基本信息
性别:男
出生年月:1983年2月
祖籍:山东临朐
联系地址:山东省青岛市崂山区松岭路238号,邮编266100
中国海洋大学海洋地球科学学院
E-mail 地址:liuxiting@ouc.edu.cn
RG主页:https://www.researchgate.net/profile/Xiting_Liu
简历
· 学习经历
2010.10-2014.12,德国不来梅大学地球科学学学院,自然科学博士
2007.9-2010.7,中国地质大学(武汉)地球科学学院,理学硕士
2003.9-2007.6,东北大学资源与土木工程学院,工学学士
· 工作简历
2022.12-至今,中国海洋大学海洋地球科学学院,教授
2017.11-2022.11,中国海洋大学海洋地球科学学院,副教授
2015.01-2017.10,中国科学院海洋研究所,博士后
· 学术兼职
中国海洋湖沼学会地质学分会理事
国际沉积学家协会(IAS)会员
《Marine Geology》编委
《古地理学报》编委
NC, EPSL, GRL, GCA, CG, MG等期刊审稿专家
· 主持的科研项目
[1].2023.1-2026.12 国家自然科学基金面上项目:末次冰消期以来浙闽沿岸泥质沉积物内活性铁源汇过程及环境响应(42276060)
[2].2022.1-2024.12 山东省优秀青年基金项目:海洋沉积学编号(ZR2021YQ26)
[3].2020.1-2023.12国家自然科学基金面上项目:东海内陆架沉积物中自生黄铁矿的形成机制和对环境演化的响应(41976053)
[4].2019.12.-2021.11青岛海洋科学与技术试点国家实验室海洋地质过程与环境功能实验室创新团队建设资助项目:东海泥质区自生黄铁矿对末次冰消期以来沉积环境演化的响应机制(MGQNLM-TD201901)
[5].2017.1-2019.12国家自然科学基金青年基金:全新世浙闽泥质沉积体物源示踪及其古气候意义(41606062)
[6].2016.5-2017.10中国博士后科学基金面上项目:全新世东海泥质沉积自生黄铁矿和石膏的成因及其地质意义(2016M592257)
主要学术领域
· 学科方向
海洋沉积学、古气候学
· 近期研究兴趣
(1)海洋沉积矿物:泥质沉积物内自生矿物(黄铁矿、菱铁矿等)的成因机制及其相关生物地球化学过程。
(2)大陆边缘沉积过程与沉积记录:边缘海沉积物的源汇过程,内陆架泥质区的沉积动力过程,以及沉积物向深海输入的路径。
(3)古气候和古海洋:利用沉积记录的物理、化学特征,重建地质历史时期古气候和古海洋演化。
代表性论文目录
截止2024.8,已发表论文90篇,其中第一/通讯作者40余篇。
2024年
[1].Liu, X.T.*, Wang, H.J., Liu, J.R., Zhuang, G.C.*, 2024. Microbial sulfate reduction and its role in carbon sequestration in marine sediments. Journal of Earth Science 35, 1378–1381.
[2].Chang, X., Liu, X.T*, Zhang, K.D*, Li, A.C, Hu, L.M, Zhang, M.Y, Wang, H.J, Zhuang, G.C, Shen, J., 2024. Dominant host phase of mercury within the sediments of the East China Sea inner shelf: Implications for mercury inputs. Chemical Geology 668, 122334.
[3].Zhang, M.Y., Mingyu Zhang, M.Y., Liu, X.T.*, Li, A.C., Chang, X., Hu, L.M., Bi, N.S., Zhuang, G.C., Wang, H.J., 2024. Fate of terrigenous organic carbon within shelf sediments from the East China Sea controlled by sea-level and climatic changes since the last deglaciation, Palaeogeography. Palaeoclimatology, Palaeoecology 650, 112386.
[4].Miao, X.M., Wei, J.G., Li, J.R., Liu, X.T.*, Dong, W., Li, J., Feng, X.L.*, 2024. Isotopically light Mo in sediments of methane seepage controlled by the benthic Fe-Mn redox shuttle process. Global and Planetary Change 239, 104512.
