非常规天然气中氦资源潜力及富集机制

doi:10.7623/syxb202502011

石油学报 ›› 2025, Vol. 46 ›› Issue (2): 440-455,482.DOI: 10.7623/syxb202502011

非常规天然气中氦资源潜力及富集机制

马勇¹, 陈践发¹, 辛志源¹, 罗情勇¹, 罗超², 张海鹏¹, 钟可塑², 车世琦¹, 马健斌¹, 秦长彩¹

1. 油气资源与工程全国重点实验室,中国石油大学(北京) 北京 102249;
2. 中国石油西南油气田公司页岩气研究院四川成都 610051

收稿日期:2024-05-28 修回日期:2024-09-09 出版日期:2025-03-13 发布日期:2025-03-13
通讯作者: 陈践发,男,1961年7月生,2001年获中国科学院地球化学研究所博士学位,现为中国石油大学(北京)地球科学学院教授,主要从事天然气地质和地球化学研究工作。Email:jfchen@cup.edu.cn
作者简介:马勇,男,1988年7月生,2016年获中国石油大学(北京)博士学位,现为中国石油大学(北京)地球科学学院副教授,主要从事油气地质和地球化学研究工作。Email:mayong@cup.edu.cn
基金资助:
国家重点研发计划项目"富氦天然气成藏机制及氦资源分布预测技术"(2021YFA0719000)和国家自然科学基金项目"碎屑岩地层天然气运移过程中烃-岩石相互作用机理"(No.42173030)资助。

Helium resource potential and enrichment mechanism of unconventional gas

Ma Yong¹, Chen Jianfa¹, Xin Zhiyuan¹, Luo Qingyong¹, Luo Chao², Zhang Haipeng¹, Zhong Kesu², Che Shiqi¹, Ma Jianbin¹, Qin Changcai¹

1. State Key Laboratory of Petroleum Resources and Engineering, China University of Petroleum (Beijing), Beijing 102249, China;
2. Shale Gas Research Institute, PetroChina Southwest Oil & Gasfield Company, Sichuan Chengdu 610051, China

Received:2024-05-28 Revised:2024-09-09 Online:2025-03-13 Published:2025-03-13

摘要/Abstract

摘要： 从含氦、富氦天然气藏中提取氦气是目前工业制氦最重要的途径,评价储量规模巨大的非常规天然气中的氦含量及成因机制对于丰富氦资源来源具有重要意义。基于全球450个含氦页岩气和煤层气样品的地球化学特征分析表明,页岩气中的氦含量为6× 10^-8~0.011 4(平均为0.057 % ),煤层气中的氦含量为5×10^-7~0.022 8(平均为0.115 % ),超过24 % 的非常规天然气样品中的氦含量达到0.05 % 。非常规天然气整体具有较低的³He/⁴He比值(0.002~0.930,平均为0.071),表明壳源氦为其主要来源。U、Th含量及放射性衰变模拟计算表明,页岩气的源内氦含量与其现今实测氦含量的分布特征一致,富氦页岩气中的⁴⁰Ar/³⁶Ar比值与同期源岩累积产生的⁴⁰Ar/³⁶Ar比值相同,且富氦页岩气藏中往往不发育与深部幔源或基底连通的大型断裂,这表明页岩气中的氦主要来自页岩源内富U、Th矿物的放射性衰变。氦气具有比甲烷更强的吸附能力,且页岩气藏中较低的氦浓度可形成毛细管阻力,二者共同作用是页岩气中的氦气能够保存的主要原因。煤层气的源内氦含量通常较小(＜120×10^-6),远低于现今气藏实测的氦含量。富氦煤层气中的氦主要来自基底岩石的放射性衰变。生氦潜力、储层渗透性和水动力作用是导致页岩气和煤层气中氦气富集机制差异的主要原因。U含量在10×10^-6以上且具有一定含气量(＞1 m³/t)的石炭纪之前古老页岩,以及成藏年代较晚、底部有充足氦源(包括壳源氦和幔源氦)供给的煤层是富氦非常规天然气富集的有利区带。中国中—上扬子地区寒武系页岩和鄂尔多斯盆地石炭系—二叠系煤层是富氦非常规天然气的有利勘探层位。

