鄂尔多斯盆地大牛地气田上古生界致密气轻烃地球化学特征

倪春华; 吴小奇; 王萍; 王付斌; 贾会冲; 朱建辉; 张毅; 姜海健

doi:10.11781/sysydz202402366

鄂尔多斯盆地大牛地气田上古生界致密气轻烃地球化学特征

doi: 10.11781/sysydz202402366

倪春华^{1, 2,},
吴小奇^{1, 2, ,},
王萍^{1, 2},
王付斌³,
贾会冲⁴,
朱建辉^{1, 2},
张毅^{1, 2},
姜海健^{1, 2}

1.
中国石化石油勘探开发研究院无锡石油地质研究所, 江苏无锡 214126
2.
中国石化油气成藏重点实验室, 江苏无锡 214126
3.
中国石化华北油气分公司油气勘探管理部, 郑州 450006
4.
中国石化华北油气分公司勘探开发研究院, 郑州 450006

基金项目:

国家自然科学基金项目 42172149

国家自然科学基金项目 U2244209

中国石化科技部攻关项目 P23230

中国石化科技部攻关项目 P22132

中国石化科技部攻关项目 P21077-1

详细信息

作者简介:
倪春华(1981—)，男，博士，高级工程师，本刊编委，从事油气地质与地球化学研究。E-mail: nichunhua.syky@sinopec.com

通讯作者:
吴小奇(1982—)，男，博士，高级工程师，本刊青年编委，从事油气成藏地球化学研究。E-mail: xqwu@163.com

中图分类号: TE133.1
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- 被引次数: 0
出版历程
- 收稿日期: 2023-06-09
- 修回日期: 2024-01-26
- 刊出日期: 2024-03-28

Geochemical characteristics of light hydrocarbons in Upper Paleozoic tight gas from Daniudi Gas Field, Ordos Basin

NI Chunhua^{1, 2
,},
WU Xiaoqi^{1, 2
, ,},
WANG Ping^{1, 2},
WANG Fubin³,
JIA Huichong⁴,
ZHU Jianhui^{1, 2},
ZHANG Yi^{1, 2},
JIANG Haijian^{1, 2}

1.
Wuxi Research Institute of Petroleum Geology, SINOPEC, Wuxi, Jiangsu 214126, China
2.
SINOPEC Key Laboratory of Hydrocarbon Accumulation, Wuxi, Jiangsu 214126, China
3.
Department of Oil and Gas Exploration Management, SINOPEC North China Company, Zhengzhou, Henan 450006, China
4.
Research Institute of Exploration and Production, SINOPEC North China Company, Zhengzhou, Henan 450006, China

