北祁连山元古宙末－寒武纪主动大陆裂谷火山作用

北祁连山元古宙末－寒武纪大陆裂谷火山岩系为双峰式火山岩套，主要由基性与酸性火山岩组成。基性火山岩有磁性玄武岩与拉斑玄武岩两个岩浆系列，且富集ＬＲＥＥ与ＬＩＬ，其岩浆源区为与洋岛玄武岩源相似的富集地幔柱源。软流圈地幔柱上涌导致岩石圈地慢部分熔融，其熔体与地幔柱衍生熔浆混合，形成本区具有中等钕，锶同位素比值特点的基性岩浆。基性岩浆上侵至陆壳，引起下部陆壳深熔，产生长英质岩浆。地幔柱上隆促使大陆扩张，及至形成北祁连山元古宙末－寒武纪大陆裂谷。     

松辽盆地长岭断陷中基性火山岩的时代与其成因

锆石U-Pb定年结果显示,松辽盆地长岭断陷松南180井中基性火山岩形成于101～116 Ma的早白垩世晚期,属于营城组,非火石岭组火山岩。岩相学观察主要由安山岩和橄榄玄武岩组成,化学成分显示为玄武岩、粗面玄武岩和玄武质粗面安山岩,属碱性系列,镁质量分数较低,镁值较小（Mg^#=0.27~0.53）。稀土元素总量较高（w（∑REE）=（164.98~257.27）×10^-6）,轻重稀土分馏明显（（La/Yb）_N=6.60~10.96）,铕异常微弱（δEu=0.85~1.02）。富集大离子亲石元素和轻稀土元素, Rb,K 相对亏损,相容元素（Cr、Co、Ni）质量分数低,高场强元素Nb、Ta弱富集,整体表现出与 OIB(洋岛玄武岩)一致的稀土图谱和微量元素特征。岩浆源区为软流圈地幔,经历了深部地幔流体的交代富集作用,岩浆未遭受地壳物质的混染。     

藏西北黑石北湖一带新近纪火山岩的特征及构造意义

青藏高原西北部黑石北湖一带发育的橄榄安粗岩系列火山岩具有由早到晚从基性到中性连续演化的特征，3期火山活动期次分明，以中心式喷发为主，K-Ar年龄分别为9．23Ma、3．19Ma和3Ma。该火山岩的稀土元素、微量元素、同位素组成特征与藏北其他地区的新生代火山岩基本相近。火山活动为新构造活动的响应，受控于青藏高原隆升过程中产生的走滑断裂。     

西藏羌塘戈木错渐新世钾质火山岩的地球化学特征及其构造意义

羌塘戈木错出露一套30Ma的钾质火山岩,岩石类型包括橄榄碱玄岩、橄榄粗面玄武岩、霓辉粗面岩和含白榴石响岩。火山岩的SiO2含量变化于46%~60%之间,Al2O3含量在13%~21%之间,Mg#介于0.14和0.63之间,K2O/Na2O>1。岩石强烈富集轻稀土元素（LREE）,亏损相容元素（Cr、Ni）和高场强元素（Nb、Ta、Ti）,全岩εHf(t)值变化于-1.28~-6.20之间。研究表明,戈木错火山岩母岩浆起源于软流圈流体交代的古俯冲地幔楔的低程度熔融,同源岩浆经历了AFC作用。戈木错火山岩和区域上的鱼鳞山、火车头山钾质—超钾质火山岩共同组成了羌塘渐新世钾质—超钾质火山岩带。综合南羌塘新生代火山岩岩浆性质的演化,认为岩浆的产生可能与35Ma左右羌塘陆内俯冲板片断离导致的软流圈上涌-岩石圈减薄作用有关。     

Melt and fluid inclusion evidence for a genetic relationship between magmatism in the Shuangliao volcanic field and inorganic CO2 gas reservoirs in the southern Songliao Basin,China

