青海省花岗岩类岩石谱系单位的划分方案

依据遇源岩浆演化理论和花岗岩类岩石等级体制的划分,将青海省侵入岩划分为１３个构造岩石区,划分了１０８个超单位、１１７个（命名）单元（含７个独立单元）、２５５个岩性单元及数十个类型的年代加岩性侵入体。全省侵入岩成因初步分为幔源型、壳幔混合型、壳源深部型、壳源浅部型和浅壳源型;其分别形成于裂谷,深部裂冲、板块俯冲、板内挤压、板块碰撞及造山期后抬升环境。     

东天山中酸性侵入岩浆作用及其地球动力学意义

东天山地区华里西中一晚期中酸性侵入岩浆活动强烈，加里东期、华里西早期及印支期花岗岩类分布零星，初步可分为南、北两个岛弧花岗岩带。除哈尔里克有少量碱性花岗岩外，花岗岩类均属钙碱性岩石系列。从早期到晚期，中性性侵入岩浆作用经历了板块碰撞前、火山弧、碰撞同期、板内伸展、陆内叠覆造山和非造山6个演化阶段，岩石成因类型可分为M、CM、C、A4种类型。南、北岛弧的碰撞与缝合从北东向南西呈现出递进演化的特点。土屋－赤湖、石英滩、维权、白山等铜、钼、金矿床与华里西中期岛弧环境产出的过铝质钙碱性系列CM型花岗岩类关系密切。     

天山造山带古生代侵入岩地质特征及构造意义

通过对天山造山带古生代侵入岩岩石类型、岩石地球化学特征及年代学研究,初步厘定不同构造带侵入岩浆序列及形成构造环境。天山地区古生代侵入岩主要包括奥陶—志留纪俯冲期钙碱性花岗岩、泥盆纪后碰撞型正长花岗岩、石炭纪中早期俯冲型钙碱性花岗岩、石炭纪晚期后碰撞型正长花岗岩、石炭纪末后碰撞型镁铁-超镁铁质岩、二叠纪早期后造山型碱性花岗岩及洋壳残片等。俯冲期侵入岩主要为花岗闪长岩-石英二长闪长岩-石英闪长岩组合;同碰撞期为花岗闪长岩-二长花岗岩组合;后碰撞期为组成花岗岩-二长花岗岩组合;后造山期为正长花岗岩-碱性花岗岩组合。认为该地区古生代侵入岩与Terskey洋、北天山洋、南天山洋等洋盆演化密切相关,并建立了天山地区古生代构造演化模式图。     

三江地区义敦岛弧造山带演化和成矿系统

义敦岛弧是喜马拉雅巨型造山带中的一个复合造山带,它经历了印支期洋壳俯冲造山、燕山湖弧-陆碰撞和喜马拉雅期陆内走滑作用诸演化历史。可能由于洋壳板片俯冲角度不同,义敦晚三叠世古岛弧带(206～237 Ma)南北两段具有不同的发育历史,北段昌台弧以发育孤间裂谷为特色,具张性弧特征,发育扩张环境流体聚敛成矿系统,形成VMS型Zn-Pb-Cu矿床和浅成低温热液型Ag-Au-Hg矿床;南段中甸弧不发育弧后盆地,但广泛发育钙碱性弧火山岩-玢岩-斑岩杂岩系和挤压环境岩浆-流体成矿系统,形成斑岩型-夕卡岩型铜多金属矿床。在三叠纪-侏罗纪之交的弧-陆碰撞作用中,早期大陆板片俯冲形成同碰撞花岗岩带(约200 Ma),晚期造山后伸展作用,形成A型花岗岩带(75～138 Ma),伴随扬子大陆板片俯冲而发生的强烈剪切和推覆,在甘孜-理塘蛇绿混杂带发育挤压剪切环境流体聚敛成矿系统,形成剪切带型金矿。伴随造山后伸展和A型花岗岩侵位,发育伸张环境岩浆-流体聚敛成矿系统,主要形成夕卡岩型锡矿和构造破碎带热浪脉型银多金属矿床。印度-亚洲大陆碰撞在义敦造山带主要表现为陆内走滑作用,并控制碱性花岗岩和花岗斑岩的发育(50～30 Ma),伴随斑岩型金矿的形成。     