摘要

摘要: 大牛地气田是鄂尔多斯盆地典型致密砂岩大气田之一。为了更深入了解该区天然气的成因和来源，揭示天然气运移相态，对大牛地气田上古生界致密气开展了轻烃地球化学特征分析。研究表明，该区上古生界致密气C_5-7轻烃组成具有异构烷烃优势分布，C_6-7轻烃组成中芳烃含量整体偏低(＜10%)，甚至未检出芳烃，C₇轻烃组成具有甲基环己烷优势分布特征，甲基环己烷相对含量均超过50%。上二叠统下石盒子组天然气K₁值、K₂值均与二叠系山西组和石炭系太原组天然气一致，而δ¹³C₁值则与山西组天然气一致，与太原组天然气有明显不同。与山西组天然气相比，下石盒子组天然气整体具有偏低的苯/正己烷、苯/环己烷和甲苯/正庚烷比值，以及明显偏高的正庚烷/甲基环己烷比值。轻烃地球化学特征及烷烃气碳氢同位素组成综合表明，大牛地气田上古生界天然气为典型煤成气，其中山西组和太原组天然气均为原地自生自储，而下石盒子组天然气为下伏山西组烃源岩生成的天然气经历了游离相垂向运移聚集形成，太原组烃源岩不具有显著贡献。受天然气运移和水溶等作用影响，庚烷值、异庚烷值、苯/正己烷比值等轻烃指标直接用于判识大牛地气田致密气成熟度会存在偏差。
- 轻烃化合物 /
- 成熟度 /
- 天然气成因 /
- 气源对比 /
- 运移相态 /
- 大牛地气田 /
- 鄂尔多斯盆地
Abstract: The Daniudi Gas Field is one of the typical tight sandstone gas fields in the Ordos Basin. In order to better understand the genetic types and source of natural gas and reveal the migration phase of natural gas, the geochemical analysis of light hydrocarbons in the Upper Paleozoic tight gas from the Daniudi Gas Field has been conducted in this study. The results indicate that, the C_5-7 light hydrocarbons in the Upper Paleozoic tight gas are dominated by iso-alkanes, and the C_6-7 light hydrocarbons display low contents of aromatics (< 10%), which are even undetectable. The C₇ light hydrocarbons are dominated by methylcyclohexane (MCH) with the relative MCH contents exceeding 50%. The K₁ and K₂ values of natural gas from the Lower Shihezi Formation (P₁x) are consistent with those from the Shanxi (P₁s) and Taiyuan (C₃t) formations, respectively. The δ¹³C₁ values of the P₁x gas are consistent with those of the P₁s gas and significantly different from those of the C₃t gas. Compared with the P₁s gas, the P₁x gas mainly displays lower benzene/n-hexane, benzene/cyclohexane and toluene/n-heptane ratios, as well as significantly higher n-heptane/methylcyclohexane ratios. Geochemical characteristics of light hydrocarbons and carbon and hydrogen isotopic compositions of alkanes indicate that, the Upper Paleozoic natural gas from the Daniudi Gas Field is typical coal-derived gas. The P₁s and C₃t gases were in-situ self-generated and self-accumulated, whereas the P₁x gas was mainly derived from the underlying P₁s source rocks and accumulated via vertical migration in free phase, with insignificant contributions of the C₃t source rocks. Due to the effect of migration and water solution of natural gas, the deviation exists in the identification of thermal maturity for tight gas from the Daniudi Gas Field using the light hydrocarbon indexes such as heptane and isoheptane values and benzene/n-hexane ratios.
- light hydrocarbon compounds /
- thermal maturity /
- natural gas origin /
- gas-source correlation /
- migration phase state /
- Daniudi Gas Field /
- Ordos Basin
注释:

1) 所有作者声明不存在利益冲突。

1) 利益冲突声明/Conflict of Interests

2) 倪春华、吴小奇、王付斌、贾会冲参与论文的构思；王萍、朱建辉、张毅、姜海健参与实验设计；王萍完成实验操作；倪春华、吴小奇、朱建辉参与论文写作和修改。所有作者均阅读并同意最终稿件的提交。

2) 作者贡献/Authors’Contributions

HTML全文

图 1 鄂尔多斯盆地大牛地气田位置(a)及地层综合柱状图(b)

据参考文献[24]修改。

Figure 1. Location of Daniudi Gas Field in Ordos Basin (a) and stratigraphic column (b)

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图 2 大牛地气田上古生界天然气轻烃色谱图

1.2-甲基戊烷；2.3-甲基戊烷；3.正己烷；4.甲基环戊烷；5.苯；6.环己烷；7.2-甲基己烷；8.3-甲基己烷；9.正庚烷；10.甲基环己烷。

Figure 2. Chromatogram of light hydrocarbons in natural gas from Upper Paleozoic, Daniudi Gas Field

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图 3 大牛地气田上古生界天然气C_5-7正构烷烃、异构烷烃和环烷烃组成

底图据戴金星等^[27]。

Figure 3. Ternary diagram of n-C_5-7, iso-C_5-7 and cyc-C_5-7 in natural gas from Upper Paleozoic, Daniudi Gas Field

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图 4 大牛地气田上古生界天然气正庚烷、甲基环己烷和二甲基环戊烷相对组成

底图据戴金星等^[27]。

Figure 4. Ternary diagram of n-heptane, methylcyclohexane and various dimethylcyclopentane in natural gas from Upper Paleozoic, Daniudi Gas Field