We have studied melt and fluid inclusions in minerals from alkali basalts, mantle xenoliths, and dawsonite-bearing sandstones from the Shuangliao volcanic field in southern Songliao Basin, Northeast China. The inclusions have been investigated using petrographic, geochemical, and laser Raman spectroscopic techniques. Volcanic rocks of the Shuangliao field are predominantly alkali olivine basalts that contain rare mantle xenoliths. Silicate melt and fluid inclusions are common in both olivine phenocrysts and the mantle xenoliths. The fluid inclusions are mainly composed of CO₂ with small amounts of CO, CH₄, N₂, and H₂O, which is consistent with an upper mantle origin. CO₂ gas reservoirs in the southern Songliao Basin are mostly derived from a mantle–magmatic source. Coeval fluid-inclusion homogenization temperatures, coupled with the thermal burial history, show that the CO₂ gas reservoirs in the southern Songliao Basin are Cenozoic (40–63 Ma) and coeval with the magmatism in the Shuangliao volcanic field. Despite the relatively small scale of this volcanic activity, it released large amounts of CO₂. Much of the magma was not erupted, and CO₂- and H₂O-rich magma was probably intruded into the basin along deep faults, acting as a major source of inorganic CO₂ gas in the southern Songliao Basin.     

新疆阿尔泰库卫铜镍硫化物-钛铁氧化物复合型矿化镁铁-超镁铁质杂岩体成因

库卫镁铁-超镁铁质杂岩体位于新疆阿尔泰南缘,兼具铜镍矿化岩体和钒钛铁矿化岩体的双重特征,主要组成岩石类型有中粒辉长岩、条带状橄榄辉长岩、橄榄苏长辉长岩、角闪辉长岩和含橄辉长岩等。本文采用LA-ICP-MS锆石U-Pb定年法,获得中粒辉长岩、橄榄苏长辉长岩和含橄辉长岩的加权平均年龄分别为398.7±3.7Ma、397.5±2.3Ma和385.2±1.6Ma,表明库卫岩体是早中泥盆世构造-岩浆活动的产物。岩体的主量元素显示其属亚碱性系列,并具有向拉斑系列岩石演化的趋势。具有Ba、U、Ta、Pb、Sr、Ti和Eu的正异常,Th的负异常,显示了相似的LREE相对富集的右倾型配分模式,表明它们可能为同源岩浆演化的产物。结合地球化学特征和区域地质背景,推测库卫岩体为早中泥盆世俯冲消减环境的产物,其原始岩浆可能来源于受俯冲物质交代的地幔楔和软流圈的混合体,不同的岩石类型是相似来源的岩浆经强烈分异的结果。库卫岩体兼具铜镍矿化岩体和钒钛铁矿化岩体的双重特征,但形成铁钛矿床的潜力略显不足。     

长江中下游—大别造山带中生代火山岩特征及成因

中国中东部长江中下游地区和大别造山带广泛发生了中生代岩浆作用,火山岩均集中在中间阶段,时代分别为135~127 Ma和133~125 Ma。长江中下游地区多个中生代火山盆地发育高钾钙碱性系列双峰式火山岩和中基性橄榄安粗岩系列火山岩。这些岩石富集大离子亲石元素,亏损高场强元素,弱富集Sr-Nd-Hf同位素,具有高放射成因Pb同位素组成,指示地幔源区地壳组分的加入。其中,中基性火山岩起源于富集的岩石圈地幔,受到俯冲大洋板片析出的含水熔体交代,晚阶段的超碱质火山岩起源于类似交代介质交代的软流圈地幔,指示岩浆源区的加深。大别造山带中生代火山岩包括高钾钙碱性系列和超钾质系列,均富集大离子亲石元素,亏损高场强元素,高度富集Sr-Nd-Hf同位素,具有低放射成因Pb同位素组成,与长江中下游地区差异显著。其中,高钾钙碱性系列火山岩起源于交代富集的岩石圈地幔,交代介质为印支期深俯冲的华南陆壳析出熔体,而晚阶段的超钾质火山岩起源更深,是深俯冲的华南陆壳在高压下,多硅白云母分解产生熔体交代的地幔源区。长江中下游地区幔源火山岩记录了俯冲的古太平洋板块的直接物质贡献,而大别造山带地幔源区记录了印支期俯冲陆壳的信息。两个构造单元火山岩早、晚阶段均表现出岩浆源区的加深,长江中下游地区对应了古太平洋板块的低角度俯冲及俯冲板片的回卷(约130 Ma),而大别造山带在古太平洋板块俯冲回卷的动力学机制下,发生造山带的垮塌和岩石圈的拆沉。     