东秦岭古生代以来花岗质岩浆活动及其构造意义

东秦岭自古生代以来经历了多期花岗质岩浆活动形成了大量的花岗质岩石。依据锆石U-Pb年龄,这些花岗岩可分为三个主要期次:加里东期花岗岩、印支期花岗岩和燕山期花岗岩。详细研究这些花岗岩的岩石地球化学特征发现,早古生代的花岗岩表现为与大洋俯冲作用有关的岛弧钙碱性系列岩石,早中生代花岗岩具有后碰撞阶段花岗岩的地球化学特征,晚中生代花岗岩主要为Ⅰ型花岗岩并伴有A型花岗岩的出现。这说明东秦岭区域上经历了俯冲造山作用到碰撞造山和碰撞后陆内演化等不同阶段。     

东准噶尔北缘两类钙碱性花岗岩特征及其构造-成矿意义

依据前人对东准噶尔地区花岗岩类年代学和地球化学研究,将东准噶尔北缘钙碱性花岗岩划分为两类：一类为俯冲钙碱性花岗岩;另一类为后碰撞高钾钙碱性花岗岩。岩石地球化学对比研究发现,两类钙碱性花岗岩存在系统差异,兼具有相似性。岩石地球化学特点差异表现为俯冲钙碱性花岗岩,显示亲岛弧岩浆性,后碰撞高钾钙碱性花岗岩具有陆内后碰撞深成岩浆的特点。两者之间的相似性表明,造山带内花岗岩类由俯冲钙碱性→后碰撞高钾钙碱性系列演化是由于俯冲造山向碰撞造山快速转化、空间上位于同一造山带内,源区岩浆有双重性的特点。钙碱性花岗岩产出的构造环境具有多样性,成岩过程受造山带不同演化阶段相应构造背景制约,洋陆俯冲的岛弧环境和陆内造山的后碰撞环境分别是俯冲钙碱性和后碰撞高钾钙碱性花岗岩形成的构造背景。埃达克质岩浆亲和性显示俯冲钙碱性花岗岩与部分后碰撞高钾钙碱性花岗岩均有形成不同背景（岛弧和后碰撞）斑岩型矿床的潜力。后碰撞高钾钙碱性花岗岩与IOCG型矿床的空间联系,表明造山带伸展背景的后碰撞环境,也可能是IOCG型矿床产出的构造背景。两类钙碱性花岗岩构造背景的差异可能初步印证了具有岛弧斑岩型矿床的哈腊苏-卡拉先格尔和IOCG型矿床的老山口南东一带成矿环境的差异。     

西藏冈底斯地块中新生代中酸性侵入岩浆活动与构造演化

冈底斯地块上的中新生代中酸性岩浆活动,是北部班公湖-怒江和南部雅鲁藏布两个特提斯演化及其后的陆内汇聚碰撞造山和后造山伸展等大地构造事件的完整记录.地块上的中酸性岩浆活动可划分为3个带,其中北部岩带岩浆岩形成于燕山期,其类型从早期的Ⅰ型到中期的过渡型演化为晚期的S型,分别形成于板块俯冲-缝合-碰撞等构造条件下,是北部班公湖-怒江特提斯演化的集中反映.中部和南部岩浆岩带则集中体现了雅鲁藏布特提斯时空演化的完整经历.其中,南部岩带岩体以燕山晚期为主,喜马拉雅早期次之,成因及形成环境与特提斯洋壳向北俯冲作用密切相关(燕山晚期),同时俯冲结束后的同碰撞条件下的岩浆活动在该岩带内也有明显的反映(喜马拉雅早期);中部岩带岩体以喜马拉雅早期为主,燕山晚期次之.岩体大部分为同碰撞环境下岩浆活动的产物,它表征了随着洋壳板块向北俯冲程度的加深和强度的加剧,岩浆活动中心在不断向北迁移,并最终缝合碰撞的过程.因此该岩带内岩浆岩主要形成于俯冲的晚阶段及缝合后的同碰撞条件下.喜马拉雅晚期的小斑岩体实际上广泛出露于整个冈底斯地块上,它反映的是该区在经历了碰撞造山后发生的陆内伸展的构造过程.     

