东天山觉罗塔格构造带雅满苏组火山岩的矿物学研究

东天山觉罗塔格构造带雅满苏组的构造背景一直存有较大争议。斑晶成分和结构的研究可以对岩浆系列、构造背景和岩浆演化的物理化学条件作出制约。本文报道了雅满苏组火山岩中斜长石和辉石斑晶的研究成果。辉石属于普通辉石-顽透辉石系列,部分样品的辉石颗粒与寄主岩达到了岩浆平衡。辉石判别图解表明寄主岩浆属于亚碱性系列,形成于俯冲带环境,与微量元素判别结果相一致。根据辉石-熔体温压计,得到辉石结晶时的温度在1150℃左右,压力相当于5~10 km的地壳深度。雅满苏组火山岩中主体的斜长石属于拉长石,JX-24-1斜长石为中长石,成分和结构特征都表明该颗粒为捕虏晶。辉石和斜长石捕虏晶共同揭示了雅满苏组火山岩在地壳浅部发生了结晶分异和围岩混染的岩浆过程。     

羌塘北缘上新世恒梁湖火山岩内含石榴子石长英质捕虏体岩石学与矿物化学特征

本文以羌塘地体北缘出露面积最大的上新世恒梁湖火山岩为研究对象，对火山岩内含石榴子石长英质捕掳体的岩相学、显微结构及矿物化学综合研究，揭示出此类捕掳体系深部地壳超高温部分熔融残余，其中石榴子石以高Mg#值(41~46)为特征。传统地质压力计估算其发生部分熔融的压力为1. 18~1. 53 GPa，对应深度约39~50 km，火山岩与捕掳体相互作用的温压条件为950~1050 ℃，1. 30~1. 66 GPa，对应深度约43~55 km。火山岩熔体快速上升冷却过程中，熔体沿捕掳体裂隙或边缘与石榴子石发生反应形成斜方辉石和斜长石，而火山岩基质内辉石及长石表现出强烈的成分环带。此研究结果首次揭示了北羌塘北缘中 深地壳岩石部分熔融所产生的熔体及其岩相学和矿物化学特征，亦为此区域地壳深部面波低速异常及强各向异性提供了深部岩石学方面的限定。     

冀北小张家口基性-超基性杂岩的成因:岩石学、地球化学和Nd-Sr同位素证据

冀北小张家口基性-超基性杂岩体主要由辉石岩和次要的纯橄岩组成,并含有方辉橄榄岩透镜状捕掳体.岩石学和元素地球化学数据表明,辉石岩和纯橄岩可能是堆晶成因,而方辉橄榄岩可能是来自地幔源区的地幔岩捕掳体(抽取玄武质熔体之后的难熔残余).辉石岩和纯橄岩都表现出相当富集的Nd-Sr同位素特征,εND (t)=-2～10,ISr=0.7045～0.7081,表明它们的母岩浆来自富集的岩石圈地幔的部分熔融.化学成分和同位素成分一致表明,母岩浆在以橄榄石和辉石为主的分离结晶过程中,遭受下地壳不同程度的混染.辉石岩受显著混染,不能代表岩石圈地幔的同位素成分;而纯橄岩是最初的分离结晶体,仅受轻微下地壳混染,可近似反应岩石圈地幔源区的同位素成分.小张家口岩体的形成可能与古亚洲洋的缝合(240～250Ma)有关.     

