黔南基性岩墙岩石地球化学、SHRIMP锆石U-Pb年代学及地质意义

祝明金; 田亚洲; 聂爱国; 张恒; 杨华燊

doi:10.3799/dqkx.2018.724

黔南基性岩墙岩石地球化学、SHRIMP锆石U-Pb年代学及地质意义

doi: 10.3799/dqkx.2018.724

1.
贵州大学资源与环境工程学院, 贵州贵阳 550025
2.
贵州理工学院资源与环境工程学院, 贵州贵阳 550003
3.
中国地质科学院地质研究所, 北京 100037

基金项目:

贵州大学人才引进项目 702400163301

国家自然科学基金 41262005

国家自然科学基金 41703036

贵州理工学院高层次人才科研启动经费项目 XJGC20140702

详细信息

作者简介:
祝明金(1986-), 男, 博士研究生, 矿物学、岩石学、矿床学专业

通讯作者:
田亚洲

中图分类号: P581
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出版历程
- 收稿日期: 2017-12-20
- 刊出日期: 2018-04-15

Petrogeochemistry, Zircon SHRIMP U-Pb Geochronology of Mafic Dykes in South Guizhou and Their Geological Implications

1.
College of Resources and Environmental Engineering, Guizhou University, Guiyang 550025, China
2.
College of Resources and Environmental Engineering, Guizhou Institute of Technology, Guiyang 550003, China
3.
Institute of Geology, Chinese Academy of Geological Sciences, Beijing 100037, China

摘要

摘要: 基性岩墙，与层状、环状基性杂岩体和高Ti、低Ti玄武岩共同组成了峨眉山大火成岩省岩石组合.为进一步确定大火成岩省及相关生物灭绝事件的时间联系，及更深化研究大火成岩省的成因，对分布于贵州省南部的基性岩墙进行了主、微量元素、Sr-Nd同位素测定和锆石SHRIMP U-Pb年代学研究.黔南基性岩墙∑REE=135.66×10^-6~280.59×10^-6，LREE/HREE为6.42~7.54，（La/Yb）_N为7.94~9.85，轻重稀土分异明显，δEu为1.0~1.3，具有Ba、Sr、K等LILE富集，Nb、Ta、Zr、Hf等HFSE亏损特征，显示与峨眉山高钛玄武岩相似的地球化学特征.Th/Ta（1.80~1.94）、Nb/U（30.8~39.88）、Th/La（0.08~0.10）、Nb/Th（7.89~8.40）比值与原始地幔相似，较低的初始（⁸⁷Sr/⁸⁶Sr）_i比值（0.705 278~0.706 052）、ε_Nd（t）（-0.5~+1.6）、以及Th/Ta比值（< 2.13）显示岩浆无明显的地壳混染，岩浆可能形成于受地幔柱作用的富集石榴石地幔源区10%~12%的部分熔融.SHRIMP锆石²⁰⁶Pb/²³⁸U加权平均年龄为261.2±2.6 Ma，反映峨眉山大火成岩的喷发时间可能集中在260 Ma左右，并可能与瓜德鲁普末期的生物灭绝有关.
- 基性岩墙 /
- 岩石学 /
- 地球化学 /
- SHRIMP锆石U-Pb年龄 /
- 峨眉山大火成岩省 /
- 黔南
Abstract: The rocks of Emeishan large igneous province (ELIP) are mainly composed of mafic dykes, layered and ring mafic complex, high Ti and low Ti basalts. The major elements, trace elements, Sr-Nd isotopes and zircon SHRIMP U-Pb ages of mafic dykes from South Guizhou Province were studied in order to further determine the temporal link between ELIP and related mass extinction events and research the genesis of ELIP in this paper. Results show ∑REE=135.66×10^-6-280.59×10^-6, LREE/HREE=6.42-7.54, (La/Yb)_N=7.94-9.85, relatively enriched LREE to HREE, δEu=1.0-1.3, enriched LILE, such as Ba, K, Sr, depleted HFSE, such as Nb, Ta, Zr, Hf, displaying similar geochemical characteristics of Emeishan high Ti basalts. The similar ratios of Th/Ta(1.80-1.94), Nb/U(30.8-39.88), Th/La(0.08-0.10), Nb/Th(7.89-8.40) to primitive mantle, low (⁸⁷Sr/⁸⁶Sr)_i(0.705 278-0.706 052)), ε_Nd(t)(-0.5~+1.6) and Th/Ta(< 2.13) imply no obvious crustal contamination, and the mafic rocks may have been caused by 10%-12% partial melting of the garnet peridotite in their source region that interacted with the upwelling Emeishan plume at the periphery of the plume. The 261.2±2.6 Ma age of zircon SHRIMP U-Pb may imply that the ELIP formed by a mantle plume at~260 Ma and was one of the likely causes of the end-Guadalupian mass extinction.
- mafic dyke /
- petrology /
- geochemistry /
- zircon SHRIMP U-Pb age /
- Emeishan large igneous province /
- South Guizhou