阿尔金构造带西段早古生代侵入岩地球化学特征及构造意义

通过1∶25万瓦石峡幅和阿尔金山幅区域地质调查发现,阿尔金构造带西段发育有大量早古生代侵入岩,可划分为3条构造-岩浆岩带。岩石组合和地球化学分析结果表明,北带塔特勒克布拉克花岗岩系列具同源岩浆演化特征,为碰撞造山阶段形成的产物;中带其昂里克浆混花岗岩组合和南带尖石山花岗岩系列显示不同原岩岩浆混合特点,是俯冲-消减阶段到碰撞阶段壳-幔相互作用产物,表明阿尔金构造带西段早古生代侵入岩类属造山型花岗岩,时代与阿尔金地区高压-超高压变质作用时间可对比,是早古生代洋陆俯冲-碰撞的地质记录。说明塔里木和柴达木板块间在早古生代存在板块的汇聚碰撞,形成了该区高压-超高压变质岩和广泛发育的加里东期造山型花岗岩。     

钦杭成矿带西段古龙花岗岩株群岩石学、地球化学及年代学

古龙花岗岩株群包括大村、古龙、思泰、社山、上木水、大坡等侵入体,岩性主要为石英闪长岩-英云闪长岩-花岗闪长岩-二长花岗岩组合,岩石普遍含角闪石。岩石化学系列属于钙碱性系列-高钾钙碱性系列,主量元素具高CaO低K2O的特征。稀土总量低,轻稀土富集,弱Eu亏损。微量元素Nb、Ta、Sr、P、Ti强烈亏损,Th、U、Zr、Hf相对富集。对古龙岩体进行了高精度的LA-ICP-MS锆石U-Pb定年,获得石英闪长岩等时线年龄为445.9±1.2Ma(MSWD=0.035)。研究认为古龙花岗岩株群形成于早志留世,属于加里东期I型花岗岩,形成于华南加里东期造山带俯冲-碰撞挤压构造背景,岩浆物质来源主要为俯冲带幔源岩浆并混入了部分壳源物质。     

西拉沐伦成矿带中生代花岗岩浆活动与钼成矿作用

位于华北克拉通北缘的西拉沐伦成矿带内花岗岩浆活动及钼矿化发育,带内主要成矿侵入体岩石类型包括二长花岗岩、斑状花岗岩、花岗斑岩及流纹斑岩,这些岩石属于高钾钙碱性和钾玄岩系列,岩浆源区为古老下地壳和新生地壳。这些侵入体形成于早—中三叠世、晚侏罗世及早白垩世。带内钼矿床包括斑岩型、石英脉型、云英岩型和火山-次火山热液型4种类型,以斑岩型矿床最为发育。带内钼矿床形成时代与相关侵入岩时代一致,也形成于早—中三叠世、晚侏罗世及早白垩世,以早白垩世钼矿床最为发育。3期成岩成矿作用分别形成于华北板块与西伯利亚板块同碰撞至后碰撞构造环境、古太平洋板块向欧亚大陆俯冲的构造环境和中国东部岩石圈减薄构造环境。     

论雅鲁藏布大峡谷地区冈底斯岛弧花岗岩带

雅鲁藏布大峡谷北部的冈底斯岛弧花岗岩带可分为若干亚带，但岩浆活动大致可分为两大期次，分别与两次大规模造山活动有关，喜马拉雅造山作用在本区形成大量中新世花岗岩体，分布在离雅鲁藏布结合带较近部位；本区北部大量的早侏罗世至晚白垩世花岗岩，据其空间展布、岩浆活动时间、成因类型和岩石组合特征分析，应与怒江特提斯洋的闭合造山有关，同时说明本次造山作用可能是中生代的一次长期的构造-岩浆活动。     

Composition,sources, and geodynamic nature of giant batholiths in Central Asia: Evidence from the geochemistry and Nd isotopic characteristics of granitoids in the Khangai zonal magmatic area

