冀东太古宙高级变质区深部构造相韧性变形条带的成因及演化

冀东太古宙片麻岩中的条带状构造极其发育,经研究认为它们是深部构造相韧性变形带的主要结构构造特征。按成因类型将其划分为变余沉积条带、变质分异条带、复合条带和构造置换条带等。并研究了不同成因条带的组成特征、形成演化及识别标志。这一研究对认识下部地壳构造特征具有重要意义。     

天堂山花岗质岩石带状构造的成因与演化

天堂山地区花岗质岩石中条带状构造异常发育,据成因可分为分异条带状构造和构造置换－－复合条带状构造两种类型。它们的形成与岩石变形变质作用有密切关系,形成和演化过程可分为３个阶段：递进变形变质阶段;重熔活化阶段;构造置换改造阶段。分异条带状构造是岩石在递进变形变质作用过程中具不同熔点的矿物发生分离和分异形成的。     

构造片麻岩含义及其成因机制

构造片麻岩是地壳深部构造层次上韧性变形带主要的构造岩类型之一,其内保留了大量岩石流变特征的重要信息,在前寒武纪高级变质岩区广泛发育。构造片麻岩是由强烈塑性变形作用、变质作用和部分熔融作用共同作用形成的动力变质构造岩,是一种宏观上具有明显的强塑性流变特征而没有明显粒径减小的构造岩;在露头和手标本上以密集条带状构造和片麻状构造为特征,在微观上为典型三边平衡结构和复晶石英条带构造。熔体存在是控制影响构造片麻岩形成的主要因素之一,主要变形机制为扩散蠕变和颗粒流动,使岩石整体产生巨大应变,而单个矿物晶体不产生变形。构造片麻岩带可以分为3种不同类型：同变质期的层状构造片麻岩带、退变质期的线性构造片麻岩带和网状构造片麻岩带。     

江西大背坞地区韧性剪切带中岩石变形与矿物变化的关系

浅变质碎屑岩中韧性剪切变形往往引起进变质作用,并导致矿物变化,其主要表同为同构造变斑晶,绢云母重结晶和形成动力分异条带,从剪切带外侧到剪切带中心,同构造变斑晶由小变大,重结晶须云母含量逐渐增高,动力分异条带仅发育于剪切带中心强变形区,在一定变形范围内,重结晶绢云母含量与应变强度呈线性正相关。     

吉林太古宙花岗岩类构造─岩浆演化

本文较为详细地研究了吉林太古宙花岗质岩石的地质,地球化学及构造特征,将花岗质岩石划分为三个岩浆演化系列,它们分别与不同的构造变形阶段相对应,即变形前-同变形壳源岩浆分异系列、晚变形深熔岩浆分凝系列和变形后壳源岩浆分异系列。通过上壳岩、花岗岩的变质作用、变形作用、岩浆活动的综合研究,讨论了麻粒岩变质作用与TTG岩浆形成于岛孤或活动大陆边缘的大地构造环境,剪切变形对深熔作用的影响,提出辉石花岗岩类的形成与造山带的伸展拆离作用有关。     

构造地球化学的回顾与展望

较早的构造地球化学研究思想是“经受着变形的岩石可以发生化学变化”( Sorby,1863).经过长期、广泛和深入研究,相继提出了应力矿物、构造变质、构造动力成岩成矿、改造成矿、构造相和构造地球化学等概念和认识,揭示了构造作用在控制岩石形成和变形过程中还影响其中地球化学元素的分布、分异和成矿等,推动了大地构造、区域地质、...     

新疆那拉提构造带基底变形特征及构造意义

塔里木-伊犁微板块间的南天山洋最终消亡缝合线——那拉提构造带,基底由下元古界那拉提岩群的片麻岩、变质表壳岩及早元古代片麻状花岗岩组成．经研究分析,上述岩石遭受了4期变质变形．本文从不同构造层次和深度残留下的变质变形构造研究入手,初步探讨了不同构造演化阶段那拉提构造基底的变质变形特征．     

高州市马贵镇片麻状花岗岩显微结构构造特征及意义

通过对高州马贵镇元古代片麻状花岗岩变形变质显微结构构造特征的研究，揭示出该区片麻状花岗岩是中深层次流变剪切过程中部分熔融的产物，片麻状、条纹状、眼球状构造是应力变形变质分异的结果。同时指出，岩石存在不同期次的构造叠加，部分片麻状花岗岩经多次构造叠加和热液参与再造为构造片岩。     