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图 1 黔南基性岩墙地质图

a.研究区大地构造位置图, 据程裕淇(1994)；b.黔南基性岩墙地质略图，据1：20万罗甸幅(贵州省地质局108队，1965；1：20万罗甸幅)、乐业幅地质图(广西壮族自治区地质局，1972；1：20万乐业幅地质图)修改.T₂b².中三叠统边阳组中段；T₁.下三叠统；P₂m.中二叠统茅口组；P₂q.中二叠统栖霞组；C₂mp.上石炭统马平组；C₂hn.上石炭统黄龙组；C₁d-b.下石炭统大塘组-摆佐组；D₃s-d.上泥盆统响水洞组-代化组；D₂h.中泥盆统火烘组；βμ.基性岩墙

Fig. 1. Geological background of the mafic dyke, South Guizhou

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图 2 ELIP基性岩墙群分布及采样位置

据李宏博等(2010)

Fig. 2. Distribution of ELIP mafic dyke swarms and sample location

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图 3 基性岩墙野外露头(a)、手标本(b)以及正交偏光镜下特征(c)

Pl.斜长石；Cpx.单斜辉石；Mt.磁铁矿

Fig. 3. Photos of the outcrops (a), hand specimen (b) and microscope of the mafic dyke in cross-polarized light (c)

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图 4 黔南基性岩墙SiO₂-K₂O+Na₂O图解(a)和Nb/Y-Zr/TiO₂×0.000 1图解(b)

图a据Bas et al.(1986)；图b据Winchester and Floyd(1977)

Fig. 4. SiO₂ vs. K₂O+Na₂O (a), and Nb/Y-Zr/TiO₂×0.000 1 (b) for the mafic dyke from South Guizhou

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图 5 黔南基性岩墙Harker图解

Fig. 5. Harker diagrams for the mafic dyke from South Guizhou

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图 6 黔南基性岩墙稀土元素球粒陨石标准化图解(a)和微量元素原始地幔蛛网图(b)

图a据Taylor and McLennan(1985)；图b据Sun and McDonough(1989).峨眉山高钛玄武岩数据来自Xu et al.(2001); Xiao et al.(2003); Zhou et al.(2006)

Fig. 6. Chondrite-normalized REE patterns (a) and primitive mantle-normalized trace element patterns (b) for the mafic dyke from South Guizhou

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图 7 黔南基性岩墙Sr-Nd同位素初始比值

峨眉山玄武岩数据来自Xu et al.(2001); Song et al.(2004, 2008); Xiao et al.(2004); Wang et al.(2007); Fan et al.(2008); Qi and Zhou(2008); Shellnutt et al.(2008).DMM, EMI, EMII来自Zindler and Hart(1986); Hart(1988); Weaver(1991)

Fig. 7. Plot of initial ε_Nd(t) vs. (⁸⁷Sr/⁸⁶Sr)_i for the mafic dyke from South Guizhou

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图 8 黔南基性岩墙锆石U-Pb年龄谐和图及CL图像

Fig. 8. Zircon SHRIMP U-Pb convordia diagrams and CL images for the mafic dyke from South Guizhou

