Detrital zircon geochronology of Neoproterozoic-Early Paleozoic sedimentary rocks in Baoshan terrane and its tectonic significance
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摘要:
滇西潞西地区位于青藏高原东南缘,大地构造位置上属于保山地体。由于新生代强烈的陆内变形作用,保山地体与青藏高原腹地体的对应关系难以确定。野外观察及LA-ICP-MS锆石U-Pb测年结果表明,潞西新元古代-早古生代地层(震旦系-寒武系蒲满哨群及下奥陶统大矿山组)大部分碎屑锆石Th/U>0.1,说明其大多为岩浆成因。U-Pb年龄跨度较大,太古宙-早古生代都有分布,且具有明显的562Ma、892Ma及2265Ma年龄峰,以及较弱的1680Ma和2550Ma年龄峰。保山地体潞西地区沉积岩碎屑锆石年龄分布特征与特提斯喜马拉雅、南羌塘沉积地层碎屑锆石年龄分布特征相似,说明其具有相同的物源——冈瓦纳大陆北部的印度大陆。在新元古代晚期-早古生代,保山地体位于印度大陆北缘,与南羌塘、喜马拉雅地体相邻。伴随着俯冲相关的增生造山过程,保山地体形成相应的新元古代末期-早古生代沉积地层。
Abstract:The Luxi area of west Yun'nan which belongs to Baoshan terrane is located on the southeastern margin of the Tibetan Plateau. It is difficult to confirm the relationship between Baoshan terrane and Tibetan Plateau due to the strong deformation in Cenozoic. Based on the field study and LA-ICP-MS U-Pb dating, the authors hold that most detrital zircons of Neoproterozoic to early Paleozoic strata in Luxi area have high Th/U ratios (>0.1), which corresponds to the features of magmatic zircons. Zircon UPb ages are distributed from Archean to Early Paleozoic, with age peaks showing strong peaks of Cambrian (562Ma), Neoproterozoic (890Ma), Paleoproterozoic (2292Ma), and some weaker age peaks of Mesoproterozoic (1676Ma) and Neoproterozoic (2500Ma). The detrital zircon age distribution pattern in Baoshan terrane is similiar to that in South Qiangtang and Tethys Himalayan sedimentary strata, indicating that they were all derived from the Indian block located on the northern margin of Gondwanaland. From late Neoproterozoic to Early Paleozoic, Baoshen terrane was located on the northern margin of India block, adjacent to the north Qiangtang and Himalayan terrane. During the accretionary orogenic process related to the subduction, the late Newproterozoic to Early Paleozoic sedimentary strata were formed in the Baoshan terrane.
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冈底斯巨型构造-岩浆带夹持于印度河-雅鲁藏布缝合带(IYZSZ)与班公湖-怒江缝合带(BN⁃SZ)之间[图1-a],带内发育大量中—新生代中酸性火山岩[2]。美苏组出露于班戈-八宿地层分区及狮泉河-永珠-嘉黎构造-地层分区[3]。该组为江西地调院实施1: 25万邦多区幅和措麦区幅地质调查时创建,其定义为不整合于晚白垩世竟柱山组之上的一套以基性-中性-酸性-酸碱性火山熔岩为主,夹火山碎屑岩的岩石组合,代表裂隙-中心式喷发-沉积的火山岩系[4],时代归属古新世—始新世[4-5]。该套岩石组合在尼玛地区被先后归属于达多群②、达多组③及林子宗群[6]。1: 5万撞多勒幅区调工作,据地层岩性组合、火山喷发方式、喷发-沉积环境及岩浆演化特点,将出露于别若则错地区的一套以酸性火山熔岩、酸性火山碎屑岩夹少量砂岩的组合归属于美苏组④,该套岩石组合前人曾归属于江巴组①⑤、竟柱山组[6]。美苏组创建以来,除建组时有少量岩石学、岩石化学特征描述外,后期1: 5万调查也仅进行了岩性对比,未见相关报道。本文在野外调查的基础上,根据锆石U-Pb年龄,结合地球化学特征,探讨了美苏组流纹岩的成因和大地构造背景,为认识冈底斯北部新生代岩浆-构造演化提供基础资料。
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1—第四系;2—早-晚白垩世美苏组;3—晚白垩世竟柱山组;4—早白垩世去申拉组;5—早白垩世多尼组;6—晚侏罗世日松组; 7—晚侏罗世多仁组;8—早-中侏罗世拉贡塘组;9—晚二叠世下拉组;10—晚石炭世拉嘎组;11—中始新世钾长花岗岩; 12—晚白垩世闪长岩;13—早白垩世石英闪长岩;14—地质界线;15—角度不整合界线;16—区域大断裂;17—一般断裂; 18—推测断裂;19—测年样品采集位置(本项目测试);20—研究区位置;NQFAB—那曲弧前盆地;NG—北冈底斯; MG—中冈底斯;GBAFUB—冈底斯弧背断隆带;SG—南冈底斯; SMLMF—沙莫勒-麦拉-洛巴堆-米拉山断裂; GLZCF—噶尔-隆格尔-扎日南木错-措麦断裂带;SLYNJOMZ—獅泉河-拉果错-永珠-纳木错- 嘉黎蛇绿混杂岩带;BNSZ—班公湖-怒江缝合带;IYZSZ—印度河-雅鲁藏布缝合带Figure 1. Geological sketch map of tectonic units of Gangdise (a) and geological sketch map of the Bierou-Zecuo area (b)1. 地质概况及岩石学特征
研究区美苏组出露于别若则错北东约10km,北西-南东向展布,宽0.8~3.0km,构造上处于北冈底斯南缘,以发育侏罗系—古近系火山沉积及大量白垩纪基性-中酸性侵入岩为特征(图 1-b)。地层不整合于早白垩世去申拉组之上,其上仅见第四系覆盖。美苏组岩性以浅灰色、紫红色流纹质火山角砾岩、凝灰岩、流纹岩、安山岩为主,夹灰绿色斑状、杏仁状玄武岩、玄武质火山集块岩、紫红色砂岩、黑色硅质岩等,流纹岩中可见大量的石泡构造。在走向上岩性、岩相较稳定,但厚度变化较大。本区美苏组与层型剖面[4]对比,同样表现为基性-中性-酸性的岩石组合,但厚度更大,可达1232.65m。
本文采集的样品为美苏组酸性熔岩及酸性火山碎屑岩两大类,岩石呈浅灰色、紫红色。流纹岩(图版Ⅰ-a)具斑状结构,基质为显微晶质结构(图版Ⅰ-b),斑晶为石英(约3%),0.1~2.3mm,多被熔蚀为次圆状,透长石(约7%)呈半自形板状、他形粒状,少量红褐色具暗化边片状黑云母;基质为显微晶质状的斜长石、钾长石,以钾长石为主,次为石英、磁铁矿,岩石有弱的粘土、绢云母蚀变。球粒流纹岩(图版Ⅰ-c)具球粒结构(图版Ⅰ-d)球粒(约75%)呈圆状、椭圆状,粒径0.1~16mm,由纤维状的长英质组成,部分脱玻化形成纤维状雏晶石英,少量球粒含透长石(约3%)、石英斑晶(约4%),胶结物为流纹质熔岩(约16%)及褐铁矿(约3%),流纹质熔岩呈隐晶质状,部分胶结物沿球粒边部形成细小的椭圆状球粒,排列呈孔雀羽毛状分布。流纹质(晶屑岩屑)凝灰岩(图版Ⅰ-e)为火山凝灰结构(图版Ⅰ-f),凝灰质含量43%~80%,由石英、长石等晶屑及流纹岩、粗面岩岩屑组成,胶结物主要为小于0.05mm的隐晶质火山灰,少量重结晶的长英质物质,岩石具褐铁矿、方解石等轻微蚀变。
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图版Ⅰa.流纹岩野外露头;b.流纹岩镜下特征(单偏光);c.球粒流纹岩野外露头;d.球粒流纹岩镜下特征(正交偏光);e.晶屑岩屑流纹质凝灰岩野外露头;f.晶屑岩屑流纹质凝灰岩镜下特征(单偏光)图版Ⅰ.2. 锆石U-Pb年龄
锆石单矿物分选由四川华阳岩矿测试中心完成。西北大学大力动力学国家重点实验室进行阴极发光(CL)图像采集及LA-ICP-MS锆石U-Pb测年。采用标准锆石91500校正Pb/U同位素分馏。激光器为ArF193nm紫外准分子激光器,单脉冲能量220mJ,最高重复频率20Hz,能量密度可达20J/cm2,剥蚀直径20μm左右。为了控制仪器的稳定性及测试精度,每测试5个未知样后测定1次标准样。数据处理采用Glitter(ver4.0,Macquarie University)和Isoplo(tver2.49)软件程序[7]。
锆石U-Pb年龄样品(P01(179))采集于美苏组上部流纹岩内,其位置为北纬32°28′03″、东经83°07′24″(图 1-b)。样品选取24颗锆石进行LA-ICP-MS法U-Pb测年,分析锆石为无色-浅黄色透明,颗粒形状规则,主要表现为柱状自形晶,粒径为80~120μm,个别可达190μm,长宽比为1~2(图版Ⅰ)。CL图像表现出典型的岩浆韵律环带和明暗相间的条带结构(图 2),属无核岩浆结晶锆石,可代表流纹岩的成岩年龄。测试数据结果见表 1,共测得24个数据,其U-Pb谐和图见图 3-a,最小的14个测点(1、3、4、6、8、10、12~17、20、21)的206Pb/238U年龄为38.5±1.0~44.5±3.2Ma,给出的加权平均值为39.62±0.77Ma(MSWD=0.99,置信度95%)(图 3-b),可代表流纹岩的结晶时代,为晚始新世。