新疆东昆仑达拉库岸镁铁-超镁铁质岩体年代学、地球化学及成矿条件

达拉库岸镁铁-超镁铁质岩体位于东昆仑造山带南带之喀拉米兰晚古生代沟弧系,主要由二辉橄榄岩、单辉橄榄岩、橄榄二辉岩、单辉辉石岩和辉长岩组成。辉长岩的锆石U-Pb谐和年龄为244.4±1.5Ma,属于中三叠世。岩石普遍弱富集稀土元素和大离子亲石元素(Rb、Ba、Sr),亏损不相容元素(Nb、Ta)。岩体原生岩浆为高镁拉斑玄武质岩浆(Mg O 11.4%,Fe O10.8%)。元素地球化学和Nd、Sr同位素组成特征表明岩浆源区为富集岩石圈地幔,岩浆运移和侵位过程中遭受不同程度地壳物质的同化混染作用。依据橄榄石组分模拟获得橄榄石结晶过程中母岩浆达到硫饱和,并发生硫化物的熔离作用。从岩体特征、矿石结构、原生岩浆性质、深部硫化物熔离和物探信息等方面综合分析,岩体具有形成岩浆型铜镍硫化物矿床的良好条件。     

大别山北缘定远组双峰式火山岩-新元古代晚期裂解事件记录

为了了解大别山北缘构造属性,对定远组地层组成、形成时代及地球化学特征进行调查与研究.野外调查表明,定远组主要由一套变火山岩及云母片岩、云母石英片岩、浅粒岩、板岩等组成,其中变火山岩包括变玄武岩与变流纹质火山岩,并构成典型的双峰式火山岩建造;此外,还含有早古生代构造地层单位.运用LA-ICP-MS对酸性火山岩锆石进行U-...     

中国东部地区新生代岩浆活动对区域性CO2形成时间的制约

中国东部地区新生代存在 4个岩浆活动期 :第一期 6 5～ 4 1Ma ,第二期 4 1～ 2 1Ma ,第三期 2 1～ 13Ma ,第四期 11Ma至今。对研究区内火山岩地球化学研究表明 ,古近纪早期火山岩以拉斑玄武岩和钙碱性玄武岩为主 ,后期特别是从沙三期开始逐渐转变为碱性岩石。火山岩中CO2 包裹体含量统计表明 ,沙三段 (Es3 )中CO2 含量明显高于其它几个岩性段 ,而碱性岩中CO2 的含量又明显高于拉斑玄武岩中的含量。沙三期是整个东部地区一个较重要的岩浆活动期和火山活动发生重大改变的时期 ,从沙三期到馆陶期形成的碱性岩具有最大的CO2 成藏潜力 ,沙三期及以后的火山岩与CO2 在空间上存在密切关系 ,因此沙三期到馆陶期是形成区内CO2 的主要时期。     

吉林省长白山地区新生代火山岩的特点及其成因

长白山地区新生代火山岩是一套玄武岩、粗面岩和钠闪碱流岩的双峰式火山岩组合。玄武岩类分别属于碱性玄武岩系列和拉斑玄武岩系列。奶头山期玄武岩是幔源原生岩浆直接喷发于地表的产物,其他各期玄武岩是幔源原生岩浆经历了一定程度分异作用的产物。粗面岩和钠闪碱流岩与玄武岩有成因联系,可能是玄武岩浆通过分离结晶作用而形成的。本区新生代火山岩是大陆裂谷构造环境下的产物,是在地幔增温和底辞上升过程中形成的。     

中亚造山带中新生代壳幔相互作用特征与过程——新疆北部幔源岩浆岩系对比研究

新疆北部中新生代幔源岩浆岩多位于大型走滑断裂带或者裂谷带附近,岩石系列均具有高的TiO2含量,富碱、高度富集不相容元素和轻稀土(LREE),εNd(t)值低正值到负值,(87Sr/86Sr)i值较高,不相容元素比值La/Nb和Nb/U显示中新生代玄武岩浆在形成过程中的壳幔作用明显不同于古生代造山过程,岩浆来源于类似OIB源的富集地幔。而新疆北部地区的二叠纪幔源镁铁-超镁铁岩来源于亏损地幔,陆壳物质参与了岩浆的形成,源区可能混入了早期的弧组分或俯冲的洋壳。由于古生代多个洋盆闭合和增生造山作用致使中亚造山带的岩石圈不断增厚,于古生代晚期发生拆沉去根作用,软流圈亏损地幔上涌形成二叠纪镁铁-超镁铁岩系,而拆沉的岩石圈以及俯冲下沉的洋壳及其沉积物,在地幔环境熔融交代改造原始地幔,使中亚地区的地幔自古生代晚期以后逐渐转换为整体富碱、富含轻稀土(LREE)和不相容元素的富集地幔。被改造了的富集地幔在中新生代沿裂谷带或大型走滑断裂薄弱带上涌,形成了中新生代幔源岩浆的喷发和侵位。     