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图 5 大牛地气田上古生界天然气δD₁与δ¹³C₁值相关图

底图据参考文献[28]。

Figure 5. Correlation between δD₁ and δ¹³C₁ values of natural gas from Upper Paleozoic, Daniudi Gas Field

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图 6 大牛地气田上古生界天然气庚烷值和异庚烷值相关图

底图据THOMPSON^[18]。

Figure 6. Correlation between heptane and isoheptane values of natural gas from Upper Paleozoic, Daniudi Gas Field

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图 7 大牛地气田上古生界天然气苯/正己烷(a)、甲苯/正庚烷(b)比值与δ¹³C₁值相关图

Figure 7. Correlation between benzene/n-hexane (a), toluene/n-heptane (b) and δ¹³C₁ values of natural gas from Upper Paleozoic, Daniudi Gas Field

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图 8 大牛地气田上古生界天然气(2-MH+2, 3-DMP)/C₇与(3-MH+2, 4-DMP)/C₇相关图

Figure 8. Correlation between (2-MH+2, 3-DMP)/C₇ and (3-MH+2, 4-DMP)/C₇ of natural gas from Upper Paleozoic, Daniudi Gas Field

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图 9 大牛地气田上古生界天然气(P₂+N₂)/C₇与P₃/C₇相关图

Figure 9. Correlation between (P₂+N₂)/C₇ and P₃/C₇ of natural gas from Upper Paleozoic, Daniudi Gas Field

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图 10 大牛地气田上古生界天然气δ¹³C₁(a)和δ¹³C₂(b)与正庚烷/甲基环己烷相关图

Figure 10. Correlation between δ¹³C₁ (a), δ¹³C₂ (b) and n-heptane/methyl-cyclohexane of natural gas from Upper Paleozoic, Daniudi Gas Field

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图 11 大牛地气田下石盒子组(P₁x)天然气苯/正己烷(a)和正庚烷/甲基环己烷比值(b)分布

Figure 11. Distribution of benzene/n-hexane (a) and n-heptane/methylcyclohexane (b) ratios of Lower Shihezi natural gas from Daniudi Gas Field

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图 12 大牛地气田上古生界天然气苯/正己烷与苯/环己烷(a)、甲苯/正庚烷(b)相关图

Figure 12. Correlation between benzene/cyclohexane (a), toluene/n-heptane (b) and benzene/n-hexane of Upper Paleozoic natural gas from Daniudi Gas Field

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表 1 大牛地气田上古生界天然气轻烃相对组成和烷烃气碳氢同位素值

Table 1. Relative composition of light hydrocarbons and carbon and hydrogen isotopic values of alkanes in natural gas from Upper Paleozoic, Daniudi Gas Field

