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姓名 彭澎 性别:
职称 研究员 学历 博士
电话 010-82998530 传真: 010-62010846
Email: pengpengwj@mail.iggcas.ac.cn 邮编: 100029
地址 北京朝阳区北土城西路19号,中科院地质地球所
更多信息:
 
简历:

  彭澎,男,湖南益阳人,博士,博士生导师,研究员,中国科学院大学岗位教授。1996年毕业于益阳县一中(先后更名为益阳市第十一中学、箴言中学);2000年毕业于北京大学地质学系,获构造地质学学士学位;2005年毕业于中国科学院地质与地球物理研究所,获矿物学岩石学矿床学博士学位。主要从事前寒武纪地质学和岩石学领域的研究和教学工作。对早期大陆地壳形成与演化,前寒武纪构造体制及其浅层响应机制,早期地球环境,超大陆演化等研究方向感兴趣。开展《超大陆与全球演化》、《岩石学》、《大陆地壳演化》、《地球化学分析技术》、《野外地质实习》等课程教学工作。担任《岩石学报》(编委)、《大地构造与成矿》(编委)、Island Arc(AE)、JMPS(AE)、Precambrian Research(EBM)、EE(EBM)等期刊编委、前寒武地质专业委员会委员、中国金属学会冶金地质分会委员。第十二届全国青联委员、第五届中国青年科技工作者协会理事。作为客邀(联合)主编,在ESR、PR、岩石学报、地质科学等期刊组织专辑。获国家自然科学二等奖(排名第三,2013)、“孙贤鉥奖”(2014)、“朱李月华优秀教师奖”(2018)等;获得国家优秀青年基金、国家杰出青年科学基金、特支计划等项目资助。

中国科学院地质与地球物理研究所前寒武纪地质学/矿物学、岩石学、矿床学博士 (2000.7-2005.6)
北京大学构造地质学学士 (1996.7-2000.7)

中国科学院地质与地球物理研究所博士后 (2005.6)、副研究员 (2007.12)、研究员 (2012.12)
加拿大地质调查局访问学者 (2009.3-2009.9)
西澳大学访问教授 (2013.9-2014.3)

中国科学院大学教师主页

 
研究方向:
  • 前寒武纪地质学
  • 岩浆岩岩石学
  • 岩墙群、火山岩系和大岩浆岩省
  • 早期板块构造的浅层响应机制
  • 超大陆重建
  • 华北克拉通重大地质事件与成矿
 
学科类别:
地质学
 
职务:
 
社会任职:
 
获奖及荣誉:

中国科学院大学地球与行星科学学院 杰出贡献教师(2023)"朱李月华优秀教师奖"(2018)
"孙贤鉥奖"(Shen-su Sun Award)(2014颁奖辞答谢辞
"中央国家机关青年岗位能手"(2014)
国家自然科学二等奖(排名第三,2013)
中国科学院"卢嘉锡青年人才奖"(2012)
中国科学院"科教结合"教育创新项目教学贡献奖(2011)
中国地质学会第十二届"青年地质科技奖-银锤奖"(2010)
中国科学院"刘永龄特别奖"(2004) 

中国科学院青年创新促进会首批会员(2011)、首批优秀会员(2015)
国家自然科学基金委优秀青年基金获得者(2013)
国家自然科学基金委国家杰出青年科学基金获得者(2021)

 
承担科研项目情况:

主要从事前寒武纪地质学和岩浆岩岩石学领域的研究和教学工作。对早期大陆地壳形成与演化,早期板块构造的前寒武纪构造体制及其浅层响应机制,超大陆重建等研究方向感兴趣。


中国-巴西联合地学研究中心:
定位:面向世界科技前沿,服务国家和中国科学院科技合作,以中巴互补的地质记录为核心对象,以前寒武纪构造体制及其浅层响应机制为主攻方向,探索地球早期演化和宜居地球的形成,推动与相关国家的国际交流合作与科学社会发展。
中心主任:彭澎
联合主任:Wilson Teixeira院士;Farid Chemale Junior院士


固体同位素实验室
实验室致力于发展基于热电离质谱技术(ID-TIMS)的微量-高精度同位素分析方法,拓展同位素分析技术应用领域,支撑地球早期过程、大陆形成演化与成矿、大陆/大洋岩石圈演化与壳幔相互作用、造山带构造演化、表生环境演化、比较行星学等领域的学科发展与科技创新。
实验室主任:彭澎


前寒武纪地质学科组
面向地球科学前沿,以前寒武纪地质学,尤其是大陆岩石圈的形成演化和早期板块构造的建立发展为主攻方向,以板块体制建立关键期的深部圈层演变及其浅层响应机制为切入点,以地球早期演化和宜居地球的形成为科学目标,推动前寒武纪大数据和同位素平台建设,推动大陆地壳形成演化动力学、地球早期表生环境演化、超大陆启动与演化等方向的发展。
学科组长:彭澎

研究生招生:每年招收有志于从事前寒武纪地质学或者岩浆岩岩石学研究的硕士和博士研究生各1名(2022-2023年无计划)。

博士后招聘:2023-2027年引进博士后2-3名。招聘热爱科学事业的青年研究人员。优先合作方向:沉积地球化学、环境地球化学、超大陆重建。

博士后:

刘嘉惠博士
在站博士后
合作导师:郭敬辉研究员(一导)、彭澎研究员
毕业学校:中国科学院大学
毕业时间:2022年6月
入所时间:2022年8月
研究方向:变质岩石学与前寒武纪地质学
合作项目:变质地质大数据研究
联系方式:
liujiahui16@mails.ucas.ac.cn


王冲博士
在站博士后,合作导师:彭澎研究员、邓成龙研究员
毕业学校:本所
毕业时间:2019年6月
入所时间:2019年7月
出站时间:2023年1月8日
出站报告题目:巨大陆的识别及对超大陆旋回动力学的启示
就业情况:本所特聘副研究员
研究方向:古地磁学与前寒武纪地质学
合作项目:元古宙超大陆重建
联系方式:
wangchong@mail.iggcas.ac.cn

张京博士
在站博士后
毕业学校:英国杜伦大学
毕业时间:2016年6月
入所时间:2016年8月
出站时间:2018年8月
研究方向:火山学、矿物学与地球化学
合作项目:矿物环带化学成分精细剖析与开放体系岩浆活动重建
联系方式:
jing.zhang@mail.iggcas.ac.cn

毕业研究生:

李云
硕士
2011年7月入学,2014年6月毕业
研究方向:大型基性岩墙群和超大陆重建
硕士论文:华北1800-1600 Ma基性岩墙群对比研究:以鲁西为例
答辩日期:2014年5月30日
E-mail:
liyun110cug@sina.com

王冲
硕士、博士
2013年7月入学,2016年6月/2019年6月毕业
研究方向:大型基性岩墙群和超大陆重建
硕士论文:燕辽裂谷地球中年期(1.7~0.75 Ga)构造背景:来自冀东基性岩墙群的证据
答辩日期:2016年5月20日
博士论文:华北克拉通在奴那/哥伦比亚超大陆中的位置:古地磁及地质对比综合约束
导师:彭澎研究员、李正祥教授
答辩日期:2019年6月2日
目前去向:博士后
E-mail:
wangchongrongr@163.com

王欣平
博士
2012年7月入学,2014年7月转博,2017年7月毕业
研究方向:前寒武纪岩浆活动与构造体制
博士论文:华北辽东地区21-19亿年岩浆作用的岩石成因及构造背景研究
答辩时间:2017年5月27日10:00(地6楼4层中厅会议室)
目前去向:山西师范大学
E-mail:
wangxinping8@gmail.com

杨书艳
硕士
2014年7月入学,2017年7月毕业
研究方向:大型基性岩墙群和超大陆重建(太行岩墙群成因)
硕士论文:1780 Ma太行岩墙群和熊耳火山岩系的成因关系:以吕梁地区为例
答辩时间:2017年5月27日11:00(地6楼4层中厅会议室)
目前去向:顺义区地震局
E-mail:
yangshuyan14@mails.ucas.ac.cn

孙风波
博士
2016年7月入学,2020年1月毕业
研究方向:大型基性岩墙群与超大陆重建(沉积地质学)
博士论文:徐淮盆地中-新元古界沉积演化及其对华北克拉通东南缘古构造格局的指示
指导教师:彭澎研究员、周锡强副研究员
答辩日期:2019年12月5日
目前去向:河南理工大学
E-mail:
sunfengbonnn@126.com