Data on the composition, inner structure, and magma sources of giant batholith in the Central Asian Orogenic Belt are analyzed with reference to the Khangai batholith. The Khangai batholith was emplaced in the Late Permian–Early Triassic (270–240 Ma) and is the largest accumulations (>150000 km²) of granite plutons in central Mongolia. The plutons are dominated by granites of normal alkalinity and contain subalkaline granites and more rare alkaline granites. The batholith is hosted in the Khangai zonal magmatic area, which consists of the batholith itself and surrounding rift zones. The zones are made up of bimodal basalt–trachyte–comendite (pantellerite) or basalt-dominated (alkaline basalt) volcanic associations, whose intrusive rocks are dominated by syenite and granite, granosyenite, and leucogranite. Both the batholith and the rift zones were produced within the time span of 270–240 Ma. Although the rocks composing the batholith and its rift surroundings are different, they are related through a broad spectrum of transitional varieties, which suggests that that the mantle and crustal melts could interact at various scale when the magmatic area was produced. A model is suggested to explain how the geological structure of the magmatic area and the composition of the magmatic associations that make up its various zones were controlled by the interaction between a mantle plume and the lithospheric folded area. The mantle melts emplaced into the lower crust are thought to not only have been heat sources and thus induced melting but also have predetermined the variable geochemical and isotopic characteristics of the granitoids. In the marginal portions of the zonal area, the activity of the mantle plume triggered rifting associated with bimodal and alkaline granite magmatism. The formation of giant batholiths was typical of the evolution of the active continental margin of the Siberian paleocontinent in the Late Paleozoic and Early Mesozoic: the Khangai, Angara–Vitim, and Khentei batholiths were formed in this area within a relatively brief time span between 300 and 190Ma. The batholiths share certain features: they consist of granitoids of a broad compositional range, from tonalite and plagiogranite to granosyenite and rare-metal granites; and the batholiths were produced in relation to rifting processes that also formed rift magmatic zones in the surroundings of the batholiths. The large-scale and unusual batholith-forming processes are thought to have occurred when the active continental margin of the Late Paleozoic Siberian continent overlapped a number of hotspots in the Paleo- Asian Ocean. This resulted in the origin of a giant anorogenic magmatic province, which included batholiths, flood-basalt areas in Tarim and Junggar, and the Central Asian Rift System. The batholiths are structural elements of the latter and components of the zonal magmatic areas.     

Tectono-metamorphic evolution of the Neyriz metamorphic complex, Quri-Kor-e-Sefid area (Sanandaj-Sirjan Zone, SW Iran)

The Neyriz region includes outcrops of metamorphic rocks that are thrust over the Neotethyan ophiolites. These rocks are affected by a major deformational event, the result of which includes a shearing polyphase foliation present in gneissic core domes, overprinted by a crenulation cleavage. These fundamental structures developed contemporaneously with a medium-pressure metamorphism which is characterized by the syn-kinematic crystallization of kyanite and the beginning of anatexis, followed by the development of retrometamorphic mineral parageneses. The major deformation phase in the area occurred during the Early-Cimmerian orogeny in the Late Triassic. Following the orogeny, the gneiss domes started to rise into the upper levels of the crust. From the geodynamic point of view, after the Mid-Permian the studied area was situated at southern passive margin of the Iranian plate; the central Iranian microcontinent at that time was separated by the Neotethys ocean from the Gondwanian supercontinent. After the Late Triassic the region became an active margin associated with an accretionary prism. The margin was finally involved in an orogenic wedge after the closure of the Neotethyan oceanic basin in the Late Mesozoic. Closure of the basin resulted in a major thrusting of the metamorphic rocks of the southern Iranian margin over the Neotethyan ophiolites.     

甘孜—理塘断裂带北段新生代构造特征及金矿成矿作用

甘孜—理塘断裂带自古生代以来经历了一系列复杂的演化过程，为一规模宏大、结构复杂并受到新生代喜马拉雅期逆冲推覆和左行平移走滑剪切作用强烈改造肢解的蛇绿混杂岩带。金矿成矿主要与新生代喜马拉雅期逆冲推覆和平移走滑以及成矿期后的表生氧化作用有关。沿该断裂带广泛发育水热活动，显示了现代热液成矿作用仍在进行中。重视新生代喜马拉雅期构造活动规律的研究对该区找矿具有重要意义。     

