發布信息

會員中心

當前位置: 首頁 » 創新人物 » 基礎科學 » 地質學 »

陳代釗——碳酸鹽沉積學與沉積地球化學專家、中國科學院地質與地球物理研究所研究員

點擊圖片查看原圖





有效期至：	長期有效
最后更新：	2022-06-21

您好，歡迎回來

發布專家信息	推廣科研成果
管理專家主頁	查看站內留言
完善專家資料	進入商務中心
加為好友	發送信件

QQ空間新浪微博騰訊微博人人網更多

陳代釗，1963年出生于湖南省綏寧縣�，F為中科院地質與地球物理研究所研究員（兼國科大崗位教授），博士生導師。

主要從事沉積學（特別是海相碳酸鹽巖、細粒碎屑巖以及硅質巖沉積學）和沉積地球化學的基礎理論和應用研究；對南方泥盆系碳酸鹽巖沉積學、盆地分析、重要地質時期古海洋環境與生物協同演化以及有機質富集機理進行過系統研究，現主要對新元古代-古生代重大轉折期的各圈層相互作用過程、有機質富集和白云巖化作用機理與相關儲層發育預測進行重點研究。主持多項國家自然科學基金（面上、重點）項目和大型企業委托項目，參加過多項國家重大基礎研究項目（973或重點研發項目）和國家重大（油氣）專項的研究工作。

教育及工作經歷：

1980-1984：湖南科技大學學習，煤田地質與勘探專業，獲學士學位。

1984-1986：湖南科技大學地質系工作，助教，講授巖石-礦物學。

1986-1989：中國礦業大學（北京）學習，沉積學研究方向，獲碩士學位。

1989-1992：中國科學院地質研究所學習，沉積學研究方向，獲博士學位。

1992-1997：中國科學院地質研究所工作，助研-副研（1995晉升副研究員），主要從事沉積學（特別是碳酸鹽巖沉積學）、層序地層/盆地分析方面的研究工作。

1997.12-2000.06：英國University of Durham，高訪及博士后研究人員（分別得到中科院和英國 K.C. Wong - Royal Society Fellowship 資助），主要從事我國南方及英格蘭南部泥盆系沉積學、旋回地層/層序地層方面的研究工作。

2000.06-2002.03：中國科院地質與地球物理研究所工作，副研究員，主要從事沉積學、旋回地層/層序地層及古海洋學方面的研究工作。

2002.03-2003.03：加拿大University of Regina,博士后研究人員，從事加拿大 Williston 盆地 Mississipian 系碳酸鹽巖沉積學、層序地層和儲層性質以及我國南方泥盆系白云巖的成因和晚泥盆世古海洋學及生物絕滅的研究工作。

2002.12 -現在：中國科學院地質與地球物理研究所工作，研究員(博士生導師)，學科組組長，中國科學院大學崗位教授，繼續從事沉積學、沉積地球化學及深時氣候-環境與能源效應等相關領域的研究工作。

學術兼職：

1、2014-10-29-2018-10，中石化勘探開發研究院《構造與儲層實驗室》第一屆學術委員會委員。

2、2013-12-13-今，湖南科技大學頁巖氣資源利用湖南省重點實驗室學術委員會委員。

3、2013-07-01-今，國際學術期刊《 Facies》副主編。

4、2010-10-01-2014-10，中石油集團《碳酸鹽巖儲層重點實驗室》學術委員會委員。

5、2009-01-01-今，中國礦物巖石地球化學學會沉積學專業委員會委員，中國地質學會沉積地質專業委員會委員。

6、2005-01-01-今，沉積學報編委，編委。

7、國際沉積學會（IAS）會員。

研究方向：

本人的研究興趣涉及“軟巖”地質學的許多方面，現主要從事基礎沉積學（特別是碳酸鹽巖、細粒碎屑巖及硅質巖沉積學）、層序地層-旋回地層學與盆地分析、成巖作用與流體/巖石相互作用、應用沉積學（白云巖儲層發育與分布）、沉積地球化學（包括低溫地球化學、生物地球化學）、海洋缺氧與有機質富集、深時地球系統過程（Deep-time GeoSystem）等方面的研究。

研究領域：

碳酸鹽沉積學（沉積相、旋回-層序地層與盆地演化、白云化作用與儲集性），頁巖-硅巖沉積學，沉積地球化學（生物地球化學，低溫地球化學），深時氣候-環境變化，深時地球圈層耦合與地球宜居性。

承擔科研項目情況：

1.國家自然科學基金重大研究計劃（特提斯地球動力系統）重點項目，91755210，古生代揚子地塊有機質幕式超常富集、資源效應與古特提斯演化過程中的地圈-生物圈相互作用，2018-01至2021-12，已結題，主持。

2. 國家重點研發計劃（深地資源勘查開采）項目（超深層及中新元古界油氣資源形成保持機制與分布預測）之專題，編號2017YFC060310302，微生物碳酸鹽巖有效儲層形成與分布規律，2018-05至2021-12，已結題，專題主持。

3.國家自然科學基金石油化工聯合基金重點項目，U1663209、深層-超深層規模性白云巖儲層形成機理與地質模式，2016-01至2019-12，結題，參加。

4.國家自然科學基金，面上項目，41472089，中上揚子地區埃迪卡拉紀-寒武紀轉折期古海洋演化與有機質富集，2015-01至2018/12，已結題，主持。

5.國家重點基礎研究發展計劃（973計劃）項目，2012CB214802，下古生界碳酸鹽巖優質儲層形成與分布預測課題之專題：深層白云巖儲層形成機理與分布評價，2012-01至20 16-09，已結題，專題主持。

6.國家科技重大（油氣）專項專題，2011ZX05008-003-10，塔里木盆地深層白云巖形成演化與分布預測，2011-01至2015-09，已結題，專題主持。

7.國家自然科學基金面上項目，41072027，南方泥盆紀碳酸鹽巖高分辨率磁化率變化及古環境和氣候意義，2011-01至2013/12，已結題，主持。

8.國家科技重大（油氣）專項專題，2008ZX05008-003-002，塔里木盆地深層白云巖儲集體形成演化與分布規律，2008-01至2010/12，已結題，專題主持。

9.國家自然科學基金石油化工聯合基金重點項目，40839907，中上揚子古生界優質烴源巖形成：地質-生物協同演化控制機理，2009-01至2012/12，已結題，主持。

10.國家重點基礎研究發展計劃（973計劃）項目，2006CB705802, “CO2地下埋存的地質理論”課題之專題：CO2地質埋存體的儲蓋層地質表征，2006-01至2011-12，已結題，專題主持

11.國家重點基礎研究發展計劃（973計劃）項目，2005CB422101，“中國海相碳酸鹽巖層系形成與后期演化”課題之專題：揚子地塊海相碳酸鹽巖層系優質烴源巖發育的構造沉積背景，2005-01至2010-12，已結題，專題主持。

12.國家自然科學基金面上項目，40673013，湖南-廣西某些地區弗拉-法門附件高分辨率Sr-Nd同位素記錄及古環境變化，2007-01至2009-12，已結題，主持。

