马绪宣

论文发表：

Cai, Z.H., He, B.Z., Meert, J.G., Ma, X.X.*, Jiao, C.L., Liu, R.H., Chen, X.J., Yun, X.R., 2021. Neoproterozoic tectonic transition from subduction-related convergence to continental extension of the Tarim Block, NW China. Precambrian Research, Accepted.

Ma, X.X., Gao, L.E., Zhao, Z.B., Chen, X.J., Li, H.B., 2021. Early Eocene leucocratic sill/dike swarms in the Gangdese belt, southern Tibet: tectonic implications for Indo-Asian collision. China Geology, 1, 56-66.

Ma, X.X., Xu, Z.Q., Meert, J.G., Tian, Z.L.*, Li, H.B., 2020. Early Eocene high-flux magmatism and concurrent high-temperature metamorphism in the Gangdese belt, southern Tibet. GSA Bulletin, https://doi.org/10.1130/B35770.1.

Ma, X.X., Xu, Z.Q., Zhao, Z.B., Yi, Z.Y., 2020. Identification of a new source for the Triassic Langjiexue Group: evidence from a gabbro-diorite complex in the Gangdese magmatic belt and zircon microstructures from sandstones in the Tethysan Himalaya, southern Tibet. Geosphere, 16, 407-434.

Ma, X.X., Meert, J.G., Xu, Z.Q., Yi, Z.Y.*, 2018. Late Triassic intra-oceanic arc system within Neotethys: evidence from cumulate appinite in the Gangdese belt, southern Tibet. Lithosphere, 10, 545-565.

Ma, X.X., Meert, J., Xu, Z.Q., Zhao, Z.B., 2018. The Jurassic Yeba Formation in the Gangdese arc of S. Tibet: implications for upper plate extension in the Lhasa terrane. International Geology Review   https://doi.org/10.1080/00206814.2018.1434835.

Ma, X.X., Xu, Z.Q., Meert, J., 2017. Syn-convergence extension in the southern Lhasa terrane: evidence from late Cretaceous adakitic granodiorite and coeval gabbroic-dioritic dykes. Journal of Geodynamics 110, 12-30.

Ma, X.X., Xu, Z.Q., Meert, J., Santosh, M., 2017. Early Jurassic intra-oceanic arc system of the Neotethys Ocean: constraints from andesites in the Gangdese magmatic belt, south Tibet. Island Arc, DOI 10.1111/iar.12202. 

Ma, X.X., Meert, J.G., Xu, Z.Q., Zhao, Z.B., 2017. Evidence of magma mixing identified in the Early Eocene Caina pluton from the Gangdese Batholith, southern Tibet. Lithos 278-281, 126-139.

Ma, X.X., Xu, Z.Q., Chen, X.J.*, Meert, J.G., He, Z.Y., Liang, F.H., Meng, Y.K., Ma, S.W., 2017. The origin and tectonic significance of the volcanic rocks of the Yeba Formation in the Gangdese magmatic belt, South Tibet. Journal of Earth Science 28, 265-282.

Ma, X.X., Xu, Z.Q., Meert, J.G., 2016. Eocene slab breakoff of Neotethys as suggested by dioritic dykes in the Gangdese magmatic belt, southern Tibet. Lithos 248-251, 55-65.

Ma, X.X., Shu, L.S.*, Meert, J.G., 2015. Early Permian slab breakoff in the Chinese Tianshan belt inferred from the post-collisional granitoids. Gondwana Research 27, 228-243. 

Ma, X.X., Shu, L.S.*, Meert, J.G., Xu, Z.Q., 2014. The fingerprint of Precambrian basement in the Chinese Central Tianshan: evidence from inherited/xenocrystic zircons of magmatic rocks. Geological Magazine 1-8.

Ma, X.X., Shu, L.S.*, Meert, J.G., Li, J.Y., 2014. The Paleozoic evolution of Central Tianshan: Geochemical and geochronological evidence. Gondwana Research 25, 797-819. 