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图 9 黔南基性岩墙Nb/Yb-Th/Yb(a)和Nb/Yb-TiO₂ /Yb(b)图解

据Pearce(2008)

Fig. 9. Nb/Yb vs.Th/Yb (a) and Nb/Yb vs. TiO₂/Yb (b) diagrams for the mafic dyke from South Guizhou

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图 10 黔南基性岩La/Yb-Sm/Yb图解

底图引自王妍(2011)

Fig. 10. La/Yb vs. Sm/Yb diagram for the mafic dyke from South Guizhou

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表 1 黔南基性岩墙岩石主量元素(%)、微量和稀土元素(10^-6)化学成分分析结果

Table 1. Major (%) and trace and REE element (10^-6) abundances for the mafic dyke from South Guizhou

样号	GG14-1	GG14-2	QJ1-1	ec7	ec8	ec10	BS2	BS5	LM1	LM4
SiO₂	47.00	46.20	45.50	45.80	47.50	48.50	46.00	45.50	44.40	46.80
TiO₂	3.10	3.28	3.29	2.81	3.65	3.63	2.79	2.83	3.25	3.65
Al₂O₃	12.90	13.05	14.10	14.15	12.45	12.55	15.70	15.60	13.95	12.05
Fe₂O₃	15.60	15.50	14.92	14.08	16.36	14.33	13.98	14.72	14.76	16.46
MnO	0.23	0.21	0.22	0.19	0.27	0.19	0.16	0.18	0.20	0.27
MgO	5.52	4.32	6.02	5.24	4.05	5.64	4.48	4.70	5.80	4.90
CaO	7.51	9.22	10.00	9.20	6.76	7.35	7.61	8.22	10.80	8.24
Na₂O	4.25	3.98	2.63	3.57	4.08	4.70	3.72	3.68	2.93	3.07
K₂O	0.75	1.06	1.18	0.59	1.34	0.45	0.94	0.99	0.64	1.10
P₂O₅	0.76	0.84	0.71	0.71	1.08	0.93	0.54	0.57	0.73	0.95
LOI	2.42	1.91	1.74	2.88	1.59	1.55	3.42	2.86	2.48	2.00
Total	100.04	99.57	100.31	99.22	99.13	99.82	99.34	99.85	99.94	99.49
Rb	13.40	18.00	21.40	9.70	22.70	8.30	22.90	23.90	7.30	22.50
Sr	454	916	606	602	332	437	596	663	694	708
Ba	340	440	640	270	570	360	490	490	1860	600
Th	2.50	3.20	2.80	2.70	3.90	3.40	1.80	1.90	2.60	3.50
U	0.60	0.70	0.70	0.60	0.80	0.80	0.40	0.50	0.60	0.80
Nb	21.00	25.90	22.10	21.60	31.90	27.20	15.10	15.40	21.70	29.40
Ta	1.36	1.68	1.46	1.44	2.17	1.81	0.97	0.98	1.43	1.89
Pb	2.10	7.10	2.60	1.30	3.00	2.00	2.00	1.90	1.60	4.40
Zr	106.50	129.00	150.00	98.10	130.50	146.50	77.60	83.00	125.00	152.50
Hf	3.20	3.80	3.90	2.90	3.90	4.10	2.30	2.40	3.70	4.20
Ti	18 585	19 664	19 724	16 846	21 882	21 762	16 726	16 966	19 484	21 882
Ni	39.30	25.10	81.60	35.50	7.50	20.80	59.80	66.50	83.90	6.30
V	311	367	345	310	297	343	362	404	344	335
La	30.50	35.50	27.60	30.70	49.70	37.80	22.90	23.10	29.40	43.10
Ce	69.00	80.10	62.70	68.50	110.00	88.40	51.20	52.60	67.00	97.90
Pr	8.80	10.10	8.25	8.88	14.05	11.40	6.66	6.77	8.41	12.30
Nd	37.80	42.80	33.60	36.90	58.00	47.50	27.80	28.70	35.30	51.20
Sm	8.01	8.84	7.08	7.89	11.70	10.30	6.37	6.24	7.54	10.85
Eu	3.11	3.66	3.13	2.93	4.17	3.30	2.45	2.42	3.11	3.92
Gd	7.87	8.72	6.93	7.60	11.45	9.95	6.21	6.06	7.12	10.50
Tb	1.11	1.23	0.89	1.09	1.60	1.34	0.91	0.85	0.93	1.46
Dy	6.12	7.03	5.23	6.12	8.97	7.48	4.87	4.98	5.44	8.42
Ho	1.19	1.34	1.02	1.20	1.69	1.48	0.95	0.98	1.02	1.62
Er	3.32	3.79	2.50	3.32	4.46	4.01	2.56	2.34	2.60	4.23
Tm	0.42	0.45	0.34	0.44	0.61	0.49	0.36	0.33	0.35	0.51
Yb	2.50	3.08	2.15	2.52	3.62	3.24	2.07	1.93	2.20	3.43
Lu	0.40	0.47	0.32	0.40	0.57	0.50	0.35	0.31	0.33	0.49
Y	30.50	35.10	26.70	31.10	42.90	38.70	23.90	23.50	26.60	40.20
δEu	1.20	1.27	1.37	1.16	1.10	1.00	1.19	1.20	1.30	1.12
∑REE	180.15	207.11	161.74	178.49	280.59	227.19	135.66	137.61	170.75	249.93
LREE/HREE	6.86	6.93	7.35	6.87	7.51	6.97	6.42	6.74	7.54	7.15
(La/Yb)_N	8.75	8.27	9.21	8.74	9.85	8.37	7.94	8.59	9.59	9.01
Th/Ta	1.84	1.90	1.92	1.88	1.80	1.88	1.86	1.94	1.82	1.85
Nb/U	35.00	37.00	31.57	36.00	39.88	34.00	37.75	30.80	36.17	36.75
Th/La	0.08	0.09	0.10	0.09	0.08	0.09	0.08	0.08	0.09	0.08
Nb/Th	8.40	8.09	7.89	8.00	8.18	8.00	8.39	8.11	8.35	8.40
La/Nb	1.45	1.37	1.25	1.42	1.56	1.39	1.52	1.50	1.35	1.47