[5].Kong, F.X., Liu, X.T.*, Li, A.C., Dong, J., Wang, H.J., Zhuang, G.C., Zhang, Z.H., Li, C. 2024. Depositional control on the fate of reactive iron in shelf sediments since the last deglaciation: A case study of the East China Sea. Marine Geology 475, 107358.
[6].Lan, K., Liu, X.T.*, Li, A.C., Xu, F.J., Qiao, P. J., Wang, H.J., 2024. Changes in chemical weathering regime of shelf sediments of the East China Sea controlled by sea-level and climatic changes since the last deglaciation. Journal of Asian Earth Sciences 268, 106169.
[7].Chang, X., Liu, X.T.*, Li, T.G.*, Xiong, Z.F., Duan, B.C., Huang, J., Liu, J.P., Zhang, M.Y., Wang, A.M. and Wang, H.J., 2024. Late Quaternary marine transgressions off the Shandong Peninsula inferred from paleosalinity indicators: Implications for Holocene mud wedge formation. Chemical Geology 657, 122117.
[8].Yu, X.X., Liu, X.T.*, Weia, G.J., Li, A.C., Lin, M*., 2024. Holocene climate regulates multiple sulfur isotope compositions of pyrite in the East China Sea via sedimentation rate. Marine and Petroleum Geology 161, 106687.
[9].Li, Q., Wang, H.B.*, Cai, F., Luo, D., Kong, F., Li, A., Liu, X.T.*, 2024. Influence of methane seep activities and sea-level changes on elemental and isotopic compositions and abundance of carbonates in sediments of the Okinawa Trough since the Last Glacial Period. Journal of Asian Earth Sciences 260, 105942.
[10].Liu, Q., Du, G.X., Li, X.J., Liu, J.R., Meng, N., Li, C.Y., Liu, X.T., Zhang, G.L.*, Yang, G.P., Joye, S. and Zhuang, G.C.*, 2024. Dynamics and controls of methane oxidation in the aerobic waters of eastern China marginal seas. Journal of Geophysical Research: Oceans 129, e2023JC020280.
[11].Ren, X.X., Xu, J.P., Wang, H.J., Liu, M., Liu, X.T., Li, Y. and Wu, X.*, 2024. The depositional characteristics of turbidity current in Manila Trench: sediment provenance, geochemical elements and organic carbon burial. Journal of Asian Earth Sciences 264, 106074.
[12].Qu, Y*, Zhong, H., Liu, X.T., Zhang, W.F., Chen, T.Y., 2024. Coupling and decoupling between sedimentary mercury and organic carbon preservation in the oxygenated marine environment. Geochemistry, Geophysics, Geosystems 25: e2023GC011201.
[13].Miao, X.M., Oppo, D., Wei, J.G.*, Lin, Z.Y., Liu, X.T., Wu, T.T., Yu, X., Wu, K.K., Li, J.R.*, 2024. Enrichment pattern of tungsten in sediments under methane seepage environments: applicability as a proxy for tracing and reconstructing past methane seepage. Chemical Geology 663, 122262.
[14].Dong, J.*, Shi, X.F.*, Dai, H.J., Lu, Z.Y.*, Liu, X.T., Astakhov, A., Hu, L.M., Yang, G., Vasilenko, Y., Bosin, A., Gao, J.J., Liu,Y.G., Zou, J.J., Yao, Z.Q., Li, A.C., 2024. Arctic sea ice loss warmed the temperate East Asian winter in the mid-Holocene. Communications Earth & Environment 5, 401.
[15].Wei, J.G., Miao, X.M.*, Gan, K.L.*, Li, J.T., Li, J.W., Liu, X.T., Xu, H.C., Chen, S., Ta, K.W., Wan, Z.F., Wu, T.T., 2024. Formation of tubular seep-carbonate deciphered from mineralogical and geochemical characteristics: An example from the South China Sea. Frontiers in Marine Science 11, 1451624.
[16].谷玉, 常鑫, 孔凡兴, 兰凯, 庄光超, 刘喜停*. 全新世以来南黄海中部泥质区沉积物的源汇过程及其控制因素, 海洋地质与第四纪地质
[17].孔凡兴, 张哲远, 徐方建, 董江, 李安春, 谷玉, 胡利民, 陈天宇, 刘喜停*, 2024. 末次冰消期以来东海内陆架沉积物活性铁命运及其环境响应, 古地理学报
[18].张企盈, 苗晓明, 常鑫, 孔凡兴, 谷玉, 刘喜停*. 自生黄铁矿指示海底甲烷渗漏, 地球科学进展 39, 589-601.