Ma, X.X., Shu, L.S.*, Santosh, M., Li, J.Y., 2013. Paleoproterozoic collisional orogeny in Central Tianshan: assembling the Tarim Block within the Columbia supercontinent. Precambrian Research 228, 1-19. 

Ma, X.X., Shu, L.S.*, Santosh, M., Li, J.Y., 2013. Petrogenesis and tectonic significance of an early Palaeozoic mafic-intermediate suite of rocks from the Central Tianshan, northwest China. International Geology Review 55, 548-573.

Ma, X.X., Shu, L.S.*, Jahn, B.M., Zhu, W.B., Faure, M., 2012. Precambrian tectonic evolution of Central Tianshan, NW China: constraints from U–Pb dating and in situ Hf isotopic analysis of detrital zircons. Precambrian Research 222, 450-473. 

Ma, X.X., Shu, L.S.*, Santosh, M., Li, J.Y., 2012. Detrital zircon U–Pb geochronology and Hf isotope data from Central Tianshan suggesting a link with the Tarim Block: implications on Proterozoic supercontinent history. Precambrian Research 206-207, 1-16. 

Zhao, Z.B., Li, C., Ma, X.X., 2021. How does the elevation changing response to crustal thickening process in the central Tibetan Plateau since 120 Ma? China Geology, 1, 32-43.

Xu, Z.Q., Li, Y., Ji, S.C., Li, G.W., Pei, X.Z., Ma, X.X., Xiang, H., Wang, R.R., 2020. Journal of Asian Earth Sciences 188, 104052.

Cao, W.R., Yang, J.M., Zuza, A.V., Ji, W.Q., Ma, X.X., Chu, X., Burgess, Q.P., 2020. Crustal tilting and differential exhumation of Gangdese Batholith in southern Tibet revealed by bedrock pressures. Earth and Planetary Science Letters 543, 116347.

Huang, H., Wang, T., Tong, Y., Qin, Q., Ma, X.X., Yin, J.Y., 2020. Rejuvenation of ancient micro-continents during accretionary orogenesis: insights from the Yili Block and adjacent regions of the SW Central Asian Orogenic Belt. Earth-Science Reviews 208, 103255.

Zhao, Z.B., Bons, P.D., Li, C., Wang, G.H., Ma, X.X., Li, G.W., 2020. The Cretaceous crustal shortening and thickening of the South Qiangtang Terrane and implications for proto-Tibetan Plateau formation. Gondwana Research 78, 141-155.

Meng, Y.K., Xiong, F.H., Xu, Z.Q., Ma, X.X., 2019. Petrogenesis of Late Cretaceous mafic enclaves and their host granites in the Nyemo region of southern Tibet: implications for the tectonic-magmatic evolution of the Central Gangdese Belt. Journal of Asian Earth Sciences 176, 27-41.

Meng, Y.K., Xu, Z.Q., Santosh, M., Ma, X.X., Chen, X.J., Guo, G.L., Liu, F., 2016. Late Triassic crustal growth in southern Tibet: evidence from the Gangdese magmatic belt. Gondwana Research 37, 449-464.

Cai, Z.H., Xu, Z.Q., Yu, S.Y., Li, S.Z., He, B.Z., Ma, X.X., Chen, X.J., Xu, X.Y., 2018. Neoarchean magmatism and implications for crustal growth and evolution of the Kuluketage region, northeastern Tarim Craton. Precambrian Research, 304, 156-170.

Cai, Z.H., Jiao, C.L., He, B.Z., Qi, L.X., Ma, X.X., Cao, Z.C., Xu, Z.Q., Chen, X.J., Liu, R.H., 2020. Archean-Paleoproterozoic tectonothermal events in the central Tarim Block: constraints from granitic gneisses revealed by deep drilling wells. Precambrian Research 347, 105776.

Ding, R.X., Zou, H.P., Min, K., Yin, F., Du, X.D., Ma, X.X., Su, Z.X., Shen, W.J., 2017. Detrital zircon U-Pb geochronology of Sinian-Cambrian strata in the Eastern Guangxi area, China. Journal of Earth Science 28, 295-304.