苏向东
博士
2015年6月入学,2017年7月转博,2020年毕业
研究方向:富铁辉长岩/玄武岩成因
博士论文:945-900 Ma徐淮高铁钛岩床群的成因及其对华北克拉通东南缘裂谷演化的启示
指导教师:彭澎研究员
答辩日期:2020年5月27日
目前去向:郑州大学
E-mail:
xiangdongsu@163.com

张志越
博士
2016年7月入学, 2018年7月转博,2021年毕业
研究方向:大型基性岩墙群和超大陆重建(新元古代沉积环境分析)
博士论文:大连盆地新元古界化学地层学及其古环境/古气候指示意义
指导教师:彭澎研究员;副导师:冯连君高级工程师、Ross N Mitchell研究员
答辩日期:2021年5月25日
E-mail:
zhangzhiyue16@mails.ucas.ac.cn

周小童
博士
2016年7月入学,2021年毕业
研究方向:开放体系岩浆作用过程
博士论文:斜长石斑晶示踪开放体系岩浆过程:以拉明顿火山为例
指导教师:彭澎研究员;副导师:张京博士
答辩日期:2021年5月25日
E-mail:
zhouxiaotong16@mails.ucas.ac.cn

康健丽
博士研究生(在职)
2020年9月入学
研究方向:早期板块构造阶段深部过程与浅层响应机制
博士论文:华北云中地区多期次岩浆事件的成因及其对古元古代构造环境转换演化的启示
答辩时间:2024年5月20日
E-mail:
kangjianliww@126.com

在读研究生(按年级/姓氏拼音为序):
博士研究生:

李润
硕转博研究生
2020年9月入学,2022年4月转博
指导教师:周锡强副研究员(一导)、彭澎研究员
研究方向:埃迪卡拉纪古海洋碳循环
E-mail:
18801167381@163.com

徐毕升
硕士研究生
2022年7月入学
研究方向:岩浆岩岩石学方向(层侵纪岩浆作用成因)
E-mail:
xubisheng22@mails.ucas.ac.cn

李冰荷
直博生
2022年7月入学
研究方向:岩石成因地球化学方向(大型基性岩墙群的起源与演化)
E-mail:
libinghe22@mails.ucas.ac.cn

秦照原
博士研究生
2017年7月入学
2019年7月转博
研究方向:岩浆岩微观结构、微区成分变异与岩浆过程
E-mail:
qinzhaoyuan17@mails.ucas.ac.cn

刘旭
直博生
2019年7月入学
研究方向:碱性岩的岩石成因及其环境效应
指导教师:彭澎研究员(一导)、Ross N Mitchell研究员
E-mail:
liuxu@mail.iggcas.ac.cn

戴克
直博生
2021年9月入学(生源:中国地质大学(武汉))
研究方向:前寒武纪沉积环境
指导教师:彭澎研究员(一导)、周锡强副研究员
E-mail:
daike21@mails.ucas.ac.cn

刘玉书
博士研究生
2023年9月入学,兰州大学(本科),中山大学(硕士)
研究方向:岩浆岩古地磁研究、超大陆重建与真极移
指导老师:Ross N Mitchell研究员(一导)、彭澎研究员
E-mail:
liuyushu23@mails.ucas.ac.cn

本科生:
南京大学 地空学院:
2013级:王凯、徐鹏霄、严圳、岳行知、赵鑫昊

中国地质大学(武汉)李四光学院
2012级:张志越(2016年转为研究生)
2013级:王浩
2015级:刘旭(2019年转为直博生)

成都理工大学 地球科学学院:
2013级:秦照原(2017年转为研究生)

 
代表论著:

2024

  1. Kang, J.-L., Peng, P.*, Wang, H., Liu, X., Xiao, Z., Wang, X., Liu, J., Wang, C., 2024. Continental subduction in Paleoproterozoic: Insights from ∼1.9 Ga nepheline syenite in the North China craton. Precambrian Research 404, 108346 https://doi.org/10.1016/j.precamres.2024.107346
  2. 康健丽, 彭澎, 王慧初, 任云伟. 2024. 山西云中山地区~2.53 Ga碱性花岗岩的成因和地质意义[Petrogenesis and geological implications of the ~2.53 Ga alkaline granites in Yunzhong Mts, Shanxi]. 岩石学报 404(11): 3448-3464. https://doi.org/10.18654/1000-0569/2024.11.07  
  3.  Sun, F., Wu, Y., Zhao, T., Zheng, D.*, Peng, P.*, 2024. Detrital zircon geochronology and whole-rock geochemistry of the 1.8–1.7 Ga Xiong’er volcanic-sedimentary succession in the southern North China craton and their implications for basin evolution. Precambrian Research 414: 107608. https://doi.org/10.1016/j.precamres.2024.107608
  4.  Shang, G., Zhai, M. *, Peng, P., Miao, P., Li, Q., 2024. A climate change from icehouse to greenhouse following Huronian glaciation: Evidence from long-term storm deposits of the Paleoproterozoic Hutuo Group in the North China Craton. Journal of Asian Earth Sciences 274: 106289. https://doi.org/10.1016/j.jseaes.2024.106289
  5.  Li, R., Zhou, X. *, Eddy, M.P., Ickert, R.B., Wang, Z., Tang, D., Huang, K.-J., Peng, P., 2024. Stratigraphic evidence for a major unconformity within the Ediacaran System. Earth and Planetary Science Letters 636: 118715. https://doi.org/10.1016/j.epsl.2024.118715
  6.  Liu, Y.S., Mitchell, R.N.*, Bleeker, W., Peng, P., Salminen, J., Evans, D.A.D., 2024. Conformably Variable Geocentric Axial Dipole at ca. 2.1 Ga: Paleomagnetic Dispersion of the Indin Dyke Swarm, Slave Craton. Journal of Geophysical Research: Solid Earth 129: e2024JB029046
  7. Li, C.F. *, Chu, Z.Y., Peng, P., 2024. Precise Determination of Cd Isotope Ratios at 3-10 ng Level by Thermal Ionization Mass Spectrometry Using a Molybdenum Silicide Emitter. Anal Chem., 96, 15436−15445. https://doi.org/10.1021/acs.analchem.4c03362
  8.  Zou, A.P., Chu, Z.-Y.*, Wang, M.-J., Peng, P, 2024. An improved chromatographic method for separation of Re and PGE mass fractions in organic-ich  geological samples. J. Anal. At. Spectrom. 39: 1405-1416
  9. 龙晓平, 赵国春, 翟明国, 郭敬辉, 初航, 彭澎, 张少兵, 尹常青. 2024. 前板块构造与大陆起源研究进展及关键 科学问题. 科学通报 69 (12): 1572-1585.
  10.  梅清风, 杨进辉, 孙金凤, 李秋立, 吴石头, 凌潇潇, 彭澎, 王浩. 2024. Acasta片麻杂岩多期次热事件:来自锆石,榍石和磷灰石的原位微区年代学证据. 中国科学:地球科学 54 (03) :  693-707. Mei QF, Yang JH, Sun JF, Li QL, WU ST, Ling XX, Peng P, Wang H, 2024. Multiple thermal events recorded in the Acasta Gneiss Complex: Evidence from in-situ dating of zircon, titanite, and apatite. Science China Earth Sciences 267(67): 673-686.
  11. Li, C.-F.*, Wang, X.-C., Chu, Z.-Y., Peng, P., 2024. A low-cost and high precision determination method of 87Sr/86Sr ratios for red wine using thermal ionization mass spectrometry without column separation. Journal of Analytical Atomic Spectrometry 39, 235-243.
  12.  Liou, P. *, Caro, G., Cui, X., Li, C., Peng, P., Guo, J., Zhai, M., 2024a. Long-term isolation of Hadean mantle domains revealed from coupled 147-146Sm-143-142Nd systematics in the eastern North China Craton. Earth and Planetary Science Letters 638: 118761. https://doi.org/10.1016/j.epsl.2024.118761
  13. Kang, J.L., Zhai, M., Guo, J., Wang, H., Zhou, Y., Zhao, L., Liou, P., Peng, P. *, 2024. Continental crust and general tectonic framework of the North China Craton: a synopsis, in: Zhai, M.G., Peng, P., Zhou, Y.Y., Zhao, L. (eds), Early Continent Evolution of the North China Craton, pp. 1-43. https://doi.org/10.1016/B978-0-443-13889-8.00008-5
  14.  Liou, P. *, He, H., Guo, J., Peng, P., Zhai, M., 2024b. Mesoarchean continental growth and evolution in the North China craton, in: Zhai, M.G., Peng, P., Zhou, Y.Y., Zhao, L. (eds), Early Continent Evolution of the North China Craton, pp. 105-134. https://doi.org/10.1016/B978-0-443-13889-8.00009-7
  15. Zhai, MG, Peng, P, Zhou, YY,  Zhao, L. 2024. Early Continent Evolution of the North China Craton. Elsevier, https://doi.org/10.1016/C2022-0-02935-4; Paperback ISBN: 9780443138898. eBook ISBN: 9780443138881
  16.  Zhao, G., Li, X., Peng, P., Wang, J., 2024. Early plate tectonics and evolution of continental crust in the North China craton: Editorial preface. Earth-Science Reviews 252, 104748. https://doi.org/10.1016/j.earscirev.2024.104748 https://www.sciencedirect.com/journal/earth-science-reviews/special-issue/1004P9S4HZR