13.國家自然科學基金面上項目，40372062，湘南泥盆紀拉分碳酸鹽臺間盆地碳酸鹽沉積作用與盆地演化動力學，2004-01至2007-12，已結題，主持。

14.國家自然科學基金面上項目，49872043，華南泥盆紀碳酸鹽成壤作用、幕次與古氣候、古環境，1999-01至2001-12，已結題，主持。

15.國家自然科學基金青年項目，49402027，湘桂泥盆紀臺地碳酸鹽旋回沉積、臺地演化及模擬研究，1995-01至1997-12，已結題，主持。

主要成就：

陳代釗研究員在我國較早地開展了海相層序地層的研究工作，用層序地層/旋回地層方法成功地解決了泥盆紀臺地碳酸鹽地層的長距離對比和構造影響的鑒別問題。在盆地分析方面，以桂林陽朔地區為例，詳細研究了臺間拉分盆地同構造碳酸鹽沉積作用規律以及走滑斷裂作用對碳酸鹽臺地形成演化的控制作用，大大豐富了該類型盆地的研究內容。最早報道了我國泥盆紀弗拉斯-法門（F/F）轉折期碳同位素正向偏移、多重同位素組合（C-Sr-S）樣式以及與生物大絕滅事件潛在聯系，認為頻繁的氣候波動可能是此次事件的主因；同時，根據軌道旋回理論對該事件進行了準確定年（~450 Kyr）。提供了揚子和塔里木板塊寒武紀初期海底富硅熱液活動（硅煙囪）的直接與地球化學證據并建立了與該時期獨特海洋化學循環的聯系，提出了深海海洋氧化與寒武紀生命大爆發的成因聯系；在我國最早開展了熱液白云巖化作用實例研究，確認塔里木盆地下古生界白云巖廣泛熱液改造與二疊紀大火成巖省有密切的成因聯系，并對潛在的熱液改造白云巖儲層分布提供了見解。

出版專著（專輯）：

1. Iryu Y., Cabioch G., Chen D.Z., Matsuda H., Piller W.E. (Eds.), Carbonates: Biological, Geochemical and Physical Processes Sedimentary Geology, Vol. 214, Amsterdan: Elsevier, B.V., 2009-05, 第 3 作者

2. Magnetic Susceptibility Application-A Window onto Ancient Environments and Climatic Variations, Geol Soc Spec. Publ., 414, Geological Society, London, 2015-03, 第 5 作者

3. 沉積學姜在興 陳代釗 主編礦物學，巖石學，地質學中國石化出版社,2022-04-01

發表（英文）論文：

1. Liu, K., Jiang, M.S., Zhang, L.Y., Chen, D.Z*., 2022. A new high-resolution palaeotemperature record during the Middle-Late Ordovician transition derived from conodont d18O palaeothermometry. Jour. Geol. Soc. Lond., doi: 10.1144/jgs2021-148.

2.Wang, Y.Z., Chen, D.Z*., Liu, M., Liu, K., Tang, P., 2022. Ediacaran carbon cycling and Shuram excursion recorded in the Tarim Block, northwestern China. Precambrian Res., 377： 106694, doi: 10.1016/j.precamres.2022.106694.

3.Liu, K., Jiang, M.S., Huang, T.Y., Zhang, L.Y., Wang, Y.Z., Chen, D.Z*., 2022. A reassessment on the timing and potential drivers of the major seawater 87Sr/86Sr drop in the Ordovician Period: New evidence from conodonts in China. Chemical Geol., 604: 120906, doi: 10.1016/j.chemgeo.2022.120906.

4.Liu, M., Chen, D.Z*., Jiang, L., Stockey, R., Aseal, D., Zhang, B., Liu, K., Yang, X.R., Yan, D.T., Planavski, N., 2022. Oceanic anoxia and extinction in the latest Ordovician. Earth Planet. Sci. Lett., 588: 117553, doi: 10.1016/j.epsl.2022.117553.

5.Jiang, L., Zhao, M.Y., Shen, A.J., Huang, L.L., Chen, D.Z., Cai, C.F., 2022. Pulses of stmosphere oxygenation during the Cambrian radiation of animals. Earth Planet. Sci. Lett., 590: 117565, doi: 10.1016/j.epsl.2022.117565.

6.Ge, X.T., Chen, D.Z*., Zhang, G.J., Huang, T.Y., Liu, M., El-Shafeiy, M., 2022. Marine redox evolution and organic accumulation in an intrashelf basin, NE Sichuan Basin during the Late Permian. Marine and Petroleum Geology, 140: 105633, doi: 10.1016/j.marpetgeo.2022.105633.

7.Tang, P., Chen, D.Z., Wang, Y.Z., Ding, Y., El-Shafeiy, M., Yang, B., 2022. Diagenesis of microbialite-dominated carbonates in the Upper Ediacaran Qigebrak Formation, NW Tarim Basin, China: Implications for reservoir development. Marine and Petroleum Geology, 136: 105476, doi: 10.1016/j.marpetgeo.2021.105476.

8.Liu, M., Ji, C.J., Hu, H.W., Xia, G.Q., Yi, H.S., Them II, T.R., Sun, P., Chen, D.Z., 2021. Variations in microbial ecology during the Toarcian Oceanic Anoxic Event (Early Jurassic) in the Qiangtang Basin, Tibet: Evidence from biomarker and carbon isotopes. Palaeogeography, Palaeoclimat. Palaeoecol., 580: 110626, doi: 10.1016/j.palaeo.2021.110626.

9.Zhou, X.Q., Chen, D.Z., Zhang, L.Y., Tang, D.J., Guo, C., 2021. Silica-rich seawater in the early Cambrian: Sedimentological evidence from bedded cherts. Terra Nova, 33: 494-501, doi: 10.1111/ter.12541

10.Yang, X.R., Yan, D.T., Chen, D.Z., Liu, M., She, X.H., Zhang, B., Zhang, L.W., Zhang, J.F., 2021. Spatiotemporal variation of sedimentary carbon and nitrogen isotopic compositions in the Yangtze shelf sea across the Ordovician-Silurian boundary. Paleogeogr. Palaeoclimat. Palaeoecol., 567: 110257, doi: 10.1016/j.palaeo.2021.110257

11.Zhang, G.J., Chen, D.Z*., Huang, K.J., Liu, M., Huang, T.Y., Yeasmin, R., Fu, Y., 2021. Dramatic attenuation of continental weathering during the Ediacaran-Cambrian transition: Implications for the climatic-oceanic-biological co-evolution. Global Planet. Change, 203: 103518, doi: 10.1016/j.gloplacha.2021.103518.

12.Zhang, G.J., Chen, D.Z*., Ding, Y., Huang, T.Y., 2021. Redox fluctuations and organic accumulation on the outer shelf of the Early Cambrian (Ages 2-3) Yangtze sea: Geochemical records on a seawad submarine sill. Geol. J., 56:1841–1857, doi: 10.1002/gj.4031.

13.Ding, Y., Li, Z.W., Liu, S.G*., Song, J.M., Zhou, X.Q., Sun, W., Zhang, X.H., Li, S.J., Ran, B., Peng, H.L., Li, Z.Q., Wang, H., Chen, D.Z*., 2021. Sequence stratigraphy and tectono-depositional evolution of a late Ediacaran epeiric platform in the upper Yangtze area, South China. Precam. Res., 354: 106077, doi: 10.1016/j.precamres.2020.106077.