井号	深度/m	层位	C_5-7相对组成/%			C_6-7相对组成/%			C₇相对组成/%			甲基环己烷指数/%	δ¹³C_V-PDB /‰		δD₁ _V-SMOW / ‰
井号	深度/m	层位	正构烷烃	异构烷烃	环烷烃	链烷烃	环烷烃	芳烃	二甲基环戊烷	正庚烷	甲基环己烷	甲基环己烷指数/%	CH₄	C₂H₆	δD₁ _V-SMOW / ‰
D1		P₁x	23.8	49.8	26.4	52.0	47.2	0.8	24.4	12.9	62.7	61.3	-37.4	-25.7	-201
D2	2 548	P₁x	24.2	50.9	24.8	62.0	36.8	1.3	21.0	22.8	56.2	55.2	-35.8	-26.1	-181
D3	2 633	P₁x	22.4	51.1	26.5	52.4	46.0	1.6	25.8	11.5	62.8	61.4	-37.7	-25.2	-197
D4	2 675	P₁x	28.6	54.1	17.3	77.0	22.5	0.5	19.3	38.3	42.4	41.9	-35.8	-26.2	-181
D5	2 709	P₁x	34.8	44.5	20.7	70.5	28.9	0.6	18.9	39.1	42.0	41.4	-35.5	-26.5	-185
D6	2 716	P₁x	23.8	48.3	27.9	58.8	40.6	0.6	36.7	18.3	45.0	44.4	-37.1	-25.9	-197
D7	2 749	P₁x	29.9	43.9	26.2	62.9	36.3	0.7	17.2	32.0	50.8	50.0	-34.3	-25.9	-181
D8	2 789	P₁x	23.6	54.8	21.6	59.8	39.8	0.4	29.2	14.5	56.3	55.2	-34.7	-25.4	-189
D9	2 660	P₁x	31.0	44.1	24.9	65.7	34.3	-	16.0	32.4	51.6	50.9	-35.7	-26.0	-184
D10	2 631	P₁x	22.6	53.3	24.1	54.9	44.7	0.4	28.2	10.4	61.4	60.2	-37.2	-24.9	-198
D11	2 667	P₁x	22.8	48.5	28.7	58.7	40.3	1.0	16.4	24.0	59.5	58.6	-34.5	-25.8	-181
D12	2 669	P₁x	34.5	43.7	21.8	70.1	29.7	0.2	13.7	38.3	48.0	47.3	-35.4	-25.7	-182
D13	2 673	P₁x	19.6	52.1	28.2	55.9	44.0	0.1	20.9	11.4	67.7	66.6	-34.6	-25.2	-183
D14	2 698	P₁x	34.4	47.5	18.1	75.6	24.4	-	25.6	37.7	36.7	36.4	-35.5	-26.2	-188
D15	2 703	P₁x	20.9	52.4	26.7	57.7	42.3	-	20.8	15.0	64.3	63.3	-34.9	-25.6	-180
D16	2 700	P₁x	28.3	51.2	20.5	72.1	27.9	-	14.9	38.0	47.0	46.6	-35.5	-25.7	-182
D17	2 635	P₁x	25.5	54.8	19.7	63.8	36.2	-	29.4	15.0	55.6	54.6	-36.6	-26.0	-197
D18	2 716	P₁x	21.1	51.3	27.5	57.4	42.6	-	20.8	14.8	64.4	63.5	-35.0	-25.6	-181
D19	2 675	P₁x	24.6	52.1	23.3	65.1	34.9	-	16.8	25.7	57.5	56.8	-35.0	-26.2	-180
D20	2 685	P₁x	25.8	48.7	25.5	63.9	36.1	-	17.2	28.4	54.4	53.9	-35.2	-25.8	-181
D21	2 680	P₁x	22.8	51.5	25.7	61.0	39.0	-	17.6	21.9	60.5	59.8	-35.1	-26.0	-179
D22	2 630	P₁s	24.5	53.7	21.8	60.3	38.8	0.8	26.2	17.1	56.7	55.6	-36.0	-25.1	-197
D23	2 830	P₁s	24.1	52.5	23.4	58.5	39.7	1.8	26.5	17.2	56.4	55.3	-36.0	-25.3	-195
D24	2 783	P₁s	21.6	47.0	31.4	44.4	47.5	8.1	20.2	11.2	68.6	67.2	-35.0	-24.0	-196
D25	2 831	P₁s	22.9	52.0	25.1	57.3	41.4	1.3	28.5	14.7	56.9	55.9	-35.9	-24.6	-193
D26	2 819	P₁s	25.1	51.6	23.3	58.1	41.2	0.7	20.5	17.4	62.1	60.7	-33.3	-24.8	-179
D27	2 812	P₁s	23.3	49.1	27.6	53.4	44.0	2.6	22.1	14.7	63.1	61.9	-34.1	-24.8	-186
D28	2 846	P₁s	21.5	46.2	32.3	55.8	41.6	2.6	31.5	17.1	51.4	50.6	-35.8	-24.5	-193
D29	2 744	P₁s	19.7	49.6	30.7	49.0	49.3	1.7	20.4	9.2	70.4	69.1	-33.8	-23.9	-192
D30	2 879	P₁s	22.1	53.5	24.4	56.2	43.8	-	22.0	11.0	67.0	65.9	-34.5	-25.1	-186
D31	2 881	P₁s	32.5	50.8	16.7	62.4	35.9	1.7	35.3	14.0	50.7	50.1	-37.0	-25.0	-209
D32	2 826	P₁s	22.5	51.8	25.8	55.5	44.5	-	21.1	12.0	66.8	65.6	-34.4	-25.5	-187
D33		P₁s	28.4	45.3	26.3	49.3	50.3	0.5	20.1	15.0	64.8	63.6	-36.9	-25.0	-201
D34	2 820	P₁s	24.6	54.5	20.9	56.4	42.9	0.7	24.8	12.9	62.4	61.3	-36.2	-24.2	-201
D35	2 795	C₃t	25.8	49.9	24.3	57.0	39.9	3.1	20.3	17.2	62.5	61.4	-37.5	-25.5	-201
D36	2 439	C₃t	27.7	51.7	20.6	61.7	36.6	1.7	22.8	19.6	57.6	56.6	-37.5	-26.1	-204
D37	2 417	C₃t	23.6	48.2	28.2	53.4	41.9	4.6	17.6	16.5	65.9	64.4	-37.9	-25.2	-197
D38	2 557	C₃t	22.5	48.9	28.6	55.0	42.0	3.0	21.8	17.3	60.9	59.8	-37.7	-25.0	-195
D39	2 570	C₃t	21.7	44.6	33.8	47.4	45.7	6.9	19.5	16.2	64.3	62.9	-37.8	-24.8	-197
D40	2 795	C₃t	24.9	51.6	23.5	58.2	41.1	0.7	21.7	12.6	65.7	64.6	-38.0	-25.3	-205
D41	2 453	C₃t	26.2	54.3	19.5	62.7	36.7	0.7	22.6	11.6	65.8	64.7	-37.8	-25.1	-204
D42	2 455	C₃t	25.5	49.8	24.7	56.4	43.6	-	21.6	12.2	66.3	65.2	-37.7	-24.9	-205
D43	2 466	C₃t	24.4	51.5	24.1	55.4	43.5	1.1	19.5	10.4	70.2	68.9	-37.8	-25.2	-204
D44	2 462	C₃t	20.8	52.6	26.6	57.6	41.7	0.7	19.3	15.2	65.5	64.4
D45		C₃t	27.4	54.5	18.1	65.2	34.4	0.5	29.0	13.7	57.3	56.5	-37.2	-25.4	-198