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图 3 美苏组流纹岩锆石U-Pb谐和图及206Pb/238U年龄图Figure 3. U-Pb concordia dirgram and 206Pb/238U age plot of the zircon from Meisu Formation rhyolite表 1 美苏组流纹岩(P01(179))LA-ICP-MS锆石U-Th-Pb同位素分析数据Table 1. LA-ICP-MS zircon U-Th-Pb isotopic analyses of Meisu Formation rhyolite (P01(179))测点 同位素比值 年龄/Ma 206Pb/38U 1σ 207Pb/235U 1σ 207Pb/206Pb 1σ 208Pb/232Th 1σ 206Pb/238U 1σ 207Pb/235U 1σ 208Pb/232Th 1σ 1 0.00649 0.00016 0.09509 0.0067 0.10627 0.00837 0.00249 0.00007 41.7 1.0 92.2 6.2 50.3 1.4 2 0.00705 0.00016 0.14056 0.00768 0.14458 0.00930 0.00368 0.00011 45.3 1.0 133.5 6.8 74.3 2.2 3 0.00693 0.00050 0.04572 0.01574 0.04783 0.01684 0.00286 0.00028 44.5 3.2 45.4 15.3 57.7 5.7 4 0.00616 0.00089 0.03751 0.03158 0.04416 0.03769 0.00161 0.00039 39.6 5.7 37.4 30.9 32.4 7.9 5 0.01257 0.00071 0.83390 0.06569 0.48128 0.04763 0.01336 0.00065 80.5 4.5 615.8 36.4 268.2 12.9 6 0.00687 0.00100 0.04494 0.03232 0.04747 0.03481 0.00322 0.00078 44.1 6.4 44.6 31.4 65.1 15.7 7 0.00914 0.00020 0.42774 0.01499 0.33927 0.01643 0.00857 0.00019 58.7 1.3 361.6 10.7 172.4 3.8 8 0.00602 0.00010 0.04187 0.00225 0.05043 0.00312 0.00186 0.00003 38.7 0.6 41.7 2.2 37.6 0.7 9 0.00720 0.00017 0.19359 0.00937 0.19487 0.01157 0.00470 0.00013 46.3 1.1 179.7 8.0 94.8 2.5 10 0.00629 0.00018 0.04126 0.00621 0.04754 0.00738 0.00214 0.00010 40.4 1.2 41.1 6.1 43.2 2.1 11 0.00885 0.00020 0.35398 0.01403 0.2902 0.01516 0.00866 0.00021 56.8 1.3 307.7 10.5 174.3 4.3 12 0.00599 0.00016 0.03905 0.00508 0.04727 0.00638 0.00210 0.00008 38.5 1.0 38.9 5.0 42.4 1.6 13 0.00685 0.00055 0.04638 0.01763 0.04907 0.01907 0.00271 0.00034 44.0 3.5 46 17.1 54.8 6.9 14 0.00669 0.00052 0.04518 0.01635 0.04896 0.01814 0.00185 0.00024 43.0 3.3 44.9 15.9 37.3 4.8 15 0.00633 0.00059 0.03968 0.01884 0.04543 0.02198 0.00245 0.00042 40.7 3.8 39.5 18.4 49.4 8.5 16 0.00676 0.00109 0.04464 0.04805 0.04787 0.05206 0.00224 0.00056 43.5 7.0 44.3 46.7 45.3 11.3 17 0.00611 0.00027 0.04128 0.00827 0.04898 0.01012 0.00197 0.00010 39.3 1.7 41.1 8.1 39.8 2.1 18 0.00787 0.00111 0.13800 0.05582 0.12715 0.05431 0.00265 0.00054 50.5 7.1 131.3 49.8 53.5 10.8 19 0.00707 0.00087 0.04625 0.03535 0.04744 0.03672 0.00286 0.00059 45.4 5.6 45.9 34.3 57.8 11.9 20 0.00632 0.00022 0.04044 0.00711 0.04640 0.00840 0.00210 0.00014 40.6 1.4 40.3 6.9 42.5 2.9 21 0.00639 0.00019 0.04269 0.00639 0.04842 0.00748 0.00223 0.00012 41.1 1.2 42.4 6.2 45 2.4 22 0.01918 0.00072 1.48434 0.07226 0.56111 0.0364 0.02164 0.00066 122.5 4.6 924 29.5 432.8 13.2 23 0.00719 0.00046 0.04674 0.01563 0.04711 0.01607 0.00305 0.00035 46.2 2.9 46.4 15.2 61.5 7.0 24 0.00735 0.00107 0.04872 0.04896 0.04808 0.04881 0.00356 0.00058 47.2 6.9 48.3 47.4 71.9 11.7 3. 岩石地球化学
主量、稀土及微量元素样品加工由华阳地矿检测中心实验室完成,测试由国土资源部武汉矿产资源监督检测中心武汉综合岩矿测试中心完成。主量、微量和稀土元素检测采用AXIOS X射线荧光光谱仪、X Series2等离子质谱仪、IRIS Intripid2XSP ICP全谱直读光谱仪、ZEEnit600石墨炉原子吸收光谱仪、AFS-230E原子荧光分光光度计分析。美苏组流纹岩主量、稀土及微量元素分析结果见表 2。
表 2 美苏组酸性火山岩主量、微量和稀土元素分析结果Table 2. Major, trace elements and REE analyses of acid volcanic rocks from Meisu Formation样品 流纹岩 流纹质凝灰岩 P01(174) D3241☆ P05(504) P01(135) GP70☆ P05(476) SiO2 72.85 74.04 78.54 74.82 75.60 77.48 Al2O3 12.39 14.25 10.76 12.03 12.83 11.34 Fe2O3 1.23 1.42 0.69 0.67 0.37 0.55 FeO 0.16 0.54 0.10 0.10 0.44 0.09 CaO 1.56 0.33 0.37 0.86 1.09 0.40 MgO 0.22 0.55 0.31 0.20 0.08 0.58 K2O 5.47 2.25 3.56 5.87 3.77 3.33 Na2O 1.52 4.59 3.28 2.60 2.59 3.19 TiO2 0.25 0.10 0.10 0.10 0.10 0.11 P2O5 0.03 0.03 0.02 0.03 0.04 0.02 MnO 0.09 0.02 0.02 0.11 0.03 0.09 灼失 4.15 1.20 2.22 2.53 2.31 2.79 H2O+ 2.46 0.92 1.78 1.85 1.72 2.16 H2O- 0.44 0.12 0.73 1.16 0.18 1.31 CO2 1.67 ― 0.19 0.71 - 0.68 总和 99.92 99.32 99.97 99.92 99.25 99.97 AR 3.01 2.77 3.87 2.35 2.19 3.38 NK/A 0.68 0.70 0.86 0.88 0.65 0.78 A/CNK 1.10 1.35 1.08 0.99 1.24 1.18 Cr 4.29 11.00 5.72 4.96 1.00 5.32 Ni 2.26 16.00 2.72 1.56 13.4 2.44 Co 3.67 4.80 8.34 3.78 1.00 6.36 Rb 228 185 94.2 176 174 98 Cs 5.05 5.00 21.60 7.76 8.50 15.90 W 44.5 1.8 82.1 35.8 2.2 55.5 Sr 51.6 170 28.8 203 84.4 38 Ba 94.8 38 35.1 90.1 48.2 28.1 V 8.18 4.4 5.01 4.21 1.36 8.41 Nb 80.7 88.7 51.0 48.1 40.0 38.1 Ta 6.35 4.97 3.36 3.96 3.54 3.54 Zr 247 298 97.2 156 122 85.4 Hf 8.96 9.40 4.38 5.84 4.71 4.66 U 1.69 4.18 2.91 2.20 1.34 3.39 Th 20.5 25.7 9.86 13.1 20.4 14.4 La 47.9 32.0 41.4 47.8 35.4 51.6 Ce 84.6 88.0 68.0 74.9 43.9 86.6 Pr 10.60 12.00 7.96 8.51 5.80 8.96 Nd 36.4 36.0 25.6 25.3 21.2 27.2 Sm 7.70 7.20 4.43 4.08 3.68 4.59 Eu 0.31 0.32 0.3 0.27 0.28 0.34 Gd 6.19 4.80 3.53 3.46 2.74 3.97 Tb 0.98 1.00 0.51 0.51 0.46 0.56 Dy 5.83 6.00 3.04 3.11 3.14 3.32 Ho 1.13 1.10 0.61 0.67 0.64 0.68 Er 2.99 2.6 1.74 2.02 2.16 1.89 Tm 0.45 0.50 0.30 0.35 0.30 0.31 Yb 2.90 2.90 2.07 2.56 2.49 2.11 Lu 0.37 0.37 0.30 0.37 0.33 0.29 Y 27.7 22.0 15.2 17.9 17.6 17.7 ∑REE 208.35 194.79 159.79 173.91 122.52 192.42 δEu 0.13 0.16 0.23 0.22 0.26 0.24 (La/Yb)N 10.88 7.27 13.17 12.3 9.37 16.11 注:☆样品据参考文献①;AR=(Al2O3+CaO+Na2O+K2O)/(Al2O3+CaO-Na2O-K2O);NK/A=(Na2O+K2O)/Al2O3(摩尔比); A/CNK=Al2O3/(CaO+Na2O+K2O)(摩尔比);主量元素含量单位为%,微量和稀土元素为10-6 3.1 主量元素