14.Yang, X.R., Yan, D.T., Chen, D.Z., Liu, M., She, X.H., Zhang, J.F., Wei, X.S., Lu, Z.Y., 2020. Spatial variation of carbon isotope compositions of carbonate and organic organic matter from the Late Ordovician sedimentary succession in the Yangtze Platform, South China: Implications for sea-level eustasy and shoaling of marine chemocline. J. Asian Earth Sci., 202: 10454, doi: 10.1016/j.jseaes.2020.104540.

15.Zhang, L.Y., Chen, D.Z*., Kuang, G.D., Guo, Z.H., Zhang, G.J., Wang, X., 2020. Persistent oxic deep ocean conditions and frequent volcanic activities during the Frasnian-Famennian transition recorded in South China. Global Planet Change, 195: 10335, doi: 10.1016/j.gloplacha.2020.103350.

16.Zhang, L.Y., Chen, D.Z*., Huang, T.Y., Yu, H., Zhou, X.Q., Wang, J.G., 2020. An abrupt oceanic change and frequent climatic fluctuations across the Frasnian-Famennian transition of Late Devonian: Constraints from conodont Sr isotope. Geological Journal, 55: 4479-4492.

17.Guo, C., Chen D.Z*., Qing, H.R., Zhou, X.Q., Ding, Y., 2020. Early dolomitization and recrystallization of the Lower-Middle Ordovician carbonates in the western Tarim Basin (NW China). Marine Petrol. Geol., 111: 332-349.

18.Ding, Y., Chen, D.Z*., Zhou, X.Q., Huang, T.Y., Guo, C., Yeasmin, R., 2020. Paired d13Ccarb-d13Corg evolution of the Dengying Formation from the northeastern Guizhou and implications for stratigraphic correlation and Late Ediacaran carbon cycle. J. Earth Sci., 31 (2): 342-353. doi: 10.1007/s12583-018-0886-1.

19.Huang, T.Y., Chen, D.Z*., Ding, Y., Zhou, X.Q., Zhang, G.J., 2020. SIMS U-Pb zircon geochronological and carbon isotope chemostratigraphic constraints on the Ediacaran-Cambrian boundary succession in the Three Gorges area, South China. J. Earth Sci., 31 (1): 67-78. doi 10.1007/s12583-019-1233-x.

20.Yan, D.T., Chen, D.Z., Wang, Z.Z., Li, J., Yang, X.R., Zhang, B., 2019. Climatic and oceanic controlled deposition of Late Ordovician-Early Silurian black shales on the North Yangtze platform, South China. Marine Petroleum Geol., 110: 112-121.

21.Liu, M., Chen, D.Z*., Zhou, X.Q., Tang, D.J., Them II, T.R., Jiang, M.S., 2019. Upper Ordovician marine red limestones, Tarim Basin, NW China: A product of an oxygenated deep ocean and changing climate? Global and Planetary Change, 183: 103032, doi: 10.1016/j.gloplacha.2019.103032.

22.Huang, T.Y., Chen, D.Z.*, Fu, Y., Yeasmin, R., Guo, C., 2019. Development and evolution of a euxinic wedge on the ferruginous outer shelf of the early Cambrian Yangtze sea. Chem. Geol., 524: 259-271, doi: 10.1016/j.chemgeo.2019.06.24.

23.Ding, Y., Chen, D.Z*., Zhou, X.Q., Guo, C., Huang, T.Y., Zhang, G.J., 2019. Tectono-depositional pattern and evolution of the middle Yangtze Platform (South China) during the late Ediacaran. Precambrian Res., 333: 105426, doi: 10.1016/j.precamres.2019.105426.

24.Ding, Y., Chen, D.Z*., Zhou, X.Q., Guo, C., Huang, T.Y., Zhang, GJ., 2019. Cavity-filling dolomite speleothems and submarine cements in the Ediacaran Dengying microbialites, South China: Responses to high-frequency sea-level fluctuations in an ‘aragonite-dolomite sea’. Sedimentology, 66, 2511-2537, doi: 10.1111/sed.12605.

25.Wei, W., Zhu, X.M., Chen, D.Z., Zhu, S.F., He, M.W., Sun, S.F., 2019. Pore fluid and diagenetic evolution of carbonate cements in lacustrine carbonate-siliciclastic rocks: A case from the Lower Cretaceous of the Erenaoer Sag, Erlian Basin, NE China. J. Sed. Res., 89, 457-477.

26.Liu, M., Chen, D.Z*., Zhou, X.Q., Yuan, W., Jiang, M.S., Liu, L.J., 2019. Climatic and oceanic changes during the Middle-late Ordovician transition in the Tarim Basin, NW China and implications for the Great Ordovician Biodiversification Event. Palaeogeogr. Paleoclimat. Palaeoecol., 514: 522-535.

27.Ding, Y., Chen, D.Z*., Zhou, X.Q., Huang, T.Y., Guo, C., Yeasmin, R., 2018. Paired d13Ccarb-d13Corg evolution of the Dengying Formation from the northeastern Guizhou and implications for stratigraphic correlation and Late Ediacaran carbon cycle. J. Earth Sci., doi: 10.1007/s12583-018-0886-1.

28.Zou, C.N., Qiu, Z., Poulton, S.W., Dong, D.Z., Wang, H.Y., Chen, D.Z., Liu, B., Shi, Z.S., Tao, H.F., 2018. Ocean euxinia and climate change “double whammy” drove the Late Ordovician mass extinction. Geology, 46 (6): 635-538.

29.Wang, X., Liu, S.A., Wang, Z.R., Chen, D.Z., Zhang, L.Y., 2018. Zinc and strontium isotope evidence for climate cooling and constraints on the Frasnian-Famennian (~372 Ma) mass extinction. Palaeogeogr. Paleoclimat. Palaeoecol., 498: 68-82.

30.Dong, S.F., You, D.H., Guo, Z.H., Guo, C., Chen, D.Z*., 2018. Intense silicification of Ordovician carbonates in the Tarim Basin: Constraints from fluid inclusion Rb-Sr isotope dating and geochemistry of quartz. Terra Nova, 30: 406-413; doi: 10.1111/ter.12356.

31.Guo, C., Chen, D.Z*., Zhou, X.Q., Ding, Y., Wei, W.W., Zhang, G.J., 2018. Depositional facies and cyclic patterns in a subtidal-dominated ramp during the Early-Middle Ordovician in the western Tarim Basin (NW China). Facies, 64:16; doi: 10.1007/s10347-018-0529-0.

32.Guo, C., Chen D.Z*., Song, Y.F., Zhou, X.Q., Ding, Y., Zhang, G.J., Depositional environments and cyclicity of the Early Ordovician carbonate ramp in the western Tarim Basin (NW China). J. Asian Earth Sci., 158: 29-48.

33.De Vleeschouwer, D., da Silva, A.-C., Sinnesael, M., Chen, D.Z., Day, J., Whalen, M., Guo, Z.H., and Claeys, P. 2017. Timing and pacing of the Late Devonian mass extinction event regulated by eccentricity and obliquity. Nature Communications, 8:226, doi: 10.1038/s41467-017-02407-1.