[19].兰凯, 刘喜停, 李铁刚*, 熊志方, 2024. 末次盛冰期以来山东半岛近岸沉积物化学风化强度对古气候和海平面变化的响应机制. 海洋科学进展
[20].李娜, 张钰莹, 王楠, 吴晓, 叶君, 刘喜停, 胡利民*, 2024. 末次冰消期以来南黄海中部泥质区有机碳埋藏演化记录, 沉积学报, DOI: 10.14027/j.issn.1000-0550.2023.035.
2023年
[21].Liu, X.T.*, Gu Y., Dong J., Li A.C.*, Zhuang G.C., Wang, H.J., 2023. Iron-bearing minerals indicate sea-level rise of the East China Sea inner shelf since the last deglaciation. Science Bulletin 68, 364-366.
[22].Liu, X.T.*, Fan, D.D., Xu, F.J. Liu, J.P., 2023. Sedimentation on the continental margins: from modern processes to deep-time records, Frontiers in Earth Science 10, 1048801.
[23].Chang, X., Liu, X.T.*, Liu, J.R., Zhang, M.Y., Gu, Y., Wang, N., Wang, H.J., Zhuang, G.C., Yu, J.J., Chen, J.*, 2023. Late Quaternary marine transgressions inferred from the pyrite sulfur content and isotopes within core sediments from the southeast coast of China. Palaeogeography, Palaeoclimatology, Palaeoecology 618, 111513.
[24].Lai, W.B., Liu, X.T.*, Tian, J.W., Wang, H.J., Zhang, J., Huang, J., Wan, S.M., 2023. Mineralogy of sediments in the Mariana Trench controlled by environmental conditions of the West Pacific since the Last Glacial Maximum. Journal of Asian Earth Sciences 245, 105553.
[25].Li, D.Y.*, Xu, X.Y, Liu, X.T.*, Cheng, H.G., Xu, S.J. Jiang. X.D., 2023. Grain size and geochemistry characteristics of Core S01-10 from the central Okinawa Trough since 14 ka: Indications for sediment source and the East Asian winter monsoon, Marine Geology 460, 107053.
[26].Zhang, M.Y., Liu, X.T.*, Xu, F.J.*, Li, A.C., Gu, Y., Chang, X., Zhuang, G.C., Zhang, K.D., Bi, N.S., Wang, H.J., 2023. Organic carbon deposition on the inner shelf of the East China Sea constrained by sea-level and climatic changes since the last deglaciation. Journal of Ocean University of China 22, 1300-1312.
[27].Hu, L.M.*, Ji, Y.H. Zhao, B., Liu, X.T., Du, J.Z., Liang, Y.T, Yao, P., 2023. The effect of iron on the preservation of organic carbon in marine sediments and its implications for carbon sequestration, Science China Earth Sciences 66, 1946-1959.
[28].Ma, Z.X., Wu, H.C., Hu, S.X., Fang, Q., Liu, X.T., Zhou, C.Y., Wen, W., Zhang, Q.Y, Huang, J.Y., Min, X., 2023. Temporal duration and preservation mechanism of the Middle Triassic Luoping biota from South China constrained by geochronology and cyclostratigraphy. Global and Planetary Change 229, 104254.
[29].Miao, X.M. Wei J.G.*, Liu, X.T., Qiao X.K., Li, J.R., 2023. The control of turbidite deposition on pyrite sulfur isotopic composition in sediments on the continental slope of the South China Sea. Marine Geology 465, 107163.
[30].Yan, T.H, Wang, H.J, Ai, L.N, Liu, X.T., Hu, L.M., Bi, N.S., Han, Z.Z., Wu, X.*, 2023. Sedimentary evolution of the western North Yellow Sea mud patch: A Holocene perspective, Continental Shelf Research 269, 105144.
[31].胡利民*, 季钰涵, 赵彬, 刘喜停, 杜佳宗, 梁彦韬, 姚鹏, 2023. 铁对海洋沉积有机碳保存的影响及其碳汇意义.中国科学: 地球科学53, 1967-1981.