华南中-晚二叠世之交碳酸盐岩磁学特征及环境意义

磁学参数作为可靠的古气候和古环境指标, 能为全球环境变化、气候过程研究提供有价值的资料.对广西来宾铁桥剖面瓜德鲁普-乐平统界线地层进行详细岩石磁学研究, 结果表明, 铁桥剖面样品中主要磁性矿物是顺磁性矿物以及少量磁铁矿、赤铁矿.在瓜德鲁普-乐平统界线附近, 岩石磁学特征发生显著变化, 磁化率先增大再减小, 携磁矿物成分呈硬磁性矿物(赤铁矿)→软磁性矿物(磁铁矿)→硬磁性矿物(赤铁矿)的变化趋势, 这些转变仅在界线上下大约4m的岩层内完成, 与中二叠世晚期的海平面变化、古海水温度变化同步.中-晚二叠世之交碳酸盐岩磁学参数的变化显著, 反映磁性矿物在各圈层之间的运移和转换发生了转变, 这一转变起因于当时的气候环境变化.瓜德鲁普世晚期和乐平世早期, 海平面较高, 来宾地区物源少, 铁桥剖面的携磁矿物主要来自粉尘赤铁矿; 中-晚二叠世之交短暂的大规模海退作用使华南古陆面积大幅度增加, 同时陆生植物大规模灭绝, 地表侵蚀加剧, 来宾地区物源增多, 此时, 铁桥剖面的携磁矿物主要来源于河流输入的磁铁矿.      

辽西兰家沟钼矿区成矿构造、岩浆演化及成矿作用

根据兰家沟钼矿区控矿旋卷构造特征、燕山期花岗岩体的岩石化学特征、稀土元素特征和成矿元素含量,讨论了该矿区形成的地质构造条件和岩浆演化分异作用在钼矿床形成过程中的成矿作用和找矿前景。     

Ilmenite, magnetite, and peraluminous Mesoproterozoic anorogenic granites of Laurentia and Baltica

Emplacement of 1.6 to 1.3 Ga Mesoproterozoic plutons in Baltica and Laurentia formed an immense belt of A-type granite batholiths that include (1) low-fO₂, ilmenite-series granite intrusions from the Baltic region to Wyoming, (2) high-fO₂, magnetite-series granite intrusions of the central to southwestern U.S., and (3) peraluminous, two-mica granite intrusions from Colorado to central Arizona. These mineralogic divisions are mirrored by substantial elemental and oxygen isotopic differences. The ilmenite-series granites, which often contain classic rapakivi textures, have the highest Fe/Mg ratios and are highest in LIL element enrichment. They also have the lowest whole-rock δ¹⁸O values at 5.7‰ to 7.7‰. The magnetite-series granites are less potassic, less LILE-enriched, and have higher whole-rock δ¹⁸O values, ranging from 7.6‰ to 10.8‰. Although they retain A-type characteristics, the peraluminous granites are the least LILE-enriched and have the lowest Fe/Mg ratios. They also have the highest whole-rock δ¹⁸O values ranging from 8.8‰ to 12.0‰. Feldspar, where strongly reddened, can exhibit elevated δ¹⁸O values, which is interpreted to indicate subsolidus exchange with surface-derived aqueous fluids. Quartz δ¹⁸O values are interpreted to generally retain their magmatic values. The transcontinental mineralogic, chemical, and oxygen isotopic variations are interpreted as indicative of broad changes in the composition of a lower crustal source, which is compatible with a reduced mantle-derived crustal source for the ilmenite-series granites and a more oxidized crustal source for the others, including a metasedimentary component in the source for the two-mica granite subprovince.

Widespread thermal metamorphism at 1.4 Ga is present throughout much of the magmatic province and is viewed as a consequence of this immense event. Compressional deformation associated with several western 1.4 Ga Laurentia granite batholiths, alternatively interpreted as the distal expressions of a presumed 1.4 Ga orogeny, have at least in part been shown to be localized on preexisting Paleoproterozoic zones of deformation. Thus, we do not find compelling evidence for a 1.4 Ga orogeny related to the formation of most of these granites. Renewed intrusions at 1.0–1.1 Ga between and immediately following phases of the Grenville orogeny indicate that situations leading to their formation need to be more broadly considered.

The origin of this red granite-forming event in Laurentia and Baltica is considered as part of a global magmatic event that was coeval with intrusion of massif anorthosites and associated charnockites. Most are viewed as anorogenic, but it is recognized that the same conditions leading to their formation may have occurred during extensional phases of orogens. The immense volumes of red granites produced are also essentially unique to the Mesoproterozoic and appear to be tied to the stabilization and eventual break up of supercontinents of both Paleoproterozoic and Mesoproterozoic age.     