关键词: 氦气, 页岩气, 煤层气, 富氦非常规天然气, 富集成藏机制

Abstract: At present, it is the most important way for industrial helium production by extracting helium from helium-containing and helium-rich natural gas reservoirs. It is of great significance to evaluate the helium content and formation mechanism of unconventional gas with huge reserves, which can enrich the source of helium resources. The geochemical characteristic analyses of 450 helium-containing shale gas and coalbed methane (CBM)samples taken from the world show that the helium content of shale gas ranges from 6×10^-8 to 0.011 4 (0.057 % on the average), that of CBM ranges from 5×10^-7 to 0.022 8 (0.115 % on the average), and that of more than 24 % of unconventional gas samples can reach 0.05 % . Unconventional gas generally has a low ³He/⁴He ratio (from 0.002 to 0.93, 0.071 on the average), indicating that crust-derived helium is the main source. The radioactive decay calculations of uranium and thorium contents indicate that the helium content generated in shale gas source is consistent with the distribution characteristics of the currently measured helium content. The ⁴⁰Ar/³⁶Ar ratio in helium-rich shale gas is the same as that the accumulative ratio of contemporaneous source rocks. Large faults connected with deep mantle source or basement were usually not developed in helium-rich shale gas reservoirs. All of those indicate that helium in shale gas is mainly resulted from the radioactive decay of uranium and Th-rich minerals in the shale source. Helium has a stronger adsorption capacity than methane, and the lower concentration of helium in shale gas reservoirs may lead to capillary resistance, which are the primary causes for the preservation of helium in shale gas. The content of helium generated in CBM source is usually lower (less than 20×10^-6)than that currently measured in gas reservoir, and the helium in helium-rich CBM is primarily originated from the radioactive decay of basement rocks. Helium-producing potential, reservoir permeability and hydrodynamics are the main reasons for the differences in helium enrichment mechanism of shale gas and CBM. The favorable zones for the enrichment of helium-rich unconventional gas include the pre-Carboniferous shale with certain gas content above 1 m³/t and uranium content above 10×10^-6, and the coal seam with late accumulation and sufficient helium source supply (including crust source helium and mantle source helium)at the bottom of the reservoir. In addition, the Cambrian shale in the Middle and Upper Yangtze areas and the Carboniferous-Permian coal seam in Ordos Basin are considered as the favorable exploration horizons for unconventional helium-rich gas in China.

Key words: helium, shale gas, coalbed methane, helium-rich unconventional gas, enrichment and accumulation mechanism

中图分类号:

TE132.3

马勇, 陈践发, 辛志源, 罗情勇, 罗超, 张海鹏, 钟可塑, 车世琦, 马健斌, 秦长彩. 非常规天然气中氦资源潜力及富集机制[J]. 石油学报, 2025, 46(2): 440-455,482.

Ma Yong, Chen Jianfa, Xin Zhiyuan, Luo Qingyong, Luo Chao, Zhang Haipeng, Zhong Kesu, Che Shiqi, Ma Jianbin, Qin Changcai. Helium resource potential and enrichment mechanism of unconventional gas[J]. Acta Petrolei Sinica, 2025, 46(2): 440-455,482.