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表 2 黔南基性岩墙Sr-Nd同位素数据

Table 2. Sr-Nd isotopic data for the mafic dyke from South Guizhou

样品编号	Rb	Sr	⁸⁷Rb/⁸⁶Sr	⁸⁷Sr/⁸⁶Sr	±2σ	(⁸⁷Sr/⁸⁶Sr)_i	Sm	Nd	¹⁴⁷Sm/¹⁴⁴Nd	¹⁴³Nd/¹⁴⁴Nd	±2σ	ε_Nd(t)
GG13	31.7	490	0.187	0.706 582	12	0.706 052	8.21	37.6	0.132 0	0.512 545	10	0.4
GG14-2	18.0	916	0.057	0.706 264	11	0.705 894	8.84	42.8	0.124 9	0.5125 99	6	1.6
GG14-4	16.1	466	0.100	0.706 267	12	0.705 608	8.45	39.5	0.129 3	0.512 587	13	1.3
QJ1-1	21.4	606	0.102	0.705 988	15	0.705 583	7.08	33.6	0.127 4	0.512 509	13	-0.2
QJ1-2	22.1	559	0.114	0.706 008	13	0.705583	6.84	33.2	0.124 6	0.512 491	12	-0.5
QJ1-3	23.0	536	0.124	0.706 045	11	0.705 881	7.00	33.9	0.124 8	0.512 500	10	-0.3
ec11	20.7	561	0.107	0.706 280	13	0.705 278	9.48	42.8	0.133 9	0.512 602	9	1.4
BS5	23.9	663	0.104	0.705 665	13	0.705 405	6.24	28.7	0.131 4	0.512 559	9	0.6
LM4	22.5	708	0.092	0.705 748	15	0.705 888	10.85	51.2	0.128 1	0.512 546	15	0.5
LMZK2	27.5	620	0.128	0.706 365	14	0.706 052	7.47	34.7	0.130 1	0.512 510	11	-0.3