2023

  1. Mitchell R., Feng L., Zhang Z., Peng P, 2023. Carbonate–organic decoupling during the first Neoproterozoic carbon isotope excursion. The Innovation Geoscience 1(3), 100046. https://doi.org/10.59717/j.xinn-geo.2023.100046
  2. Liu, X., Peng, P.*, Mitchell, R. N.*, Wang, C., Kang, J., 2023. Circum-cratonic Triassic syenite province of North China craton reveals heterogeneous lithospheric mantle related to dual subduction. Journal of Geophysical Research: Solid Earth, 128, e2023JB027084. https://doi.org/10.1029/2023JB027084
  3. Liou, P.*, Guo, J., Peng, P. & Zhai, M., 2023 Geological evolution of the North China Craton in the first billion years of Earth's history. Earth-Science Reviews https://doi.org:10.1016/j.earscirev.2023.104608
  4. Cho, D.-L.#, Peng, P.*#, Hwan Lee, S., Park, J.-Y., Seo, I., Sun, F., Li, Q., and Zhang, Y., 2023 Identify vestiges of large igneous provinces in deep time: A 0.9 Ga case from North China (Sino-Korean) craton. Precambrian Research 398: 107220 https://doi.org:10.1016/j.precamres.2023.107220
  5. Chu, Z.*, Qiu, Y., Zhou, X., Yang, X., Peng, P., Zhao, T., Xu, J., 2023. Re-Os, Sr-Nd isotopic and PGE elemental constraints for the formation of mid-Proterozoic ironstones in North China Craton: Implications for the atmospheric oxygen level. Earth and Planetary Science Letters 621, 118367. https://doi.org/10.1016/j.epsl.2023.118367
  6. Li, C.-F.*, Chu, Z.-Y., Peng, P., 2023. Low-cost and sensitive method for Pb isotope determination using a novel β-Si3N4 emitter by thermal ionization mass spectrometry. Talanta 257: 124390. https://doi.org/10.1016/j.talanta.2023.124390
  7. 王欣平,* 彭澎, 李小兵. 2023. 华北克拉通五台山~2520 Ma辉长岩侵入体的成因及其地质意义[Petrogenesis and geological implications of the ca. 2520Ma gabbroic intrusions in Wutai Mountain of the North China Craton]. 岩石学报 39(3): 845-864.
  8. Peng, P.*, Liu, X., Feng, L., Zhou, X., Kuang, H., Liu, Y., Kang, J., Wang, X., Wang, C., Dai, K., Wang, H., Li, J., Miao, P., Guo, J., Zhai, M., 2023. Rhyacian intermittent large igneous provinces sustained Great Oxidation Event: Evidence from North China craton. Earth-Science Reviews 238: 104352. https://doi.org/10.1016/j.earscirev.2023.104352
  9. 张拴宏*, 彭澎. 2023. 元古宙大火成岩省与超大陆重建及古环境. 科学通报 68: 2324–2340. Zhang S H, Peng P. 2023. Proterozoic large igneous provinces and implications for paleogeographic and paleoenvironmental reconstructions. China Science Bulletin 68: 2324–2340. (in Chinese with English abstract). https://doi.org/10.1360/TB-2021-1355

2022

  1. Peng P, Su X, Wang C & Liu X. 2022 Role of Large Igneous Provinces in Lithospheric Mantle Evolution: A Case Study in North China. Goldschmidt 2022 Abstract: https://doi.org/10.46427/gold2022.13025
  2. Hu YY(胡悠扬), Zhao XX*, Peng P, Yang FL*, Yuan W, Chen WW, Xu MC. 2022. Paleogeography of Rodinia at 925 Ma: Constraints From New Paleomagnetic Results From Mafic Dykes in North China and Brazil. Journal of Geophysical Research: Solid Earth https://doi.org/10.1029/2022JB025079
  3. Su, X.*(苏向东), Wang, G., Peng, P., and Tang, Y., 2022, Keel of the eastern North China craton weakened by Proterozoic large igneous provinces: International Geology Review https://doi.org/10.1080/00206814.2022.2059709
  4. Peng, P.*, Mitchell, R. N.*, and Chen, Y., 2022, Earth's one-of-a-kind fault: The Tanlu fault. Terra Nova 34, 381-394: https://doi.org/10.1111/ter.12611 https://doi.org/10.1111/ter.12620
  5. Zhang, Y.-B.*(张艳斌), Wan, B., Wu, F.-Y., Zhai, M.-G., Wang, T., Zhang, X.-H., Li, Q.-L., Peng, P. and Hou, Q.-L., 2022. Late Cretaceous-early Paleogene magmatism in the Gyeongsang basin, southeast Korea and its implications for middle Paleogene climate change. Journal of Asian Earth Sciences 237, 105346. https://doi.org/10.1016/j.jseaes.2022.105346
  6. Peng, P.*, Xu, H., Mitchell, R.N.*, Teixeira, W., Kirscher, U., Qin, Z., Oliveira, E.P., Girardi, V.A.V., Wang, C., Chemale, F., 2022. Earth's oldest hotspot track at ca.1.8 Ga advected by a global subduction system. Earth and Planetary Science Letters 585.117530 https://dx.doi.org/10.1016/j.epsl.2022.117530
  7. Peng, P.*, Abu Anbar, M.M., He, X.-F., Liu, X., Qin, Z., 2022. Cryogenian accretion of the Northern Arabian-Nubian shield: Integrated evidence from central Eastern Desert Egypt. Precambrian Research 371,106599. https://dx.doi.org/10.1016/j.precamres.2022.106599
  8. Liou, P.*(刘鹏), Guo, J., Peng, P., Mitchell, R. N., Jiang, N., Zhai, M., and Mao, M., 2022, Crustal growth of the north china craton at ca. 2.5 Ga: Science Bulletin 67(15): 1553-1555. https://doi.org/10.1016/j.scib.2022.06.002
  9. Sun, F.(孙风波), Peng, P., Zheng, D.*, Zuo, P., 2022. Reappraising the provenance of Early Neoproterozoic strata in the Southern-Southeastern North China Craton and its implication for paleogeographic reconstruction. Minerals 12, 510. https://doi.org/10.3390/min12050510
  10. Wang, C.(王冲), Peng, P., Mitchell, R.N., & Liu,X. 2022. Casting a vote for shifting the Statherian: Petrogenesis of 1.70 and 1.62?Ga mafic dykes in the North China Craton. Lithos 414-415, 106631. https://dx.doi.org/10.1016/j.lithos.2022.106631
  11. Wang, X. P., Peng, P., and Wang, C., 2022, A new 1.32 Ga Tianshui mafic sill in the Liaodong area and its relations to the Yanliao large igneous province in the northern North China Craton: Precambrian Research 369: 106535. https://doi.org/10.1016/j.precamres.2021.106535
  12. Peng P*, Xu HR, Wang C, Su XD, Sun FB, Wang XP, 2022. Spatiotemporal evolution of large igneous provinces and their related rifts in North China craton: Role in craton breakup and destruction. Geological Society, London, Special Publications. SP518: SP518-2021-45. http://dx.doi.org/10.1144/SP518-2021-45

