-1
[36] FLOYD P A,LEVERIDGE B E. Tectonic environment of the Devonian Gramscatho basin,south Cornwall:framework mode and geochemical evidence from turbiditic sandstones[J]. Journal of the Geological Society,1987,144(4):531-542. doi: 10.1144/gsjgs.144.4.0531
[37] GU X X,LIU J M,ZHENG M H,et al. Provenance and tectonic setting of the Proterozoic turbidites in Hunan,South China:geochemical evidence[J]. Journal of Sedimentary Research,2002,72(3):393-407. doi: 10.1306/081601720393
[38] ALLEGRE C J,MINSTER J F. Quantitative models of trace element behavior in magmatic processes[J]. Earth and Planetary Science Letters,1978,38(1):1-25. doi: 10.1016/0012-821X(78)90123-1
[39] HU J J,LI Q,FANG N Q,et al. Geochemistry characteristics of the Low Permian sedimentary rocks from central uplift zone,Qiangtang Basin,Tibet:insights into source-area weathering,provenance,recycling,and tectonic setting[J]. Arabian Journal of Geosciences,2015,8(8):5373-5388. doi: 10.1007/s12517-014-1583-8
[40] TAYLOR S R, MCLENNAN S M. The Continental Crust: its Composition and Evolution. An Examination of the Geochemical Record Preserved in Sedimentary Rocks[M]. Oxford: Blackwell Scientific Publications, 1985.
[41] 张学敏,岳琼申. 地球化学方法在化学风化作用和物源判别中的应用综述[J]. 华南地质与矿产,2018,34(1):41-58.
[42] 徐长贵,加东辉,宛良伟. 渤海走滑断裂对古近系源-汇体系的控制作用[J]. 地球科学,2017,42(11):1871-1882.
[43] 王孝辕,黄江波,杨海风,等. 莱北低凸起构造成因演化及其对沉积体系的控制作用[J]. 东北石油大学学报,2018,42(2):1-10.
[44] 杨海风,钱赓,徐春强,等. 渤海湾盆地黄河口凹陷中央构造脊沙河街组砂体展布规律与储层发育特征[J]. 地球科学,2023,48(8):3068-3080.
[45] MAYNARD J B,VALLONI R,YU H S. Composition of modern deep-sea sands from arc-related basins[J]. Geological Society,1982,10(1):551-561. doi: 10.1144/GSL.SP.1982.010.01.36
[46] 杜利林,郭敬辉,耿元生,等. 扬子西南缘盐边群时代及构造环境:来自碎屑沉积岩的约束[J]. 岩石学报,2013,29(2):641-672.
[47] ROSER B P,KORSCH R J. Determination of tectonic setting of sandstone-mudstone suites using SiO2 content and K2O/Na2O ratio[J]. The Journal of Geology,1986,94(5):635-650. doi: 10.1086/629071
[48] BHATIA M R,CROOK K A W. Trace element characteristics of graywackes and tectonic setting discrimination of sedimentary basins[J]. Contributions to Mineralogy and Petrology,1986,92(2):181-193. doi: 10.1007/BF00375292
[49] BHATIA M R. Rare earth element geochemistry of Australian Paleozoic graywackes and mudrocks:provenance and tectonic control[J]. Sedimentary Geology,1985,45(1/2):97-113. doi: 10.1016/0037-0738(85)90025-9
[50] 刘士林,刘蕴华,林舸,等. 渤海湾盆地南堡凹陷新近系泥岩稀土元素地球化学特征及其地质意义[J]. 现代地质,2006,20(3):449-456.
[51] 金宠. 黄骅坳陷和济阳坳陷中生界构造特征、演化及动力机制[D]. 青岛: 中国海洋大学, 2007.
[52] 朱日祥. “华北克拉通破坏”重大研究计划结题综述[J]. 中国科学基金,2018,32(3):282-290.
[53] 董树文,张岳桥,龙长兴,等. 中国侏罗纪构造变革与燕山运动新诠释[J]. 地质学报,2007,81(11):1449-1461.
[54] 朱日祥,徐义刚. 西太平洋板块俯冲与华北克拉通破坏[J]. 中国科学(地球科学),2019,49(9):1346-1356.
[55] 朱光,王薇,顾承串,等. 郯庐断裂带晚中生代演化历史及其对华北克拉通破坏过程的指示[J]. 岩石学报,2016,32(4):935-949.
-
图(9)
表(3)
计量
- 文章访问数: 623
- PDF下载数: 17
- 施引文献: 0