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表 2 大牛地气田上古生界天然气轻烃地球化学特征参数

Table 2. Typical geochemical parameters of light hydrocarbons in natural gas from Upper Paleozoic, Daniudi Gas Field

井号	层位	庚烷值/%	异庚烷值	2, 4-二甲基戊烷/2, 3-二甲基戊烷	气源岩最大埋深温度/℃	苯/正己烷	苯/环己烷	正庚烷/甲基环己烷	甲苯/正庚烷	K₁	P₂/C₇/%	N₂/C₇/%	P₃/C₇/%	K₂
D1	P₁x	8.18	1.18	0.777	136.2	0.076	0.099	0.205	0.005	1.09	13.76	8.83	7.61	0.34
D2	P₁x	12.50	2.44	0.771	136.1	0.101	0.140	0.406	0.012	1.09	21.26	6.66	10.91	0.39
D3	P₁x	7.18	1.19	0.844	137.5	0.115	0.138	0.183	0.136	1.04	13.83	8.82	8.54	0.38
D4	P₁x	18.53	4.48	0.966	139.5	0.028	0.093	0.905	-	1.09	28.30	5.27	15.11	0.45
D5	P₁x	22.67	2.73	1.068	141.0	0.025	0.080	0.932	0.012	1.09	23.02	6.11	9.09	0.31
D6	P₁x	9.28	1.58	0.849	137.5	0.048	0.071	0.406	-	1.15	20.89	10.06	10.58	0.34
D7	P₁x	19.23	2.55	0.815	136.9	0.050	0.098	0.630	0.002	1.09	20.39	6.20	9.04	0.34
D8	P₁x	8.73	1.33	0.976	139.6	0.029	0.052	0.258	0.007	1.06	16.54	9.33	9.06	0.35
D9	P₁x	19.07	2.86	0.777	136.2	-	-	0.629	-	1.07	20.84	5.38	9.53	0.36
D10	P₁x	6.31	1.14	0.799	136.6	0.039	0.050	0.169	-	1.06	13.70	9.19	8.95	0.39
D11	P₁x	13.49	2.90	0.666	133.9	0.096	0.101	0.403	-	1.10	20.05	5.84	10.74	0.41
D12	P₁x	24.31	2.74	0.629	133.0	0.007	0.024	0.799	0.003	1.06	18.49	4.91	10.35	0.44
D13	P₁x	6.24	2.19	0.732	135.3	-	-	0.168	0.031	1.05	18.27	6.96	10.81	0.43
D14	P₁x	17.59	3.23	1.074	141.1	-	-	1.026	-	1.08	26.82	6.38	13.29	0.40
D15	P₁x	8.10	2.10	0.660	133.8	-	-	0.233	-	1.06	17.55	6.72	11.36	0.47
D16	P₁x	19.67	4.81	0.741	135.5	-	-	0.809	-	1.06	26.25	4.52	13.81	0.45
D17	P₁x	8.79	1.37	0.923	138.8	-	-	0.271	-	1.02	16.12	8.81	10.06	0.40
D18	P₁x	8.13	2.20	0.767	136.0	-	-	0.230	-	1.09	18.47	6.82	11.06	0.44
D19	P₁x	13.99	3.45	0.766	136.0	-	-	0.447	-	1.06	22.33	5.68	11.79	0.42
D20	P₁x	16.13	2.84	0.674	134.1	-	-	0.522	-	1.10	21.10	5.56	11.23	0.42
D21	P₁x	12.05	2.79	0.686	134.3	-	-	0.361	-	1.06	19.24	5.73	12.22	0.49
D22	P₁s	10.24	1.49	0.896	138.4	0.050	0.090	0.301	0.053	1.08	17.12	8.41	9.21	0.36
D23	P₁s	10.10	1.45	0.839	137.4	0.150	0.227	0.304	0.011	1.07	16.32	8.46	9.49	0.38