宁芜地区中生代富钾和富钠火山岩的源区特征:岩石学和地球化学证据

宁芜中生代火山盆地广泛产出早白垩世中基性火山岩,钾质岩石主要为龙王山组英安岩、粗安岩,钠质火山岩主要为大王山组玄武粗安岩、粗安岩、英安岩以及钠质安山玢岩类。钠质辉石安山玢岩的锆石U-Pb年龄为128.9±1.9Ma,为早白垩世产物。稀土元素球粒陨石标准化配分曲线均表现为一致的平缓右倾型式,Eu负异常不明显,富集大离子亲石元素,亏损高场强元素,具Nb、Ta的负异常。钾质龙王山组火山岩总体Cs、Rb、Ba、Th、U等LILE含量较钠质大王山组火山岩和钠质安山玢岩高,并具有较高的Si、K,较低的Ca、Mg,高Rb/Sr,高Isr(0.70521~0.70857);钠质火山岩具有较低的Si、富Na、高Sr、低I_(sr)(0.70544~0.70768),Mg~#相对较高。钠质辉石闪长玢岩斑晶中有斜长石的矿物结构和成分不平衡现象,锆石Hf同位素特征为ε_(Hf)(t)=-6.2~+0.6,变化较大,指示岩浆混合过程。地幔源区可能是由中元古代俯冲板块释放出流体发生交代作用后形成的富集地幔,钾质火山岩地幔源区交代矿物可能以金云母为主,崆岭群TTG片麻岩为其地壳端元。而钠质火山岩地幔源区交代矿物可能以角闪石和单斜辉石为主,中元古上溪群变质基性岩或新生下地壳基性岩为其地壳端元。     

腾冲活火山的岩浆演化

腾冲火山活动分老期（包括上新世、早更新世和中更新世）和新期（中更新世—全新世,包括马鞍山、黑空山和打鹰山）,代表性火山岩分别是玄武岩、英安质熔结凝灰岩、玄武质粗安岩和粗安岩,均属于高钾钙碱性火山岩。新期马鞍山、黑空山、打鹰山火山活动至少可以追溯到中更新世,岩浆成分从中更新世粗面玄武岩—玄武质粗安岩演化到晚更新世—全新世粗安岩。它们有一共同的岩浆源（或岩浆房）,岩浆形成演化与壳幔作用和岩浆房内的辉石分离结晶作用有关。根据岩浆演化趋势,现在腾冲活火山之下岩浆房中的岩浆将向更富碱和富硅的粗面质或流纹质岩浆演化。     

腾冲马鞍山、打鹰山、黑空山火山岩浆来源与演化

本文对马鞍山、打鹰山、黑空山火山岩主微量和Sr、Nd、Pd同位素地球化学研究认为,腾冲火山岩浆源区具有MORB与富集地幔混合之特征,推测为新特提斯俯冲洋壳重新熔融,导致腾冲地区的高钾钙碱性岩浆的火山活动,解释了腾冲在新生代大陆板内构造环境背景下出现岛弧或活动大陆边缘火山岩地球化学特征的现象。马鞍山、打鹰山和黑空山火山高钾钙碱性岩浆经历了岩浆房阶段辉石、钛铁矿的结晶分离作用和岩浆上升过程中斜长石的结晶分离作用,导致岩浆成分从中基性向中酸性演化,火山岩从玄武质粗安岩→粗安岩→粗面质英安岩演化。     

东昆仑东段香加南山花岗岩基斜长石成分组成与岩浆演化和混合作用

东昆仑东段香加南山花岗岩基岩浆混合作用明显,斜长石作为主要造岩矿物,是研究岩石成因、示踪岩浆演化和岩浆混合过程的有效工具。对香加南山花岗岩基中寄主岩及暗色微粒包体中的斜长石进行岩相学和矿物化学研究。电子探针结果显示:寄主岩中正常环带斜长石(39~48,21~36)、包体中斜长石捕掳晶(41~49,35~36,43~49,31~47,27~38)和寄主岩矿物中包裹斜长石(29~45,14~32)具有演化的An值;部分寄主岩斜长石核部由于受到后期蚀变具有较高的An值(59~72)。包体中基质斜长石大部分具核边结构,核部(52,31)和边部(33~37,25)An值存在间断;少量斜长石核部受到蚀变,An值较低(49),幔部(55~71)An值高于边部(46~49);部分包体中基质斜长石核部呈补丁状,暗色部分An值较高(66),浅色部分An值较低(33~39)。包体中斜长石捕掳晶主要分为干净斜长石捕掳晶和含有矿物的斜长石捕掳晶两大类,干净斜长石环带明显或聚片双晶发育,An值变化范围较小(41~49,35~36);含有暗色矿物的斜长石捕掳晶An值整体也呈震荡变化(43~49,31~47,27~38),但由于受到蚀变,部分测点An值较高(78),少量斜长石具有高An值增生边(73)。以上研究显示,结晶于寄主岩的斜长石正常演化序列反映寄主岩从演化早期到晚期,岩浆逐渐从偏基性向酸性转变;包体基质斜长石为包体进入寄主岩温度、压力和水饱和度降低导致斜长石受到熔蚀后继续结晶结果;包体中斜长石捕掳晶来自寄主岩,由于进入包体后温度和压力产生变化,以及后期生长,导致斜长石的成分和构造有所不同。香加南山花岗岩基及暗色微粒包体中斜长石的复杂环带为幔源镁铁质岩浆注入长英质岩浆混合作用的结果。     

