Lithologic Reservoirs ›› 2007, Vol. 19 ›› Issue (3): 59-65.doi: 10.3969/j.issn.1673-8926.2007.03.011

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Advances of strontium isotope in sedimentology

LIU Haonian,HUANG Sijing,HU Zuowei,WU Meng,WANG Qingdong   

  1. State Key Laboratory of Oil & Gas Reservoi r Geology and Exploitation , Chengdu University of Technology , Chengdu 610059 , China
  • Online:2007-09-15 Published:2007-09-15

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Abstract:

The studies on strontium isotope have received rapid development s in all fields of sedimentology, with the continuous development of dissolution technology for strontium isotope samples of marine carbonate, testing method for diagenetic alteration and strontium isotope database of marine sediment s in the period of geologic history. Strontium isotope is applied to carry out the researches in the aspect s of the provenance analysis, dating marine sediments, paleoclimate and paleoenvironment analysis, water-rock interaction and hydrogeochemistry. The latest progress and development t rends in these fields are discussed.

 

Key words: oil sources, high quality sandbody traps, confluent passage way, key-factor enrichment, Erlian Basin

[1] McArthur J M, Burnett J, Hancock J M. Strontium isotopes at K/ T boundary; discussion [J]. Nature, 1992, 355 (6355) :28.
[2] Palmer M R, Edmond J M. The strontium isotope budget of the modern ocean [J]. Earth and Planetary Science Letters, 1989, 92(1) :11-26.
[ 3] Palmer M R, Elder field H. Sr isotope composition of seawater over the past 75 Myr[J]. Nature, 1985, 314(6011) :526-528.
[ 4] Denison R E, Koelpnick R B, Burke W H, et al. Construction of the Mississippian, Pennsylvanian and Permian seawater 87 Sr/ 86Sr curve [J]. Chemical Geology, 1994, 112 (122) :145- 167.
[5] Burke W H, Dennison R E, Hetherington E A, et al. Variation of seawater 87 Sr/ 86 Sr throughout Phanerozoic time [J]. Geology, 1982, 10 :516-519.
[ 6] Gao Gland L S. Geochemistry of Cambro-Ordovician Arbuckle limestone, Oklahoma: implications for diagenetic 18 O alteration and secular δ 13C and 87 Sr/ 86 Sr variation [ J]. Geochimica et Cosmochimica Acta, 1991, 55 (10) :2911-2920.
[ 7] Veizer J, Buhl D, Diener A, et al. Strontium isotope stratigraphy; potential resolution and event correlation [J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 1997, 132(124): 65-77.
[ 8] Veizer J, Ala D, Azmy K,et al. 87 Sr/ 86 Sr, δ 13 C andδ 18O evol ution of Phanerozoic seawater [J]. Chemical Geology, 1999, 161 :59-88.
[ 9] Howarth R J, McArthur J M. Statistics for strontium isotope stratigraphy; a robust LOWESS fit to marine Srisotope curve for 02206 Ma, with look-up table for derivation of numeric age [J].Journal of Geology, 1997, 105(4) :441-456.
[ 10] McArthur J M, Howarth R J, Bailey T R. Strontium isotope stratigraphy; LOWESS Version 3; Best fit to the marine Sr-isotope curve for 02509 Ma and accompanying look-up table for deriving numerical age[J]. Journal of Geology, 2001, 109 (2): 155-170.