宕昌好梯第三纪超镁铁质岩中巨晶及其形成条件

分布于好梯第三纪陆相地层中的超镁铁质岩属碱性超基性岩，为超镁铁煌斑岩。该岩石系中心式超基性火山爆发—喷溢产物。其产出与南北向幔型断裂活动和地幔部分熔融岩浆贯入密切相关。根据岩石组合及产状，好梯陆相超基性火山岩可分为火山颈相、喷发相和次火山岩相。其中火山颈相和喷发相内的碎屑熔岩含有大量的二辉橄榄岩包体，并与单斜辉石和橄榄石巨晶共生。研究结果表明，巨晶系岩浆在上地幔条件下结晶的高压产物     

Magmatic history of the Eastern Creek Volcanics,Mt Isa,Australia: insights from trace-element and platinum-group-element geochemistry

The Paleoproterozoic basalts of the Eastern Creek Volcanics are a series of continental flood basalts that form a significant part of the Western Fold Belt of the Mt Isa Inlier, Queensland. New trace-element geochemical data, including the platinum-group elements (PGE), have allowed the delineation of the magmatic history of these volcanic rocks. The two members of the Eastern Creek Volcanics, the Cromwell and Pickwick Metabasalt Members, are formed from the same parental magma. The initial magma was contaminated by continental crust and erupted to form the lower Cromwell Metabasalt Member. The staging chamber was continuously replenished by parental material resulting in the gradual return of the magma composition to more primitive trends in the upper Cromwell Metabasalt Member, and finally the Pickwick Metabasalt Member formed from magma dominated by the parental melt. The Pickwick Metabasalt Member of the Eastern Creek Volcanics has elevated PGE concentrations (including up to 18 ppb Pd and 12 ppb Pt) with palladium behaving incompatibly during magmatic fractionation. This trend is the result of fractionation under sulfide-undersaturated conditions. Conversely, in the basal Cromwell Metabasalt Member the PGE display compatible behaviour during magmatic fractionation, which is interpreted to be the result of fractionation of a sulfide-saturated magma. However, Cu remains incompatible during fractionation, building up to high concentrations in the magma, which is found to be the result of the very small volume of magmatic sulfide formation (0.025%). Geochemical trends in the upper Cromwell Metabasalt Member represent mixing between the contaminated Cromwell Metabasalt magmas and the PGE-undepleted parental melt. Trace-element geochemical trends in both members of the Eastern Creek Volcanics can be explained by the partial melting of a subduction-modified mantle source. The generation of PGE- and copper-rich magmas is attributed to melting of a source in the subcontinental lithospheric mantle below the Mt Isa Inlier which had undergone previous melt extraction during an older subduction event. The previous melt extraction resulted in a sulfur-poor, metal-rich metasomatised mantle source which was subsequently remelted in the Eastern Creek Volcanic continental rift event. The proposed model accounts for the extreme copper enrichment in the Eastern Creek Volcanics, from which the copper has been mobilised by hydrothermal fluids to form the Mt Isa copper deposit. There is also the potential for a small volume of PGE-enriched magmatic sulfide in the plumbing system to the volcanic sequence.     

Geochemical evolution of Middle—Late Cenozoic magmatism in the northern part of the Rio Grande Rift,Western United States

Geochemical studies of the Middle—Late Cenozoic succession of volcanic rocks from the northern part of the Rio Grande Rift were conducted. The initial activation of the rift structure was coeval with voluminous eruptions of lava and pyroclastic material of mainly intermediate and acid compositions in the San Juan volcanic field 35–27 Ma. The composition of the volcanic products after the rifting was dominated by basic and intermediate lavas. It is shown that the basanites and alkali basalts of the territory had geochemical characteristics of sublithospheric slab and above–sl ab sources. The processes of the riftogenic thinning of lithosphere are expressed by geochemical parameters that reflect the interaction between the liquids from the sublithospheric mantle and the rocks from different levels of both the lithospheric mantle and lower crust. In the 35–18 Ma interval, melts of different–depth sublithospheric and lithospheric sources erupted simultaneously in the northern part of the rift. However, the products of interaction between the sublithospheric and lithospheric materials dominated later in the past 15 Ma, although the sublithospheric magmatic liquids erupted at the northern structural termination of the rift within the Yampa volcanic field at about 10 Ma.     