松辽盆地东南隆起区营城组珍珠岩斑晶矿物研究

松辽盆地早白垩世营城组火山岩系含有丰富的珍珠岩,为松辽盆地重要的油气勘探目的层位。在松辽盆地边缘东南隆起九台地区出露有比较新鲜的珍珠岩,内部斑晶保存完好,裂隙发育;斑晶矿物主要有斜长石、黑云母、角闪石,还有镁铁质的单斜辉石和斜方辉石。对含斑晶珍珠岩和剔除斑晶后的珍珠岩玻璃质分别进行地球化学分析,斑晶矿物进行单矿物电子探针成分研究。其结果表明：该珍珠岩属于酸性高钾钙-碱性系列,微量和稀土元素特征显示与上部地壳相似;斑晶矿物单斜辉石为斜紫苏辉石和次透辉石,斜方辉石为紫苏辉石,均显示变质成因,属于捕虏晶;与珍珠岩相邻层位玄武岩的斑晶斜长石为拉长石,单斜辉石为铁次透辉石,属于岩浆成因。这些特征表明,珍珠岩原岩可能来自于上部地壳,其辉石等捕虏晶为岩浆上侵运移过程与围岩发生混染作用的结果。     

东昆仑东段哈拉尕吐花岗岩基岩浆混合作用:来自岩石学和矿物学约束

哈拉尕吐花岗岩基位于东昆仑东段,其中花岗闪长岩岩浆混合作用明显,是研究岩浆混合作用的良好对象.从岩石学、岩相学和矿物化学等方面对哈拉尕吐花岗岩基进行了详细研究.电子探针结果显示:寄主岩斜长石的An值同相对应包体中斜长石捕掳晶近似;包体中基质斜长石大部分具核边结构,核部和边部An值存在间断;部分包体中浅色基质斜长石的An值与具核边结构斜长石的边部近似;辉长闪长岩中斜长石具较高的An值.寄主岩角闪石同相对应包体中角闪石捕掳晶的结晶温度、压力和氧逸度较为接近;包体中基质角闪石的结晶温度和压力低于寄主岩角闪石,氧逸度稍高于寄主岩角闪石;辉长闪长岩角闪石具有最高的结晶温度和压力及最低的氧逸度.哈图沟剖面和德福胜剖面寄主岩中的斜长石和角闪石的成分具有一定差别.岩浆不同期次侵入结晶和岩浆自身演化,使不同地点斜长石和角闪石的成分和物理化学特征具有一定变化.镁铁质岩浆位于地壳深部,氧逸度较低,使结晶的角闪石具有较高的形成压力和较低的氧逸度,斜长石具较高An值;随着镁铁质岩浆注入寄主岩,由于环境突变,使斜长石受到熔蚀;由于岩浆上侵以及两种岩浆物理化学性质差别较大,导致温度、压力和水饱和度降低,氧逸度升高,使包体中残留岩浆快速结晶,形成具核边结构、浅色均一的斜长石,以及结晶程度较差、较高氧逸度的角闪石.      