2022年
[32].Liu, X.T.*, Zhang M.Y., Li A.C., Dong, J., Zhang, K.D., Gu Y., Chang, X., Zhuang, G.C., Li, Q., Wang, H.J., 2022. Sedimentary pyrites and C/S ratios of mud sediments on the East China Sea inner shelf indicate late Pleistocene-Holocene environmental evolution. Marine Geology 450, 106854.
[33].Chang, X., Liu, X.T.*, Wang H.J., Zhuang, G.C., Ma, Z.X., Yu, J.J., Chen, J.*, 2022. Depositional control on the sulfur content and isotope of sedimentary pyrite from the southeast coast of China since MIS5. Frontier in Marine Science 9, 1005663.
[34].Miao, X.M., Liu, X.T.*, Li., Q.*, Li, A., Cai, F., Kong, F.X., Zhuang, G.C., Wang, H.J., 2022. Porewater geochemistry indicates methane seepage in the Okinawa Trough and its implications for the ancient carbon cycle of the subtropical West Pacifica. Palaeogeography, Palaeoclimatology, Palaeoecology 607, 111266.
[35].Li, D.Y.*, Liu, X.T.*, Cheng, H.G., Liang, J., Xu, S.J., Dong, G., Li, C.Y., Jiang, X.D., 2022. Development of submarine canyons on the continental slope of the Okinawa Trough with potential origin related to methane seepage. Ore Geology Reviews 149, 105088.
[36].Dong, J., Shi, X.F.*, Gong, X.*, Astakhov, S.A., Hu, L.M., Liu, X.T., Yang, G., Wang, Y.X., Vasilenko, Y., Qiao, S.Q., Bosin, A., Lohmann, G., 2022. Enhanced Arctic sea ice melting controlled by larger heat discharge of Mid-Holocene rivers. Nature Communications 13, 5368.
[37].Mao, S.H., Zhang, H.H., Zhuang, G.C.*, Li, X.J., Liu, Q., Zhou, Z., Wang, W.L., Yang C., Lu, K.Y., Liu, X.T., Montgomery, A., Joye, B.S., Zhang, Y.Z., Yang. G.P.*, 2022. Aerobic oxidation of methane significantly reduces global diffusive methane emissions from shallow marine waters. Nature Communications 13, 7309
[38].Miao, X.M., Feng, X.L.*, Li, J.R., Liu, X.T., Liang, J.Q., Feng, J.X., Xiao, Q.W., Dan, X.P., Wei, J.G.*, 2022. Enrichment mechanism of trace elements in pyrite under methane seepage Geochemical Perspectives Letters 21, 18-22.
[39].Ma, Z.X.*, Hu, S.X., Wu, H.C., Liu, X.T., Zhou, C.Y., Wen, W., Zhang, Q.Y., Huang, J.Y., Min, X. 2022. High productivity promoted exceptional fossil preservation of the Luoping biota during the early Middle Triassic, South China. Palaeogeography, Palaeoclimatology, Palaeoecology 607, 111286.
[40].Xu, F.J., Hu, B.Q.*, Zhao, J.T., Liu, X.T., Cui, R.Y., Ding, X., Wang, G.F., Huang, J.P., 2022. Topographic and climatic control on chemical weathering of mountainous riverine sediments of Hainan Island, South China Sea. Frontiers in Earth Science 9, 770236.
[41].Miao, X.M., Feng, X.L.*, Hu, L.M., Li, J.R., Liu, X.T., Wang, N., Xiao, Q.W., Wei, J.G.*, 2022. Coupled δ15NTN and δ13CTOC insights into methane seepage activities in bulk marine sediments of the Qiongdongnan Basin, South China Sea. Journal of Ocean University of China 21, 1495-1503.
[42].谷玉, 刘喜停*, 吴晓, 王爱美, 毕乃双, 王厚杰, 2022. 山东半岛全新世泥质区近岸沉积过程与沉积记录. 古地理学报, 24, 164-179.
[43].袁媛, 庄光超*, 毛士海, 刘佳睿, 刘喜停, 杨桂朋, 2022. 海洋环境中乙烷和丙烷的分布及生物转化. 地球科学进展, 37, 370-381.
[44].董宏坤, 万世明*, 刘喜停, 2022. 海洋沉积物早期成岩作用研究进展. 沉积学报, 40, 1172-1187.