34.Guo, C., Chen, D.Z*., Dong, S.F., Qian, Y.X., Liu, C.G., 2017. Early dolomitisation of the Lower-Middle Ordovician cyclic carbonates in northern Tarim Basin, NW China, Sci. China Earth Sci., 60 (7), 1283-1298; doi: 1007/s11430-017-9056-1.

35.Wei, W.W., Chen, D.Z*., Qing, H.R., Qian, Y.X., 2017. Hydrothermal dissolution of deeply buried Cambrian dolomite rocks and porosity generation: integrated with geological studies and reactive transport modeling in the Tarim Basin, China. Geofluids, 12, 1-19; doi: 10.1155/2017/9562507.

36.Dong, S.F., Chen, D.Z*., Zhou, X.Q., Qing, H.Q., 2017. Tectonically driven dolomitization of Cambrian to Lower Ordovician carbonates of the Quruqtagh area, north-eastern flank of Tarim Basin, north-western China. Sedimentology, 64, 1079-1106.

37.Yeasmin, R., Chen D.Z*., Fu, Y., Guo, C., 2017. Climatic forcing on the organic accumulation across the shelf during the Early Cambrian (Age 2 through 3) in the mid-upper Yangtze Block, NE Guizhou, South China. J. Asian Earth Sci., 134, 365-386.

38.Chen, D.Z., Guo, Z.H., Jiang, M.S., Guo, C., Ding, Y., 2016. Dynamics of cyclic carbonate deposition and biotic recovery on platforms during the Famennian of Late Devonian in Guangxi, South China: Constraints from high-resolution cycle and sequence stratigraphy. Palaeogeogr. Paleoclimat. Palaeoecol., 448, 245-265, doi: 10.1016/j.palaeo.2015.11.043.

39.Ma, X.P., Gong, Y.M., Chen, D.Z., Racki, G., Chen, X.Q., Liao, W.H., 2016. The Late Devonian Frasnian-Famennian Event in South China – Patterns and causes of extinctions, sea level changes, and isotope variations. Palaeogeogr. Paleoclimat. Palaeoecol., 448, 224-244, doi 10.1016/j.palaeo.2015.10.047.

40.Guo, C., Chen, D.Z.*, Qing, H.R., Dong, S.F., Li, G.R., Wang, D., Qian, Y.X., Liu, C.G., 2016. Multiple dolomitization and later hydrothermal alteration on the Upper Cambrian-Lower Ordovician carbonates in the northern Tarim Basin. Marine and Petroleum Geology, 72, 295-316.

41.Chen Daizhao, Zhou Xiqiang, Fu Yong, Wang Jianguo, Yan Detian, 2015. New U-Pb zircon ages of the Ediacaran-Cambrian boundary strata in South China. Terra Nova, 27 (1), 62-68.

42.Yu, H., Zhou, X.Q., Wang, J.G., Guo, C., Wei, H.Y., Chen, D.Z., 2015. The origin of bedding-parallel fibrous calcite veins in the Lower Permian Chisia Formation in western Hubei Province, South China. Sci. Bull., 60 (20), 1778-1786.

43.Whalen, M.T., Sliwinski, M.G., Payne, J., Day, J.E., Chen, D., Da Silva, A.-C., 2015. Chemostratigraphy and magnetic susceptibility of the Late Devonian Frasnian-Famennian transition in western Canada and southern China: Implications for carbon and nutrient cycling and mass extinction. In: Da Silva, A.C., Whalen, M., Hladil, J., Chadimova, L., Chen, D., Spassov, S., Boulvain, F., Devleeschouwer, X., 2015 (Eds.). Magnetic Susceptibility Application: A window onto Ancient Environments and Climatic Variations. Geological Society (London) Special Publication 414, 37-72.

44.Da Silva, A.C., Whalen, M., Hladil, J., Chadimova, L., Chen, D., Spassov, S., Boulvain, F., Devleeschouwer, X., 2015 (Eds.). Magnetic Susceptibility Application: A window onto Ancient Environments and Climatic Variations. Geological Society (London) Special Publication 414, pp. 283.

45.Zhang Yanqiu, Chen Daizhao*, Zhou Xiqiang, Guo Zenghui, Wei Wenwen, Mutti, M., 2015. Depositional facies and stratal cyclicity of dolomites in the Lower Qiulitag Group (Upper Cambrian) in northwestern Tarim Basin, NW China. Facies, 2015, 61 (1): 417, doi 10.1007/s10347-014-0417-1.

46.Zhou Xiqiang, Chen Daizhao*, Tang Dongjie, Dong Shaofeng, Guo chuan, Guo Zenghui, Zhang Yanqiu, 2015. Biogenic iron-rich filaments in the quartz veins in the uppermost Ediacaran Qigebulake Formation, Aksu area, northwestern Tarim Basin, China: Implications for iron oxidizers in subseafloor hydrothermal systems. Astrobiology, 15 (7), 523-537.

47.Zhou Xiqiang, Chen Daizhao*, Dong Shaofeng, Zhang Yanqiu, Guo Zenghui, 2015. Diagenetic barite deposits in the Yurtus Formation in Tarim Basin, NW China: Implications fro barium and sulfur cycling in the earliest Cambrian. Precambrian Research, 263, 79-87.

48.Zhou Xiqiang, Chen Daizhao*, Qing Hairuo, Qian Yixiong, Wang Dan, 2014. Submarine silica-rich hydrothermal activity during the earliest Cambrian in the Tarim Basin, Northwest China. International Geology Review, 56 (15), 1906-1918.

49.Xu, X., Mao, Q., Li, X., Pirajno, F., Qu, X., Deng, G., Chen, D., Zheng, B., Dong, L., 2014. Copper-zinc albite porphyry Hersai porphyry copper deposit, East Jungar, China: A transition between late magmatic and hydrothermal porphyry copper deposit. Ore Geol. Rev., 61, 141-156.

50.Da Silva A-C., Whalen, M.T., Hladil, J., Koptikova, L., Chen, D.Z., Spassov, S., Boulvain, F., Devleeschouwer, X., 2014. Application of magnetic susceptibility as a paleoclimatic proxy on Paleozoic sedimentary rocks and characterization of the magnetic signal – IGCP-580 projects and events. Episodes, 37 (2), 87-95.

51.Ji Congwei, Qing Hairuo, Chen Daizhao, Luo Ping, Jin Zhijun, Shao Longyi, 2013. Characteristics and dolomitization of Upper Cambrian to Lower Ordovician dolomite from the outcrop in Keping Uplift, western Tarim Basin, Northwest China. Acta Geologica Sinica-English Edition, 87 (4), 1005-1018.

52.Dong ShaoFeng, Chen Daizhao*, Qing HaiRuo, Jiang MaoSheng, Zhou XiQiang, 2013. In situ stable isotopic constraints on dolomitizing fluids for the hydrothermally-originated saddle dolomites at Keping, Tarim Basin. Chinese Science Bulletin, 58, 2877-2882.

53.Dong Shaofeng, Chen Daizhao*, Qing Hairuo, Zhou Xiqiang, Wang Dan, Guo Zenghui, Jiang Maosheng, Qian Yixiong, 2013. Hydrothermal alteration of dolostones in the Lower Ordovician, Tarim Basin, NW China: Multiple constraints from petrology, isotope geochemistry and fluid inclusion microthermometry. Marine and Petroleum Geology, 46, 270-286.