松潘—甘孜褶皱带较场弧形构造特征及其大地构造意义

根据详细野外露头特征及显微构造特征将较场弧形带由南向北分为三个变形带:弧顶部、弧核部和弧翼部,不同分带具有明显不同的变形特征。由南向北变形特征由以塑性变形为主过渡为脆性变形为主,变质流体活动喜马拉雅构造期活动强烈,且向北逐渐增强;弧核部以叠瓦状逆冲构造特征分隔弧顶和弧翼部;弧翼部东西两翼变形及变质流体活动特征具有一定差异性。较场弧形带总体体现出多期次南北向挤压—张性应力变形构造特征,叠加北西—北北西向同构造期挤压变质运动,其宏观和微观变形特征与典型"走滑成因"模式弧形构造特征相异,为其大地构造成因机制的解释提出了新的限制条件。     

煤岩构造变形与动力变质作用

煤岩是一种对温度、压力等地质环境因素十分敏感的有机岩,地质演化过程中的各种构造-热事件必然导致煤岩发生一系列物理与化学结构的变化,并形成不同类型的构造煤。在构造应力作用下,煤岩不仅发生脆性和韧性变形,而且还产生不同程度的动力变质作用。因而,关于煤岩构造变形与动力变质作用的研究不仅具有重要的科学意义,而且在煤层气资源评价以及煤与瓦斯突出危险性预测方面也具有重要的实际意义。文中在已有研究成果基础上,通过对构造煤系列Ro,max、XRD和NMR(CP/MAS+TOSS)等测试和实验方法的对比研究,深入分析了煤岩不同构造变形和动力变质特征,进一步探讨了构造应力下煤岩动力变质作用的机理。研究成果表明,在构造应力作用下,煤岩脆性变形主要是通过破裂面上快速机械摩擦转化为热能而引起煤岩化学结构与其成分的改变;而韧性变形煤主要是通过局部区域应变能的积累而引起煤岩化学结构的破坏,从而发生不同机制的动力变质作用。     

青藏高原拉萨地体北部的前寒武纪变质作用及构造意义

青藏高原南部拉萨地体中分布的角闪岩相至麻粒岩相变质岩一直被认为是前寒武纪变质基底,但并没有获得可靠的年代学证据。本文运用原位锆石U-Pb定年方法,在拉萨地体北部那果地区的变质岩中获得了约720Ma的变质年龄,从而证明拉萨地体北部在新古元代经历了角闪岩相变质作用和近同期的岩浆作用。基于这一成果和在拉萨地体中、南部高级变质岩中陆续获得的中、新生代变质年龄,对拉萨地体变质作用的时、空变化及其成因进行了初步探讨。     

The Higo metamorphic complex in Kyushu, Japan as the fragment of Permo–Triassic metamorphic complexes in East Asia

The Higo terrane in west-central Kyushu Island, southwest Japan consists from north to south of the Manotani, Higo and Ryuhozan metamorphic complexes, which are intruded by the Higo plutonic complex (Miyanohara tonalite and Shiraishino granodiorite).The Higo and Manotani metamorphic complexes indicate an imbricate crustal section in which a sequence of metamorphic rocks with increasing metamorphic grade from high (northern part) to low (southern part) structural levels is exposed. The metamorphic rocks in these complexes can be divided into five metamorphic zones (zone A to zone E) from top to base (i.e., from north to south) on the basis of mineral parageneses of pelitic rocks. Greenschist-facies mineral assemblages in zone A (the Manotani metamorphic complex) give way to amphibolite-facies assemblages in zones B, C and D, which in turn are replaced by granulite-facies assemblages in zone E of the Higo metamorphic complex. The highest-grade part of the complex (zone E) indicates peak P–T conditions of ca. 720 MPa and ca. 870 °C. In addition highly aluminous Spr-bearing granulites and related high-temperature metamorphic rocks occur as blocks in peridotite intrusions and show UHT-metamorphic conditions of ca. 900 MPa and ca. 950 °C. The prograde and retrograde P–T evolution paths of the Higo and Manotani metamorphic complexes are estimated using reaction textures, mineral inclusion analyses and mineral chemistries, especially in zones A and D, which show a clockwise P–T path from Lws-including Pmp–Act field to Act–Chl–Epi field in zone A and St–Ky field to And field through Sil field in zone D.The Higo metamorphic complex has been traditionally considered to be the western-end of the Ryoke metamorphic belt in the Japanese Islands or part of the Kurosegawa–Paleo Ryoke terrane in south-west Japan. However, recent detailed studies including Permo–Triassic age (ca. 250 Ma) determinations from this complex indicate a close relationship with the high-grade metamorphic terranes in eastern-most Asia (e.g., north Dabie terrane) with similar metamorphic and igneous characteristics, protolith assembly, and metamorphic and igneous ages. The north Dabie high-grade terrane as a collisional metamorphic zone between the North China and the South China cratons could be extended to the N-NE along the transcurrent fault (Tan-Lu Fault) as the Sulu belt in Shandong Peninsula and the Imjingang belt in Korean Peninsula. The Higo and Manotani metamorphic complexes as well as the Hida–Oki terrane in Japan would also have belonged to this type of collisional terrane and then experienced a top-to-the-south displacement with forming a regional nappe structure before the intrusion of younger Shiraishino granodiorite (ca. 120 Ma).     