2021年
[45].Liu, X.T.*, Zhang M.Y., Li A.C., Fan, D.D., Dong, J., Jiao C.Q., Chang, X., Gu Y., Zhang, K.D., Wang, H.J., 2021. Depositional control on carbon and sulfur preservation onshore and offshore Oujiang Estuary: implications for C/S ratio as a salinity indicator. Continental Shelf Research 227, 104510.
[46].Xu, F.J., Dou, Y.G.*, Zhao, J.T., Li, J., Liu, X.T., Xu, K.H., Ca, F., Wen, Z.H., Chen, X.H., 2021. Low-latitude control on sea surface temperatures in the middle Okinawa Trough over the last 3.6 kyr. Geo-Marine Letters 41, 39.
[47].Miao, X.M., Feng, X.L.*, Liu, X.T., Li, J.R., Wei, J.G.*, 2021. Effects of methane seepage activity on the morphology and geochemistry of authigenic pyrite. Marine and Petroleum Geology 133, 105231.
[48].Zhang, K.D., Li A.C.*, Liu, X.T., Chen, M.T., Lu, J., Zhang, J., Wang, H.L., 2021. Heavy mineral record from the East China Sea inner shelf: implications for provenance and climate changes over the past 1500 years. Continental Shelf Research 226, 104488.
[49].Xu, F.J., Hu, B.Q.*, Zhao, J.T., Liu, X.T., Xu, K.H., Xiong, Z.F., Wang, F.F., Ding, X., Li, Q., Guo, J.W., 2021. Provenance and weathering of sediments in the deep basin of the northern South China Sea during the last 38 kyr. Marine Geology 440, 106602.
[50].Mao, S.H., Zhuang, G.C.*, Liu, X.W., Jin, N., Zhang, H.H.*, Montgomery, A., Liu, X.T., Yang, G.P., 2021. Seasonality of dimethylated sulfur compounds cycling in north China marginal seas. Marine Pollution Bulletin 170, 112635.
[51].Dong, J., Li, A.C.*, Lu, Z.Y.*, Liu, X.T., Wan, S.M., Yan, H., Yu, Z.J., Feng, X.J., Shi, X.F., 2021. Millennial-scale interaction between the East Asian winter monsoon and El Niñorelated tropical Pacific precipitation in the Holocene. Palaeogeography Palaeoclimatology, Palaeoecology 573, 110442.
[52].Ma, Z.X.*, Hu, S.X., Liu, X.T., Zhou, C.Y., Wen, W., Zhang, Q.Y., Huang, J.Y., Min, X., 2021. The link between exceptional fossil preservation and paleoredox conditions in the Middle Triassic Luoping Biota from South China. Geological Journal 56, 6231-6244.
[53].Wu, Y.C., Li, J.L., Wang, J., Zhuang, G.C., Liu, X.T., Zhang, H.H.*, Yang, G.P., 2021. Occurance, emission and environmental effects of non-methane hydrocarbons in the Yellow Sea and the East China Sea. Environmental Pollution 270, 116305.
[54].张明宇, 常鑫, 胡利民, 毕乃双, 王厚杰, 刘喜停*, 2021. 东海内陆架有机碳的源-汇过程及其沉积记录. 沉积学报, 39, 593-609.
[55].龚承林*,齐昆,徐杰,刘喜停,王英民,2021. 深水源—汇系统对多尺度气候变化的过程响应与反馈机制. 沉积学报 39, 231-252.
2020年
[56].Liu, X.T.*, Li, A.C.*, Fike, D., Dong, J., Xu, F.J., Zhuang, G.C., Fan, D.D., Yang, Z.S., Wang, H.J., 2020. Environmental evolution of the East China Sea inner shelf and its constraint on pyrite sulfur contents and isotopes since the last deglaciation. Marine Geology 429, 106307.
[57].Dong, J., Li, A.C*., Liu, X.T., Wan, S.M., Xu, F.J., Shi, X.F., 2020. Holocene climate enhances the spatial-temporal evolution of mud sediment on the East China Sea shelf. Journal of Geophysical Research: Earth Surface 125, e2020JF005731.