54.Chen Daizhao, Wang Jianguo, Racki, G., Li Hua, Wang Chengyuan, Ma Xueping, Whalen, M., 2013. Large sulphur isotopic perturbations and oceanic changes during the Frasnian-Famennian transition of the Late Devonian. J. Geol. Soci. Lond., 170, 465-476.

55.Qian Yixiong, You Donghua, Chen Daizhao, Qing Hairuo, He Zhiliang, Ma Yuchun, Tian Mian, Xi Binbin, 2012. The petrographic and geochemical signatures and implication of origin of the Middle and Upper Cambrian dolostones in eastern margin Tarim: Comparative studies with the Whirlpool Point of the Western Sedimentary Basin. Acta Petrologica Sinica, 28 (8), 2524-2541.

56.Wei Hengye, Chen Daizhao*, Wang Jianguo, Yu Hao, Tucker, M.E., 2012. Organic accumulation in the lower Chihsia Formation (Middle Permian) of South China: Constraints from pyrite morphology and multiple geochemical proxies. Palaeogeogr. Palaeoclimat. Palaeoecol., 353-355, 73-86.

57.Wei Hengye, Chen Daizhao, Yu Hao, Wang Jianguo, 2012. End-Guadalupian mass extinction and negative carbon isotope excursion at Xiaojiaba, Guangyuan, Sichuan. Sci. China-Earth Sci., 55, 1480-1488.

58.Wang Jianguo, Chen Daizhao, Yan Detian, Wei Hengye, Xiang Lei, 2012. Evolution from an anoxic to oxic deep ocean during the Ediacaran-Cambrian transition and implications for bioradiation. Chem. Geol., 306-307, 129-138.

59.Wang Jianguo, Chen Daizhao*, Wang Dan, Yan Detian, Zhou Xiqiang, Wang Qingchen, 2012. Petrology and geochemistry of chert on the marginal zone of Yangtze Platform, western Hunan, South China, during the Ediacaran-Cambrian transition. Sedimentology, 59, 809-829.

60.Yan Detian, Chen Daizhao*, Wang Qingchen, Wang Jianguo, 2012. Predominance of straitified anoxic Yangtze Sea interrupted by short-term oxygenation during the Ordo-Silurian transition. Chem. Geol., 291, 69-78.

61.Yan Detian, Chen Daizhao*, Wang Qingchen, Wang Jianguo, 2010. Large-scale climatic fluctuations in the latest Ordovician on Yangzt block, south China. Geology, 38, 599-602.

62.Iryu Y., Cabioch G., Chen D.Z*., Matsuda H., Piller W.E. (Eds.), 2009. Carbonates: Biological, Geochemical and Physical Processes. Sediment. Geol., 214, pp.100 (Special issue).

63.Chen Daizhao, Wang Jianguo, Qing Hairuo, Yan Detian, Li Renwei, 2009. Hydrothermal venting activities in the Early Cambrian, South China: Petrological, geochronological and stable isotopic constraints. Chem. Geol., 258: 168-181.

64.Yan Detian, Chen Daizhao*, Wang Qingcheng, Wang Jianguo, Wang Zhuozhuo, 2009. Carbon and sulfur isotopic anomalies across the Ordovician-Silurian boundary on Yangtze Platform, South China. Palaeogeogr. Palaeoclimat. Palaeoecol., 274: 32-39.

65.Yan Detian, Chen Daizhao, Wang Qingcheng, Wang Jianguo, 2009. Geochemical changes across the Ordovician-Silurian transition on the Yangtze Platform, South China. Science in China (Ser. D), 52: 38-54.

66.Yan Detian, Chen Daizhao, Wang Qingcheng, Wang Jianguo, Chu Yang, 2008. Environmental redox changes of the Yangtze Sea during the Ordo-Silurian transition. Acta Geologica Sinica-English Edition, 82 (3): 679-689.

67.Jiang Zaixing, Chen Daizhao, Qiu Longwei, Liang Hongbin and Ma Jun, 2007. Source-controlled carbonates in a small Eocene half-graben lake basin (Shulu Sag) in central Hebei Province, North China. Sedimentology, 54, 265-292.

68.Zhai Mingguo, Guo Jinghui, Li Zhong, Chen Daizhao, Peng Peng, Li Tiesheng, Hou Quanlin, Fan Qicheng, 2007. Linking the Sulu UHP belt to the Korean Peninsula: Evidence from eclogite, Precambrian basement, and Paleozoic sedimentary basins. Gondwana Research, 12, 388-403.

69.Chen Daizhao, Qing Hairuo, Yan Xin, Li He, 2006. Hydrothermal venting and basin evolution (Devonian, South China): Constraints from rare earth element geochemistry of chert. Sediment. Geol., 183, 203-216.

70.Chen Daizhao, Qing Hairuo, Li Renwei, 2005. The Late Devonian Frasnian-Famennian (F/F) biotic crisis: Insights from δ13Ccarb, δ13Corg, 87Sr/86Sr isotopic systematics. Earth Planet. Sci. Letters, 235, 151-166.

71.Bian Qiantao, Zhu Shixing, Pospelov, I.I., Semikhatove, M.A., Sun Shufen, Chen Daizhao and Na Chunguan, 2005. Discovery of the Jiawengmen stromatolite assemblage in the southern belt of Eastern Kunlun, NW China and its significance. Acta Geologica Sinica (English Edition), 79 (4): 471-480.

72.Zhu Jingquan, Li Yongtie, Jiang Maosheng and Chen Daizhao, 2004. Carbon isotopic composition and its implication of the Lower Cretaceous Aptian-Albian shallow water carbonates in the Cuoqin Basin, northern Tibet. Science in China (Series D), 47: 247-254.

73.Chen Daizhao and Tucker, M.E., 2004. Palaeokarst and its implication for the extinction event at the Frasnian-Famennian boundary (Guilin, South China). Jour.Geol. Soci. London, 161, 895–898.

74.Chen Daizhao, Qing Hairuo and Yang Chao, 2004. Multistage hydrothermal dolomites in the Middle Devonian (Givetian) carbonates from the Guilin area, South China. Sedimentology, 51, 1029–1051.

75.Zhu Jingquan, Li Yongtie, Jiang Maosheng and Chen Daizhao, 2004. Carbon isotopic composition and its implication of the Lower Cretaceous Aptian-Albian shallow water carbonates in the Cuoqin Basin, northern Tibet. Science in China (Series D), 47, 247-254.

76.Chen Daizhao, Tucker, M.E., 2003. Frasnian-Famennian mass extinction: Insights from high-resolution sequence stratigraphy and cyclostratigraphy in South China. Palaeogeogr. Palaeoclimat. Palaeoecol., 193, 87-111.

77.Chen Daizhao, Tucker, M.E., Shen Yan’an, Yans, J. and Preat, A., 2002. Carbon isotopic excursions and sea-level change: Implications for the Frasnian-Famennian biotic crisis. Jour. Geol. Soci. London, 159, 63-66.

78.Chen Daizhao, Tucker, M.E., Jingquan Zhu and Maosheng Jiang, 2002. Carbonate platform evolution: from a bioconstructed platform margin to a sand shoal system (Devonian, Guilin, South China). Sedimentology, 49, 737-764.