2021

  1. Zhou XT(周小童), Peng P*, Zhang J, Wang C, 2021. In-situ chemistry of plagioclase and amphibole phenocrysts of Mt. Lamington volcano in Papua New Guinea: Evidence for influence of Woodlark spreading ridge to Papuan arc. Lithos 396–397: 106242. https://doi.org/10.1016/j.lithos.2021.106242
  2. Zhao L*, Zhai MG, Zhang XH, Zhang YB, Peng P, Li QL, 2021. A brief review of the Precambrian geology of the northern Korean Peninsula. Journal of the Geological Society of Korea 57(4): 437-466.
  3. Zhang YB*, Zhai MG, Wu FY, Zhang XH, Li QL, Peng P, Zhao L, Zhou LG, 2021. Reviews on the Paleozoic-Mesozoic granitoids and sedimentary rocks in North Korea. Journal of the Geological Society of Korea 57(4): 523-544.
  4. 王洛娟, 郭敬辉, 彭澎. 2021. 华北克拉通孔兹岩带古元古代凉城石榴石花岗岩成因机制及其岩石学意义 [Petrogenesis of Paleoproterozoic Liangcheng garnet granitoids in the Khondalite Belt, North China Craton]. 岩石学报 37(2): 375-390. https://doi.org/10.18654/1000-0569/2021.02.04
  5. Zhang Y-B, Zhai MG, Wu FY, Zhang XH, Li QL, Peng P, Zhao L, Zhou LG, 2021. In situ zircon U-Pb dating of Jurassic granitoids in North Korea and its tectonic implications. Lithos 398–399: 106346. https://doi.org/10.1016/j.lithos.2021.106346
  6. Wang C(王冲), Mitchell R, Murphy JB, Peng P, Spencer CJ, 2021. The role of superblocks megacontinents in the supercontinent cycle. Geology, 49: https://doi.org/10.1130/G47988.1.
  7. Zhai MG, Zhao L, Zhu XY, Peng P, Guo JH, Li QL, Zhao TP, Lu JS, Li XH, 2021. Late Neoarchean magmatic-metamorphic event and crustal stabilization in the North China craton. American Journal of Science 321: 206-234
  8. 彭澎*, 胡波*, 张志越, 张艳斌, 郭敬辉, 翟明国. 2021. 朝鲜半岛平南盆地地质演化综述[Review on geological evolution of the Pyongnam basin in Korean peninsula]. 岩石学报, 37(1): 129-142.
  9. Zhang ZY(张志越), Peng P*, Feng LJ, Gong Z, Mitchell RN*, Li YL, 2021. Oldest-known Neoproterozoic carbon isotope excursion: Earlier onset of Neoproterozoic carbon cycle volatility. Gondwana Res 94 1-11. https://doi.org/10.1016/j.gr.2021.01.013.
  10. 王芳*, 彭澎, 陈超, 胡洪飞, 黄冬琴, 陈福坤, 翟明国. 2021. 冀北独石口古元古代变辉长闪长岩的成因及其地质意义[Petrogenesis and geological significance of the Paleoproterozoic Dushikou metagabbro-diorite in northern Hebei province]. 岩石学报, 37(1): 269-183.
  11. Su XD(苏向东), Peng P*, Foley S, Teixeira W, Zhai M-G, 2021. Initiation of continental breakup documented in evolution of the magma plumbing system of the ca. 925?Ma Dashigou large igneous province, North China. Lithos 384–385, 105984. DOI: 10.1016/j.lithos.2021.105984
  12. Zhang XH*, Yang ZL, Zhang YB, Zhai MG, Wu FY, Peng P, Li QL, Hou QL, 2021. Paleoproterozoic Orosirian tectono-thermal events in the Nangrim Massif, North Korea: Cratonic and supercontinental connection. Lithos 384–385, 105983. https://doi.org/10.1016/j.lithos.2021.105983.

2020

  1. 林伟、彭澎、周锡强、郭敬辉、陈代钊 等著,华北克拉通形成与破坏野外地质实习指南. 科学出版社 2020,ISBN 978-7-03-066222-4.
  2. 朱日祥 等著. 2020. 华北克拉通破坏. 北京:科学出版社. 参与撰写
  3. Wang XP, Oh CW, Peng P, Zhao L, Zhai MG, Lee SH, 2020. Petrogenesis of ~2.1?Ga mafic and granitic magmatism and tectonic implication of Jiaobei Terrane in North China Craton. Lithos 378-379: 105806. https://doi.org/10.1016/j.lithos.2020.105806
  4. 刘博, 翟明国, 彭澎, 郭敬辉, 刘鹏. 2020. 大数据驱动下变质岩岩石学研究展望. 高校地质学报 26(4): 411-423.
  5. Xu HR(徐慧茹), Yang T, Dekkers MJ, Peng P, Li SH, Deng CL, Zhu RX, 2020. Magma flow pattern of the 1.78 Ga dyke swarm of the North China Craton during the initial assembly of the Supercontinent Nuna/Columbia: Constraints from rock magnetic and anisotropy of magnetic susceptibility studies. Precambrian Research 345, 105773. https://doi.org/10.1016/j.precamres.2020.105773
  6. Wang C(王冲), Peng P, Li ZX, Pisarevsky S, Denyszyn S, Liu YB, El Dien HG, Su XD, The 1.24–1.21 Ga Licheng Large Igneous Province in the North China Craton: Implications for Paleogeographic Reconstruction. JGR Solid Earth 125(4), e2019JB019005. https://doi.org/10.1029/2019JB019005
  7. Wang XP(王欣平), Oh CW, Peng P, Zhai MG, Wang XH, Lee BY, 2020. Distribution pattern of age and geochemistry of 2.18–2.14 Ga I- and A-type granites and their implication for the tectonics of the Liao-Ji belt in the North China Craton. Lithos 364-365: 105518. https://doi.org/10.1016/j.lithos.2020.105518
  8. Zhai MG*, Peng P*, 2020. Origin of early continents and beginning of plate tectonics. Science Bulletin 5(2): 970-973 https://doi.org/10.1016/j.scib.2020.03.022
  9. Mei QF(梅清风), Yang JH, Wang YF, Wang H, Peng P, 2020. Tungsten isotopic constraints on homogenization of the Archean silicate Earth: Implications for the transition of tectonic regimes. Geochimica et Cosmochimica Acta, 278: 51-64. https://doi.org/10.1016/j.gca.2019.07.050
  10. Su XD (苏向东), Peng P*, Zhu RZ, Mao YJ, Zhang ZY, Sun FB, 2020. Multi-stage evolution of the Xuhuai rift: Insights from the occurrence and compositional profiles of doleritic sills in the southeastern margin of the North China Craton. Gondwana Research 82:221-240. https://doi.org/10.1016/j.gr.2020.01.003
  11. Sun FB, Peng P*, Zhou XQ, Magalhaes AJC, Guadagnin F, Zhou XT, Zhang ZY, Su XD, 2020. Provenance analysis of the late Mesoproterozoic to early Neoproterozoic Xuhuai Basin in the southeast North China Craton: Implications for paleogeographic reconstruction. Precambrian Research 337: 105554. https://doi.org/10.1016/j.precamres.2019.105554

2019

  1. Zhai MG*, Zhang XH, Zhang YB, Wu FY, Peng P, Li QL, Li Z, Guo JH, Li TS, Zhao L, Zhou LG, Zhu XY. 2019. The geology of North Korea: An overview. Earth Science Reviews, 194: 57-96. https://doi.org/10.1016/j.earscirev.2019.04.025
  2. Peng P*, Qin ZY, Sun FB, Zhou XT, Guo JH, Zhai MG, Ernst RE, 2019. Nature of charnockite and Closepet granite in the Dharwar Craton: Implications for the architecture of the Archean crust. Precambrian Research 334: 105478. https://doi.org/10.1016/j.precamres.2019.105478
  3. Peng P*, Ernst R, Soderlund U, Hamilton M, 2019. Dyke Swarms: Keys for Precambrian Paleogeographic Reconstruction – Proceedings of the Seventh International Dyke Conference. Precambrian Research 329, 1-4. https://doi.org/10.1016/j.precamres.2019.01.002
  4. Wang C*(王冲), Li ZX, Peng P, Pisarevsky S, Liu YB, Kirscher U, Nordsvan A, 2019. Long-lived connection between the North China and North Australian cratons in supercontinent Nuna: paleomagnetic and geological constraints. Science Bulletin 64: 873–876. https://doi.org/10.1016/j.scib.2019.04.028
  5. Lee BY, Oh CW*, Cho DL, Zhai MG, Lee BC, Peng P, Yi K, 2019. The Devonian back-arc basin and Triassic arc-continent collision along the Imjingang belt in the Korean Peninsula and their tectonic meaning. Lithos 328-329: 276-296. https://doi.org/10.1016/j.lithos.2019.01.011
  6. Yang SY(杨书艳), Peng P*, Qin ZY, Wang XP, Wang C, Zhang J, Zhao TP, 2019. Genetic relationship between 1780 Ma dykes and coeval volcanics in the Lvliang area, North China. Precambrian Research, 329, 232-246.
  7. Srivastava RK, Ernst R, Peng P, 2019. Dyke Swarms of the World: A Modern Perspective. Springer Singapore, 1-492. https://doi.org/10.1007/978-981-13-1666-1