[ 11] 黄思静. 上扬子地台区晚古生代海相碳酸盐岩的碳、 锶同位素 研究[J]. 地质学报, 1997, 71(1) :45-53.
[ 12] 黄思静, 石和, 张萌, 等. 上扬子石炭 —二叠纪海相碳酸盐的锶 同位素演化与全球海平面变化[J]. 沉积学报, 2001, 19 (4) : 481-487.
[ 13] 黄思静, 石和, 张萌, 等. 龙门山泥盆纪锶同位素演化曲线的全 球对比及海相地层的定年[J]. 自然科学进展, 2002, 12 (9) : 945-951.
[ 14] 黄思静, 石和, 毛晓冬, 等. 重庆秀山寒武系锶同位素演化曲线 及全球对比[J]. 地质论评, 2002, 48(5) :509-516.[ 15] 石和, 黄思静, 沈立成, 等. 川黔上古生界锶同位素演化曲线的 地层学意义[J]. 地层学杂志, 2002, 26 (2) :106-110.[ 16] 石和, 黄思静, 赵鹏肖. 四川江油石炭纪锶同位素曲线 ———年 代地层对比和海平面变化[J]. 地质通报, 2003, 22 (2) :113- 117.
 [17] 石和, 黄思静, 赵鹏肖. 贵州惠水石炭纪锶同位素曲线及年代 地层对比[J]. 中国地质, 2003, 30 (2) :138-143.
[ 18] 黄思静, 石和, 沈立成, 等. 西藏晚白垩世锶同位素曲线的全球 对比及海相地层的定年[J]. 中国科学(D 辑), 2004, 34 :335- 344.
[19] 石和, 黄思静, 孙治雷. 西藏定日贡扎上白垩统锶同位素曲线 及年代地层划分[J]. 地层学杂志, 2006, 30 (1) :21-25.
[ 20] 江茂生, 朱井泉, 陈代钊, 等. 塔里木盆地奥陶纪碳酸盐岩碳、 锶同位素特征及其对海平面变化的响应[J]. 中国科学 (D 辑), 2002, 32 (1) :36-42.
[ 21] 黄思静, 裴昌蓉, 卿海若, 等.四川盆地东部海相下 —中三叠统 界线的锶同位素年龄标定[J]. 地质学报, 2006, 80 (11) :1691- 1698.
 [22] 黄思静, 孙治雷, 吴素娟, 等.三叠纪全球海水的锶同位素组成 及其主要控制因素[J]. 矿物岩石, 2006, 26 (1) :43-48.
[ 23] 孟宪伟, 杜德文, 陈志华, 等. 长江、 黄河流域泛滥平原细粒沉积物87 Sr/ 86 Sr空间变异的制约因素及其物源示踪意义[J]. 地 球化学, 2000, 29(6) :562-570.
[ 24] 孙省利, 曾允孚. 西成矿化集中区热水沉积岩物质来源的同位 素示踪及其意义[J]. 沉积学报, 2002, 20(1) :41-46.[ 25] 张霄宇, 张富元, 章伟艳. 南海东部海域表层沉积物锶同位素 物源示踪研究[J]. 海洋学报, 2003, 25 (4) :43-49.
[ 26] 饶文波, 杨杰东, 陈俊, 等. 中国干旱 —半干旱区风尘物质的 Sr, Nd 同位素地球化学:对黄土来源和季风演变的指示[J]. 科学通报, 2006, 51(4) :378-386.
[ 27] 黄思静, 石和, 刘洁, 等. 锶同位素地层学研究进展[J]. 地球科学进展, 2001, 16(2) :194-200.
[ 28] 张萌, 黄思静, 张η,等.锶同位素地层学在海相地层定年中的 潜在价值[J].成都理工大学学报(自然科学版), 2003, 30 (3) : 242-248.
[ 29] 杨杰东, 郑文武, 王宗哲, 等. Sr、 C 同位素对苏皖北部上前寒武系时代的界定[J]. 地层学杂志, 2001, 25 (1) :44-47.
[ 30] 潘家华, 刘淑琴, 杨忆, 等. 太平洋海山磷酸盐的锶同位素成分 及形成年代[J]. 矿床地质, 2002, 21(4) :350-355.
[ 31] 郑文武, 杨杰东, 洪天求, 等. 辽南与苏皖北部新元古代地层 Sr 和 C 同位素对比及年龄界定[J]. 高校地质学报, 2004, 10 (2) :165-178.
[ 32] 黄思静, 石和, 张萌, 等.锶同位素地层学在奥陶系海相地层定 年中的应用 ———以塔里木盆地塔中 12 井为例[J]. 沉积学报, 2004, 22(1) :125.
[ 33] 蓝先洪. 海洋锶同位素研究进展[J]. 海洋地质动态, 2001, 17 (10) :1-3.
[ 34] Dia A N, Cohen A S, O’ Nions R K, et al. Seawater Sr isotope variation over the past 300 kyr and influence of global climate cycles [J]. Nature, 1992, 356 (6372) :786-788.
[ 35] Clemens S C, Farrell J W, Gromet L P. Synchronous changes in seawater strontium isotope composition and global climate [J]. Nature, 1993, 363 (6430) :6072609.
[ 36] Sophie V, Eddy K,Ian J F, et al. Mg, Sr and Sr isotope geochemistry of a Belgian Holocene speleothem; implications for paleoclimate reconstructions[J]. Chemical Geology, 2000, 169 (122) :131-144.
[ 37] Li H C, Ku T L, You C F, et al. 87 Sr/ 86 Srr and Sr/ Ca in speleothems for paleoclimate reconstruction in central China between 70 and 280 kyr ago [J], Geochimica et Cosmochimica Acta, 2005, 69 (16) :3933-3947.
[ 38] 韦刚健, 桂训唐, 于津生. 南海第四纪海水 Sr 同位素组成演化 [J]. 海洋地质与第四纪地质, 1996, 16 (2) :15221.
[ 39] 孙志国, 蓝先波, 刘宝柱, 等. 西沙珊瑚礁中青藏高原隆升的锶 同位素记录[J]. 海洋科学, 1996, (3) :35-41.
[ 40] 孙志国. 黄河三角洲贝壳堤的锶同位素特征[J]. 海洋地质动 态, 2003, 19(7) :19-22.
[ 41] 陈俊. 汪永进, 陈  ,等. 中国黄土地层 Rb和Sr 地球化学特 征及其古季风气候意义[J]. 地质学报, 2001, 75(2) :259-266.