Magmatic sources and geodynamics of the early Mesozoic Northern Mongolia-Western Transbaikalia rift zone

The Northern Mongolia-Western Transbaikalia rift zone is the largest Mesozoic riftogenic structure in eastern Asia and extends for a distance of more than 1200 km. The zone consists of depressions and grabens, which were formed between 233 and 188 Ma and are filled with basaltic and basalt-comendite (bimodal) volcanic associations accompanied by numerous peralkaline granite massifs. Geochemical and isotope (Sr, Nd, and Pb) studies showed that mantle and crustal sources contributed to the formation of the magmatic rocks of the rift zone. The basalts were formed from incompatible element-enriched mantle sources. Geochemical and isotope-geochemical data suggest that the peralkaline salic rocks (comendites and peralkaline grantoids) and basalts are genetically related and were formed by the fractionation of a common parental magma. In addition, the magmatic associations contain peralkaline granites and comendites whose isotope signatures indicate their formation through the crustal contamination of derivatives of basaltic melts. The rift zone has arisen during the formation of the Mongolia-Transbaikalia zoned magmatic area in a complex geodynamic setting, combining collision in the Mongolia-Okhotsk suture with a mantle plume impact. The rift zone occupies the northern periphery of the area, being controlled by the Northern Mongolia-Transbaikalia fault system, which marks the boundaries (sutures) of large terranes in the lithosphere. Asthenospheric traps beneath suture boundaries served as pathways for the penetration of a mantle plume into the upper lithosphere, thus playing an important role in the localization of the riftogenic processes.     

长白山地区新生代火山岩及其幔源包体的矿物化学及矿物包裹体研究

长白山地区新生代火山岩主要为玄武岩类、粗面岩类和碱性流纹岩类。其中奶头山期碱性玄武岩中含有幔源的尖晶石二辉橄榄岩包体和辉石岩包体。幔源包体及不同期次火山岩的主要矿物是橄榄石、单斜辉石、斜方辉石、尖晶石、斜长石、碱性长石。不同寄主岩石中的矿物组成及其化学成分具有一定的变化，反映了岩浆分异演化的特征；矿物及火山熔岩中的包裹体成分及玻璃熔体结构的激光拉曼光谱分析结果表明，地下深处的岩浆含有较多的挥发分，岩浆上升过程中发生了强烈的出溶作用；岩浆由起源经分异演化上升到地壳浅部直至喷发，幔源的挥发分减少，而浅成或壳源的挥发分增多，特别是在岩浆喷发过程中，地下水或大气成分起了重要作用。     

Petrogenesis of Miocene alkaline volcanic suites from western Bohemia: whole rock geochemistry and Sr–Nd–Pb isotopic signatures