79.Chen Daizhao, Tucker, M.E., Zhu Jingquan and Jiang Maosheng, 2001. Sedimentation in a starved basin, Middle to Late Devonian, southern Guilin, South China. Basin Res., 13, 141-168.

80.Chen Daizhao, Tucker, M.E., Jiang Maosheng and Zhu Jingquan, 2001. Long-distance correlation between tectonic-controlled, isolated carbonate platforms by cyclostratigraphy and sequence stratigraphy in the Devonian of South China. Sedimentology, 48, 57-78.

81.Jiang Maosheng, Zhu Jingquan, Chen Daizhao, Zhang Renhu and Qiao Guangsheng, 2001. Carbon and strontium isotope variations and responses to sea-level fluctuations in the Ordovician of the Tarim Basin. Science in China (Series D), 144, 816-823.

82.Chen Daizhao, Zhang Pengfei, 1996. Cyclothems of the Longtan Formation, Upper Permian, western Guizhou, Scientia Geologica Sinica (Overseas Edition), 5 (1): 91-104.

發表（中文期刊）論文：

[1]何治亮,馬永生,張軍濤,朱東亞,錢一雄,丁茜,陳代釗.中國的白云巖與白云巖儲層:分布、成因與控制因素[J].石油與天然氣地質,2020,41(01):1-14.

[2]陳代釗,張艷秋,周錫強,董少鋒.塔里木盆地西緣上寒武統下丘里塔格群熱液白云巖改造時限:來自古地磁的約束[J].石油與天然氣地質,2020,41(01):50-58.

[3]宋亞芳,陳代釗,郭川,周錫強.塔里木盆地肖爾布拉克剖面肖爾布拉克組下段微生物碳酸鹽巖沉積特征[J].沉積學報,2020,38(01):55-63.

[4]周錫強,陳代釗,劉牧,胡建芳.中國沉積學發展戰略:沉積地球化學研究現狀與展望[J].沉積學報,2017,35(06):1293-1316.

[5]陳代釗,錢一雄.深層—超深層白云巖儲集層:機遇與挑戰[J].古地理學報,2017,19(02):187-196.

[6]周錫強,遇昊,黃泰譽,張力鈺,張恭境,付勇,陳代釗.重晶石沉積類型及成因評述——兼論揚子地區下寒武統重晶石的富集機制[J].沉積學報,2016,34(06):1044-1056.

[7]王卓卓,施立志,張永生,陳代釗,梁江平.湘桂地區泥盆紀硅巖Rb-Sr、Sm-Nd同位素地球化學特征及構造沉積背景研究[J].沉積學報,2015,33(04):679-686.

[8]錢一雄,杜永明,陳代釗,尤東華,張軍濤,陳躍,劉忠寶.塔里木盆地肖爾布拉克剖面奇格布拉克組層序界面與沉積相研究[J].石油實驗地質,2014,36(01):1-8.

[9]陳代釗,汪建國,嚴德天,韋恒葉.中揚子地區早寒武世構造—沉積樣式與古地理格局[J].地質科學,2012,47(04):1052-1070.

[10]錢一雄,尤東華,陳代釗,卿海若,何治亮,馬玉春,田蜜,席斌斌.塔東北庫魯克塔格中上寒武統白云巖巖石學、地球化學特征與成因探討——與加拿大西部盆地惠而浦(Whirlpool point)剖面對比[J].巖石學報,2012,28(08):2525-2541.

[11]錢一雄,陳代釗,尤東華,卿海若,何治亮,董少峰,馬玉春,焦存禮,田蜜.塔東北庫魯克塔格地區中上寒武統白云巖類型與孔隙演化[J].古地理學報,2012,14(04):461-476.

[12]遇昊,陳代釗,韋恒葉,汪建國.鄂西地區上二疊樂平統大隆組硅質巖成因及有機質富集機理[J].巖石學報,2012,28(03):1017-1027. 通訊作者

[13]韋恒葉,陳代釗.鄂西—湘西北地區二疊紀棲霞期巖相古地理[J].古地理學報,2011,13(05):551-562.

[14]焦存禮,邢秀娟,何碧竹,陳代釗,李程成,劉忠寶.塔里木盆地下古生界白云巖儲層特征與成因類型[J].中國地質,2011,38(04):1008-1015.

[15]王旭,沈建偉,陳代釗,楊紅強,王月.塔里木盆地柯坪-巴楚地區早古生代白云巖類型及微量元素地球化學特征[J].礦物巖石,2011,31(02):23-32.

[16]錢一雄,尤東華,陳代釗,陳躍,姜海健,劉忠寶.塔里木盆地肖爾布拉克上震旦統蘇蓋特布拉克組層序界面與沉積相[J].地質科學,2011,46(02):445-455.

[17]陳代釗,汪建國,嚴德天,韋恒葉,遇昊,王清晨.揚子地區古生代主要烴源巖有機質富集的環境動力學機制與差異[J].地質科學,2011,46(01):5-26.

[18]汪建國,陳代釗,嚴德天,韋恒葉,遇昊.湘西地區前寒武紀—寒武紀轉折期碳酸鹽—硅泥質沉積體系的截然轉換:地層—沉積樣式,形成機理及意義[J].地質科學,2011,46(01):27-41.

[19]嚴德天,王清晨,陳代釗,汪建國,邱振.揚子地區晚奧陶世碳酸鹽臺地淹沒事件及其地質意義[J].地質科學,2011,46(01):42-51.

[20]韋恒葉,陳代釗,遇昊,汪建國.鄂西地區中二疊統棲霞組下部烴源巖形成機理[J].地質科學,2011,46(01):68-82.

[21]遇昊,陳代釗,韋恒葉,汪建國,常華進.二疊紀末期海洋缺氧:來自黃鐵礦形態的證據[J].地質科學,2011,46(01):83-91.

[22]卿海若,陳代釗.非熱液成因的鞍形白云石:來自加拿大薩斯喀徹溫省東南部奧陶系Yeoman組的巖石學和地球化學證據[J].沉積學報,2010,28(05):980-986.

[23]王丹,王旭,陳代釗,楊長春,Hairuo Qing,吳茂炳,邢秀娟.塔里木盆地塔北、塔中地區寒武系—奧陶系碳酸鹽巖中鞍形白云石膠結物特征[J].地質科學,2010,45(02):580-594.

[24]王丹,陳代釗,楊長春,王旭,吳茂炳,邢秀娟.埋藏環境白云石結構類型[J].沉積學報,2010,28(01):17-25.

[25]汪建國,陳代釗,嚴德天.重大地質轉折期的碳、硫循環與環境演變[J].地學前緣,2009,16(06):33-47.

[26]許志剛,陳代釗,曾榮樹,郭凱,李元平,肖斌,王旭.我國吉林油田大情字井區塊CO_2地下埋存試驗區地質埋存格架[J].地質學報,2009,83(06):875-878+896+879-884.

[27]嚴德天,陳代釗,王清晨,汪建國.揚子地區奧陶系-志留系界線附近地球化學研究[J].中國科學(D輯:地球科學),2009,39(03):285-299.

[28]許志剛,陳代釗,曾榮樹,郭凱,王旭.CO2地下地質埋存原理和條件[J].西南石油大學學報(自然科學版),2009,31(01):91-97+192-193.