Limited basement involvement in Caledonian deformation, Hinnøy, Nnorth Norway, and tectonic implications

Structural and petrographic relationships on east Hinnøy, north Norway, indicate that the Caledonian nappes which are exposed directly to the east were emplaced over an older Precambrian crystalline terrane (Lofoten terrane) while at amphibolite facies metamorphic conditions. Caledonian structural and metamorphic effects disappear structurally downward away from the basal thrust of the nappe stack. The limited involvement of the basement in Caledonian deformation is explained by the limited availability of water which was introduced from external sources. The external water source is hypothetically the autochthonous and allochthonous cover, and the Precambrian Austerfjord Group metasedimentary rocks within the basement, which underwent prograde metamorphic dehydration during Caledonian orogenesis. The mechanisms by which addition of water concentrated strain in the basement probably include reaction-induced ductility-and hydrolytic weakening of the constituent silicate minerals. There are two main tectonic implications: (1) in collisional metamorphic belts, the lithosphere of the underthrusted plate may remain rigid below 15–25 km depth; and (2) the common phenomenon of detachment of crystalline thrust sheets at mid-crustal levels may be controlled in some cases by the limited access of water to pre-existing crystalline rocks, rather than by thermal structure.     

High-grade metamorphism and hydrous melting of metapelites in the Pinos terrane (W Cuba): Evidence for crustal thickening and extension in the northern Caribbean collisional belt

The Pinos terrane (Isle of Pines, W Cuba) is a coherent metamorphic complex that probably represents a portion of the continental margin of the Yucatan Block during the Mesozoic. Within the framework of other metamorphic terranes in the Greater Antilles, the Pinos terrane is characterized by the occurrence of high‐grade kyanite‐, sillimanite‐ and andalusite‐bearing metapelites and migmatites. Assessment and modelling of phase relations in these high grade rocks indicate that they reached a peak temperature of c. 750 °C at 11–12 kbar, and then underwent strong decompression to c. 3 kbar at c. 600 °C. Decompression was contemporaneous with the main synmetamorphic deformation in the area (D2), and was accompanied by segregation of trondhjemitic partial melts formed by wet melting of metapelites. Metamorphism terminated in the Uppermost Cretaceous (68 ± 2 Ma; ⁴⁰Ar/³⁹Ar dates on biotite and muscovite). The P–T–t‐deformation relations of the high‐grade rocks suggest that crustal thickening (during collision of this portion of the Yucatan margin with the Great Volcanic Arc of the Caribbean?) was followed by decompression interpreted to reflect exhumation by extension, possibly related to the initial development of the Yucatan Basin in the uppermost Cretaceous.     