美苏组酸性火山岩主量元素特征表现为高SiO2(72.85%~78.54%,平均75.56%)、富碱(Alk=6.36%~ 8.47%,平均7.00%)、贫CaO(0.33% ~1.56%,平均0.77%)和MgO(0.08%~0.58%,平均0.32%)。K2O/Na2O值(除D3241)大于1(1.04~3.60),平均值为1.66。很高的K含量及高K/Na值,普遍被理解为在部分熔融的过程中,受控于源区较高的K含量[8-9],或者是较低的分熔程度[10]。在TAS分类图解(图 4)中,样品点均落入流纹岩系列。在AR-SiO2图解(图 5-a)中,样品点主要落在碱性区域。NK/A=0.65~0.86(平均0.76),A/CNK=0.99~1.35(平均1.16).CIPW计算结果表明,所有样品都含有标准矿物刚玉分子,刚玉分子为0.91~3.76,在A/CNK-A/NK图(图 5-b)上,主要落入过铝质区(1个样品为准铝质),过铝质的花岗质岩石是壳源的[16],主要与大陆碰撞中沉积岩的重熔作用有关[17]。值得关注的是,该套火山岩具有很低的TiO2含量(0.10% ~0.25%,平均0.13%),低于岛弧区钙碱系列酸性火山岩类(0.50%)[18]及大陆板内常见酸性岩类[19],暗示该套火山岩经历过一定程度的分离结晶作用,由于钛铁氧化物的早期分离结晶,造成岩石中偏低的TiO2含量[20]。
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图 4 美苏组酸性火山岩TAS分类图解[11]Pc—苦橄玄武岩; B—玄武岩; O1—玄武安山岩; O2—安山岩; O3—英安岩; R—流纹岩; S1—粗面玄武岩; S2—玄武质粗面安山岩;S3—粗面安山岩;T—粗面岩、粗面英安岩;F—副长石岩;U1—碱玄岩、碧玄岩;U2—响岩质碱玄岩;U3—碱玄质响岩;Ph—响岩Figure 4. TAS diagram of acid volcanic rocks of the Meisu Formation![]()
3.2 稀土和微量元素
美苏组酸性火山岩稀土元素总量为123×10-6~ 208×10-6,在球粒陨石标准化稀土元素分布模式图(图 6-a)上,轻稀土元素(LREE)略向右倾斜,重稀土元素(HREE)较平缓,轻稀土元素分馏程度略高于重稀土元素,(La/Yb)N值为7.27~16.11,δEu=0.13~0.26,显示右倾的V字形分布模式,近似于“海鸥型”,与典型碱流岩几乎完全一致[10]。强烈的负Eu异常,反映岩石在形成过程中有斜长石的结晶分离或源区部分熔融残留斜长石[21]。
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EKR—东昆仑高Nb-Ta流纹岩, 构造环境:俯冲-碰撞晚期; TIBET—西藏冈底斯造山带林子宗火山岩帕那组流纹岩, 构造环境:陆陆碰撞; CBS—长白山碱流岩, 构造环境:弧后拉张; GHM—澳大利亚Glass House Mountain碱流岩, 构造环境:板内(与热点有关)Figure 6. Chondrite-normalized REE patterns (a) and primitive mantle normalized trace elements patterns (b) of acid volcanic rocks from Meisu Formation在原始地幔标准化蛛网图(图 6-b)上,曲线显示右倾富集型分布型式。曲线前半部分元素总体呈富集状态,后半部分相容元素富集度较低,表现为板内火山岩的地球化学特征[20],表明其应来自大陆板内深部局部熔融[19]。岩石大离子亲石元素Rb、K及高场强元素Th、Ce、Zr、Hf相对富集,高场强元素Nb、Ta相对亏损,大离子亲石元素Ba、Sr及高场强元素P、Ti强烈亏损,类似于东昆仑高Nb-Ta流纹岩,并可以与典型的碱流岩对比[10]。需要说明的是,Nb、Ta虽然有微弱的负异常,但其高Nb(38×10-6~89×10-6,平均58× 10-6)、Ta(3×10-6~6×10-6,平均4×10-6)含量与冈底斯带同时期的酸性火山岩的Nb、Ta强烈亏损截然不同[10, 24-25]。
4. 讨论
4.1 岩石源区及岩石成因
地球化学特征显示,美苏组酸性火山岩具有高硅、富铝、富碱,贫CaO、MgO的特征,大离子亲石元素及高场强元素Rb、K、Th、Ce、Zr、Hf相对富集,Ba、Sr、P、Ti强烈亏损,暗示岩浆可能来源于大陆板内深部的局部熔融。酸性火山岩的Rb/Sr、Ti/Y和Ti/Zr值分别为0.9~4.4(平均2.4)、35.1~70.6(平均45.9)和3.9~7.9(平均5.8),位于壳源岩浆(Rb/Sr > 0.5,Ti/Y < 100,Ti/Zr < 20)范围[26-27]内,是陆壳熔融的产物。
Nb、Ta在侵蚀和变质作用过程中较稳定,有示踪原始岩浆源区的特征[28-29]。单纯的地壳熔融成因与美苏组酸性火山岩显示的高Nb、Ta及强烈亏损Sr、Eu、Ba的微量元素特征不符,这是由于地壳具有继承性的Nb、Ta负异常,如果没有其他富集Nb、Ta岩浆的加入,任何程度的地壳部分熔融和分离结晶都无法产生高Nb、Ta含量的熔体[10]。美苏组酸性火山岩Nb/Ta=10.8~17.9(平均13.3),1个样品在幔源岩浆值(17±1)[30]范围,其他则略小于幔源岩浆值,也可以说明岩浆源有幔源物质参与。别若则错地区美苏组酸性火山岩Nb*≈1、Ta*≈>1,与典型的碱流岩分布范围近于一致(图 7),典型碱流岩CBS和GHM(AI > 1)呈现出Nb-Ta正异常,其由碱性玄武岩分离结晶形成,很少或没有受到陆壳混染[10]。
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由上述分析可知,区内美苏组酸性火山岩的地球化学特征具有“集壳幔特性于一身”的属性,因此,笔者认为,形成本区酸性火山岩的初始熔体为富碱和富Nb、Ta的幔源玄武质岩浆与壳源岩浆以某一特定比例混合/混染的产物,混染应该发生在上地壳,因此有轻微的Nb、Ta负异常。同时,由于酸性火山岩具有明显的负Eu异常(δEu=0.13~0.26),不能完全排除分离结晶形成部分酸性火山岩的可能性(图 8)。这种富Nb-Ta玄武岩浆一般具板内玄武岩的特征,可能反映裂谷伸展背景甚至地幔柱活动[10]。
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图 8 美苏组酸性火山岩Zr-Zr/Sm图解Figure 8. Zr versus Zr/Sm diagram of acid volcanic rocks from Meisu Formation4.2 构造环境
不同学者对于印度大陆与亚洲大陆的碰撞过程有不同的认识,有学者认为, 印度与亚洲大陆碰撞自65Ma或70Ma左右开始,到45Ma或40Ma左右完成,以后转入后碰撞期[31-34],主碰撞期为55~50Ma[35];也有学者认为,印度-亚洲大陆碰撞经历主碰撞(65~41Ma)、晚碰撞(40~26Ma)和后碰撞过程(25~0Ma)[36],并将早期碰撞过程划分为4个阶段:①70~60Ma,新特斯洋板片回转,印度大陆与亚洲大陆发生碰撞(≥65Ma),导致加厚地壳深熔;②60~54Ma,印度大陆板片向北陡深俯冲,下地壳缩短加厚,地壳深熔作用持续;③53~41Ma,新特提斯洋板片发生断离,并向下拆沉。软流圈物质透过板片断离窗上涌,诱发地幔楔、上覆加厚的镁铁质下地壳熔融;④陡深俯冲的印度大陆板片因特提斯洋板片断离而发生折返,开始低角度俯冲(<40Ma),导致高原内部的陆内俯冲、走滑剪切与地壳缩短,造成冈底斯岩浆间断(40~26Ma)和拉萨地体初始抬升[24]。别若则错美苏组酸性火山岩位于北冈底斯南缘,流纹岩LA-ICP-MS锆石206Pb/238U年龄为39.62±0.77Ma(n=14,MSWD=0.99),时代为晚始新世。该时期印度大陆与亚洲大陆板块主碰撞已完成,是印度大陆与亚洲大陆板块后碰撞期[31-34]或晚碰撞期[36]的起始时间。美苏组火山岩在命名地尼玛地区具“双峰式”特点,被认为属于造山带向板内过渡环境[4-5],在研究区被认为是局限的“伸展盆地”构造环境①。本次采集的美苏组酸性火山岩样品在Rb/30-Hf-3Ta图解(图 9-a)中,落入碰撞后和板内交汇区,在(Y+Nb)-Rb图解(图 9-b)中主要落入板内花岗岩区。结合地球化学特征,综合认为,晚始新世冈底斯带别若则错地区处于后碰撞阶段陆内伸展(裂谷)环境,南侧新特提斯洋壳向北俯冲,导致高原内部的陆内俯冲、走滑剪切,引发大范围地壳伸展减薄,软流圈物质上涌,上涌的软流圈物质为具有富碱和富Nb、Ta特征的幔源玄武质岩浆,幔源玄武质岩浆与上地壳壳源岩浆以某一特定比例混合/混染,形成研究区高Nb-Ta的酸性火山岩。
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5. 结论
(1) 美苏组酸性火山岩显示的特征为高硅、富铝、富碱,贫CaO、MgO,高Nb、Ta,大离子亲石元素及高场强元素Rb、K、Th、Ce、Zr、Hf相对富集,Ba、Sr、P、Ti强烈亏损的特征,岩石地球化学特征表明,美苏组火山岩“集壳幔特性于一身”,是初始熔体为富碱、富Nb、Ta的幔源玄武质岩浆与壳源岩浆以某一特定比例混合/混染的产物。
(2) 通过LA-ICP-MS锆石U-Pb测年,获得岩石结晶年龄为39.62±0.77Ma(n=14,MSWD=0.99),形成时代为晚始新世。
(3) 美苏组酸性火山岩产于大陆板内伸展(裂谷)环境,其地球动力学背景与南侧新特提斯洋壳向北俯冲,导致高原内部的陆内俯冲、走滑剪切与地壳缩短有关。
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图 1 保山地体地质简图及采样位置
BS—保山地体;TC—腾冲地体;SM—思茅地体;HM—喜马拉雅地体;LS—拉萨地体;QT—羌塘地体
Figure 1. Geological map of Baoshan terrane and sampling locations
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图版Ⅰ
a.保山地体早古生代大矿山组砾岩; b. 大矿山组砂岩; c. 蒲满哨群砂岩; d. 样品 YC381显微照片; e. 样品 YC438显微照片; f. 样品 YC543显微照片; g. 样品 YC313显微照片; h. 样品 YC351显微照片
图版Ⅰ.
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图 2 保山地体大矿山组、蒲满哨群碎屑锆石阴极发光(CL)图像(a)和U-Pb谐和图及年龄频谱图(b~f)