藏北蚕眉山地区中新世火山岩地球化学特征及成岩过程研究

青藏高原北部蚕眉山地区中新世火山熔岩属于可可西里新生代火山岩带中段的羌巴欠岩省,从早至晚由玄武粗安岩、粗安岩、粗面英安岩等3类岩石组成,全岩K-Ar法年龄为12.81~14.51Ma。玄武粗安岩、粗安岩和粗面英安岩的Si O2含量分别为53.85%~56.02%、59.22%~61.84%、64.81%~67.70%。火山岩K2O+Na2O含量为6.21%~8.20%,K2O含量为3.17%~4.94%,K2O/Na2O=1.01~1.52,Ti O2含量为0.77%~1.88%,属钾玄岩系列,ACNK=0.54~0.90,KNA=0.57~0.72,属偏铝质岩石。LREE强烈富集,ΣREE=297×10-6~939×10-6,(La/Yb)N=45.1~127.4,δEu=0.73~0.95,高度富集LILE(K、Rb、Cs、Sr、Ba、U、Th),相对贫HFSE(Nb、Ta、Zr、Hf)。根据地球化学特征并结合区域对比,认为岩浆应来源于EMⅡ型地幔的部分熔融。氧化物Harker图解、Mg#值对微量元素协变图解、La/Sm La图解以及Mg#值和稀土元素含量变化特征等表明玄武粗安岩和粗安岩属同源岩浆演化产物,并经历了较高程度的结晶分异演化;而粗面英安岩则属于另一岩浆系列,由先期经一定程度演化的岩浆在地壳深部冷却固结的岩石后期经再次部分熔融所形成。据此认为,青藏北部新生代深部地幔熔融等岩浆作用过程应有比地表火山岩更宽的时、空尺度,区域挤压构造体制使部分幔源岩浆被封闭在深部而冷却成岩,因此,新生代火山岩的时空分布规律,一定程度上与区域构造体制的发展和迁移有关。     

云南腾冲黑空山、马鞍山和打莺山火山粗安岩显微结构特征及其火山学意义

火山喷发物记录了岩浆的整个活动历史,对火山喷发物的研究可以了解大量的岩浆活动特征信息。本文对腾冲火山区的三座全新世火山——黑空山、马鞍山和打莺山火山熔岩进行了详细的研究,包括熔岩和斑晶的成分、显微结构特征和斑晶的晶体大小分布(CSD)分析。研究发现,黑空山、马鞍山和打莺山火山熔岩以粗安岩为主,三座火山粗安岩中的斑晶成分范围接近,但它们的显微结构特征具有一定的差异,反映了不同的岩浆环境,推测来自不同的岩浆囊。黑空山粗安岩中斜长石斑晶的CSD曲线呈微上凹形,反映了小规模的岩浆混合作用。马鞍山和打莺山粗安岩的微斑晶CSD曲线呈很好的线性关系,说明微斑晶形成时的环境相对稳定,推测这些微斑晶是在岩浆上升过程中,停留在地壳的某处并形成一个小型的岩浆囊后受围岩的冷却作用形成。根据以上的分析,认为腾冲火山区下在横向和纵向上均至少存在两个岩浆囊。     

Magmatic Processes of Ashi Volcano,Western Kunlun Mountains,China

The Ashikule volcanic cluster(AVC) in western Kunlun Mountains is located in a graben region at the convergence of the Altun and Kangxiwa fault zones, and consists of more than 10 main volcanoes and dozens of volcanelloes. The Ashi volcano lies in the central part of the volcanic cluster. The lithology, chemical composition and texture of Ashi volcanic rocks were studied in detail, and their implication in magmatic processes was discussed. The phenocrysts in Ashi volcanic rocks consist mainly of plagioclase and pyroxene, and the statistical results of phenocryst contents show that the rocks can be subdivided into two groups. In group A, the content of pyroxene phenocrysts is generally higher than that of plagioclase phenocrysts, but an inverse relation occurs in group B. In TAS diagram, the compositions of both groups fall into the trachyandensite field, but they are obviously concentrated into two clusters. The two clusters exist also in the oxide diagrams. The pyroxene phenocrysts comprise augite, bronzite and hypersthene, and their Mg# histogram shows two peaks. Plagioclase phenocrysts with reaction rim are observed in rocks of both groups. The An values of the core are generally 30–40, and those of the rim are 44–48, which are closer to those of euhedral plagioclases. The bronzites are in equilibrium with the melt, and two sets of magma depths, i.e., 18–25 km and 13–18 km, can be estimated by using thermobarometer proposed by Putirka. The hypersthenes are not in equilibrium with the melt, and can be assigned to xenocrysts. The crystal size distribution(CSD) curves of plagioclase appear as kinked lines indicative of magma mixing. The above analyses show that two magma pockets might exist beneath the Ashi volcano. It is likely that they are connected with each other. The one has more evolved and contains more acidic magma, and the other is a trachyandensite magma pocket characterized by layering. The magma from the upper part of the trachyandensite magma pocket might mix with more acidic magma, resulting in a magma that is more acidic than the magma from the lower part.     

