Dedolomitization Origin and Model for the Ordovician Majiagou Formation (5th Member) in the Southern Ordos Basin

doi:10.19657/j.geoscience.1000-8527.2021.002

Abstract

Abstract:

To constrain the diagenesis and property evolution of the Ordovician carbonate reservoir in southern Ordos basin, it is important to understand the origin and mechanism of dedolomitization there. Based on core and thin-section observations, and geochemical analysis, the dedolomitization mechanism and diagenetic evolution were determined by oxygen isotopes and trace elements. Subsequently, combined with the property data, the influence of different dedolomitization styles on the reservoirs was analyzed. Finally, the dedolomitization model of the study area was constructed. Combined with the carbon-oxygen isotopes and trace element data of the samples, we show that the dolomite with gypsum core in M5₁₊₂ is generally affected by freshwater leaching, yet some of them also underwent dedolomitization caused by freshwater leaching. The Th/U, Th/Cr, Cr/Zr, and Y/Ho ratios indicate that meteoric water may have dissolved granitoids and carried terrestrial argillaceous sediments into the strata, again due to freshwater leaching. Ca²⁺ source for the freshwater-leaching-related dedolomitization was likely from the dissolved evaporite (gypsum) and gypsum cores, whilst the $CO 3 2 -$ may have sourced from calcite decomposition during the supergene dolomitization. And the main fluid migration pathways may have been dissolution fractures and suture zones. This process can be divided into 2 stages: replacement (supergene to shallow-burial stage) and cementation (shallow-burial stage). In this process, freshwater rich in Ca²⁺ and $CO 3 2 -$ may have flowed along the migration pathways, and infiltrated along intra-crystal cracks, resulting in the selective dissolution and dolomite replacement with equal volume of calcite, together with the infilling of intra-crystal pores, cracks and fractures by calcite cement, which is destructive to the reservoir.

Key words: dedolomitization, fresh water leaching, diagenetic model, Ordos Basin, Majiagou Formation

CLC Number:

TE122.2

LEI Han, HUANG Wenhui, SUN Qilong, CHE Qingsong. Dedolomitization Origin and Model for the Ordovician Majiagou Formation (5^th Member) in the Southern Ordos Basin[J]. Geoscience, 2021, 35(02): 378-387.

Figures/Tables 9

References 43

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井号	深度/m	岩性	δ¹³C_PDB/‰	δ¹⁸O_VPDB/‰	Mn/Sr	Y/Ho	Cr/Zr	Th/Cr	Th/U
Y1725	2 301.43	微晶白云岩	-0.30	-6.30	1.302	45.081	4.094	0.108	0.230
Y1757	2 906.43		-0.40	-6.30	0.862	44.168	1.447	0.108	0.277
Y1758	3 060.91		0.20	-6.17	0.490	54.487	1.255	0.075	0.634
Y1758	3 599.74		0.40	-5.40	1.042	43.234	2.407	0.053	0.761
Y430	2 385.41		0.60	-5.05	0.710	50.584	1.757	0.057	0.231
Y391	2 903.74		0.20	-5.17	-	-	-	-	-
Y628	2 810.72		0.50	-5.55	-	-	-	-	-
Y391	2 790.89	含膏模孔微晶云岩	-0.30	-5.97	2.724	-	-	-	-
Y391	2 889.75		-0.30	-5.45	2.143	-	-	-	-
Y391	2 810.63		-0.80	-6.18	1.313	-	-	-	-
Y391	3 313.2		1.02	-7.88	1.727	-	-	-	-
Y391	3 114.7		0.38	-7.82	2.157	-	-	-	-
Y1725	3 275.1		-1.24	-7.16	1.313	44.168	1.447	0.236	0.826
Y431	2 720.6		-0.89	-7.45	1.205	42.995	1.193	0.158	1.083
Y1757	3 320.3		-0.26	-7.28	2.564	39.779	0.573	0.148	0.963
Y1758	3 108.4		-1.01	-6.86	2.042	34.530	0.618	0.053	2.199
Y391	3 113.7		-0.65	-8.03	1.938	38.982	0.963	0.197	0.634
Y1725	2 265	含膏模孔微晶灰质云岩	-1.71	-7.99	4.450	30.058	0.618	0.148	3.826
Y1725	2 269		-2.95	-8.32	5.337	36.271	0.571	0.220	3.423
Y1758	3 063		-2.56	-8.02	3.724	34.530	0.380	0.307	3.138
Y1758	3 067		-2.14	-7.23	3.776	34.858	0.368	0.341	3.002
Y1757	3 317.85		-1.92	-7.83	4.687	29.697	0.647	0.234	4.233
Y431	2 718.8		-3.77	-11.04	5.787	-	-	-	-
Y628	2 809.7		-2.89	-8.68	3.173	-	-	-	-
Y677	2 259.82		-4.23	-8.76	3.776	-	-	-	-

井号	深度/m	岩性	δ¹³C_PDB/‰	δ¹⁸O_VPDB/‰	Mn/Sr	Y/Ho	Cr/Zr	Th/Cr	Th/U
Y1725	2 301.43	微晶白云岩	-0.30	-6.30	1.302	45.081	4.094	0.108	0.230
Y1757	2 906.43		-0.40	-6.30	0.862	44.168	1.447	0.108	0.277
Y1758	3 060.91		0.20	-6.17	0.490	54.487	1.255	0.075	0.634
Y1758	3 599.74		0.40	-5.40	1.042	43.234	2.407	0.053	0.761
Y430	2 385.41		0.60	-5.05	0.710	50.584	1.757	0.057	0.231
Y391	2 903.74		0.20	-5.17	-	-	-	-	-
Y628	2 810.72		0.50	-5.55	-	-	-	-	-
Y391	2 790.89	含膏模孔微晶云岩	-0.30	-5.97	2.724	-	-	-	-
Y391	2 889.75		-0.30	-5.45	2.143	-	-	-	-
Y391	2 810.63		-0.80	-6.18	1.313	-	-	-	-
Y391	3 313.2		1.02	-7.88	1.727	-	-	-	-
Y391	3 114.7		0.38	-7.82	2.157	-	-	-	-
Y1725	3 275.1		-1.24	-7.16	1.313	44.168	1.447	0.236	0.826
Y431	2 720.6		-0.89	-7.45	1.205	42.995	1.193	0.158	1.083
Y1757	3 320.3		-0.26	-7.28	2.564	39.779	0.573	0.148	0.963
Y1758	3 108.4		-1.01	-6.86	2.042	34.530	0.618	0.053	2.199
Y391	3 113.7		-0.65	-8.03	1.938	38.982	0.963	0.197	0.634
Y1725	2 265	含膏模孔微晶灰质云岩	-1.71	-7.99	4.450	30.058	0.618	0.148	3.826
Y1725	2 269		-2.95	-8.32	5.337	36.271	0.571	0.220	3.423
Y1758	3 063		-2.56	-8.02	3.724	34.530	0.380	0.307	3.138
Y1758	3 067		-2.14	-7.23	3.776	34.858	0.368	0.341	3.002
Y1757	3 317.85		-1.92	-7.83	4.687	29.697	0.647	0.234	4.233
Y431	2 718.8		-3.77	-11.04	5.787	-	-	-	-
Y628	2 809.7		-2.89	-8.68	3.173	-	-	-	-
Y677	2 259.82		-4.23	-8.76	3.776	-	-	-	-