The Mid to Late Miocene intraplate alkaline volcanic suites of western Bohemia are relict of the intensive voluminous volcanism accompanied by large-scale uplift and doming. The association with the uplift of the NE flank of the Cheb–Domažlice Graben (CDG) is uncertain in view of the mostly transpressional tectonics of the graben. The volcanism is most probably of the Ohře/Eger Rift off-rift settings. Two cogenetic volcanic suites have been recognised: (i) silica-saturated to oversaturated consisting of olivine basalt–trachybasalt-(basaltic) trachyandesite–trachyte–rhyolite (13.5 to 10.2 Ma) and (ii) silica-undersaturated (significantly Ne-normative) (melilite-bearing) olivine nephelinite–basanite–tephrite (18.3 to 6.25 Ma). A common mantle source is suggested by similar primitive mantle-normalised incompatible element patterns and Sr–Nd–Pb isotopic compositions for the assumed near-primary mantle-derived compositions of both suites, i.e., olivine basalt and olivine nephelinite. Apparently, they were generated by different degrees of partial melting of a common mantle source, with garnet, olivine and clinopyroxene in the residuum. Negative Rb and K anomalies indicate a residual K-phase (amphibole/phlogopite) and melting of partly metasomatised mantle lithosphere. The evolution of the basanite–olivine basalt–trachybasalt-(basaltic) trachyandesite–trachyte–rhyolite suite suggests the presence of an assimilation–fractional crystallization process (AFC). Substantial fractionation of olivine, clinopyroxene, Fe–Ti oxide, plagioclase/alkali feldspar and apatite accompanied by a significant assimilation of magma en route by crustal material is most evident in evolved member, namely, trachytes and rhyolites. The magmas were probably sourced by both sub-lithospheric and lithospheric partly metasomatised mantle. The evolution of the (melilite-bearing) olivine nephelinite–basanite–tephrite suite is less clear because of its limited extent. Parental magma of both these rock suites is inferred to have originated by low-degree melting of the mantle source initiated at ca. 18 Ma and reflects mixing of asthenosphere-derived melts with isotopically enriched lithospheric melts. The older Oligocene alkaline rocks (29–26 Ma) occur within the Cheb–Domažlice Graben (CDG) locally but are significant in the closely adjacent neighbouring western Ohře Rift. The Sr–Nd–Pb isotopic composition of primitive volcanic rocks of both suites is similar to that of the European Asthenospheric Reservoir (EAR). Initial Pb isotopic data plot partly above the northern hemisphere reference line at radiogenic ²⁰⁶Pb/²⁰⁴Pb ratios of ∼19 to 20, and indicate the presence of a Variscan crustal component in the source.     

安徽铜陵中生代侵入岩地质地球化学特征再认识及成因讨论

安徽铜陵地区是我国最著名的铜多金属矿产地,岩浆岩出露广泛,岩浆作用与成矿关系密切.作者广泛收集了前人对铜陵地区中生代岩浆岩的研究资料和成果,并在此基础上进行了仔细的岩相学观察和深入的岩石学、岩石化学和微量元素及同位素地球化学研究,系统总结了该区中生代侵入岩的地质地球化学特征,并探讨了其成因机制.研究认为:①铜陵地区中酸性侵入岩形成于晚侏罗世-早白垩世(135 ～ 147Ma),岩浆活动持续时间大约为10～15Ma;岩体沿近东西向深断裂呈带状分布,浅成侵入产出,受多期不同方向和性质的断裂控制.②依据Q-A-P图解确定区内侵入岩主要为辉石闪长岩、石英(二长)闪长岩和花岗闪长岩3类中酸性闪长质岩石,均属亚碱性高钾钙碱性系列.③3类侵入岩具有相似的微量元素、稀土元素和Pb-Sr-Nd-O同位素地球化学特征,反映原始岩浆起源于富集岩石圈地幔,受到壳源物质的混染.④3类侵入岩可能是地壳深部带状岩浆房不同岩浆层中的岩浆与构造运动诱发的深断裂相沟通并随机地上升、脉动式侵位形成的;深部岩浆房中的带状岩浆层可能是由于温度梯度引起扩散对流作用进而发生一定程度的熔离分异作用所致;岩浆演化过程中存在镁铁矿物及磷灰石和锆石等矿物的结晶分异作用.⑤铜陵地区中生代岩浆活动的大地构造背景是大陆板块内部,岩浆作用与晚侏罗纪古太平洋板块的俯冲作用密切相关,但同时受区域前中生代基底构造的制约;侵入岩原始岩浆起源于挤压向拉张转换的动力学背景下的岩石圈地幔加厚之后的减压熔融并底侵下地壳岩石.     

松辽盆地长岭断陷早白垩世火山岩地球化学研究

长岭断陷早白垩世火山岩富硅、富碱,岩石以非碱性系列为主,包括钙碱性和高钾钙碱性系列,碱性系列火山岩为钾玄岩系列。酸性岩与中、基性岩的微量元素特征差别明显,岩石总体微量元素特征与造山带火山岩相似,富集LREE、Rb、K和大离子亲石元素,TiO2含量低,贫Sr。火山岩的形成与造山带岩石圈拆沉作用引起地壳拉张减薄的大地构造背景有关。研究区基性火山岩为地幔岩部分熔融作用的产物,岩浆演化过程中存在单斜辉石和橄榄石等矿物的分离结晶作用,中性岩为原生玄武质岩浆分异演化的产物,营城组酸性火山岩的形成与构造活动存在直接关系,为构造剪切挤压应力致使上地壳重熔的结果。