2018

  1. Wang LJ (王洛娟), Guo JH, Yin CQ, Peng P, Zhang J, Spencer CJ, Qian JH, 2018. High-temperature S-type granitoids (charnockites) in the Jining complex, North China Craton: Restite entrainment and hybridization with mafic magma. Lithos 320-321, 435-453. https://doi.org/10.1016/j.lithos.2018.09.035
  2. Su XD (苏向东), Peng P*, Wang C, Sun FB, Zhang ZY, Zhou XT, 2018. Whole-rock and mineral chemical data from a profile of the ~900 Ma Niutishan Fe-Ti-rich sill in XuZhou, North China. Data in Brief 21: 727-735.
  3. Zhang YB (张艳斌), Hu B, Zhai MG, Wu FY, Hou QL, Peng P, Zhang XH, Li QL, 2018. In situ U-Pb zircon dating of Devonian sandstones and Paleoproterozoic gneissic granites in the Imjingang Belt: Tectonic implications for the Korean Peninsula and North China. Lithos 316: 232-242. https://doi.org/10.1016/j.lithos.2018.06.028
  4. 翟明国, 张连昌, 陈斌等,2018. 华北克拉通前寒武纪重大地质事件与成矿. 部分章节.
  5. Su XD (苏向东), Peng P*, Wang C, Sun FB, Zhang ZY, Zhou XT, 2018. Petrogenesis of a ~900?Ma mafic sill from Xuzhou, North China: Implications for the genesis of Fe-Ti-rich rocks. Lithos 318-319: 357-375.
  6. 彭澎, 王欣平, 周小童, 王冲, 孙风波, 苏向东, 陈亮, 郭敬辉, 翟明国, 2018. 8.1亿年千里山基性岩墙群的厘定及其对华北克拉通西部地质演化的启示(Identification of the ~810 Ma Qianlishan mafic dyke swarm and its implication for geological evolution of the western North China Craton). 岩石学报 34(4): 1191-1203.
  7. 彭澎, 孙风波, 王冲, 王欣平, 苏向东, 张志越, 周小童, 2018. 华北和圣弗朗西斯科克拉通前寒武纪地质对比(Comparing the Precambrian geology of the North China Craton and the S?o Francisco Craton). 地质科学 53(2): 363-399.
  8. 金明哲, 杨正赫, 彭澎, 张志越, 朴贤旭, 卞创男, 朴雄, 郑哲寿, 翟明国. 2018. 朝鲜平南盆地寒武系黄州群和法洞群的碳同位素漂移事件. 地球科学 43(11): 4096-4108. Kim MC, Yang JH, Peng P, Zhang ZY, Park HU, Byon CN, Park U, Jong CS, Zhai MG, 2018. Carbon Isotope Excursions of Cambrian Hwangju and Bopdong Groups in Pyongnam Basin, Korean Peninsula. Ear Science 43(11): 4096-4108.

2017

  1. Wang LJ (王洛娟), Guo JH, Yin CQ, Peng P, 2017. Petrogenesis of ca. 1.95 Ga meta-leucogranites from the Jining Complex in the Khondalite Belt, North China Craton: Water-fluxed melting of metasedimentary rocks. Precambrian Research 303: 355~371. https://doi.org/10.1016/j.precamres.2017.04.036
  2. Wan YS(万渝生), Peng P, Liu SJ, Kroner A, Guo JH, Dong CY, Liu DY, 2017. Late Paleoproterozoic tectono-thermal event in the northwestern North China Craton: Evidence from U-Pb dating and O-Hf isotopic compositions of zircons from metasedimentary rocks north of Hohhot City, Inner Mongolia, Northern China. Journal of Asian Earth Sciences 167: 152-164. https://doi.org/10.1016/j.jseaes.2017.09.012
  3. Peng P, Yang SY, Su XD, Wang XP, Zhang J, Wang C, 2017. Petrogenesis of the 2090 Ma Zanhuang ring and sill complexes in North China: A bimodal magmatism related to intra-continental process. Precambrian Research 303: 153-170. https://doi.org/10.1016/j.precamres.2017.03.015
  4. Xu HR(徐慧茹), Yang ZY, Peng P, Ge KP, Jin ZM, Zhu RX, 2017. Magnetic fabrics and rock magnetism of the Xiong'er volcanic rocks and their implications for tectonic correlation of the North China Craton with other crustal blocks in the Nuna/Columbia supercontinent. Tectonophysics 712-713(21): 415-425.
  5. Peng P, Zhai M, Su X, Zhao T, Zhou Y, 2017. Nature of the Late Carboniferous to Triassic magmatism along the northern margin of the North China block: link with the evolution of the Central Asian Orogen. Geodynamics & Tectonophysics 8(3): 531-532: doi: 10.5800/GT-2017-8-3-0282
  6. Teixeira W, Oliveira EP, Peng P, Dantas EL, Hollanda MHBM, 2017. U-Pb geochronology of the 2.0 Ga Itapecerica graphite-rich supracrustal succession in the S?o Francisco Craton: Tectonic matches with the North China Craton and paleogeographic inferences. Precambrian Research 293: 91-111.
  7. Wang XP(王欣平), Peng P*, Wang C, Yang SY, S?derlund U, Su XD, 2017. Nature of three episodes of Paleoproterozoic magmatism (2180 Ma, 2115 Ma and 1890 Ma) in the Liaoji belt, North China with implications for tectonic evolution. Precambrian Research 298: 252-267.
  8. Peng P, Feng LJ, Sun FB, Yang SY, Su XD, Zhang ZY, Wang C, 2017. Dating the Gaofan and Hutuo Groups – Targets to investigate the Paleoproterozoic Great Oxidation Event in North China. Journal of Asian Earth Sciences 138: 535-547.
  9. 肖文交, 秦克章, 郭敬辉, 彭澎. 2017. 序:大陆地壳的形成演化与成矿. 地质科学 52(4): I-II.