Figure 2. CL images (a), U-Pb concordia diagrams and U-Pb age frequency diagram (b~f) of detrital zircons from the Dakuangshan Formation and the Pumanshao Group in Baoshan terrane
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图 3 年龄与Th/U值关系图(a)及大矿山组(b)与蒲满哨群(c)所有样品碎屑锆石年龄频谱图
Figure 3. Age (Ma) versus Th/U ratio for samples from the Dakuangshan Formation and the Pumanshao Group in Baoshan terrane (a), and frequency diagram of detrital zircons from all samples of the Dakuangshan Formation (b) and the Pumanshao Group (c)
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图 4 保山地体、南羌塘、拉萨和特提斯喜马拉雅碎屑锆石U-Pb年龄频谱图
(锆石年龄大于1000Ma时,采用207Pb/206Pb年龄;当锆石年龄小于1000Ma时,采用206Pb/238U年龄。年龄结果包含年龄谐和度大于90%的年龄。重要的年龄峰用灰色标注)
Figure 4. Detrital zircon age distributions of the Baoshan terrane, southern Qiangtang, Lhasa and Tethyan Himalaya
表 1 保山地体新元古代末—早古生代砂岩LA-ICP-MS碎屑锆石U-Th-Pb测年结果
Table 1 LA-ICP-MS zircon U-Th-Pb dating results of the Late Proterozoic to Early Paleozoic sandstones from Baoshan terrane
测点号 Th/U 同位素比值 年龄/Ma 207Pb/206Pb ± σ 207Pb/235U ± σ 206Pb/238U ± σ 207Pb/206Pb ± σ 207Pb/235U ± σ 206Pb/238U ± σ YC381-2 1.32 0.068 0.002 1.355 0.036 0.144 0.003 878 48 870 16 868 14 YC381-3 0.42 0.102 0.002 4.149 0.077 0.294 0.004 1661 28 1664 15 1660 20 YC381-4 0.78 0.165 0.002 9.582 0.259 0.419 0.009 2507 24 2395 25 2256 43 YC381-5 1.24 0.084 0.002 2.489 0.07 0.214 0.004 1287 42 1269 20 1253 22 YC381-8 0.19 0.152 0.001 4.715 0.096 0.305 0.007 2369 9 1770 4 1716 36 YC381-7 1.16 0.064 0.001 0.985 0.019 0.112 0.001 731 43 696 9 682 6 YC381-10 0.95 0.101 0.001 3.783 0.055 0.266 0.002 1650 19 1589 12 1521 12 YC381-11 1.03 0.069 0.002 1.377 0.042 0.145 0.002 883 55 879 18 871 12 YC381-12 0.96 0.102 0.002 4.033 0.083 0.285 0.004 1662 36 1641 17 1616 20 YC381-13 0.37 0.153 0.003 8.502 0.135 0.402 0.006 2379 33 2286 16 2176 34 YC381-15 0.75 0.064 0.002 1.031 0.038 0.116 0.002 744 233 719 19 710 12 YC381-16 1.9 0.142 0.002 8.324 0.165 0.422 0.006 2257 29 2267 18 2269 27 YC381-17 0.72 0.103 0.002 3.863 0.069 0.27 0.003 1687 33 1606 14 1539 15 YC381-18 2.22 0.073 0.002 1.667 0.069 0.164 0.004 1021 62 996 26 979 21 YC381-19 0.52 0.101 0.002 4.08 0.09 0.292 0.005 1643 37 1650 18 1650 23 YC381-20 0.27 0.067 0 1.233 0.053 0.132 0.004 828 10 816 25 798 26 YC381-21 1.06 0.07 0.002 1.476 0.045 0.153 0.003 931 59 921 18 916 18 YC381-22 0.34 0.061 0.002 0.857 0.034 0.102 0.003 639 78 629 19 625 16 YC381-23 1.26 0.069 0.002 1.318 0.037 0.139 0.002 889 55 854 16 838 12 YC381-24 0.26 0.174 0 11.278 0.386 0.469 0.016 2594 3 2546 33 2478 71 YC381-25 0.37 0.144 0.004 6.99 0.412 0.35 0.016 2279 49 2110 52 1933 75 YC381-26 1.09 0.086 0.001 2.143 0.151 0.198 0.009 1328 13 1163 53 1164 49 YC381-27 0.48 0.157 0.004 9.015 0.35 0.416 0.014 2421 44 2340 35 2243 65 YC381-28 1.72 0.057 0.003 0.619 0.044 0.078 0.002 476 117 489 28 487 13 YC381-29 0.64 0.068 0.002 1.398 0.046 0.147 0.003 883 54 888 20 886 17 YC381-30 0.71 0.066 0.003 1.177 0.078 0.128 0.006 813 104 790 36 778 32 YC381-31 0.73 0.058 0.002 0.668 0.026 0.084 0.002 520 68 520 16 517 10 YC381-32 1.21 0.072 0.004 1.648 0.156 0.166 0.012 987 120 989 60 988 65 YC381-34 2.05 0.059 0.006 0.75 0.103 0.092 0.005 567 241 568 60 568 32 YC381-36 0.55 0.152 0.003 8.502 0.175 0.404 0.004 2372 31 2286 19 2187 20 YC381-37 0.38 0.063 0.001 1.012 0.026 0.116 0.002 706 44 710 13 710 10 YC381-39 0.97 0.097 0.002 3.839 0.09 0.286 0.003 1570 40 1601 19 1622 16 YC381-40 0.71 0.075 0.002 1.85 0.062 0.178 0.003 1080 61 1063 22 1054 14 YC381-41 0.32 0.075 0.002 1.868 0.041 0.179 0.002 1080 41 1070 14 1064 10 YC381-42 0.43 0.14 0.003 7.968 0.166 0.412 0.004 2231 32 2227 19 2222 20 YC381-43 2.29 0.143 0.003 8.262 0.186 0.42 0.006 2261 32 2260 20 2258 29 YC381-44 1.79 0.138 0.002 7.624 0.139 0.399 0.004 2209 24 2188 16 2164 20 YC381-45 1.03 0.144 0.002 8.429 0.142 0.423 0.004 2281 28 2278 15 2273 17 YC381-46 1.99 0.14 0.002 8.038 0.149 0.414 0.005 2233 28 2235 17 2234 21 YC381-47 0.76 0.079 0.002 2.15 0.042 0.198 0.002 1172 40 1165 13 1162 13 YC381-48 0.48 0.068 0.002 1.334 0.041 0.143 0.003 855 51 861 18 861 14 YC381-49 1.39 0.147 0.003 8.772 0.218 0.431 0.006 2314 34 2315 23 2310 27 YC381-50 0.76 0.146 0.003 8.446 0.166 0.419 0.005 2299 33 2280 18 2257 23 YC381-51 0.95 0.141 0.002 8.014 0.15 0.411 0.005 2240 30 2233 17 2221 22 YC381-52 1.41 0.145 0.002 8.508 0.168 0.426 0.005 2284 29 2287 18 2286 24 YC381-53 1.82 0.168 0.004 11.12 0.596 0.477 0.022 2539 45 2533 50 2515 95 YC381-54 1.76 0.146 0.002 8.177 0.137 0.405 0.005 2302 26 2251 15 2193 24 YC381-55 0.43 0.063 0.001 1.031 0.021 0.118 0.001 724 48 720 11 718 6 YC381-56 2.86 0.133 0.002 7.125 0.21 0.388 0.009 2200 32 2127 26 2115 42 YC381-57 0.59 0.141 0.002 7.823 0.135 0.401 0.005 2240 60 2211 16 2175 22 YC381-58 1.07 0.091 0.002 3.114 0.072 0.249 0.003 1439 42 1436 18 1432 16 YC381-59 0.91 