陕西柞-山-商晚古生代拉分断陷盆地动力学与成矿作用

采用构造-岩相学和构造-热水沉积岩相填图研究,认为陕西柞水-山阳-商县（柞-山-商）晚古生代拉分盆地,在早古生代扬子板块北被动陆缘残余洋盆基础上,经历了志留纪-早泥盆世北秦岭岛弧造山带-残余洋盆转换过程。在中泥盆世演化为秦岭微板块北缘拉分断陷盆地,晚泥盆世叠加了深源碱性热流体叠加作用明显,形成了铁白云石钠质角砾岩相带,并发生了构造反转。石炭纪陆缘拉分盆地进一步发展演化为残余海盆萎缩封闭。这种造山带-沉积盆地-岛屿构造耦合与转换过程记录了由洋盆-岛弧碰撞造山转换为陆-陆碰撞造山过程。该拉分盆地中具有明显的区域成矿分带,与多期成矿成岩地质作用有关,在造山带-沉积盆地-岛屿构造耦合与转换中,中泥盆世柞-山-商拉分断陷盆地的四周被古陆块和造山带分隔,陆-陆碰撞过程驱动了造山带流体发生大规模排泄到该盆地内,在该拉分断陷盆地内形成了大规模热水沉积成岩成矿,各类热水沉积岩相发育。在该拉分盆地中,近东西向和北东向同生断裂作用形成了次级断陷盆地,为热水沉积成岩成矿提供了沉积容纳空间。热水沉积成因的银多金属-重晶石-菱铁矿矿床定位于三级和四级热水洼地。晚泥盆世-石炭纪近南北向的岩石圈地幔收缩,陆-陆碰撞收缩成为垂向热传输主要驱动力源,导致了陆壳尺度上碱性热流体被挤压垂向排出到陆表残余海盆之中,本区脉状富金镍钴铜矿与晚泥盆世-石炭纪深源碱性热流体隐爆作用形成的碱性铁白云石钠质角砾岩带密切有关。类卡林型金矿定位于该盆地上部基底构造层和盆地热水浊流沉积相内,主要与后期脆韧性剪切带有密切关系。     

巴尔喀什-准噶尔地区地层及岩浆岩概述

巴尔喀什-准噶尔地区地层出露齐全,岩浆岩发育,太古-元古代以片岩、片麻岩、麻粒岩等变质岩系为主,为以1 230～1 100 Ma侵入的辉长-辉绿岩、花岗岩为代表的格林威尔造山事件结果,其后的里菲系多具盖层性质.文德系出露冰碛岩及碱性火山岩,象征古陆(罗丁尼亚古陆)解体;古生代地层可划分为稳定及活动型两种类型.前者为在稳定陆壳基底上的盖层,后者为古亚洲洋发展、演化至消亡全过程的不同沉积建造特征及建造组合;中-新生代地层代表陆内盆地发展、演化阶段的各类沉积.火山岩按时代分别作了介绍,总体特征是前寒武纪以偏碱性岩浆活动为主,古生代多为钙碱系列,后期发育舣峰式火山岩.中-新生代为大陆玄武岩、流纹岩岩流及部分碱性岩类.侵入岩共划分为5大侵入期,并按时代分别作了介绍.     

青藏高原南部的主要战略性矿产：勘查进展、资源潜力与找矿方向

当今世界处于百年未有之大变局中,各国对战略性矿产资源的需求显著增加。加强国内战略性矿产勘查,保障战略性矿产资源的安全供给,成为了目前的紧迫任务。东特提斯成矿域内的冈底斯-喜马拉雅造山系位于青藏高原南部边缘,是解剖和理解新特提斯洋俯冲消亡、亚洲-印度大陆碰撞与大规模成矿作用的关键地区。本文在综合分析高原南部冈底斯-喜马拉雅造山系地质构造演化与大规模成矿作用的基础上,对冈底斯、雅鲁藏布江和喜马拉雅等重点成矿带战略性矿产的种类与主要类型以及近年来的地质找矿工作取得的主要进展进行了系统总结,提出新生代以来大规模的壳幔相互作用与构造-岩浆演化过程导致了高原南部以铜、铬、金和铍稀有金属等为特色的战略性矿产资源高度富集,并认为该地区在我国急缺战略性矿产资源的资源配置中居重要地位,形成了驱龙-甲玛、朱诺、罗布莎、扎西康等多个大型矿集区,是建设我国未来战略性矿产资源接续基地的重点地区。通过对该地区各战略性矿产资源潜力的分析,提出了下一步找矿工作的重点和方向,除开展矿集区深部及外围找矿外,还应该加强新类型与新矿种的寻找。