[58].Pei, W.Q., Wan, S.M.*, Clift, P. Dong, J., Liu, X.T., Lu, J., Tan, Y., Shi, X.F., Li, A.C., 2020. Human impact overwhelms long-term climate control of fire in the Yangtze River Basin since 3.0 ka BP. Quaternary Science Reviews 230, 106165.
[59].常鑫, 张明宇,谷玉, 王厚杰, 刘喜停*, 2020. 黄、东海陆架泥质区自生黄铁矿成因及其控制因素. 地球科学进展, 35, 1306-1320.
[60].刘喜停*, 李安春, 马志鑫, 董江, 张凯棣, 徐方建, 王厚杰, 2020. 沉积过程对自生黄铁矿硫同位素的约束. 沉积学报38, 124-137.
2019年
[61].Liu, X.T.*, Fike, D., Li, A.C.*, Dong, J., Xu, F.J., Zhuang, G.C., Rendle-Bühring, R., Wan, S.M., 2019. Pyrite sulfur isotopes constrained by sedimentation rates: Evidence from sediments on the East China Sea inner shelf since the late Pleistocene. Chemical Geology 505, 66-75.
[62].Ma, Z.X.*, Liu, X.T., Yu, W.C., Du, Y.S., Du, Q.D. 2019. Redox conditions and manganese metallogenesis in the Cryogenian Nanhua Basin: Insight from the basal Datangpo Formation of South China, Palaeogeography Palaeoclimatology Palaeoecology 529, 39-52.
[63].Zhang, K.D., Li, A.C.*, Huang, P., Lu, J., Liu, X.T., Zhang, J. 2019. Sedimentary responses to the cross-shelf transport of terrigenous material on the East China Sea continental shelf. Sedimentary Geology 384, 50-59.
[64].马志鑫, 罗茂金*, 刘喜停, 任京伟, 黄腾, 孙志明, 2019. 四川南江地区上震旦统灯影组混积层系特征及成因. 沉积与特提斯地质 39, 1-13.
2018年
[65].Liu, X.T.*, Li, A.C.*, Dong, J., Zhuang, G.C., Xu, F.J., Wan, S.M., 2018. Nonevaporative origin for gypsum in mud sediments from the East China Sea shelf. Marine Chemistry 205, 90-97.
[66].Liu, X.T.*, Rendle, R., Henrich, R., 2018. High-and low-latitude forcing of the East African climate since the LGM: Inferred from the elemental composition of marine sediments off Tanzania. Quaternary Science Reviews196, 124-136.
[67].Liu, X.T.*, Li, A.C., Dong, J., Lu, J., Huang, J., Wan, S.M., 2018. Provenance discrimination of sediments in the Zhejiang-Fujian mud belt, East China Sea: Implications for the development of the mud depocenter. Journal of Asian Earth Sciences 151, 1-15.
[68].Xu, F.J., Hu, B.Q.*, Dou, Y.G., Song, Z.J., Liu, X.T., Yuan S.Q., Sun, Z.L., Li, A.C., Yin, X.B., 2018. Prehistoric heavy metal pollution on the continental shelf off Hainan Island, South China Sea: From natural to anthropogenic impacts around 4.0 kyr BP. The Holocene 28, 455-463.
[69].Dong, J., Li, A.C.*, Liu, X.T., Wan, S.M., Feng, X.G., Lu, J., Pei, W.Q., Wang, H.L. 2018. Sea-level oscillations in the East China Sea and their implications for global seawater redistribution during 14.0-10.0 kyr BP. Palaeogeography Palaeoclimatology Palaeoecology 511, 298-308.
[70].马志鑫, 罗茂金*, 刘喜停, 孙志明, 2018. 四川南江坪河石墨矿碳质来源及成矿机制. 地质科技情报 37, 134-139.
[71].朱潇, 蒋富清*, 冯旭光, 董江, 刘喜停, 王红莉, 李安春, 2018. 菲律宾海沉积物中石英的来源及其搬运方式. 海洋与湖沼 49, 1190-1202.
[72].卢健, 李绍科, 李安春*, 刘喜停, 董江, 张晋, 2018. CT扫描方法在东海泥质沉积物孔隙度分析中的应用与对比. 海洋地质与第四纪地质 38, 198-207.