2016

  1. Huang GY(黄光宇), Jiao SJ, Guo JH*, Peng P, Wang D, Liu Peng, 2016. P–T–t constraints of the Barrovian-type metamorphic series in the Khondalite belt of the North China Craton: Evidence from phase equilibria modeling and zircon U–Pb geochronology. Precambrian Research 283: 125-143.
  2. Wang XP(王欣平), Peng P*, Wang C, Yang SY, 2016. Petrogenesis of the 2115 Ma Haicheng mafic sills from the Eastern North China craton: Implications for an intra-continental rifting. Gondwana Research 39: 347–364.http://dx.doi.org/10.1016/j.gr.2016.01.009.
  3. Peng P, Richard EE, Hou GT, Soderlund U, Zhang SH, Hamilton M, Xu YG, Denyszyn S, Mege D, Pisarevsky S, Srivastava, Kusky TM, 2016. Dyke swarms: keys to paleogeographic reconstructions. Science Bulletin 6(21): 1669-1671. doi:10.1007/s11434-016-1184-x
  4. 彭澎, 杨书艳, 王欣平, 2016. 朝鲜半岛中南部三叠纪岩浆岩的分布、系列与成因浅析. 岩石学报 32(10): 3083-3097.Peng P, Yang SY, Wang XP, 2016. A preliminary study on the distribution, magma series and petrogenesis of the Triassic igneous rocks in middle-southern Korean Peninsula. Acta Petrologica Sinica 32(10): 3083-3097.
  5. 金明哲, 杨正赫, 彭澎*, 翟明国, 朴贤旭, 冯连君, 李忠日, 朱成赫. 2016. 朝鲜平南盆地埃迪卡拉系-下寒武统地层碳同位素特征. 岩石学报 32(10): 3180-3186. Kim MC, Yang JH, Peng P*, ZHai MG, Pak HU, Feng LJ, Ri CI, Ju SH, 2016. Characteristics of carbon isotope of the Ediacaran and Lower Cambrian strata in the Pyongnam basin, DPR Korea. Acta Petrologica Sinica 32(10): 3180-3186.
  6. 杨正赫, 彭澎*, 郑哲寿, 朴雄, 文正根, 金哲贤, 苟贤哲. 2016. 朝鲜平南盆地古元古界-下古生界沉积岩碎屑锆石年龄谱对比及意义. 岩石学报 32(10): 3155-3179. Yang JH, Peng P*, Jong CS, Park U, Mun JG, Kim CH, Ku HC. 2016. Comparison on ages of detrital zircons from the Paleoproterozoic to Lower Paleozoic sedimenatry rocks in the Pyongnam Basin, Korea. Acta Petrologica Sinica, 32(10): 3155-3179.
  7. 彭澎, 王冲, 杨正赫, 金正男. 2016. 朝鲜~19亿年侵入岩的岩石类型与构造背景初探. 岩石学报 32(10): 2993-3018. Peng P, Wang C, Yang JH, Kim JN, 2016. A preliminary study on the rock series and tectonic evnironment of the ~1.9 Ga plutonic rocks in DPR Korea. Acta Petrologica Sinica 32(10): 2993-3018.
  8. 葛松胜, 翟明国*, 李铁胜, 彭澎, 王浩铮, 崔夏红. 冀北中低级变质表壳岩的年代学特征及其对华北克拉通构造演化的约束. 岩石学报 32(2): 571-589. Ge SS, Zhai MG, Li TS, Peng P, Wang HZ, Cui XH, 2016. Geochronology of the medium- and low-grade metamorphosed supracrustal rocks from northern Hbei: Constraint on the Late Neoarchean tectonic evolution of the North China Craton. Acta Petrologica Sinica 32(2): 571-589.
  9. 翟明国, 胡波, 彭澎, 赵太平. 2016. 华北元古宙的多期伸展与裂谷事件. 见: 孙枢、王铁冠主编, 中国东部中-新元古界地质学与油气资源, 北京: 科学出版社 245-286.
  10. 彭澎, 2016. 华北陆块前寒武纪岩墙群及相关岩浆岩地质图(1:250万地质图及说明书). 北京: 科学出版社, 1-90. ISBN 978-7-03-048423-9; 发行号: P-3004.01; 审图号: GS(2016) 2356号 (中文、英文双语版) [Peng P, 2016. Map of Precambrian Dyke Swarms and Related Plutonic/Volcanic Units in the North China Block (1:2500 000). Beijing: Science Press: 1–90]
  11. Wang C (王冲), Peng P*, Wang XP, Yang SY, 2016. Nature of three Proterozoic (1680 Ma, 1230 Ma and 775 Ma) mafic dyke swarms in North China: implications for tectonic evolution and paleogeographic reconstruction. Precambrian Research, 285: 109-126. Doi: 10.1016/j.precamres.2016.09.015.
  12. Zhai MG, Zhang YB, Zhang XH, Wu FY, Peng P, Li QL, Hou QL, Li TS, Zhao L, 2016. Renewed profile of the Mesozoic magmatism in Korean Peninsula: Regional correlation and broader implication for cratonic destruction in the North China Craton. Science China: Earth Sciences 59 (1): 2-35.
  13. Peng P, Ernst R, 2016. Dyke swarms: Keys to Paleogeographic reconstructions, Preface for IDC7 2016. Acta Geologica Sinica 90(Supp 1): XII-XIV.
  14. Peng P, 2016. 1:2500 000 Map of Precambrian Dyke Swarms and Related Units in North China. Acta Geologica Sinica 90(Supp 1): 16 (abstract).
  15. Wang C, Peng P, Wang X, Yang S, 2016. Tectonic Environments of the Yan-Liao Rift during Earth’s Middle Age (1.7~0.75 Ga): Evidence from Mafic Dyke Swarms in Eastern Hebei, North China. Acta Geologica Sinica 90(Supp 1): 45-46(abstract).
  16. Zhai M, Hu B, Zhao T, Peng P, Meng Q. 2016. Late Paleoproterozoic-Neoproterozoic Multi-rifting Events Accompanied by Four Stages of Magmatism in the North China Craton and Their Geological Significance.Acta Geologica Sinica 90(Supp 1): 48(abstract).
  17. Peng P, Wang X, Wang C, Lai Y. 2016. Large-Scale Segregation of Immiscible Liquids in the 1780 Ma Taihang Dykes to Produce the Bimodal Xiong'er Volcanics (North China).Acta Geologica Sinica 90(Supp 1): 113(abstract).
  18. Wang X, Peng P, Yang S, Wang C. 2016. Nature of Three Episodes of Magmatism (2181 Ma, 2115 Ma and 1891 Ma) in the Liaohe Rift of North China: Implications for Tectonic Evolution. Acta Geologica Sinica 90(Supp 1): 127(abstract).
  19. Wang X, Peng P, Wang C, Yang S, 2016. Petrogenesis of the~2115 Ma Haicheng Mafic Sills in the Eastern North China Craton and Their Implications for An Intra-Continental Rifting.Acta Geologica Sinica 90(Supp 1): 128(abstract).
  20. Yang S, Peng P, Qin Z, Wang X, Wang C, 2016. Genetic Relationship of the 1780-1760 Ma Dykes and the Coeval Volcanics in the Lvliang Area, North China. Acta Geologica Sinica 90(Supp 1): 133-134(abstract).
  21. Xu H, Yang Z, Peng P, Ge K, Zhu R, 2016. Magnetic Fabric Studies of Xiong’er Volcanic Rocks in Southern Margin of the North China Craton and its Implications.Acta Geologica Sinica 90(Supp 1): 167(abstract).
  22. 朴贤旭,翟明国,杨正赫, 彭澎*, 金正男, 张艳斌,金明哲, 朴雄,冯连君. 2016. 朝鲜平南盆地祥原超群的沉积时代与拉伸纪早期碳同位素负漂移. 岩石学报. 32(7): 2181-2195. [Park HU, Zhai MG, Yang JH, Peng P*, Kim JN, Zhang YB, Kim MC, Park U, Feng LJ, 2016. Deposition age of the Sangwon Supergroup in the Pyongnam basin (Korea) and the Early Tonian negative carbon isotope interval. Acta Petrologica Sinica, 32(7): 2181-2195. (in Chinese with English abstract)]
  23. Peng  P, 2016. Structural architecture and spatial-temporal distribution of  the Archean domains in the Eastern North China craton. In: MG Zhai, Y  Zhao, TP Zhao (eds.) Metallogeny and main tectonic events of the North  China Craton. Springer-Verlag Berlin Heidelberg. 45-64.Doi:  10.10007/978-981-10-1064-4
  24. 王冲,  彭澎*, 王欣平, 李秋立, 徐希阳, 杨书艳. 2016. 华北太行岩墙群斜锆石生长世代和U-Pb年龄及其对岩浆演化的启示. 岩石学报,  32(3): 646-658.[Wang C, Peng P*, Wang XP, Li QL, Xu XY, Yang SY, 2016.  The generations and U-Pb dating of baddeleyites from the Taihang dyke  swarm in North China and their implications for magmatic evolution. Acta  Petrologica Sinica 32(3): 646-658. (in Chinese with English abstract)]
  25. Peng  P, 2015. Large Igneous Provinces, Richard E. Ernst. Cambridge  University Press (2014), (653 pp.) Gondwana Research, 28: 1585. http://dx.doi.org/10.1016/j.gr.2015.07.002 (book review)