[29]許志剛,陳代釗,曾榮樹,郭凱,李元平.CO2地下埋存分布狀況及環境影響的監測[J].氣候變化研究進展,2008(06):363-368.

[30]陳代釗.構造-熱液白云巖化作用與白云巖儲層[J].石油與天然氣地質,2008,29(05):614-622.

[31]許志剛,陳代釗,曾榮樹.CO_2地質埋存滲漏風險及補救對策[J].地質論評,2008(03):373-386.

[32]嚴德天,王清晨,陳代釗,汪建國,王卓卓.揚子及周緣地區上奧陶統—下志留統烴源巖發育環境及其控制因素[J].地質學報,2008，82(03):321-327.

[33]翟明國,郭敬輝,李忠,陳代釗,彭澎,李鐵勝,張艷斌,侯泉林,樊祺誠,胡波.蘇魯造山帶在朝鮮半島的延伸:造山帶、前寒武紀基底以及古生代沉積盆地的證據與制約[J].高校地質學報,2007(03):415-428.

[34]許志剛,陳代釗,李勝利,范洪軍,韓璐.南堡地區東營組一段儲層敏感性評價及油層保護[J].沉積與特提斯地質,2007，23(03):101-104.

[35]汪建國,陳代釗,王清晨,嚴德天,王卓卓.中揚子地區晚震旦世—早寒武世轉折期臺—盆演化及烴源巖形成機理[J].地質學報,2007，81(08):1102-1109+1162.

[36]王卓卓,陳代釗,汪建國.廣西南寧地區泥盆紀硅質巖稀土元素地球化學特征及沉積背景[J].地質科學,2007，42(03):558-569.

[37]許志剛,陳代釗,曾榮樹.CO2的地質埋存與資源化利用進展[J].地球科學進展,2007，22(07):698-707.

[38]王卓卓,陳代釗,汪建國.廣西南寧地區泥盆系硅質巖地球化學特征及沉積環境[J].沉積學報,2007，25(02):239-245.

[39]王卓卓,陳代釗.南寧地區泥盆系硅質巖地球化學及沉積構造背景[J].云南地質,2006(04):440-441.

[40]邊千韜,朱士興,I.I.Pospelov,M.A.Semikhatov,孫淑芬,陳代釗,那春光.東昆侖南帶中元古代晚期—新元古代早期疊層石組合的發現[J].地質科學,2006，41(03):500-510+551-553.

[41]陳代釗,王卓卓,汪建國.晚泥盆世地球各圈層相互作用與海洋生態危機:來自高分辨率的沉積和同位素地球化學證據[J].自然科學進展,2006，16(04):439-448.

[42]邊千韜,朱士興,I IPOSPELOV,M A SEM IKHATOV,孫淑芬,陳代釗,那春光.東昆侖南帶加嗡門疊層石組合的發現及其意義[J].地質學報,2005(04):530.

[43]曾榮樹,孫樞,陳代釗,段振豪.減少二氧化碳向大氣層的排放——二氧化碳地下儲存研究[J].中國科學基金,2004(04):6-10.

[44]朱井泉,李永鐵,江茂生,陳代釗.藏北措勤盆地早白堊世Aptian-Albian淺水碳酸鹽巖碳同位素組成及其意義[J].中國科學(D輯:地球科學),2003，33(03):216-222.

[45]江茂生,朱井泉,陳代釗,張任祜,喬廣生.塔里木盆地奧陶紀碳酸鹽巖碳、鍶同位素特征及其對海平面變化的響應[J].中國科學(D輯:地球科學),2002，32(01):36-42.

[46]江茂生 ,朱井泉 ,陳代釗 ,張任祜 ,喬廣生.Carbon and strontium isotope variations and responses to sea-level fluctuations in the Ordovician of the Tarim Basin[J].Science in China(Series D:Earth Sciences),2001(09):816-823.

[47]陳代釗.旋回地層──一個正在發展中的理論[J].第四紀研究,2000(02):186-195.

[48]陳代釗，1998. 海平面變化與沉積、成礦作用，刊于：地球系統科學 (陳述彭等主編).

[49]陳代釗.河流沉積占優勢地層中高頻層序地層──以貴州盤縣西部龍潭組為例[J].地質科學,1997(04):432-444.

[50]陳代釗.碳酸鹽旋回地層研究現狀[J].巖相古地理,1997(01):67-73.

[51]陳代釗.碳酸鹽旋回地層研究現狀[J].巖相古地理,1997,17(01):64-70.

[52]陳代釗,張鵬飛.三角洲平原上網結河的發育與聚煤作用[J].沉積學報,1996，14(03):105-114.

[53]陳代釗,陳其英,江茂生.泥盆紀海相碳酸鹽巖碳同位素組成及演變[J].巖相古地理,1995(05):22-28.

[54]陳代釗，張鵬飛，1995. 近海平原型含煤地層旋回層及其沉積演替，沉積學及巖相古地理學新進展(王英華主編)，石油工業出版社, 133-139.

[55]陳代釗,陳其英.黔南地區早、中泥盆世沉積演化的動力機制[J].沉積學報,1995，13(03):54-65.

[56]邵龍義,張鵬飛,陳代釗,羅忠.滇東黔西晚二疊世早期辮狀河三角洲沉積體系及其聚煤特征[J].沉積學報,1994，12(04):132-139.

[57]陳代釗,陳其英.黔南早、中泥盆世層序地層格架與海平面變化[J].中國科學(B輯化學生命科學地學),1994，24(11):1197-1205.

[58]陳代釗,陳其英.華南泥盆紀沉積演化及海水進退規程[J].地質科學,1994，29(03):246-255.

[59]陳代釗.就“層序地層學與巖相古地理編圖——以中國南方泥盆紀地層為例”一文的討論[J].巖相古地理,1993(02):62-63.

[60]柳祖漢,李有禹,雷躍冬,陳代釗.澧縣羊耳山地區有無下石炭統[J].湘潭礦業學院學報,1986(01):44-48.

[61]H.G.Richards,陳代釗.洋底熱泉[J].海洋地質譯叢,1986(01):64-68.

[62]George de Vries Klein,陳代釗.在海盆中根據階段性濁流沉積確定構造上升的速度[J].海洋地質譯叢,1985(03):37-40.

發表會議論文：

[1]黃泰譽,陳代釗,付勇,汪建國,郭增輝. 貴州銅仁地區早寒武世早期古海洋氧化還原條件和有機質富集機理研究[C]. 2015年全國沉積學大會沉積學與非常規資源論文摘要集. 2015:234-235.

[2]郭川,陳代釗,董少峰,魏文文,丁一. 塔里木盆地鷹山組生物潛穴白云巖成因機理[C]. 2015年全國沉積學大會沉積學與非常規資源論文摘要集. 2015:336-337.

[3]遇昊,陳代釗,韋恒葉,汪建國. 鄂西地區上二疊樂平統大隆組硅質巖成因及有機質富集機理[C]. 中國科學院地質與地球物理研究所2012年度（第12屆）學術論文匯編——油氣資源研究室. 2013:305-315.