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表 3 黔南基性岩墙SHRIMP锆石U-Pb同位素测定结果

Table 3. SHRIMP U-Pb isotopic compositions of zircons for the mafic dyke from South Guizhou

测点	²⁰⁶P_c (%)	含量及比值				同位素比值							同位素年龄(Ma)
测点	²⁰⁶P_c (%)	U (10^-6)	Th (10^-6)	²⁰⁶Pb^* (10^-6)	²³²Th/ ²³⁸U	²⁰⁷Pb^/ ²⁰⁶Pb^测值 (±%)		²⁰⁷Pb^*/ ²³⁵U测值 (±%)		²⁰⁶Pb^*/ ²³⁸U测值 (±%)		误差相关系数	²⁰⁶Pb/ ²³⁸U测值±1σ		²⁰⁷Pb/ ²⁰⁶Pb测值±1σ		不谐和度 (%)
1.1	0.26	624	587	22.1	0.97	0.050 9	2.0	0.289 0	2.20	0.041 2	1.00	0.451	260.1	±2.6	236	±46	-10
2.1	0.32	148 1	512 2	52.7	3.57	0.050 7	1.8	0.289 2	2.00	0.041 3	0.93	0.455	261.1	±2.4	229	±42	-14
3.1	0.21	203 7	660 2	73.8	3.35	0.051 2	1.3	0.297 3	1.60	0.042 1	0.93	0.579	265.8	±2.4	251	±30	-6
4.1	0.19	619	748	22.2	1.25	0.051 3	1.9	0.295 0	2.10	0.041 7	0.99	0.465	263.4	±2.6	254	±44	-4
5.1	0.14	215 5	360 0	77.4	1.73	0.051 3	1.6	0.295 3	1.80	0.041 7	0.92	0.506	263.5	±2.4	256	±36	-3
6.1	0.08	307 7	328 3	112.0	1.10	0.051 4	0.8	0.299 3	1.20	0.042 2	0.90	0.753	266.7	±2.4	259	±18	-3
7.1	0.20	773	168 5	27.3	2.25	0.051 7	1.7	0.292 4	2.00	0.041 1	0.97	0.494	259.4	±2.5	270	±39	4
8.1	0.14	497	469	17.5	0.98	0.052 4	2.5	0.295 0	2.70	0.040 9	1.00	0.379	258.2	±2.6	301	±57	14
9.1	0.13	118 3	460 3	42.0	4.02	0.051 6	1.4	0.293 5	1.70	0.041 3	0.93	0.553	260.8	±2.4	266	±32	2
10.1	0.94	863	195 1	30.7	2.34	0.050 1	3.4	0.284 0	3.50	0.041 1	0.97	0.275	259.4	±2.5	202	±79	-29