[ 42] 苏晓云, 杨杰东, 陈俊. 从黄土 Sr 同位素探讨海水87 Sr/ 86 Sr变 化的原因[J]. 南京大学学报(自然科学), 2003, 39 (3) :327- 336.
[43] 杨杰东, 陈俊, 张兆峰, 等. 距今7Ma 以来甘肃灵台剖面 Nd 和Sr 同位素特征[J]. 地球化学, 2005, 34(1) :1-6.
[ 44] 黄思静, 吴素娟, 孙治雷, 等.中新生代海水锶同位素演化和古 海洋事件[J]. 地学前缘, 2005, 12 (2) :133-141.
[ 45] Castorina F, Umberto M. Sr-isotopic composition of siderite for assessing the origin of mineralizing fluids;the case study from the Jebel Awam Deposit (central Morocco) [J]. Ore Geology Reviews, 2000, 17 (122) :83-89.
[ 46] Négrel P, Guerrot C, Cocherie A, et al. Rare earth elements, neodymium and strontium isotopic systematics in mineral waters:evidence from the Massif Central, France [J]. Applied Geochemistry, 2000, 15 (1) :345-367.
[ 47] Foden J, Barovich K,Jane M, et al. Sr-isotopic evidence for late Neoproterozoic rifting in the Adelaide Geosyncline at 586 Ma; implications for a Cu ore forming fluid flux [J]. Precambrian Research, 2001, 106(324) :291-308.
[ 48] Ross R L, Bull S, Foden J. C, O and Sr isotopic halos related to the giant McArthur River stratiform Zn2Pb2Ag deposit, northern Australia [J]. Proceedings of the Biennial SGA Meeting, 2001, 6 :293-295.
[ 49] Kloppmann W, Negrel P, Casanova J, et al. Halite dissolution derived brines in the vicinity of a Permian salt dome (N German Basin); evidence from boron, strontium, oxygen, and hydrogen isotopes [J]. Geochimica et Cosmochimica Acta, 2001, 65 (22) :4087-4101.
[ 50] Grove M J, Baker P A, Cross S L, et al. Application of strontium isotopes to understanding the hydrology and paleohydrology of the Altiplano, Bolivia-Peru (in Late-Quaternary palaeoclimates of the southern tropical Andes and adjacent regions) [J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2003, 194(1-3) :281-297.
[ 51] El-Tabakh M, Mory A, Charlotte S B, et al. Anhydrite cements after dolomitization of shallow marine Silurian carbonates of the Gascoyne Platform, southern Carnarvon Basin, Western Australia [J]. Sedimentary Geology, 2004, 164 (122): 75-87.
[ 52] Palmer M R, Helvaci C, Anthony E F. Sulphur, sulphate oxygen and strontium isotope composition of Cenozoic Turkish evaporates [J]. Chemical Geology, 2004, 209 (324) :341-356.
[ 53] G illis K M, Laurence A C, Pedersen R. Strontium isotope constraints on fluid flow in the upper oceanic crust at the East Pacific Rise [J]. Earth and Planetary Science Letters, 2005, 232 (122) :83-94.
[ 54] Matano F, Barbieri M, Nocera S D, et al. Stratigraphy and strontium geochemistry of Messinian evaporite-bearing successions of the Southern Apennines foredeep, Italy; implications for the Mediterranean “salinity crisis” and regional palaeogeography[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2005, 217(122) :872114.
[ 55] 张涛, 云露, 邬兴威, 等.锶同位素在塔河古岩溶期次划分中的 应用[J]. 石油实验地质, 2005, 27 (3) :2992303.
[ 56] 黄思静, 石和, 张萌, 等.锶同位素地层学在碎屑岩成岩研究中 的应用[J]. 沉积学报, 2002, 20(3) :359-366.
[ 57] 黄思静, 刘树根, 李国蓉, 等. 奥陶系海相碳酸盐锶同位素组成 及受成岩流体的影响[J]. 成都理工大学学报(自然科学版), 2004, 31(1) :1-7.

 
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