[4]遇昊,陳代釗,韋恒葉,汪建國,常華進. 二疊紀末期海洋缺氧:來自黃鐵礦形態的證據[C]. 中國科學院地質與地球物理研究所第11屆（2011年度）學術年會論文集(下). 2012:467-475.

[5]陳代釗,汪建國,嚴德天,韋恒葉,遇昊,王清晨. 揚子地區古生代主要烴源巖有機質富集的環境動力學機制與差異[C]. 中國科學院地質與地球物理研究所第11屆（2011年度）學術年會論文集(下). 2012:366-387.

[6]汪建國,陳代釗,嚴德天,韋恒葉,遇昊. 湘西地區前寒武紀—寒武紀轉折期碳酸鹽—硅泥質沉積體系的截然轉換:地層—沉積樣式,形成機理及意義[C]. 中國科學院地質與地球物理研究所第11屆（2011年度）學術年會論文集(下). 2012:440-454.

[7]韋恒葉,陳代釗. 鄂西-湘西北地區二疊紀棲霞期巖相古地理[C]. 中國科學院地質與地球物理研究所第11屆（2011年度）學術年會論文集(下). 2012:455-466.

[8]汪建國,陳代釗,嚴德天,韋恒葉. 埃迪卡拉紀-寒武紀轉折期深海的演化[C]. 中國礦物巖石地球化學學會第13屆學術年會論文集. 2011:503.

[9]遇昊,陳代釗,韋恒葉,汪建國,常華進. 二疊紀末期海洋缺氧——來自黃鐵礦形態的證據[C]. 中國礦物巖石地球化學學會第13屆學術年會論文集. 2011:389.

[10]許志剛,陳代釗,曾榮樹,郭凱,李元平. CO_2地下埋存分布狀況及環境影響的監測[C]. 中國科學院地質與地球物理研究所2008學術論文匯編. 2009:1749-1754.

[11]許志剛,陳代釗,曾榮樹. CO_2地質埋存滲漏風險及補救對策[C]. 中國科學院地質與地球物理研究所2008學術論文匯編. 2009:1735-1748.

[12]王卓卓,陳代釗,汪建國. 廣西南寧地區泥盆紀硅質巖稀土元素地球化學特征及沉積背景[C]. 中國科學院地質與地球物理研究所2007學術論文匯編(第六卷). 2008:294-305.

[13]王卓卓,陳代釗,汪建國. 廣西南寧地區泥盆系硅質巖地球化學特征及沉積環境[C]. 中國科學院地質與地球物理研究所2007學術論文匯編(第六卷). 2008:306-312.

[14]汪建國,陳代釗,王清晨,嚴德天,王卓卓. 中揚子地區晚震旦世—早寒武世轉折期臺—盆演化及烴源巖形成機理[C]. 中國科學院地質與地球物理研究所2007學術論文匯編(第六卷). 2008:286-293.

[15]許志剛,陳代釗,曾榮樹. CO_2的地質埋存與資源化利用進展[C]. 中國科學院地質與地球物理研究所2007學術論文匯編(第六卷). 2008:350-359.

[16]嚴德天,王清晨,陳代釗,汪建國. 揚子地區上奧陶—下志留統黑色頁巖地質特征及其油氣資源意義[C]. 中國礦物巖石地球化學學會第11屆學術年會論文集. 2007:417-419.

[17]邊千韜,朱士興,I.I.Pospelov,M.A.Sem ikhatov,孫淑芬,陳代釗,那春光. 東昆侖南帶中元古代晚期—新元古代早期疊層石組合的發現[C]. 中國科學院地質與地球物理研究所2006年論文摘要集. 2007:62.

[18]陳代釗,王卓卓,汪建國. 晚泥盆世地球各圈層相互作用與海洋生態危機:來自高分辨率的沉積和同位素地球化學證據[C]. 中國科學院地質與地球物理研究所2006年論文摘要集. 2007:79.

[19]陳代釗,卿海若,李任偉. 弗拉-法門轉折期的生物集群絕滅:來自δ~(13)C_(carb)-δ~(13)C_(org)-~(87)Sr/~(86)Sr 系統同位素和沉積學證據的新認識[C]. 第三屆全國沉積學大會論文摘要匯編. 2004:32.

[20]陳代釗,卿海若,楊朝. 廣西桂林地區中泥盆統碳酸鹽巖多期熱液白云巖化作用[C]. 第三屆全國沉積學大會論文摘要匯編. 2004:61.

[21]陳代釗. 埋藏-熱液(巖溶)成巖作用與碳酸鹽巖儲層表征——典型實例介紹及對塔中碳酸鹽巖儲層演化的思考[C]. 塔里木及周邊地區盆地（山）動力學與油氣聚集學術研討會論文摘要集. 2004:111-116.

[22]朱井泉,李永鐵,江茂生,陳代釗. 藏北措勤盆地早白堊世Aptian-Albian淺水碳酸鹽巖碳同位素組成及其意義[C]. 中國科學院地質與地球物理研究所二○○三學術論文匯編·第四卷(油氣資源). 2003:350-356.

[23]江茂生,朱井泉,陳代釗,張任祜,喬廣生. 塔里木盆地奧陶紀碳酸鹽巖碳、鍶同位素特征及其對海平面變化的響應[C]. 中國科學院地質與地球物理研究所2002學術論文摘要匯編. 2002:132.

[24]江茂生,朱井泉,陳代釗,張任祜,喬廣生. Carbon and strontium isotope variations and responses to sea-level fluctuations in the Ordovician of the Tarim Basin[C]. 中國科學院地質與地球物理研究所2001學術論文匯編（第四卷）. 2001:183-190.

[25]陳代釗. 華南泥盆紀一個拉分盆地中的碳酸鹽沉積作用[C]. 2001年全國沉積學大會摘要論文集. 2001:70.

中國科技創新人物云平臺暨“互聯網+”科技創新人物開放共享平臺（簡稱：中國科技創新人物云平臺）免責聲明： 　

1、中國科技創新人物云平臺是：“互聯網+科技創新人物”的大型云平臺，平臺主要發揮互聯網在生產要素配置中的優化和集成作用，將互聯網與科技創新人物的創新成果深度融合于經濟社會各領域之中，提升實體經濟的創新力和生產力，形成更廣泛的以互聯網為基礎設施和實現工具的經濟發展新形態，實現融合創新，為大眾創業，萬眾創新提供智力支持，為產業智能化提供支撐，加快形成經濟發展新動能，促進國民經濟提質增效升級。

2、中國科技創新人物云平臺暨“互聯網+”科技創新人物開放共享平臺內容來源于互聯網，信息都是采用計算機手段與相關數據庫信息自動匹配提取數據生成，并不意味著贊同其觀點或證實其內容的真實性，如果發現信息存在錯誤或者偏差，歡迎隨時與我們聯系，以便進行更新完善。

3、如果您認為本詞條還有待完善，請編輯詞條。

4、如果發現中國科技創新人物云平臺提供的內容有誤或轉載稿涉及版權等問題，請及時向本站反饋，網站編輯部郵箱：kjcxac@126.com。

5、中國科技創新人物云平臺建設中盡最大努力保證數據的真實可靠，但由于一些信息難于確認不可避免產生錯誤。因此，平臺信息僅供參考，對于使用平臺信息而引起的任何爭議，平臺概不承擔任何責任。　　

更多..同類創新人物