0.082 0.001 2.296 0.044 0.203 0.003 1240 35 1211 14 1192 14 YC381-60 1.81 0.119 0.003 5.608 0.182 0.342 0.009 1939 47 1917 28 1896 45 YC381-61 2.01 0.153 0.003 9.393 0.256 0.445 0.009 2376 33 2377 25 2373 40 YC381-62 4.58 0.12 0.003 5.496 0.216 0.332 0.011 1952 44 1900 34 1849 51 YC381-63 0.64 0.093 0.003 1.497 0.03 0.15 0 1494 59 929 12 902 3 YC381-64 1.31 0.062 0.005 0.969 0.113 0.112 0.008 683 156 688 59 683 44 YC381-65 5.92 0.162 0.004 8.822 0.432 0.424 0.015 2479 44 2320 48 2277 66 YC381-67 0.7 0.163 0.004 10.166 0.648 0.453 0.026 2487 42 2450 59 2408 118 YC381-68 0.12 0.181 0.001 13.45 0.266 0.531 0.009 2658 5 2712 19 2747 37 YC381-69 0.5 0.182 0.001 12.361 0.31 0.498 0.013 2676 6 2632 24 2606 55 YC381-70 0.23 0.182 0.006 11.872 0.229 0.477 0.009 2668 55 2594 18 2515 38 YC381-71 0.7 0.103 0.003 4.147 0.134 0.293 0.003 1673 57 1664 27 1656 17 YC381-72 1.31 0.066 0.002 1.208 0.04 0.132 0.002 809 65 804 19 802 10 YC381-73 1.08 0.092 0.003 3.347 0.224 0.26 0.009 1466 61 1492 52 1490 43 YC381-74 0.77 0.07 0.003 1.449 0.066 0.15 0.002 1000 100 909 27 899 9 YC381-75 0.3 0.066 0.002 1.211 0.034 0.133 0.001 809 56 806 16 803 7 YC381-76 1.24 0.145 0.003 8.674 0.214 0.432 0.006 2300 36 2304 22 2317 26 YC381-77 1.98 0.141 0.003 8.714 0.181 0.448 0.005 2237 35 2309 19 2387 20 YC381-78 0.12 0.061 0.001 1.276 0.027 0.15 0.001 655 46 835 12 902 8 YC381-79 1.47 0.096 0.002 3.587 0.079 0.271 0.002 1543 40 1547 17 1547 12 YC381-80 1.81 0.132 0.003 7.543 0.179 0.415 0.005 2120 41 2178 21 2237 22 YC438-1 0.13 0.063 0.001 1.603 0.036 0.161 0.002 694 33 971 14 960 13 YC438-2 1.34 0.438 0.058 4.113 0.117 0.298 0.004 4047 200 1657 54 1682 21 YC438-3 1.82 0.143 0.001 8.189 0.103 0.416 0.004 2261 18 2252 11 2240 16 YC438-4 0.05 0.131 0.001 6.979 0.062 0.385 0.002 2113 14 2109 8 2102 9 YC438-5 1.43 0.052 0.001 1.212 0.044 0.132 0.002 333 36 806 20 797 13 YC438-6 0.62 0.07 0.001 1.33 0.014 0.138 0.001 920 19 859 6 834 6 YC438-7 2.1 0.061 0.001 0.769 0.011 0.091 0.001 643 33 579 6 564 3 YC438-8 1.25 0.076 0.001 1.936 0.019 0.184 0.001 1094 16 1094 7 1091 7 YC438-10 0.03 0.063 0.001 1.043 0.018 0.119 0.001 720 25 726 9 726 7 YC438-11 2.94 0.077 0.001 2.041 0.018 0.192 0.001 1126 17 1129 6 1130 5 YC438-12 0.83 0.066 0.001 1.205 0.015 0.132 0.001 809 20 803 7 800 6 YC438-13 0.91 0.089 0.012 1.316 0.163 0.141 0.008 1413 270 853 72 848 45 YC438-15 1.3 0.068 0.001 1.384 0.014 0.147 0.001 883 19 882 6 881 6 YC438-16 1.31 0.156 0.001 9.314 0.089 0.432 0.003 2417 15 2369 9 2313 12 YC438-17 0.8 0.167 0.002 9.403 0.239 0.445 0.01 2523 21 2378 24 2374 45 YC438-18 1.41 0.217 0.002 17.451 0.192 0.583 0.005 2967 13 2960 11 2961 21 YC438-19 1.01 0.073 0.001 1.715 0.032 0.17 0.001 1022 39 1014 12 1010 6 YC438-20 3.01 0.09 0.001 3.085 0.024 0.247 0.001 1435 14 1429 6 1422 6 YC438-21 0.54 0.07 0.001 1.345 0.016 0.139 0.001 943 25 865 7 836 6 YC438-22 2.07 0.07 0.001 1.544 0.013 0.158 0.001 943 19 948 5 948 5 YC438-23 1.55 0.086 0.002 3.283 0.058 0.255 0.003 1346 41 1477 14 1464 15 YC438-24 0.95 0.092 0.001 3.206 0.034 0.253 0.002 1463 16 1459 8 1452 10 YC438-25 2.29 0.075 0.001 1.668 0.021 0.16 0.001 1072 19 996 8 959 7 YC438-26 1.38 0.116 0.001 5.512 0.051 0.343 0.002 1898 15 1902 8 1903 9 YC438-27 0.76 0.064 0.001 1.069 0.01 0.12 0.001 767 16 738 5 731 4 YC438-28 1.02 0.065 0.001 1.082 0.012 0.121 0.001 774 20 745 6 733 5 YC438-29 1.11 0.078 0.001 2.086 0.025 0.193 0.001 1154 22 1144 8 1137 7 YC438-30 0.96 0.086 0.001 2.762 0.034 0.231 0.002 1346 22 1345 9 1341 8 YC438-31 0.59 0.123 0.001 6.12 0.083 0.358 0.003 2007 21 1993 12 1975 15 YC438-32 6.49 0.128 0.001 6.858 0.046 0.37 0.002 2072 12 2093 7 2031 12 YC438-34 0.91 0.066 0.001 1.218 0.013 0.133 0.001 820 22 809 6 804 6 YC438-35 0.58 0.069 0.001 1.409 0.016 0.148 0.001 898 25 893 7 889 5 YC438-36 1.81 0.122 0.004 7.232 0.216 0.388 0.008 1991 56 2140 27 2113 39 YC438-37 0.29 0.061 0.001 0.989 0.016 0.118 0.001 620 28 698 8 719 6 YC438-38 2.59 0.093 0.001 2.59 0.03 0.202 0.001 1480 17 1298 8 1187 7 YC438-39 0.55 0.106 0.001 4.352 0.046 0.298 0.002 1729 12 1703 9 1679 11 YC438-40 0.55 0.069 0.001 1.418 0.019 0.149 0.001 888 29 896 8 897 5 YC438-41 0.54 0.312 0.007 29.432 0.744 0.688 0.02 3529 34 3468 25 3373 75 YC438-42 2.06 0.07 0.001 1.491 0.028 0.155 0.001 925 39 927 11 927 5 YC438-43 1.89 0.055 0.004 0.587 0.055 0.075 0.002 467 143 469 35 467 13 YC438-45 0.07 0.214 0.004 16.283 0.321 0.551 0.009 2939 29 2894 19 2828 38 YC438-46 0.76 0.1 0.001 3.897 0.047 0.283 0.002 1617 20 1613 10 1608 10 YC438-47 0.86 0.138 0.004 5.956 0.165 0.359 0.009 2209 47 1969 24 1979 42 YC438-48 0.05 0.056 0.002 0.731 0.077 0.089 0.004 443 56 557 45 552 24 YC438-49 4.42 0.062 0.001 0.79 0.02 0.093 0.001 665 44 591 11 571 8 YC438-50 1 0.068 0.001 1.303 0.016 0.139 0.001 865 31 847 7 840 5 YC438-51 