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表 4 与峨眉山大火成岩省有关的年龄统计

Table 4. Summary of reported age data from the ELIP

年龄(Ma)	测年对象	测年方法	采样地点	文献出处
254±5	辉石岩中的金云母	Ar/Ar	云南大理洱海边	Boven et al., 2002
251.2~252.8	玄武岩、粗面岩和正长岩	Ar/Ar	云南和四川	Lo et al., 2002
259±3	辉长岩	SHRIMP	攀西新街侵入岩	Zhou et al., 2002
253.6±0.4	玄武岩	Ar/Ar	广西百色	Fan et al., 2004
255.4±0.4	玄武岩	Ar/Ar	广西田阳	Fan et al., 2004
256.2±0.8	玄武岩	Ar/Ar	广西巴马	Fan et al., 2004
253.7±6.1	玄武岩	SHRIMP	广西百色	Fan et al., 2004
262±3	苏长橄榄辉长岩	SHRIMP	四川盐源	Guo et al., 2004
263±3	淡色辉长岩	SHRIMP	攀枝花侵入岩	Zhou et al., 2005
260±3	辉绿岩	SHRIMP	云南富宁	Zhou et al., 2006
258±3	闪长岩	SHRIMP	云南富宁	Zhou et al., 2006
261.6±4.4	正长岩	SHRIMP	攀西猫猫沟岩体	罗震宇等, 2006
258.9±3.4	玄武岩	Ar/Ar	峨眉山玄武岩省	侯增谦等, 2006
259.3±1.3	矿化辉长岩	TIMS	攀西红格侵入岩	Zhong and Zhu, 2006
260.7±0.8	角闪辉长岩	TIMS	攀西冰谷侵入岩	Zhong and Zhu, 2006
261±4	钠闪石花岗岩	SHRIMP	攀西白马侵入岩附近茨达A型花岗岩	Zhong et al., 2007
251±6	黑云母钾长石花岗岩	SHRIMP	攀西红格侵入岩附近矮郎河I型花岗岩	Zhong et al., 2007
249±32	铜镍硫化物矿石	Re-Os	云南白马寨	Wang et al., 2007
256.85±2.69	辉长岩中黑云母	Ar/Ar	攀枝花岩体	Wang et al., 2007
250.2 ±1.9	苦橄质基性-超基性岩	Ar/Ar	四川丹巴杨柳坪	Wang et al., 2007
257±4	宣威组底部沉积物	SHRIMP	贵州威宁	He et al., 2007
260±5	宣威组底部沉积物	SHRIMP	贵州威宁	He et al., 2007
263±4	玄武岩顶部酸性凝灰岩	SHRIMP	云南洱源	He et al., 2007
260±4	粘土岩	SHRIMP	四川朝天	He et al., 2007
263±3	辉长岩	SHRIMP	攀西力马河侵入岩	Zhou et al., 2008
261±1	闪长岩	SHRIMP	攀西朱布侵入岩	Zhou et al., 2008
262±2	正长岩	SHRIMP	攀西白马侵入岩	Zhou et al., 2008
260.6±3.5	蛇纹石化橄榄岩	SHRIMP	云南金宝山岩体	陶琰等, 2008
260.7±5.6	斜长角闪岩	SHRIMP	云南金宝山岩体	陶琰等, 2008
259.6±5.9	斑状玄武岩	SHRIMP	广西巴马	Fan et al., 2008
259.1±4.0	斑状玄武岩	SHRIMP	广西百色	Fan et al., 2008
261.6±4.4	霞石正长岩	SHRIMP	攀西猫猫沟侵入岩	Xu et al., 2008
259.8±3.5	辉石正长岩	SHRIMP	攀西米易	Xu et al., 2008
260.4±3.6	闪长岩	SHRIMP	攀西米易撒莲镇	Xu et al., 2008
261.4±2.3	A型花岗岩	SHRIMP	攀西太和侵入岩	Xu et al., 2008
266.5±5.1	辉石正长岩	SHRIMP	攀西米易黄草岩体	Xu et al., 2008
255.2±3.6	过铝质花岗岩	SHRIMP	攀西红格侵入岩附近矮郎河	Xu et al., 2008
238.4±3.4	流纹凝灰岩	SHRIMP	云南宾川	Xu et al., 2008
255.0±0.62	辉绿岩	LA-ICP-MS	贵州罗甸	韩伟等, 2009
261±2	辉长岩	SHRIMP	攀西白马侵入岩	Shellnutt et al., 2009
253.1±1.9	正长岩	SHRIMP	攀枝花侵入岩中正长岩侵入体	Zhong et al., 2009
259.69±0.61	辉长苏长岩	LA-ICP-MS	攀西大板山	王萌等, 2011