马绪宣，许志琴，刘飞，赵中宝，李海兵，2021. 大陆弧岩浆幕式作用与地壳加厚：以藏南冈底斯弧为例.地质学报，95, 107-123.

马绪宣，施彬，熊发挥，李海兵，2020.冈底斯曲水岩基岩浆混合：来自暗色岩浆包体角闪石显微结构的证据.岩石学报，36, 3063-3080.

许志琴，马绪宣，2015.中国大陆显生宙俯冲型、碰撞型和复合型片麻岩穹窿（群）.岩石学报 31, 3509-3523.

吴勇，马绪宣*，张志平，焦世文，段凯，董瀚，王小伟，马涛，李鹏举，梁志勇，曹勇刚，孔垂鹏，马亮，2016.青藏高原拉萨地块西部念青唐古拉岩群的地球化学特征及构造意义.地质学报 90，3081-3098.

许志琴，付小方，马绪宣，戚学祥，吴婵，侯立伟，赵中宝，2016.青藏高原片麻岩穹窿与找矿前景.地质学报 90, 2971-2981.

蔡志慧，马绪宣，何碧竹，2019.中天山、伊犁及塔里木地块开始参与Rodinia超大陆聚合过程早于新元古代？地质学报 93, 2426-2445.

许志琴，赵中宝，彭淼，马绪宣，李化启，赵俊猛，2016.论“造山的高原”.32， 3557-3571.

许志琴，杨经绥，侯增谦，张泽明，曾令森，李海兵，张建新，李忠海，马绪宣，2016. 青藏高原大陆动力学研究若干进展.中国地质，43，1-42.

孟元库，许志琴，陈希节，马绪宣，贺振宇，张雪松，2015.藏南冈底斯中段谢通门始新世复式岩体锆石U-Pb年代学、Hf同位素特征及其地质意义.大地构造与成矿学 39, 933-948.

孟元库，许志琴，马士委，杨斐斐，马绪宣，2016.藏南冈底斯岩浆带中段曲水韧性剪切带的变形特征及其年代学约束.地球科学 41, 1081-1098.

董汉文，许志琴，周信，巴登珠，李化启，易治宇，陈希节，马绪宣，吴婵，2016.喜马拉雅造山带北缘大反转逆冲断层（GCT）东段的活动时限及构造演化.地质学报 90, 3011-3022.

舒良树，邓兴梁，马绪宣，2019.中天山基底与塔里木克拉通的构造亲缘性.地球科学 44, 1584-1601.

赵理芳，舒良树，于常青，汪洋，瞿辰，马绪宣，2018.青藏高原东缘深部电性结构特征研究.高校地质学报，24，702-714.

许志琴，赵中宝，马绪宣，陈希节，马元，2019.从安第斯到冈底斯：从洋-陆俯冲到陆-陆碰撞.地质学报 93, 1-11.

孟元库，许志琴，陈希节，马绪宣，马士委，2015.冈底斯中段碱长花岗岩锆石U-Pb-Hf同位素特征及地质意义.中国地质 42, 1202-1213.

董汉文，许志琴，曹汇，李源，刘钊，李化启，易治宇，陈希节，马绪宣，吴婵，2018.东喜马拉雅构造结东、西边界断裂对比及其构造演化过程.地球科学 43, 933-951.

孟元库，马士委，许志琴，陈希节，马绪宣，2018.冈底斯带甲玛矿区花岗斑岩类年代学、地球化学及岩石成因.地球科学 43, 1142-1163.

马元，许志琴，李广伟，马士委，马绪宣，陈希节，赵中宝，2017.藏南冈底斯白垩纪弧后盆地的地壳变形及初始高原的形成.岩石学报 33，3861-3872.

陈希节，舒良树，马绪宣，2012.新疆尾亚蛇绿混杂岩与镁铁质麻粒岩地球化学特征及构造意义.高校地质学报，18，661-675.