冀东马兰峪背斜南翼与西部倾伏端盖层变形特征及其构造意义

燕山中部冀东遵化、迁西、青龙一带以太古宇深变质结晶岩系为核部的东西向构造形迹长期以来被认为是一个复式背斜构造,近年来又有学者提出它是一个中生代变质核杂岩。这2种不同认识涉及到华北克拉通北部中生代区域大地构造演化和稳定克拉通内部大型基底结晶岩系的剥露机制问题。对马兰峪背斜南翼和西部倾伏端盖层岩系开展的详细构造研究表明,变形总体表现为连续的褶皱变形及伴生的逆冲构造;构造样式表现为基底卷入式的厚皮构造与盖层内部软弱岩系控制的薄皮构造共存的特征;变形机制表现为顺层挤压导致的纵弯弯曲和相关的断裂构造;近南北向的缩短率介于16%～27%之间。盖层岩系中未发现变质核杂岩构造模型所预期的系列高角度正断层。基底与盖层不整合面接触带尽管在后期构造变形过程中曾经发生过局部的差异性滑动,但并不是造成大规模构造剥蚀和地壳柱切失的剥离断层。因此,冀东马兰峪背斜不是中生代的变质核杂岩,而是水平挤压背景下基底结晶岩系与盖层共同卷入纵弯褶皱变形的厚皮式褶皱构造。     

Oxide and sulphide isograds along a Late Archean, deep-crustal profile in Tamil Nadu, south India

Oxide–sulphide–Fe–Mg–silicate and titanite–ilmenite textures as well as their mineral compositions have been studied in felsic and intermediate orthogneisses across an amphibolite (north) to granulite facies (south) traverse of lower Archean crust, Tamil Nadu, south India. Titanite is limited to the amphibolite facies terrane where it rims ilmenite or occurs as independent grains. Pyrite is widespread throughout the traverse increasing in abundance with increasing metamorphic grade. Pyrrhotite is confined to the high‐grade granulites. Ilmenite is widespread throughout the traverse increasing in abundance with increasing metamorphic grade and occurring primarily as hemo‐ilmenite in the high‐grade granulite facies rocks. Magnetite is widespread throughout the traverse and is commonly associated with ilmenite. It decreases in abundance with increasing metamorphic grade. In the granulite facies zone, reaction rims of magnetite + quartz occur along Fe–Mg silicate grain boundaries. Magnetite also commonly rims or is associated with pyrite. Both types of reaction rims represent an oxidation effect resulting from the partial subsolidus reduction of the hematite component in ilmenite to magnetite. This is confirmed by the presence of composite three oxide grains consisting of hematite, magnetite and ilmenite. Magnetite and magnetite–pyrite micro‐veins along silicate grain boundaries formed over a wide range of post‐peak metamorphic temperatures and pressures ranging from high‐grade SO₂ to low‐grade H₂S‐dominated conditions. Oxygen fugacities estimated from the orthopyroxene–magnetite–quartz, orthopyroxene–hematite–quartz, and magnetite–hematite buffers average 2.5 log units above QFM. It is proposed that the trends in mineral assemblages, textures and composition are the result of an external, infiltrating concentrated brine containing an oxidizing component such as CaSO₄ during high‐grade metamorphism later acted upon by prograde and retrograde mineral reactions that do not involve an externally derived fluid phase.     

柞水岩群及其地质构造特征

在秦岭柞水地区1：5万区调填图中，从商丹构造侧前人划分泥盆系刘岭群桐峪寺组中新解体出一套由黑云母斜长变粒岩、斜长角闪岩及少量大理岩等组成的中深变质岩系。通过岩石学及原岩建造的研究，采用构造－岩层－事件方法的综合分析与对比，新建立了构造岩层（石）地层单位，称为柞水岩群，依据Sm-Nd年龄（平均值）2283Ma，将其时代暂定为中元古代，这一新成果对研究中央山系秦岭造山带华北地块与杨子地块商丹拼接地带地质体组成及地质构造特征均具有重要的意义。     

U–Pb zircon study of tectonically bounded blocks of 2940–2840 Ma crust with different metamorphic histories,Paamiut region,South-West Greenland: implications for the tectonic assembly of the North Atlantic craton