251.0±1.0	凝灰岩	LA-ICP-MS	贵州盘县	朱江等，2011
260±8	花岗岩	SHRIMP	攀西营盘梁子岩体	Shellnutt et al., 2011
261±5	镁铁质岩墙	SHRIMP	攀枝花市南部	Shellnutt and Jahn, 2011
259.5±2.7	镁铁质包体	LA-ICP-MS	攀西白马侵入岩	Zhong et al., 2011
259.0±3.1	镁铁质包体	LA-ICP-MS	攀西白马侵入岩	Zhong et al., 2011
258.2±2.2	辉长岩	LA-ICP-MS	攀西白马侵入岩	Zhong et al., 2011
258.5±2.3	正长岩	LA-ICP-MS	攀西白马侵入岩	Zhong et al., 2011
257.8±2.6	正长岩	LA-ICP-MS	攀西白马侵入岩	Zhong et al., 2011
256.2±1.5	花岗岩	LA-ICP-MS	攀西白马侵入岩	Zhong et al., 2011
257.9±2.4	辉长岩	LA-ICP-MS	攀枝花侵入岩	Zhong et al., 2011
255.4±3.1	辉长岩	LA-ICP-MS	攀枝花侵入岩	Zhong et al., 2011
259.5±1.1	正长闪长岩	LA-ICP-MS	攀枝花侵入岩	Zhong et al., 2011
259.2±1.3	正长闪长岩	LA-ICP-MS	攀枝花侵入岩	Zhong et al., 2011
257.8±2.3	正长闪长岩	LA-ICP-MS	攀枝花侵入岩	Zhong et al., 2011
259.8±1.6	正长闪长岩	LA-ICP-MS	攀枝花侵入岩	Zhong et al., 2011
255.8±1.8	正长岩	LA-ICP-MS	攀枝花侵入岩	Zhong et al., 2011
258.7±2.0	辉长岩	LA-ICP-MS	攀西红格侵入岩	Zhong et al., 2011
258.9±2.1	辉长岩	LA-ICP-MS	攀西红格侵入岩	Zhong et al., 2011
256.8±2.8	I型花岗岩	LA-ICP-MS	攀西红格侵入岩	Zhong et al., 2011
256.2±3.0	I型花岗岩	LA-ICP-MS	攀西红格侵入岩	Zhong et al., 2011
258.8±2.3	辉长岩	LA-ICP-MS	攀西太和侵入岩	Zhong et al., 2011
257.6±0.5	镁铁质侵入岩	CA-TIMS	侵入攀西沃水过铝质正长岩中	Shellnutt et al., 2012
259.2±0.4	镁铁质岩墙	CA-TIMS	侵入攀西白马侵入岩的过碱性正长岩中	Shellnutt et al., 2012
259.4±0.8	镁铁质岩墙	CA-TIMS	侵入攀西白马侵入岩的过碱性正长岩中	Shellnutt et al., 2012
259.6±0.5	准铝质正长岩	CA-TIMS	攀西沃水岩体	Shellnutt et al., 2012
259.1±0.5	准铝质正长岩	CA-TIMS	攀西大黑山岩体	Shellnutt et al., 2012
258.9±0.7	准铝质正长岩	CA-TIMS	攀西草黄岩体	Shellnutt et al., 2012
258.4±0.6	花岗岩	CA-TIMS	攀西白马侵入岩附近茨达	Shellnutt et al., 2012
257±9	玄武岩	LA-ICP-MS	广西	Lai et al., 2012
256.7±4.3	基性岩墙	LA-ICP-MS	四川冕宁	Li, 2012
257.6±2	基性岩墙	LA-ICP-MS	云南富民	Li, 2012
255.1±3. 6	黑云母二长花岗岩	LA-ICP-MS	侵入攀西红格岩体内部的大老包花岗岩	程黎鹿等, 2013
261.4±4.6	苦橄质岩墙	LA-ICP-MS	攀枝花岩体	Hou et al., 2013
263±10	辉绿岩	LA-ICP-MS	贵州普安	曾广乾等, 2014
259.1±0.5	长英质熔结凝灰岩	CA-TIMS	云南江尾镇宾川剖面	Zhong et al., 2014
259.9±1.1	辉长岩	LA-ICP-MS	攀西大板山	Liu et al., 2015
260.3±1.3	辉长苏长岩	LA-ICP-MS	攀西大板山	Liu et al., 2015
262~249	花岗岩和流纹岩	LA-ICP-MS	越南北部Phan Si Pan-Tu Le地区	Usuki et al., 2015
264±3	基性岩墙(斜锆石)	SIMS	云南武定	Fan et al., 2017
256±5	基性岩墙(斜锆石)	SIMS	云南武定	Fan et al., 2017

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