2015

  1. Peng P, Wang C, Wang X, Yang S. 2015. Qingyuan high-grade granite–greenstone terrain in the Eastern North China Craton: Root of a Neoarchaean arc. Tectonophsics, 662: 7-21. http://dx.doi.org/10.1016/j.tecto.2015.04.013.
  2. Peng P, Wang X, Lai Y, Wang C, Windley BF, 2015. Large-scale liquid immiscibility and fractional crystallization in the 1780 Ma Taihang dyke swarm: Implications for genesis fo the bimodal Xiong'er volcanic province. Lithos 136-137: 106-122. http://dx.doi.org/10.1016/j.lithos.2015.08.015.
  3. Peng P, 2015. Late Paleoproterozoic-Neoproterozoic (1800-541 Ma) Mafic Dyke Swarms and Rifts in North China. In: MG Zhai (ed.) Precambiran Geology of China. Springer-Verlag Berlin Heidelberg. 171-204 (totally 390 pages). DOI: 10.1007/978-3-662-47885-1
  4. Peng, P., 2015. Precambrian mafic dyke swarms in the North China Craton and their geological implications. Science China: Earth Sciences 58: 649-675. Link
  5. Li Y(李云), Peng P*, Wang X, Wang H. 2015. Nature of 1800-1600 Ma mafic dyke swarms in the North China Craton: Implications for the rejuvenation of the sub-continental lithospheric mantle. Precambrian Research 257: 114-123.
  6. Zhai, M.G. Hu, B., Zhao, T.-P., Peng P., Meng, Q.-R., 2015. Late Paleoproterozoic-Neoproterozoic multi-rifting events in the North China Craton and their geological significance: a review. Tectonophysics, 662: 153-166. http://dx.doi.org/10.1016/j.tecto.2015.01.019.
  7. Guo, JH, Zhai, MG, Peng, P, Jiao, SJ, Zhao, L, Wang, HZ, 2015. Paleoproterozoic Granulites in the North China Craton and Their Geological Implications. In: MG Zhai (ed.) Precambiran Geology of China. Springer-Verlag Berlin Heidelberg. 137-170 (totally 390 pages). DOI: 10.1007/978-3-662-47885-1
  8. Jiao, SJ(焦淑娟), Guo, JH, Wang, LJ, Peng P, 2015. Short-lived high-temperature prograde and retrograde metamorphism in Shaerqin sapphirine-bearing metapelites from the Daqingshan terrane, North China Craton. Precambrian Research 269: 31-57. http://dx.doi.org/10.1016/j.precames.2015.08.002.
  9. Zhao L(赵磊), Li T, Peng P, Guo J, Wang W, Wang H, Santosh M, Zhai M, 2015. Anatomy of zircon growth in high pressure granulites: SIMS U-Pb geochronology and Lu-Hf isotopes from the Jiaobei Terrane, eastern North China Craton. Gondwana Research, 28: 1373-1390. http://dx.doi.org/10.1016/j.gr.2014.10.009.
  10. Wang, LJ(王洛娟), Guo, JH, Peng P, Liu F, Windley BF, 2015. Lithological unitsat the boundaryzone between the Jining and Huai'an Complexes (central-northern margin of the North China Craton): APaleoproterozoic tectonic melange? Lithos 227: 205-224.http://dx.doi.org/10.1016/j.lithos.2015.04.006.
  11. Ge SS(葛松胜), Zhai MG, Li TS, Peng P, Santosh M, Shan HX, Zuo PF, 2015. Zircon U-Pb geochronology and geochemistry of low-grade metamorphosed volcanic rocks from the Dantazi Complex: Implications for the evolution of the North China Craton, Journal of Asian Earth Sciences 111: 948-965. http://dx.doi.org/10.1016/j.jseaes.2015.08.021
  12. 赵太平, 邓小芹, 胡国辉, 周艳艳, 彭澎, 翟明国, 2015. 华北克拉通古/中元古代界线和相关地质问题讨论(The Paleoproterozoic-Mesoproterozoic boundary of the North China Craton and the related geological issues: A review). 岩石学报. 31(6): 1495-1508.
  13. 彭澎. 高级变质花岗岩-绿岩地体的结构与成因:以华北为例. 矿物学报 增刊S1. 536.
  14. 郭倩,张丹萍,郭巨杰,彭澎,2015. 从高岭土尾矿中浮选铅锌,过程工程学报,15(06): 962-968.
  15. Zhong Y(钟焱), Zhai M, Peng P, Santosh M, Ma X, 2015. Detrital zircon U-Pb dating and whole-rock geochemistry from the clastic rocks in the northern marginal basin of the North China Craton: Constraints on depositional age and provenance of the Bayan Obo Group. Precambrian Research 258: 133-145

2014

  1. Zhai M, Wan Y, Peng P. 2014. Secular changes of mineralization linked with Precambrian major geological events in the North China Craton (Preface). Precambrian Research 255: 511-513.
  2. Xu H(徐慧茹), Yang Z, Peng P, Meert JG, Zhu R, 2014. Paleo-position of the North China craton within the supercontinent Columbia: constraints from new paleomagnetic results. Precambrian Research 255, 276-293.
  3. Mitchell RN, Bleeker W, Van Breemen O, Lecheminant TN, Peng P, Nilsson MKM, Evans DAD, 2014. Plate tectonics before 2.0 Ga: Evidence from paleomagnetism of cratons within supercontinent Nuna. American Journal of Science 314: 878-894.
  4. Peng P, Wang X, Zhai M, Guo J. 2014. Liquid immiscibility and fractional crystallization in the 1780 Ma Taihang dykes: Implications for the genesis of the bimodal Xiong'er volcanics. Goldschmidt Abstracts: 1929.
  5. Peng P, 2014. 1:2 000 000 map of Precambrian mafic magmatism in the North China Craton.LIP of the Month: 链接
  6. Peng P, Wang X, Windley BF, Guo J, Zhai M, Li Y. 2014. Spatial distribution of ~ 1950–1800 Ma metamorphic events in the North China Craton: Implications for tectonic subdivision of the craton. Lithos 202-203: 250-266.
  7. 翟明国, 胡波, 彭澎, 赵太平. 2014. 华北中—新元古代的岩浆作用与多期裂谷事件. 地学前缘 21(1): 100-119.  

2013

  1. Zhu, X., Zhai, M., Chen, F., Lv, B., Wang, W., Peng, P., Hu, B. 2013. ~2.7 Ga Crustal Growth in the North China Craton: Evidence from Zircon U-Pb Ages and Hf Isotopes of the Sushui Complex in the Zhongtiao Terrane. Journal of Geology, 121(3): 239-254.
  2. 黄雄南, 张家声, 彭澎, 李天斌. 2013. 贺兰山北段古元古代结晶基底变形特征及其区域构造意义. 岩石学报, 29: 2353-2370.
  3. Jiao, S., Guo, J., Harley, S., Peng P. 2013. Geochronology and trace element geochemistry of zircon, monazite and garnet from the garnetite and/or associated other high-grade rocks: Implications for Palaeoproterozoic tectonothermal evolution of the Khondalite Belt, North China Craton. Precambrian Research, 237: 78-100.
  4. 胡波, 翟明国, 彭澎, 刘富, 第五春荣, 王浩铮, 张海东. 2013. 华北克拉通古元古代末-新元古代地质事件——来自北京西山地区寒武系和侏罗系碎屑锆石LA-ICP-MS U-Pb年代学的证据. 岩石学报, 29: 2508-2536 .  

2012

  1. Peng, P, Guo, J., Zhai, M., Windley, B., Li, T., Liu, F. 2012. Genesis of the Hengling magmatic belt in the North China Craton: Implications for Paleoproterozoic tectonics. Lithos, 148, 27-44
  2. Peng P, Guo J, Windley BF, Liu F, Chu Z, Zhai M, 2012. Petrogenesis of Late Paleoproterozoic Liangcheng charnockites and S-type granites in the central-northern margin of the North China Craton: Implications for ridge subduction. Precambrian Research, 222-223, 107-123.
  3. Peng P, Liu F, Zhai M, Guo J, 2012. Age of the Miyun dyke swarm: Constraints on the maximum depositional age of the Changcheng System. Chinese Sci Bull 57: 105-110. 彭澎, 刘富, 翟明国, 郭敬辉. 2011. 密云岩墙群的时代及其对长城系底界年龄的制约. 科学通报, 56(35), 2975-2980.
  4. 彭澎, 李云, 刘富, 王芳. 2012. 冀西北晚太古代岩石单元的地质关系: 对早期陆壳形成的指示. 岩石学报, 28(11), 3531-3544.
  5. Guo J, Peng P, Chen Y, Jiao S, Windley BF, 2012. UHT sapphirine granulite metamorphism at 1.93–1.92 Ga caused by gabbronorite intrusions: Implications for tectonic evolution of the northern margin of the North China Craton. Precambrian Research,222-223, 124-142.
  6. Hu B, Zhai M, Li T, Li Z, Peng P, Guo J, Kusky T. 2012. Mesoproterozoic magmatic events in the eastern North China Craton and their tectonic implications: Geochronological evidence from detrital zircons in the Shandong Peninsula and North Korea. Gondwana Research,22(3–4), 828-842.
  7. Liu, F., Guo, J., Peng, P., Qian, Q., 2012. Zircon U–Pb ages and geochemistry of the Huai'an TTG gneisses terrane Petrogenesis and implications for ~2.5 Ga crustal growth in the North China Craton. Precambrian Research 212-213, 225-244.
  8. Qu M, Guo J H, Lai Y, Peng P, Liu F, 2012. Origin and geological significance of the 1.81 Ga hyalophane-rich pegmatite veins from the high-pressure granulite terrain in the Central Zone of North China Craton. Sci China Earth (D Earth Sci), 55(2), 193–203. 屈敏, 郭敬辉, 赖勇, 彭澎, 刘富, 2011. 华北克拉通中部带高压麻粒岩地体中1.81 Ga 富钡冰长石伟晶岩脉的成因及地质意义. 中国科学D地球科学,41(12), 1840-1850.  