Temperature and Hf-O isotope correlations of young erupted zircons from Tengchong (SE Tibet): Assimilation fractional crystallization during monotonic cooling

Young zircons from crystal-poor volcanic rocks provide the best samples for the investigations of pre-eruption magmatic processes and for testing a possible relationship between zircon Eu anomalies and crustal thickness. We report trace element chemistry and Hf-O isotope compositions of young zircons from 3 Holocene volcanoes in the Tengchong volcanic field, SE Tibet, in order to provide insights into magma evolution processes and conditions for high-K calc-alkaline volcanic rocks in a post-collisional setting. As decreasing zircon Ti content and falling temperature, zircon Hf content and Yb/Sm increase whereas zircon Eu anomaly and Th/U decrease, indicating fractional crystallization of plagioclase and zircon during magma cooling. More importantly, zircon Hf isotope ratio (ε_Hf values) increases with decreasing zircon Ti content and falling temperature (T), suggesting gradually increasing incorporation of relatively high ε_Hf juvenile materials in the crystallizing zircons during magma evolution. Negative correlations between zircon ε_Hf and zircon δ¹⁸O also support open-system magma evolution. Our data suggest fractional crystallization of a magma with simultaneous contamination by high ε_Hf and low δ ¹⁸O juvenile (immature) crustal materials during monotonic cooling after zircon saturation. The low-T, high-ε_Hf and low- δ ¹⁸O zircons may indicate the involvement of the early Cretaceous juvenile granitic country rocks during shallow magma evolution. Average Eu anomalies in zircons from young Tengchong lavas yield crustal thickness of 40.7 ± 6.8 km, consistent with present crustal thickness (42.5 km) determined by geophysical methods.     

Cellular plagioclase intergrowths as a result of crystal-magma mixing in the Proterozoic Åland rapakivi batholith,SW Finland

Finely cellular plagioclase intergrowths have been studied in xenocrystic andesine (An₃₂) and andesine mantled K-feldspars within mafic magmatic enclaves in a quartz-feldspar porphyry from the Proterozoic subvolcanic Hammarudda complex, Åland rapakivi batholith, SW Finland. The cellular intergrowths usually occur as 0.2–2.0 mm mantles around xenocrysts but also as entirely cellular grains, and are built up of a network of two distinct phases: one relatively Na-rich (An₃₁) and one relatively Ca-rich (An₅₀). The grains are also covered by a thin (0.08–0.12 mm), continuous, normally zoned rim outside the cellular mantle. Small inclusions (0.01–0.05 mm) of Fe–Mg minerals are concentrated in the Ca-rich part of the network. Compositionally, the Na-rich phase of the network is close to the inner non-cellular andesine of the xenocrysts. However, it has a lower Or- and a slightly lower An-content. The Ca-rich phase has the same composition as the inner part of the normally zoned rim, which outwards grades into lower An-contents that overlap the An-content of the matrix plagioclases. The cellular network was developed after the andesine xenocrysts (or andesine mantled K-feldspars) were engulfed in mafic magmatic enclaves during a mixing event. The xenocrysts became heated to a temperature just below the liquidus of the mafic magma. Dissolution of the xenocrysts developed a spongy cellular texture which was penetrated by enclave magma. Ca-rich plagioclase crystallized in the cells in equilibrium with the enclave magma, trapping Fe–Mg-rich melt. As the enclaves cooled the outermost thin rim and matrix plagioclases crystallized from the mafic melt. These processes operated in fairly large enclaves, as the one studied here, which has a diameter of 70cm. Smaller enclaves, on the other hand, were cooled more rapidly to temperatures close to the solidus of the enclave magma, and consequently had no time to dissolve the xenoxrysts.     