D24	P₁s	6.69	1.46	0.588	132.0	0.711	0.507	0.163	0.651	1.13	13.31	7.14	7.70	0.38
D25	P₁s	8.49	1.31	0.928	138.9	0.114	0.162	0.258	0.004	1.00	14.80	8.64	12.79	0.55
D26	P₁s	10.61	1.84	0.837	137.3	0.054	0.092	0.280	0.006	1.09	16.03	6.24	8.09	0.36
D27	P₁s	8.73	1.64	0.785	136.4	0.238	0.263	0.233	0.008	1.09	16.21	7.75	8.91	0.37
D28	P₁s	9.23	1.54	0.898	138.4	0.164	0.220	0.333	0.139	1.10	18.88	9.24	10.14	0.36
D29	P₁s	5.52	1.50	0.748	135.6	0.210	0.148	0.131	-	1.02	13.60	7.28	10.09	0.48
D30	P₁s	6.35	1.79	0.673	134.1	-	-	0.165	-	1.05	16.01	7.35	10.11	0.43
D31	P₁s	6.24	1.41	0.876	138.0	0.096	0.172	0.276	-	1.10	14.29	8.33	9.09	0.40
D32	P₁s	6.96	1.75	0.677	134.2	-	-	0.180	-	1.10	15.85	7.23	9.85	0.43
D33	P₁s	9.75	1.22	0.537	130.7	0.036	0.044	0.232	-	1.14	12.87	7.87	5.16	0.25
D34	P₁s	7.79	1.32	0.840	137.4	0.058	0.080	0.206	-	1.08	14.43	8.62	7.90	0.34
D35	C₃t	9.79	2.01	0.745	135.6	0.252	0.330	0.275	-	1.10	17.87	7.09	9.55	0.38
D36	C₃t	10.62	1.99	0.805	136.7	0.123	0.187	0.341	0.004	1.08	18.69	7.00	10.67	0.42
D37	C₃t	9.74	2.22	0.700	134.6	0.432	0.481	0.250	0.015	1.07	17.71	6.52	9.19	0.38
D38	C₃t	10.12	2.28	1.308	144.0	0.305	0.324	0.285	0.008	1.07	22.50	7.50	7.50	0.25
D39	C₃t	9.31	1.99	0.644	133.4	0.762	0.587	0.252	0.007	1.10	17.79	6.90	8.89	0.36
D40	C₃t	6.98	1.95	0.788	136.4	0.055	0.067	0.192	0.016	1.05	17.59	7.07	9.62	0.39
D41	C₃t	6.32	1.90	0.781	136.3	0.047	0.069	0.176	0.027	1.09	16.75	7.26	10.22	0.43
D42	C₃t	6.87	1.79	0.799	136.6	-	-	0.184	0.007	1.04	16.68	7.41	8.79	0.36
D43	C₃t	6.01	1.93	0.774	136.2	0.094	0.106	0.148	0.014	1.07	16.25	6.76	8.79	0.38
D44	C₃t	8.74	2.35	0.625	133.0	0.076	0.079	0.232	-	1.11	18.69	7.06	11.10	0.43
D45	C₃t	7.12	1.60	0.742	135.5	0.035	0.059	0.239	-	1.10	16.10	7.66	12.42	0.52
注：气源岩最大埋深温度[T=140+15ln(2, 4-二甲基戊烷/2, 3-二甲基戊烷)]^[17]；K₁=(2-甲基己烷+2, 3-二甲基戊烷)/(3-甲基己烷+2, 4-二甲基戊烷)^[25]；P₂、N₂、P₃分别为2-甲基己烷+3-甲基己烷、1, 1-二甲基环戊烷+1, 顺, 3-二甲基环戊烷+1, 反, 3-二甲基环戊烷、各类二甲基戊烷+3-乙基戊烷^[26]；K₂=P₃/(P₂+N₂)，即：(各类二甲基戊烷+3-乙基戊烷)/(2-甲基己烷+3-甲基己烷+1, 1-二甲基环戊烷+1, 顺, 3-二甲基环戊烷+1, 反, 3-二甲基环戊烷)^[26]。