2011

  1. Lv, B., Zhai, M., Li, T., Peng, P., 2011. Zircon U–Pb ages and geochemistry of the Qinglong volcano-sedimentary rock series in Eastern Hebei: Implication for ~2500 Ma intra-continental rifting in the North China Craton. Precambrian Research, 208–211: 145-160
  2. Peng P, Bleeker W, Ernst RE, S?derlund U, McNicoll V, 2011. U-Pb baddeleyite ages, distribution and geochemistry of 925 Ma mafic dykes and 900 Ma sills in the North China craton: Evidence for a Neoproterozoic mantle plume. Lithos 127: 210-221.
  3. Peng P, Guo J, Windley BF, Li X, 2011. Halaqin volcano-sedimentary succession in the central-northern margin of the North China Craton: products of Late Paleoproterozoic ridge subduction. Precambrian Research 187, 165-180.
  4. Peng P, Zhai M, Li Q, Wu F, Hou Q, Li Z, Li T, Zhang Y, 2011. Neoproterozoic (~ 900 Ma) Sariwon sills in North Korea: Geochronology, geochemistry and implications for the evolution of the south-eastern margin of the North China Craton. Gondwana Research 20: 243-254.
  5. 王洛娟,郭敬辉,彭澎,刘富,2011. 华北克拉通孔兹岩带东端孤山剖面石榴石基性麻粒岩的变质作用及年代学研究,岩石学报 27: 3689-3700.
  6. 赵瑞幅, 郭敬辉, 彭澎, 刘富, 2011. 恒山地区古元古代2.1Ga地壳重熔事件: 钾质花岗岩锆石U-Pb定年及Hf-Nd同位素研究. 岩石学报. 27(6): 1607-1623.
  7. Wang F, Chen F, Siebel W, Li S, Peng P, Zhai M, 2011. Zircon U–Pb ages and Hf isotopic composition of the Hongqiyingzi Complex, northern Hebei Province: new evidence for Paleoproterozoic and late Paleozoic evolution of the northernmargin of the North China Craton. Gondwana Research 20, 122–136.  

2010

  1. Peng P., Guo J.-H., Zhai M.-G., Bleeker W., 2010. Paleoproterozoic gabbronoritic and granitic magmatism in the northern margin of the North China craton: Evidence of crust-mantle interaction. Precambrian Research 183, 635-659.
  2. Peng P., 2010. Reconstruction and interpretation of giant mafic dyke swarms: a case study of 1.78 Ga magmatism in the North China craton. Kusky, T, Zhai, M-G, Xiao, W-J. (eds). The Evolving Continents: Understanding Processes of Continental Growth. Geological Society, London, Special Publications, 338, 163–178.
  3. Li T, Zhai M, Peng P, Chen L, Guo J, 2010. Ca. 2.5 billion year old coeval ultramafic–mafic and syenitic dykes in Eastern Hebei: Implications for cratonization of the North China Craton. Precambrian Research 180: 143-155
  4. Zhai MG, Li TS, Peng P, Hu B, Liu F, Zhang YB, 2010. Precambrian key tectonic events and evolution of the North China craton. Kusky, T, Zhai, M-G, Xiao, W-J. (eds). The Evolving Continents: Understanding Processes of Continental Growth. Geological Society, London, Special Publications, 338, 235–262.
  5. 汤艳杰, 陈福坤, 彭澎. 2010. 中国盆地火山岩特性及其与油气成藏作用的联系. 岩石学报 26(1), 185-194.
  6. 崔敏利, 张宝林, 彭澎, 张连昌, 沈晓丽, 郭志华, 黄雪飞. 2010. 豫西崤山早元古代中酸性侵入岩锆石/斜锆石U-Pb测年及其对熊耳火山岩系时限的约束. 岩石学报 26(5): 1541-1549.  

2009

  1. Peng P., 2009. 1770-1780 Ma North China Large Igneous Province. LIP of the Month: 链接
  2. 王芳, 陈福坤, 侯振辉, 彭澎, 翟明国. 2009. 华北陆块北缘崇礼-赤城地区晚古生代花岗岩类的告示年龄和Sr-Nd-Hf同位素组成. 岩石学报 25(11): 3057-3074.
  3. Oh, C.-W., Choi, S.-G., Seo, J., Rajesh, V.J., Lee, J.-H., Zhai, M.-G., Peng, P., 2009. Neoproterozoic tectonic evolution of the Hongseong area, southwestern Gyeonggi Massif, South Korea; implication for the tectonic evolution of Northeast Asia. Gondwana Research. 16, 272-284.
  4. 胡波,翟明国,郭敬辉,彭澎,刘富,刘爽. 2009. 华北克拉通北缘化德群中碎屑锆石的LA-ICP-MS U-Pb年龄及其构造意义. 岩石学报. 25(1): 193-211.

2008

  1. Peng P, Zhai M-G, Guo J-H, Zhang H-F, Zhang Y-B, 2008. Petrogenesis of Triassic postorogenic syenite plutons in the Sino-Korean craton: an example from North Korea. Geological Magazine 145 (5): 637–647.
  2. Peng, P. Zhai, M.-G., Ernst, R. Guo, J.-H., Liu, F. Hu, B., 2008. A 1.78 Ga large igneous province in the North China craton: The Xiong'er Volcanic Province and the North China dyke swarm. Lithos 101(3-4): 260-280.  

2007

  1. Peng, P. Zhai, M.-G., Guo, J.-H., Kusky, T., Zhao, T.-P., 2007. Nature of mantle source contributions and crystal differentiation in the petrogenesis of the 1.78 Ga mafic dykes in the central North China craton. Gondwana Research, 12: 29-46.
  2. Zhai MG, Guo JH, Peng P, 2007. U-Pb zircon age dating of a rapakivi granite batholith in Rangnim massif, North Korea. Geological Magazine, 144(3):547-552
  3. Zhai MG, Guo JH, Li Z, Hou QL, Peng P, Fan QC, Li TS, 2007. Linking Sulu orogenic belt to Korean Peninsula: evidences of metamorphism, Precambrian basement and Paleozoic basins. Gondwana Research, 12:388-403
  4. 翟明国, 彭澎. 2007. 华北克拉通古元古代构造事件. 岩石学报 23(11): 2665-2682.
  5. 翟明国, 郭敬辉, 李忠, 陈代钊, 彭澎, 等. 2007. 苏鲁造山带在朝鲜半岛的延伸:造山带、前寒武纪基底以及古生代沉积盆地的证据与制约. 高校地质学报 13(3): 415-428.
  6. 胡俊良, 赵太平, 陈伟, 彭澎. 2007. 华北克拉通1.75Ga基性岩墙群特征及其研究进展. 大地构造与成矿学 34(4): 457-470.
  7. 徐勇航, 赵太平, 彭澎, 翟明国, 漆亮, 罗彦. 2007. 山西吕梁地区古元古界小两岭组火山岩地球化学特征及其地质意义. 石学报 23(5): 1123-1132. 

2006

  1. Peng, P. Zhai, M.-G., Guo, J.-H., 2006. 1.80-1.75 Ga mafic dyke swarms in the central North China craton: implications for a plume-related break-up event. In: E. Hanski, S. Mertanen, T. R?m?, J. Vuollo (eds): Dyke Swarms - Time Markers of Crustal Evolution. London: Taylor & Francis: 99-112.
  2. 张华锋, 翟明国, 彭澎, 2006. 华北克拉通桑干地区高压麻粒岩的锆石SHRIMP U-Pb 年龄及其地质含义. 地学前缘, 13( 3) :190-199.
  3. 张华锋, 翟明国, 童英, 彭澎, 许保良, 郭敬辉. 2006. 胶东半岛三佛山高Ba-Sr 花岗岩成因. 地质论评. 52(1): 43-53.  

2005

  1. Peng, P., Zhai, M.G., Zhang, H.F., Guo, J.H., 2005, Geochronological constraints on the  Paleoproterozoic evolution of the North China Craton: SHRIMP zircon ages of different types of mafic dikes. International Geology Review, 47(5): pp. 492-508.  

2004

  1. 彭澎, 翟明国, 张华锋, 赵太平, 倪志耀. 2004, 华北克拉通1.8Ga镁铁质岩墙群的地球化学特征及其地质意义:以晋冀蒙交界地区为例. 岩石学报. 20(3): 439-456.
  2. 张华锋, 翟明国, 何中甫, 彭澎, 许保良, 2004. 胶东昆瑜山杂岩中高锶花岗岩地球化学成因及其地质意义, 岩石学报, 20: 269-380.  

2003

  1. Zhai, M.G., Shao, J.A., Hao, J., & Peng, P., 2003. Geological signature and possible position of the North China block in the Supercontinent Rodinia. Gondwana Research, 6, 171-183.
  2. Zhai, M.G., Guo, J.H., Li, Y.G., Liu, W.J., Peng, P. & Shi, X., 2003. Two linear granite belts in the central-western North China Craton and their implication for Late Neoarchaean- Palaeoproterozoic continental evolution. Precambrian Research, 127, 267-283.  

2002

  1. 彭澎, 等. 2002, 华北陆块对Rodinia超大陆的响应及其特征. 岩石矿物学杂志. 21(4):343-355.
  2. 彭澎, 等. 2002, 华北陆块前寒武纪两次重大地质事件的特征和性质. 地球科学进展. 17(6): 818-825.
  3. 彭澎, 等. 2002, 关于弧后扩张机制的新看法. 世界地质. 21(1): 1-7.

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