0.14 0.079 0.006 1.341 0.125 0.141 0.005 1169 154 863 54 851 28 YC438-52 0.71 0.07 0.001 1.451 0.023 0.151 0.001 920 29 910 9 904 7 YC438-53 1.5 0.147 0.001 8.705 0.111 0.429 0.003 2307 17 2308 12 2302 16 YC438-54 0.49 0.068 0.001 1.379 0.017 0.146 0.001 881 28 880 7 880 5 YC438-55 2.35 0.144 0.002 8.412 0.205 0.423 0.009 2273 20 2277 22 2275 39 YC438-56 1.32 0.056 0.01 0.618 0.119 0.077 0.005 457 393 488 75 481 33 YC438-57 1.1 0.068 0.001 1.373 0.019 0.146 0.001 880 29 877 8 876 5 YC438-58 0.28 0.073 0.001 3.789 0.166 0.276 0.006 1013 21 1590 37 1573 30 YC438-59 2.72 0.067 0.001 1.263 0.018 0.136 0.001 839 34 829 8 824 5 YC438-60 3.19 0.066 0.001 1.176 0.017 0.129 0.001 1200 30 789 8 783 5 YC438-61 1.41 0.072 0.001 1.469 0.021 0.148 0.001 977 28 918 9 892 5 YC438-62 0.97 0.072 0.001 1.627 0.02 0.164 0.001 977 29 981 8 981 7 YC438-63 0.07 0.063 0.001 1.102 0.01 0.126 0.001 722 19 754 5 767 3 YC438-64 0.56 0.059 0.001 0.695 0.008 0.086 0.001 554 30 536 5 535 5 YC438-65 0.8 0.095 0.001 3.467 0.045 0.264 0.002 1531 22 1520 10 1510 8 YC438-66 0.84 0.167 0.001 10.584 0.107 0.458 0.003 2531 14 2487 9 2430 12 YC438-67 0.93 0.077 0.001 1.964 0.02 0.186 0.001 1114 22 1103 7 1099 6 YC438-68 0.71 0.06 0.001 0.783 0.009 0.095 0.001 591 20 587 5 586 4 YC438-69 0.08 0.067 0.001 1.357 0.09 0.145 0.006 822 38 871 39 875 32 YC438-70 1.41 0.105 0.001 4.432 0.063 0.305 0.003 1717 22 1718 12 1718 14 YC438-71 0.47 0.065 0.001 1.133 0.021 0.126 0.001 789 28 769 10 764 8 YC438-72 3.24 0.101 0.002 2.578 0.055 0.216 0.001 1643 40 1294 16 1259 8 YC438-73 0.09 0.069 0.001 1.614 0.028 0.169 0.002 903 27 976 11 1006 9 YC438-74 0.83 0.083 0.001 2.494 0.108 0.212 0.006 1277 33 1270 31 1239 30 YC438-75 0.55 0.067 0.001 1.247 0.023 0.136 0.001 833 31 822 10 820 7 YC438-76 0.76 0.059 0.002 0.761 0.027 0.093 0.001 583 69 575 16 570 8 YC438-77 0.11 0.072 0.001 1.704 0.036 0.171 0.002 987 36 1010 14 1020 13 YC438-78 0.15 0.079 0.001 1.946 0.057 0.181 0.005 1161 31 1097 20 1070 26 YC438-79 0.51 0.074 0.001 1.695 0.041 0.166 0.003 1036 31 1007 15 990 14 YC438-80 1.44 0.078 0.002 2.116 0.112 0.196 0.009 1139 42 1154 36 1154 47 YC438-81 0.1 0.059 0.004 4.281 0.171 0.292 0.01 565 99 1690 34 1652 48 YC438-82 0.15 0.142 0.014 0.692 0.099 0.085 0.009 2254 112 534 68 525 54 YC438-83 0.91 0.102 0.002 4.1 0.161 0.293 0.011 1661 31 1654 32 1658 56 YC438-84 0.04 0.096 0.003 4.054 0.143 0.29 0.008 1539 59 1645 30 1643 42 YC438-85 2.63 0.171 0.002 11.266 0.516 0.477 0.021 2566 20 2545 43 2515 93 YC438-86 1.48 0.093 0.001 3.469 0.093 0.269 0.004 1480 22 1520 22 1535 20 YC438-87 1.01 0.152 0.001 9.221 0.093 0.439 0.002 2368 16 2360 9 2347 9 YC438-88 1.39 0.094 0.002 3.442 0.064 0.265 0.002 1522 32 1514 15 1513 12 YC438-89 0.29 0.069 0.001 1.413 0.033 0.149 0.001 887 44 895 14 894 5 YC438-90 0.94 0.062 0.001 0.943 0.02 0.11 0.001 676 41 675 11 673 6 YC542-1 0.04 0.073 0.002 1.711 0.046 0.169 0.002 1013 43 1013 17 1009 13 YC542-2 0.05 0.075 0.002 1.876 0.068 0.181 0.003 1066 58 1073 24 1073 19 YC542-3 0.1 0.137 0.003 7.711 0.169 0.406 0.005 2192 34 2198 20 2199 22 YC542-4 0.05 0.066 0.003 1.232 0.056 0.135 0.001 1200 89 815 26 816 7 YC542-5 0.11 0.144 0.003 8.464 0.184 0.425 0.007 2277 33 2282 20 2281 33 YC542-6 0.06 0.088 0.004 2.845 0.151 0.233 0.004 1381 79 1368 40 1350 23 YC542-7 0.07 0.088 0.002 2.836 0.048 0.234 0.003 1389 37 1365 13 1353 17 YC542-8 0.05 0.066 0.003 1.207 0.051 0.132 0.001 798 81 804 23 800 8 YC542-9 0.06 0.059 0.003 0.65 0.032 0.08 0.001 569 136 508 20 494 8 YC542-10 0.24 0.085 0.002 2.688 0.09 0.228 0.004 1322 53 1325 25 1325 19 YC542-11 1.15 0.07 0.001 1.369 0.031 0.145 0.002 928 42 876 13 871 13 YC542-12 0.14 0.072 0.001 1.485 0.045 0.151 0.003 998 28 924 18 909 16 YC542-13 0.43 0.105 0.002 3.046 0.091 0.244 0.006 1722 35 1419 23 1406 29 YC542-14 0.4 0.067 0.002 1.237 0.041 0.134 0.001 843 57 818 19 810 6 YC542-15 1.02 0.111 0.001 4.992 0.117 0.317 0.006 1820 41 1818 20 1774 31 YC542-16 0.36 0.109 0.004 3.134 0.265 0.244 0.005 1789 72 1441 65 1408 28 YC542-17 0.48 0.072 0.002 1.393 0.039 0.146 0.002 994 47 886 17 876 10 YC542-18 0.16 0.077 0.003 0.62 0.065 0.077 0.005 1121 79 490 41 479 27 YC542-19 2 0.174 0.008 10.437 0.101 0.462 0.004 2601 74 2474 11 2450 19 YC542-20 0.39 0.163 0.007 10.688 0.606 0.487 0.008 2488 73 2496 53 2559 34 YC542-21 0.58 0.133 0.002 5.436 0.14 0.34 0.005 2139 22 1891 22 1888 24 YC542-22 0.34 0.097 0.004 3.427 0.187 0.269 0.004 1570 85 1511 43 1535 19 YC542-23 0.58 0.077 0.002 1.845 0.051 0.179 0.003 1122 45 1062 18 1061 17 YC542-24 0.12 0.105 0.002 3.111 0.142 0.248 0.003 1710 29 1435 36 1430 17 YC542-25 1.76 0.103 0.001 3.799 0.077 0.274 0.006 1687 23 1592 16 1560 29 YC542-26 0.42 0.175 0.009 3.907 0.103 0.282 0.006 2602 84 1615 22 1603 31 YC542-27 0.48 0.082 0 2.845 0.086 0.234 0.006 