New fieldwork, map interpretation, petrography and single zircon U–Pb geochronology has allowed the identification of different crustal blocks in the Paamiut region, in the southern portion of the West Greenland Archaean Craton. Changes of metamorphic grade from only amphibolite facies to granulite facies (some subsequently retrogressed) corresponds with zones of Archaean high strain ductile deformation ± mylonites. U–Pb zircon dates are presented for the TTG (tonalite, trondhjemite, granodiorite) protoliths from each block in the Paamiut region, and the southern portion of the previously identified Tasiusarsuaq terrane lying to the north. The southern part of the Tasiusarsuaq terrane contains 2880–2860 Ma TTG rocks and underwent amphibolite facies metamorphism. Structurally underneath the Tasiusarsuaq terrane to the south is the Sioraq block containing 2870–2830 Ma TTG rocks partly retrogressed from granulite facies. Structurally underneath and to the south is the Paamiut block, dominated by 2850–2770 Ma granodioritic rocks that have only undergone amphibolite facies metamorphism. Also structurally overlying the Paamiut block, but cropping out separately from the Sioraq block, is the Neria block. This appears to be dominated by 2940–2920 Ma gneisses that have been totally retrogressed from granulite facies and strongly deformed. In the southernmost part of the region the Neria block overlies the greenschist to lowermost amphibolite facies Sermiligaarsuk block that contains the ⩾2945 Ma Tartoq Group. Rocks from all the blocks record ancient loss of Pb from zircons and some new zircon growth at 2820 Ma, interpreted to indicate a high grade metamorphic event at that time, including granulite facies metamorphism in the Sioraq and Neria blocks. The blocks of different metamorphic grade are interpreted to have moved to their current positions after the 2820 Ma metamorphism, explaining the change in metamorphic history across some mylonites and ductile shear zones which deform and retrogress granulite facies textures. The juxtaposed blocks and their contacts were subsequently folded under amphibolite facies conditions. The contacts are cut by undeformed Palaeoproterozoic dolerite dykes which post-date amphibolite facies metamorphism. These results, together with previously published data from the Godthåbsfjord region (north of Paamiut) shows that the North Atlantic Craton in West Greenland from Ivittuut in the south to Maniitsoq in the north (∼550 km) consists of a mosaic of ductile fault-bounded packages that attained their present relative positions in the late Archaean.     

Peak metamorphic temperatures from cation diffusion zoning in garnet

A model that relates the characteristic diffusion length and average cooling rate to peak temperature was developed for chemical diffusion in spherical geometries on the basis of geospeedometry principles and diffusion theory. The model is quantitatively evaluated for cation diffusion profiles in garnet. Important model parameters were calibrated empirically using diffusion zoning of Ca in garnet from the Pikwitonei Granulite Domain, a terrane for which the thermal history has been well characterized. The results are used: (i) to empirically test diffusion parameters for Mg and Fe(II) and (ii) to develop a tool that uses the diffusion zoning of these cations in garnet to constrain peak temperature conditions for garnet‐bearing rocks. The thermometric approach was externally tested by applying it to garnet crystals from various metamorphic terranes worldwide and comparing the results to published peak temperature estimates. The results overlap within uncertainties in all cases, but result that are based on Fe(II) and Mg chemical‐diffusion profiles are up to three times more precise than those acquired by conventional methods. The remarkable consistency of the results implies that the model is robust and provides a reliable means of estimating peak temperatures for different types of high‐grade metamorphic rock. The tool could be of particular advantage in rocks where critical assemblages for conventional thermometry do not occur or have been replaced during retrogression.     

The metamorphic aureole of the Nisa-Alburquerque batholith (SW Iberia): implications for deep structure and emplacement mode

The Nisa-Alburquerque granitic batholith (southern Variscan Belt, Iberian Peninsula) has been studied by petrological, structural and geophysical approaches, obtaining contrasting models for its deep structure and emplacement sequence. In order to test these models and gain knowledge on the thermal increase induced by the intrusion, we have studied its contact aureole, which was developed in similar country rock lithologies (mica schists alternating with metasandstones and feldespatic schists) all along the northern external contact of the batholith. Our results indicate no change in metamorphic grade and some variations in aureole width, which narrows toward the western sectors of the batholith. Cordierite is the only contact metamorphic mineral developed together with a high temperature biotite probably related to the granite thermal input. By considering these new data, together with zircon saturation temperatures within the granite and previous petrological and geophysical studies, we propose a model in which the feeder zones of the granitic magmas were an eastern main one and a western secondary one. We have also made comparisons of the metamorphic grade in the country rocks and the xenoliths within the granite. Most of the xenoliths have the same metamorphic facies as the country rocks (Crd-zone), though some of them contain slightly different assemblages (And + Crd), which could be explained in different ways: (1) differences in the primary schist compositions, (2) increased time-span of xenoliths in contact with the melt and (3) xenolith incorporation at slightly higher depths during final granite ascent.