Chalcophile element constraints on magma differentiation of Quaternary volcanoes in Tengchong,SW China

The Tengchong volcanic field comprises numerous Quaternary volcanoes in SW China. The volcanic rocks are grouped into Units 1–4 from the oldest to youngest. Units 1, 3 and 4 are composed of trachybasalt, basaltic trachyandesite and trachyandesite, respectively, and Unit 2 consists of hornblende-bearing dacite. This rock assemblage resembles those of arc volcanic sequences related to oceanic slab subduction. Rocks of Units 1 and 3 contain olivine phenocrysts with Fo contents ranging from 65 to 85 mole%, indicating early fractionation of olivine and chromite prior to the eruption of magma. All the rocks from Units 1, 3 and 4 have very low PGE concentrations, with <0.05 ppb Ru and Rh, <0.2 ppb Pt and Pd, and Ir that is commonly close to, or slightly higher than detection limits (0.001 ppb). The small variations of Pt/Pd ratios (0.4–2.2) are explained by fractionation of silicate and oxide minerals. The 5-fold variations in Cu/Pd ratios (200,000–1,000,000) for the lavas at Tengchong, which do not vary systematically with fractionation, likely reflect retention of variable amounts of residual sulfide in the mantle source. In addition, all the rocks from Units 1, 3 and 4 have primitive mantle-normalized chalcophile element patterns depleted in PGE relative to Cu. Together with very low Cu/Zr ratios (0.06–0.24), these rocks are considered to have undergone variable degrees of sulfide-saturated differentiation in shallow crustal staging magma chambers. Large amounts of olivine and chromite crystallization probably triggered sulfide saturation of magma at depth for Units 1 and 3, whereas crustal contamination was responsible for sulfide saturation during ascent of magma for Unit 4.     

江西相山潜火山岩中淬冷包体的发现及其成因机制探讨

在江西相山大型塌陷式火山盆地北部的潜火山岩岩墙中，笔者发现了闪长质的岩石包体，这种包体具典型的反向脉及淬冷边，且淬冷边内含有大量针状磷灰石。在包体内部或包体与寄主岩的边界均见有钾长石及斜长石捕虏晶，这种捕虏晶是包体岩浆从寄主岩岩浆中捕获的，常被熔蚀成筛状或浑圆状。包体与寄主岩（次斑状花岗闪长岩）的稀土元素曲线和不相容元素蛛网图的形态非常相似。因此，相山潜火山岩岩墙中的闪长质岩石包体是不同成分、不同温度的岩浆经对流及不均一岩浆混合作用而形成，在成因类型上属淬冷包体。     

腾冲新生代火山区温泉CO2气体排放通量研究

近期研究表明,不仅火山喷发期会向当时的大气圈输送大量的温室气体,火山间歇期同样会释放大量的温室气体。在火山活动间歇期,火山区主要以喷气孔、温(热)泉以及土壤微渗漏等形式向大气圈释放温室气体。腾冲是我国重要的新生代火山区,同时也是重要的水热活动区,那里出露大量的温泉,然而目前未见腾冲火山区温泉气体排放通量的研究报道。本文利用数字皂膜通量仪测量了腾冲新生代火山区温泉中CO₂的排放通量。研究结果表明,腾冲新生代火山区温泉向当今大气圈输送的CO₂通量达3.58×10³ t·a^-1,相当于意大利锡耶纳Bassoleto地热区温泉中CO₂的排放规模。腾冲火山区温泉的CO₂释放通量主要受深部岩浆囊、断裂分布、地下水循环、围岩成分等多方面因素的影响。本文根据温泉中CO₂的排放特征,将腾冲温泉分为南北两区,南区温泉CO₂通量远高于北区的温泉,热海地热区的通量为腾冲CO₂通量的最大值。在北温泉区,CO₂通量主要受控于断裂的分布;而在南温泉区,除受到断裂控制外,热海地热区底部的岩浆囊及其与围岩的相互作用成为CO₂气体的重要物质来源,同时高温的岩浆囊为温泉及CO₂的形成提供了重要热源。     

