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高校地质学报 ›› 2023, Vol. 29 ›› Issue (5): 657-678.DOI: 10.16108/j.issn1006-7493.2022018

• 岩石·矿床·地球化学 •    下一篇

浙江白垩纪大衢山岩体的成因过程:晶体—熔体分离与岩浆补给

何 晨1,夏 炎1,2*,徐夕生1,邱检生1,徐 航1,张 志1,赵思狄1   

  1. 1. 南京大学 地球科学与工程学院,内生金属矿床成矿机制研究国家重点实验室,南京 210023;
    2. 南京大学 关键地球物质循环前沿科学中心,南京 210023
  • 出版日期:2023-10-11 发布日期:2023-10-10

Genesis Process of the Cretaceous Daqushan Pluton in Zhejiang Province: Crystal-Melt Separation and Magmatic Recharge

HE Chen1,XIA Yan1, 2*,XU Xisheng1,QIU Jiansheng1, XU Hang1,ZHANG Zhi1,ZHAO Sidi1   

  1. 1. State Key Laboratory for Mineral Deposits Research, School of Earth Sciences and Engineering, Nanjing University, Nanjing 210023, China;
    2. Frontiers Science Center for Critical Earth Cycling, Nanjing University, Nanjing 210023, China
  • Online:2023-10-11 Published:2023-10-10

摘要: 穿地壳岩浆系统理论和晶粥模型为研究中国东南部白垩纪岩浆作用提供了新的思路。大衢山岩体位于浙闽沿海东北部,主体由钾长花岗岩组成,其中发育大量暗色微粒包体(MME),局部可见中—基性岩脉穿插其中,潮头门附近出露少量二长岩。MME具细粒结构,发育针状磷灰石。锆石U-Pb定年结果显示,大衢山岩体出露的钾长花岗岩、MME、二长岩、中—基性岩脉均结晶于~100 Ma。钾长花岗岩硅含量较高(SiO2=68.45%~73.82%)。岩体东端可见不含MME的晶洞花岗岩(DQS-7),具有更高硅含量(76.27%),其全岩化学成分与Sr-Nd同位素组成与大衢山周围同期出露的高硅花岗岩体(SiO2 >75%,小洋山岩体,普陀山岩体等)类似。大衢山钾长花岗岩中可见斜长石、钾长石聚晶,与大衢山晶洞花岗岩及周边高硅花岗岩具有Ba、Sr、P等微量元素“互补”的地球化学特征。进一步研究显示大衢山钾长花岗岩是由受到岩浆补给的起源于古老地壳基底重熔的长英质岩浆,经分离结晶和高硅熔体抽离后的残余堆晶固结而成,而高硅熔体形成了大衢山晶洞花岗岩及周边高硅花岗岩。大衢山基性岩脉富集大离子亲石元素,亏损Nb、Ta等高场强元素,与同期出露的浙闽沿海镁铁质岩墙具有相似的地球化学特征,起源于俯冲流体交代的富集地幔。电子探针分析结果表明,钾长花岗岩和MME中的斜长石具有核—幔—边结构,核部(花岗岩27~36、MME 25~41,后同)与边部(17~32、18~26)An值较低,幔部An值(28~57、27~65)相对较高,是岩浆混合作用的典型矿物学标志。结合元素地球化学特征和Sr-Nf-Hf同位素组成,二长岩和中性岩脉应该是幔源镁铁质岩浆与长英质岩浆发生均匀混合的产物,而MME为两种岩浆机械混合的产物。角闪石全铝压力计计算结果表明,MME的形成深度为1.8~3.0 km;二长岩中角闪石发育核—幔—边结构,核部和幔部形成深度为17.0~21.2 km,边部形成深度1.9~4.5 km,指示了不同深度相互连通的两个岩浆房。通过对钾长花岗岩、MME、晶洞花岗岩、二长岩和中—基性岩脉岩石成因及其成因联系的研究,并对比周边同期高硅花岗岩,文章建立了大衢山穿地壳岩浆系统模型。古太平洋板片后撤,沿海地区的弧后伸展和软流圈上涌导致幔源镁铁质岩浆的底侵,并进一步诱发下地壳岩石部分熔融产生长英质岩浆。幔源岩浆的持续补给和加热延长了长英质岩浆房的寿命,发生了分异演化与晶体—熔体的分离,从而形成了深度分别为17~21 km和2~3 km的两个岩浆房。两个不同深度岩浆房中发生的岩浆混合和晶体—熔体分离,最终形成钾长花岗岩、高硅花岗岩、二长岩、MME和中—基性岩脉。