1239 10 1367 23 1354 30 YC542-29 0.24 0.113 0.002 4.684 0.162 0.312 0.008 1844 31 1764 30 1749 41 YC542-30 0.56 0.069 0.001 1.664 0.081 0.167 0.004 900 45 995 31 997 20 YC542-32 0.46 0.068 0.004 0.999 0.097 0.105 0.003 872 133 704 49 641 16 YC542-33 0.25 0.068 0.002 1.413 0.055 0.15 0.004 883 61 894 23 898 22 YC542-34 0.48 0.09 0.003 2.989 0.106 0.24 0.005 1436 56 1405 27 1385 26 YC542-35 0.41 0.166 0.043 10.311 0.153 0.451 0.005 2518 45 2463 14 2399 22 YC542-38 0.48 0.074 0.003 1.495 0.038 0.154 0.001 1029 65 928 15 922 6 YC542-39 0.6 0.169 0.008 10.738 0.107 0.461 0.004 2554 9 2501 9 2443 16 YC542-41 0.51 0.092 0.002 2.491 0.062 0.211 0.003 1465 37 1269 18 1235 17 YC542-42 0.96 0.249 0.015 6.298 0.411 0.348 0.013 3176 111 2018 65 1925 61 YC542-43 0.43 0.087 0.005 2.59 0.16 0.217 0.005 1369 106 1298 45 1264 24 YC542-46 0.73 0.076 0.004 1.614 0.093 0.155 0.003 1094 105 976 36 928 15 YC542-47 0.34 0.14 0.005 8.453 0.351 0.441 0.011 2225 60 2281 38 2355 49 YC542-49 0.2 0.069 0.001 1.211 0.017 0.132 0.001 896 34 805 8 800 7 YC542-50 1.13 0.07 0.004 1.453 0.087 0.152 0.004 917 115 911 36 912 24 YC542-51 0.44 0.096 0.003 3.914 0.165 0.297 0.006 1546 67 1617 34 1674 31 YC542-52 0.84 0.128 0.004 6.577 0.223 0.373 0.005 2069 55 2056 30 2045 21 YC542-53 0.45 0.12 0.001 6.497 0.105 0.373 0.004 1958 8 2045 14 2044 20 YC542-54 0.52 0.088 0.003 2.926 0.099 0.24 0.005 1392 57 1389 26 1388 26 YC542-55 1.47 0.182 0.001 1.339 0.141 0.14 0.003 2733 9 863 11 847 16 YC542-57 1.13 0.139 0.012 1.685 0.049 0.166 0.003 2213 105 1003 19 992 14 YC542-58 0.37 0.068 0.004 1.345 0.123 0.142 0.005 865 137 866 53 857 28 YC542-59 0.51 0.1 0.003 3.781 0.137 0.275 0.005 1617 63 1589 29 1565 26 YC542-60 0.37 0.067 0.002 1.157 0.039 0.125 0.002 839 72 781 18 760 11 YC542-61 0.3 0.072 0.002 1.585 0.067 0.16 0.004 977 75 964 26 955 22 YC542-62 0.45 0.077 0.002 2.028 0.05 0.19 0.003 1124 46 1125 17 1122 15 YC542-63 0.78 0.076 0.001 0.881 0.06 0.105 0.002 1106 37 641 33 641 9 YC542-64 1.71 0.085 0.001 2.395 0.118 0.21 0.002 1322 24 1241 37 1231 13 YC542-65 1.24 0.093 0.003 3.277 0.102 0.256 0.004 1481 56 1476 24 1469 18 YC542-66 0.46 0.059 0.002 0.69 0.022 0.085 0.003 572 69 533 13 526 16 YC542-67 0.92 0.073 0.003 1.49 0.053 0.148 0.002 1022 74 926 21 888 11 YC542-68 0.38 0.069 0.002 1.41 0.039 0.148 0.002 898 45 893 16 890 14 YC542-69 0.88 0.145 0.004 7.559 0.206 0.376 0.004 2291 44 2180 24 2059 18 YC542-70 1.19 0.148 0.004 8.694 0.263 0.425 0.006 2324 48 2306 28 2285 29 YC542-71 0.74 0.169 0.004 10.323 0.289 0.442 0.006 2550 42 2464 26 2359 27 YC542-72 0.76 0.101 0.003 4.116 0.165 0.295 0.008 1643 54 1658 33 1667 41 YC542-73 2.55 0.087 0.003 2.779 0.087 0.23 0.003 1370 59 1350 24 1335 13 YC542-74 2.84 0.067 0.002 1.324 0.04 0.143 0.002 843 56 856 17 860 13 YC542-75 1.08 0.085 0.003 2.497 0.129 0.212 0.009 1324 71 1271 37 1240 46 YC542-76 0.26 0.084 0.002 2.684 0.106 0.23 0.008 1298 39 1324 29 1336 42 YC542-77 1.14 0.06 0.001 1.289 0.027 0.154 0.002 617 44 841 12 926 8 YC542-78 1.96 0.136 0.003 7.458 0.153 0.397 0.004 2173 36 2168 18 2157 19 YC542-79 2.81 0.149 0.003 9.058 0.202 0.438 0.005 2339 37 2344 20 2341 21 YC313-1 0.22 0.063 0.003 0.936 0.047 0.107 0.002 722 102 671 24 655 11 YC313-2 0.05 0.082 0.001 1.875 0.024 0.166 0.002 1243 15 1072 9 991 10 YC313-3 0.1 0.076 0 1.867 0.019 0.179 0.002 1087 10 1069 7 1061 8 YC313-4 0.8 0.151 0.001 8.863 0.13 0.426 0.007 2355 10 2324 13 2290 31 YC313-5 0.48 0.075 0 1.794 0.011 0.174 0.001 1057 7 1043 4 1037 5 YC313-6 1.95 0.083 0 2.458 0.016 0.215 0.001 1272 11 1260 5 1253 6 YC313-7 0.5 0.068 0 1.293 0.009 0.137 0.001 881 14 843 4 828 4 YC313-8 0.72 0.08 0.003 1.919 0.059 0.184 0.003 1209 88 1088 21 1086 17 YC313-9 1.62 0.111 0.001 4.521 0.051 0.294 0.003 1833 13 1735 9 1662 14 YC313-10 0.99 0.081 0 2.279 0.018 0.204 0.001 1220 12 1206 6 1196 7 YC313-11 0.08 0.104 0.004 4.361 0.205 0.304 0.009 1692 67 1705 39 1709 46 YC313-12 1.21 0.164 0.001 10.042 0.085 0.444 0.003 2495 11 2439 8 2370 14 YC313-13 0.63 0.15 0.002 9.112 0.129 0.44 0.005 2346 22 2349 13 2351 22 YC313-14 0.68 0.068 0.001 1.296 0.013 0.138 0.001 865 14 844 6 836 5 YC313-15 0.59 0.072 0.001 1.518 0.019 0.153 0.001 989 15 937 7 920 7 YC313-16 0.15 0.072 0 1.545 0.007 0.155 0.001 991 6 948 3 931 3 YC313-17 1.14 0.071 0.001 1.531 0.018 0.155 0.001 969 20 943 7 932 5 YC313-18 0.49 0.076 0 1.66 0.016 0.158 0.001 1098 9 993 6 947 7 YC313-19 0.55 0.071 0 1.544 0.011 0.158 0.001 954 11 948 4 946 5 YC313-20 0.69 0.078 0 1.91 0.01 0.178 0.001 1146 7 1085 4 1054 4 YC313-21 0.65 0.075 0.001 1.731 0.019 0.167 0.001 1072 13 1020 7 997 8 YC313-22 0.53 0.06 0 0.757 0.006 0.091 0.001 613 11 573 3 562 3 YC313-23 1.19 0.06 0 0.746 0.007 0.09 0.001 606 15 566 4 556 4 YC313-24 0.13 0.062 0 0.937 0.006 0.11 0.001 676 23 672 3 670 3 YC313-25 