Mineral chemistry,crystallization conditions and magma mixing‐mingling at Orduzu volcano (Malatya), Eastern Anatolia,Turkey

The Middle Miocene Orduzu volcanic suite, which is a part of the widespread Neogene Yamadağ volcanism of Eastern Anatolia, consists of a rhyolitic lava flow, rhyolitic dykes, a trachyandesitic lava flow and basaltic trachyandesitic dykes. Existence of mafic enclaves and globules in some of the volcanic rocks, and microtextures in phenocrysts indicate that magma mingling and mixing between andesitic and basaltic melts played an important role in the evolution of the volcanic suite. Major and trace element characteristics of the volcanic rocks are similar to those formed in convergent margin settings. In particular, incompatible trace element patterns exhibit large depletions in high field strength elements (Nb and Ta) and strong enrichments in both large ion lithofile elements (Ba, Th and U) and light rare earth elements, indicating a strong subduction signature in the source of the volcanic rocks. Furthermore, petrochemical data obtained suggest that parental magmas of rhyolite lava and dykes, and trachyandesite lava and basaltic trachyandesite dykes were derived from subduction‐related enriched lithospheric mantle and metasomatized mantle (± asthenosphere), respectively. A detailed mineralogical study of the volcanic suite shows that plagioclase is the principal phenocryst phase in all of the rock units from the Orduzu volcano. The plagioclase phenocrysts are accompanied by quartz in the rhyolitic lava flows and by two pyroxenes in the trachyandesitic lava flows and basaltic trachyandesitic dykes. Oxide phases in all rocks are magnetite and ilmenite. Calculated crystallization temperatures range from 650°C to 800°C for plagioclase, 745°C–1054°C for biotite, 888°C–915°C for pyroxene and 736°C–841°C for magnetite–ilmenite pairs. Calculated crystallization pressures of pyroxenes vary between 1.24–5.81 kb, and oxygen fugacity range from −14.47 to −12.39. The estimates of magmatic intensive parameters indicate that the initial magma forming the Orduzu volcanic unit began to crystallize in a high‐level magma chamber and then was stored in a shallow reservoir where it underwent intermediate‐mafic mixing. The rhyolitic lava flow and dykes evolved in relatively shallower crustal magma chambers. Copyright © 2007 John Wiley & Sons, Ltd.     

Petrological Implication of the Albite Rims in the Felsic Gneisses of the Fuping Complex

The albite rim is present in most felsic gneisses of the Fuping Complex. The presence of the rim indicates the coexistence of plagioclase and K-feldspar in the rock. The rim is formed immediately after the myrmekite, and both textures were derived from the alteration of K-feldspar. The difference is that that there is no quartz present in the rim, and the rim is nearly albite and the anorthite content of the rim plagioclase is substantially lower than that of the myrmekite plagioclase. Formed at 400–500°C the albite rim was derived from the K-feldspar composition adjustment in the late or post-magmatism stage. As the temperature decreased, the equilibrium between K-feldspar and plagioclase could be maintained, and reactions between the minerals occurred. The leucocratic veins in the complex show distinguished magma or migmatitic characteristics. The rim might form in the late magma or deuteric stage. The formation of the rim implies obvious granitic magma- or melt-injection activity. Typical metamorphic rocks cannot produce the rims. Anatexis after medium–high grade metamorphism might be subordinate. If present, the anatexis is water-present, but the rim texture cannot be taken as the symbol of anatexis.