关键词: 穿地壳岩浆系统, 晶粥模型, 晶体—熔体分离, 岩浆混合, 角闪石, 斜长石

Abstract: The models of trans-crustal magmatic system and crystal mush provide new insights into the study of Cretaceous magmatism in northeast China. The Daqushan pluton is located in the northeast of coastal Zhejiang and Fujian. It is mainly composed of K-feldspar granite with abundant melanocratic microgranular enclaves (MME) and is locally traversed by several mafic-intermediate dikes. A small outcrop of monzonite is exposed near the Chaotoumen. MME have a fine-grained texture with acicular apatites. Zircon U-Pb dating results show that the rock samples in the Daqushan pluton (including the K-feldspar granite, MME, monzonite, and mafic-intermediate dikes) crystallized at ~100 Ma. The K-feldspar granite are highly silicic (SiO2=68.45%-73.82%). While the miarolitic granite (DQS-7) without MME has the higher silica (76.27%), and its whole-rock geochemical and Sr-Nd isotope compositions are similar to those of coeval high silica granites (SiO2>75%) exposed around the Daqushan pluton. Daqushan K-feldspar granite bearing aggregates of plagioclase and K-feldspar exhibit“complementary”trace element geochemical characteristics with Daqushan miarolite and surrounding high silica granites. Further researches show that the Daqushan K-feldspar granite and miarolite were formed by felsic magma which originated from the partial melting of the ancient crustal basement and was recharged by mantle-derived magma. Such felsic magma underwent fractional crystallization and the extraction of high silica melt. Then, the residual silicic cumulate of the crystal mush and high silica melt crystallized and formed the Daqushan K-feldspar granite, miarolite and the surrounding coeval high silica granites. The mafic dikes of Daqushan are enriched in LILEs and depleted in HFSEs
and are derived from the partial melting of the enriched mantle metasomatized by subducted dehydration fluids. The results of EPMA analyses indicate that the plagioclase in the K-feldspar granite and MME has a core-mantle-rim texture with low- An in the core (27-36, 25-41) and rim (17-32, 18-26) and relatively high-An in the mantle (28-57, 27-65). Integration of the element geochemical characteristics and Sr-Nd-Hf isotopic results, monzonite and intermediate dikes should be the product of magma mixing of mantle-derived mafic magma and felsic magma, while MME are the product of magma mingling of the two endmembers. The results of the Al-in-hornblende geobarometer show that the crystallization depth of MME is 1.8- 3.0 km, hornblende in monzonite develops core-mantle-rim texture, the crystallization depth of hornblende core and mantle is 17.0-21.2 km, and the depth of hornblende rim is 1.9-4.5 km. Based on the study of the origin and genetic relationships of K-feldspar granite, MME, miarolite, monzonite and mafic-intermediate dikes, and compared with the surrounding coeval high silica granites, this study establishes a model of trans-crustal magmatic systems for Daqushan pluton. The rollback of the subducting paleo-Pacific plate, the back-arc extension in the coastal area and the upwelling of the asthenosphere led to the underplating of the mantle-derived mafic magma, and further induced the partial melting of basement rocks in the lower crust to produce felsic magma. The continuous recharge and heating of mantle-derived magma favor the existence of long-lived melt-bearing regions in magma chambers, promoting magma differentiation and crystal-melt separation and thus forming two magma chambers with depths of 17-21 km and 2-3 km, respectively. K-feldspar granite, high silica granites, monzonite, MME and intermediate-mafic dikes were formed by magma mingling/mixing and crystal-melt separation in two connected magma chambers at different depths.

Key words: trans-crustal magmatic system, crystal mush, crystal-melt separation, magma mixing/mingling, hornblende, plagioclase

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