1.45 0.104 0.001 4.28 0.041 0.299 0.002 1692 19 1690 8 1688 12 YC313-26 0.94 0.085 0.006 1.787 0.063 0.171 0.003 1324 132 1041 23 1018 18 YC313-27 0.52 0.075 0.003 1.523 0.058 0.156 0.003 1057 91 940 23 934 19 YC313-28 0.94 0.07 0.001 1.503 0.024 0.155 0.003 937 25 932 10 929 14 YC313-29 0.89 0.072 0.001 1.359 0.019 0.137 0.002 985 44 871 8 826 10 YC313-30 0.74 0.059 0.001 0.78 0.04 0.094 0.002 567 53 585 23 580 13 YC313-31 0.4 0.07 0.001 1.35 0.016 0.139 0.001 931 22 868 7 841 6 YC313-32 0.61 0.071 0.002 1.411 0.033 0.147 0.002 954 57 893 14 884 11 YC313-33 1.72 0.078 0.004 1.916 0.113 0.178 0.005 1144 103 1087 39 1057 30 YC313-34 0.62 0.067 0.001 1.27 0.023 0.137 0.002 839 20 833 10 829 10 YC313-35 0.54 0.074 0 1.721 0.013 0.168 0.001 1050 10 1016 5 1001 5 YC313-36 0.79 0.075 0 1.844 0.012 0.178 0.001 1069 7 1061 4 1057 5 YC313-37 0.37 0.072 0.001 1.535 0.019 0.155 0.001 977 23 944 8 929 8 YC313-38 0.42 0.11 0.004 4.858 0.172 0.321 0.006 1798 63 1795 30 1794 30 YC313-39 0.1 0.124 0.004 5.29 0.178 0.308 0.004 2014 59 1867 29 1730 21 YC313-40 0.62 0.144 0.005 7.049 0.303 0.352 0.01 2276 54 2118 38 1946 47 YC313-41 0.43 0.108 0.005 4.648 0.216 0.313 0.006 1765 77 1758 39 1756 30 YC313-42 0.91 0.111 0.001 4.989 0.07 0.325 0.004 1821 16 1818 12 1813 18 YC313-43 0.85 0.184 0.007 12.765 0.496 0.504 0.01 2687 61 2662 37 2629 44 CY351-1 0.91 0.153 0.014 9.643 0.799 0.45 0.016 2384 156 2401 76 2396 73 CY351-2 0.46 0.072 0.003 1.576 0.069 0.157 0.003 996 87 961 27 941 15 CY351-3 0.25 0.105 0.006 4.727 0.241 0.321 0.007 1717 104 1772 43 1796 36 CY351-4 0.27 0.122 0.005 5.662 0.238 0.334 0.007 1984 67 1926 36 1856 33 CY351-5 0.44 0.168 0.006 11.086 0.42 0.477 0.01 2600 57 2530 35 2516 42 CY351-6 0.48 0.067 0.003 1.312 0.073 0.141 0.003 854 100 851 32 850 17 CY351-7 0.01 0.063 0.004 1.018 0.058 0.116 0.002 717 126 713 29 710 14 CY351-8 0.64 0.059 0.004 0.679 0.045 0.084 0.002 561 160 526 27 520 12 CY351-9 0.08 0.068 0.003 1.439 0.064 0.154 0.003 857 87 905 27 924 17 CY351-10 0.15 0.064 0.004 1.149 0.104 0.128 0.007 743 141 777 49 776 42 CY351-11 0.14 0.064 0.004 1.096 0.098 0.123 0.007 731 137 751 47 746 40 CY351-12 0.23 0.068 0.002 1.364 0.048 0.145 0.003 874 129 874 21 870 15 CY351-13 0.03 0.063 0.003 1.149 0.051 0.132 0.002 694 94 777 24 801 14 CY351-14 0.63 0.059 0.003 0.703 0.033 0.086 0.002 569 136 541 20 533 9 CY351-16 0.34 0.069 0.003 1.37 0.058 0.143 0.003 903 85 876 25 860 15 CY351-18 0.58 0.057 0.003 0.687 0.032 0.087 0.002 500 101 531 19 540 9 CY351-19 0.57 0.069 0.003 1.406 0.064 0.146 0.003 906 91 891 27 880 14 CY351-20 0.48 0.072 0.003 1.494 0.066 0.15 0.003 972 83 928 27 903 17 CY351-21 0.14 0.071 0.002 1.404 0.048 0.143 0.003 954 64 891 20 861 15 CY351-22 0.48 0.075 0.003 1.718 0.064 0.165 0.003 1072 68 1015 24 986 19 CY351-23 0.07 0.104 0.003 4.699 0.151 0.325 0.005 1702 51 1767 27 1815 25 CY351-24 0.21 0.069 0.003 1.374 0.051 0.143 0.002 903 75 878 22 864 12 CY351-25 0.22 0.063 0.003 0.925 0.047 0.106 0.002 709 100 665 25 649 11 CY351-26 0.9 0.164 0.01 9.467 0.605 0.417 0.011 2497 104 2384 59 2246 50 CY351-27 0.25 0.111 0.006 5.015 0.277 0.326 0.007 1817 100 1822 47 1820 32 CY351-28 0.49 0.065 0.004 1.116 0.061 0.125 0.002 767 122 761 29 761 14 CY351-29 0.25 0.128 0.005 6.375 0.241 0.359 0.006 2073 66 2029 33 1979 27 CY351-30 0.43 0.17 0.005 11.411 0.392 0.485 0.009 2567 52 2557 32 2550 41 CY351-31 0.1 0.125 0.004 6.246 0.192 0.362 0.005 2028 54 2011 27 1990 25 CY351-32 1.01 0.134 0.006 7.187 0.325 0.388 0.01 2167 72 2135 40 2112 45 CY351-33 0.47 0.069 0.003 1.386 0.057 0.145 0.003 902 71 883 24 873 16 CY351-34 0.62 0.058 0.005 0.663 0.062 0.083 0.002 520 204 517 38 516 11 CY351-35 0.48 0.074 0.003 1.765 0.07 0.172 0.004 1043 73 1033 26 1025 19 CY351-36 0.25 0.161 0.005 9.096 0.38 0.406 0.011 2470 50 2348 38 2197 50 CY351-37 0.09 0.07 0.003 1.499 0.072 0.155 0.004 1000 96 930 29 927 20 CY351-38 0.87 0.179 0.009 12.239 0.628 0.497 0.013 2643 85 2623 48 2601 54 CY351-39 1.99 0.069 0.003 1.464 0.071 0.153 0.003 906 94 916 29 915 19 CY351-40 0.34 0.068 0.003 1.327 0.054 0.14 0.003 880 85 858 24 846 15 CY351-41 1.01 0.132 0.006 6.905 0.35 0.38 0.009 2124 78 2099 45 2075 44 CY351-42 0.45 0.063 0.003 1.049 0.049 0.12 0.002 706 109 729 24 729 13 CY351-43 0.18 0.071 0.003 1.551 0.065 0.157 0.003 963 92 951 26 941 18 CY351-44 0.35 0.099 0.006 3.894 0.2 0.283 0.008 1610 107 1612 42 1608 39 CY351-45 0.23 0.068 0.003 1.391 0.054 0.147 0.003 880 123 885 23 884 15 CY351-47 0.53 0.056 0.002 0.649 0.029 0.084 0.002 456 94 508 18 521 11 CY351-48 0.2 0.069 0.003 1.402 0.054 0.147 0.002 894 78 890 23 885 11 CY351-49 0.6 0.069 0.003 1.437 0.072 0.15 0.003 894 98 905 30 903 15 CY351-50 0.12 0.122 0.004 5.846 0.208 0.345 0.005 1992 58 1953 31 1911 26 
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