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鄂尔多斯盆地大牛地气田上古生界致密气轻烃地球化学特征

doi: 10.11781/sysydz202402366

作者简介:
倪春华(1981—)，男，博士，高级工程师，本刊编委，从事油气地质与地球化学研究。E-mail: nichunhua.syky@sinopec.com

通讯作者:
吴小奇(1982—)，男，博士，高级工程师，本刊青年编委，从事油气成藏地球化学研究。E-mail: xqwu@163.com

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Geochemical characteristics of light hydrocarbons in Upper Paleozoic tight gas from Daniudi Gas Field, Ordos Basin

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留言板

鄂尔多斯盆地大牛地气田上古生界致密气轻烃地球化学特征

doi: 10.11781/sysydz202402366

作者简介: 倪春华(1981—)，男，博士，高级工程师，本刊编委，从事油气地质与地球化学研究。E-mail: nichunhua.syky@sinopec.com

通讯作者: 吴小奇(1982—)，男，博士，高级工程师，本刊青年编委，从事油气成藏地球化学研究。E-mail: xqwu@163.com

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Geochemical characteristics of light hydrocarbons in Upper Paleozoic tight gas from Daniudi Gas Field, Ordos Basin

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出版历程

目录

作者简介:
倪春华(1981—)，男，博士，高级工程师，本刊编委，从事油气地质与地球化学研究。E-mail: nichunhua.syky@sinopec.com

通讯作者:
吴小奇(1982—)，男，博士，高级工程师，本刊青年编委，从事油气成藏地球化学研究。E-mail: xqwu@163.com