Thermodynamic conditions of framework grain dissolution of clastic rocks and its application in Kela 2 gas field
详细信息 查看全文
- 作者:Xingyun Lai (1) (2)
Bingsong Yu (1) (2)
Junyuan Chen (1)
Xiaolin Chen (1)
Jianqing Liu (1)
Mingxiang Mei (1)
Weiguang Jing (1)
Suhua Cheng (1) - 关键词:dissolution of feldspar ; thermodynamic conditions ; groundwater pore chemistry ; Kela 2 gas field
- 刊名:Science China Earth Sciences
- 出版年:2005
- 出版时间:January 2005
- 年:2005
- 卷:48
- 期:1
- 页码:21-31
- 全文大小:594KB
- 参考文献:1. Hayes, J. B., Sandstone diagenesis-the hole truth. Aspects of diagenesis, Society of Economic Paleontologists and Mineralogists, 1979, 26: 127鈥?39.
2. Schmidt, V., McDonald, D. A., Platt, R. L., Pore geometry and reservoir aspects of secondary porosity in sandstones, Bulletin of Canadian Petroleum Geology, 1977, 25: 271鈥?90.
3. Heald, M. T., Larese, R. E., The significance of the solution of feldspar in porosity development, Journal of Sedimentary Peotrology, 1973, 43: 458鈥?60.
4. Siebert, R. M., Moncure, G. K., Lahann, R. W., A theory of framework grain dissolution in sandstones ((eds. McDonald, D. A., Surdam, R. C.), Clastic Diagenesis, Tulsa, Oklahoma, USA: The American Association of Petroleum Geologists, 1985, 163鈥?76.
5. Boles, J. R., Secondary porosity reactions in the Stevens sandstone, San Joaquin Valley, California ((eds. McDonald, D. A., Surdam, R. C.), Clastic Diagenesis, Tulsa, Oklahoma, USA: The American Association of Petroleum Geologists, 1985, 217鈥?24
6. Garreis, R. M., Christ, C. L., Solutions, Minerals and Equilibria. New York: San Francisco, Freeman Cooper, and Co, 1965, 450.
7. Burley, S. D., Kantorwiez, J. D., Waugh, B., Clastic diagenesis ((eds. Brenchley, P. T., Williams, B. P.), Sedimentology: Recent developments and applied aspects, Geological Society, 1985, 18: 189鈥?26.
8. Kaiser, W. R., Predicting reservoir quality and diagenetic history in the Frio Formation (Oligocene) of Texas ((eds. McDonald, D. A., Surdam, R. C.), Clastic Diagenesis, Tulsa, Oklahoma, USA: The American Association of Petroleum Geologists, 1985, 195鈥?16.
9. Tu Guangzhi, Low Temperature Geochemistry (in Chinese), Beijing: Geological Publishing House, 1998, 265.
10. Capuano, R. M., Hydrochemical constraints on fluid-mineral equilibria during compaction diagenesis of kerogen-rich geopres-sured sediments, Geochim. Cosmochim. Acta, 1990, 54: 1283鈥?299. CrossRef
11. Helgeson, H. C., Delany, J. M., Nesbitt, H. W. et al., Summary and critique of the thermodynamic properties of rock-forming minerals, Am. Jour. Science, 1978, 278-A: 1鈥?29.
12. Maier, C. G., Kelly, K. K., An equation for the representation of high temperature heat content data, Am. Chemical Soc. Jour., 1932, 54(8): 3243鈥?246. CrossRef
13. Tanger, IV, J. C., Helgeson, H. C., Calculation of the thermodynamic and transport properties of aqueous species at high pressures and temperatures: revised equations of state for the standard partial molal properties of ions and electrolytes, Am. Jour. Sci., 1988, 288: 19鈥?8.
14. Wang Gaoshang, Li Pengjiu, Data Handbook for Calculation of Thermal Fluid Equilibrium (in Chinese), Beijing: Geological Publishing House, 1991, 100.
15. Holland, T. J. B., Powell, R., An internally consistent thermodynamic data set of phases of petrological interest, J. Metamorphic. Geol., 1998, 16: 309鈥?43. CrossRef
16. Surdam, R. C., Bosese, S. W., Crossey, L. J., The chemistry of secondary porosity ((eds. McDonald, D. A., Surdam, R. C.), Clastic Diagenesis. Tulsa, Oklahoma, USA: The American Association of Petroleum Geologists, 1985, 127鈥?50.
17. Hanor, J. S., Origin and migration of subsurface sedimentary brines. Society of Economic Paleontologists and Mineralogists Short Course, 1988, 21. - 作者单位:Xingyun Lai (1) (2)
Bingsong Yu (1) (2)
Junyuan Chen (1)
Xiaolin Chen (1)
Jianqing Liu (1)
Mingxiang Mei (1)
Weiguang Jing (1)
Suhua Cheng (1)
1. China University of Geosciences, School of Earth Sciences and Mineral Resources, 100083, Beijing, China
2. Key Laboratory of Lithospheric Tectonics, Deep-level Process and Exploration of Ministry of Education, 100083, Beijing, China - ISSN:1869-1897
文摘
Feldspar and clastic debris are the most important constituent framework grains of sedimentary clastic rocks and their chemical dissolution plays an essential role in the formation and evolution of the secondary pore in the reservoir rocks. On the basis of thermodynamic phase equilibrium, this study investigates the chemical equilibrium relationships between fluid and various plagioclase and K-feldspar in diagenesis of the sediments, particularly, the impact of temperature and fluid compositions (pH, activity of K+, Na+, Ca2+and so on) on precipitation and dissolution equilibria of feldspars. Feldspar is extremely easily dissolved in the acid pore water with a low salinity when temperature decreases. The dissolution of anorthite end-member of plagioclase is related to the Ca content of the mineral and the fluid, higher Ca either in the mineral or in the fluid, easier dissolution of the feldspar. Moreover, the dissolution of albite end-member of plagioclase is related to Na of both the mineral and fluid, lower Na out of both the mineral and fluid, easier dissolution of the mineral. Similarly, lower-K fluid is more powerful to dissolve K-feldspar than the higher. The anorthite component of plagioclase is most easily dissolved in ground water-rock system, the albite is the secondary, and K-feldspar is the most stable. Selective dissolution of plagioclase occurs in diagenesis because of the plagioclase solid solution that is mainly composed of albite and anorthite end-members, Ca-rich part of which is preferentially dissolved by the pore water, in contrast to the Na-rich parts. Based on investigation of reservoir quality, secondary pore, dissolution structures of feldspar, clay minerals and ground water chemistry of the Kela 2 gas field of Kuqa Depression in the Tarim basin of Western China, we discovered that the secondary pore is very well developed in the highest quality section of the reservoir, and the plagioclase of which was obviously selectively dissolved, in contrast to the overgrowth of K-feldspar. Chemistry of the ground water out of the highest quality section of the reservoir is consistent with the complete dissolution field of anorthite, partial dissolution field of albite component of plagioclase, and the precipitation of K-feldspar on the temperature-logK phase equilibrium diagram drawn from this study. The thermodynamic modeling calculation gave us an insight into formation of the secondary pore within the reservoir, and the dissolution of plagioclase an important cause of the secondary pore. It is assumed that the solvent to dissolve the plagioclase frame grains originated from the origin-enriched compacted fluid acids out of the mudstone buried beneath the top of geopressured zones in the Kuqa Depression.