2017年
[73].Liu, X.T.*, Rendle-Bühring, R., Kuhlmann, H., Li, A.C., 2017. Two phases of the Holocene East African Humid Period: Inferred from the high-resolution geochemical record off Tanzania. Earth and Planetary Science Letters 460, 123-134.
[74].Liu, X.T.*, Rendle-Bühring, R., Henrich, R., 2017. Geochemical composition of Tanzanian shelf sediments indicates Holocene climatic and sea-level changes. Quaternary Research 87, 442-454.
[75].Sun, Y.D.*, Liu, X.T., Yan, J.X., Li, B., Chen, B., Bond, D., Joachimski, M., Wignall, P., Wang, X., Lai, X.L.*, 2017. Permian (Artinskian to Wuchapingian) conodont biostratigraphy in the Tieqiao section, Laibin area, South China. Palaeogeography Palaeoclimatology Palaeoecology 465, 42-63.
[76].Xu, F.J., Hu, B.Q.*, Dou, Y.G., Liu, X.T., Wan, S.M., Xu, Z.K., Tian, X., Liu, Z.Q., Yin, X.B., Li, A.C., 2017. Sediment provenance and paleoenvironmental changes in the northwestern shelf mud area of the South China Sea since the mid-Holocene. Continental Shelf Research 144, 21-30.
2016年
[77].Liu, X.T.*, Rendle-Bühring, R., Henrich, R., 2016. Climate and sea-level controls on turbidity current activity on the Tanzanian upper slope during the last deglaciation and the Holocene. Quaternary Science Reviews 133, 15-27.
[78].Liu, X.T.*, Rendle-Bühring, R., Meyer, I., Henrich, R., 2016. Holocene shelf sedimentation patterns off equatorial East Africa constrained by climatic and sea-level changes. Sedimentary Geology 331, 1-11.
[79].Huang, J.*, Wan, S.M., Xiong, Z.F., Zhao, D.B., Liu, X.T., Li, A.C., Li, T.G., 2016. Geochemical records of Taiwan-sourced sediments in the South China Sea linked to Holocene climate changes. Palaeogeography Palaeoclimatology Palaeoecology 441, 871-881.
[80].马志鑫*, 罗亮, 刘喜停, 刘伟, 孙志明, 2016. 重庆秀山小茶园锰矿南华纪大塘坡组古环境条件分析. 古地理学报 18, 473-486.
2015年以前
[81].Liu, X.T., Yan, J.X.*, Xue, W.Q., Ma, Z.X., Li, B., 2014. The geobiological formation process of the marine source rocks in the Middle Permian Chihsia Formation of South China. Science China: Earth Sciences 57, 957-964.
[82].刘喜停, 颜佳新*, 马志鑫, 薛武强, 2014. 华南栖霞组灰岩-泥灰岩韵律层的成因. 地球科学:中国地质大学学报, 39, 155-164.
[83].刘喜停, 颜佳新*, 薛武强, 马志鑫, 李波, 2014. 华南中二叠统栖霞组海相烃源岩形成的地球生物学过程. 中国科学: 地球科学 44, 1185-1192.
[84].刘喜停, 颜佳新*, 薛武强, 2012. 灰岩-泥灰岩韵律层的差异成岩作用. 地质论评 58, 627-635.
[85].刘喜停, 颜佳新*, 2011. 铁元素对海相沉积物早期成岩作用的影响. 地球科学进展 26, 482-492.
[86].刘喜停, 马志鑫, 颜佳新*, 2010. 扬子地区晚二叠世吴家坪期沉积环境及烃源岩发育的控制因素. 古地理学报 12, 244-252.
[87].刘喜停, 颜佳新*, 2009. 海水化学演化对生物矿化的影响综述. 古地理学报 11, 446-454.
[88].李波, 颜佳新*, 刘喜停, 薛武强, 2010. 白云岩有机成因模式: 机制, 进展与意义. 古地理学报 12, 699-710.
[89].薛武强, 刘喜停, 颜佳新*, 马志鑫, 2015. 重庆南川地区中二叠统茅口组眼球状灰岩成因. 地质科学 50, 1001-1013.
[90].马志鑫*, 罗亮, 李波, 刘喜停, 2015. 黔东下寒武统清虚洞组地球化学特征及其对沉积环境演化的指示. 地质科技情报 34, 71-77.