参考文献

[1] 彭威龙,刘全有,张英,等. 中国首个特大致密砂岩型(烃类)富氦气田——鄂尔多斯盆地东胜气田特征[J].中国科学:地球科学,2022,52(6):1078-1085.
PENG Weilong,LIU Quanyou,ZHANG Ying,et al.The first extra-large helium-rich gas field identified in a tight sandstone of the Dongsheng gas field,Ordos Basin,China[J].Science China Earth Sciences,2022,65(5):874-881.
[2] 徐永昌,沈平,陶明信,等.东部油气区天然气中幔源挥发份的地球化学——Ⅰ.氦资源的新类型:沉积壳层幔源氦的工业储集[J].中国科学(D辑),1996,26(1):1-8.
XU Yongchang,SHEN Ping,TAO Mingxin,et al.Geochemistry on mantle-derived volatiles in natural gases from eastern China oil/gas provinces (I):a novel helium resource—commercial accumulation of mantle-derived helium in the sedimentary crust[J].Science in China Series D,1997,40(2):120-129.
[3] BROWN A A.Formation of high helium gases:a guide for explorationists[C]//2010 AAPG Convention and Exhibition.New Orleans:AAPG,2010:80115.
[4] 秦胜飞,李济远,梁传国,等.中国中西部富氦气藏氦气富集机理——古老地层水脱氦富集[J].天然气地球科学,2022,33(8):1203-1217.
QIN Shengfei,LI Jiyuan,LIANG Chuanguo,et al.Helium enrichment mechanism of helium rich gas reservoirs in central and western China:degassing and accumulation from old formation water[J].Natural Gas Geoscience,2022,33(8):1203-1217.
[5] 王晓锋,刘全有,刘文汇,等.中国东部含油气盆地幔源氦气资源富集成藏机理[J].中国科学:地球科学,2022,52(12):2441-2453.
WANG Xiaofeng,LIU Quanyou,LIU Wenhui,et al.Accumulation mechanism of mantle-derived helium resources in petroliferous basins,eastern China[J].Science China Earth Sciences,2022,65(12):2322-2334.
[6] 王海东,刘成林,范立勇,等.古隆起背景下多源供氦氦气富集模式——以鄂尔多斯盆地庆阳气田为例[J/OL].天然气地球科学,(2024-08-22).https://kns.cnki.net/kcms2/article/abstract?v= rdiHbV4QUxYTb1tBRkJ7OZfnbRgPRwJAa3albkb6hYyCNZVu 5B1sQHjDOAtQl-aBeZN0M0_nJfFrGqs09Qe2BQGm91ydZX5O x_2tm6gFSqZLamj0kbGZVbde6ur2Ex6mTAIqSMm_73-hTdQ GccoKzDd76na8RZRUsWRXYNE6ReJDo9CKL3fm6-1fXWhN8 jn5&uniplatform=NZKPT&language=CHS.
WANG Haidong,LIU Chenglin,FAN Liyong,et al.Helium enrichment patterns of multi-source helium supply in the context of paleo-uplifment:a case study of the Qingyang gas field in the Ordos Basin[J/ OL].Natural Gas Geoscience,(2024-08-22).https:// kns.cnki.net/kcms2/article/abstract?v=rdiHbV4QUxYTb1t BRkJ7OZfnbRgPRwJAa3albkb6hYyCNZVu5B1sQHjDOAtQl-a BeZN0M0_nJfFrGqs09Qe2BQGm91ydZX5Ox_2tm6gFSqZLamj 0kbGZVbde6ur2Ex6mTAIqSMm_73-hTdQGccoKzDd76na8RZR UsWRXYNE6ReJDo9CKL3fm6-1fXWhN8jn5& uniplatform= NZ KPT&language=CHS.
[7] YAKUTSENI V P.World helium resources and the perspectives of helium industry development[J].Neftegazovaya Geologiya Teoriya I Praktika,2014,9(1):1-22.
[8] BALLENTINE C J,LOLLAR B S.Regional groundwater focusing of nitrogen and noble gases into the Hugoton-Panhandle giant gas field,USA[J].Geochimica et Cosmochimica Acta,2002,66(14):2483-2497.
[9] 陶小晚,李建忠,赵力彬,等.我国氦气资源现状及首个特大型富氦储量的发现:和田河气田[J].地球科学,2019,44(3):1024-1041.
TAO Xiaowan,LI Jianzhong,ZHAO Libin,et al.Helium resources and discovery of first supergiant helium reserve in China:Hetianhe gas field[J].Earth Science,2019,44(3):1024-1041.
[10] 徐永昌,沈平.幔源氦的工业储聚和郯庐大断裂带[J].科学通报,1990,35(12):932-935.
XU Yongchang,SHEN Ping.Industrial accumulation of mantle source helium and the Tanchenglujiang fracture zone[J].Chinese Science Bulletin,1991,36(6):494-498.
[11] 陈燕燕,陶士振,杨秀春,等.页岩气和煤层气中氦气的地球化学特征和富集规律[J].天然气地球科学,2023,34(4):684-696.
CHEN Yanyan,TAO Shizhen,YANG Xiuchun,et al.The geochemical characteristics and enrichment of helium in shale gas and coalbed methane[J].Natural Gas Geoscience,2023,34(4):684-696.
[12] MILKOV A V,FAIZ M,ETIOPE G.Geochemistry of shale gases from around the world:composition,origins,isotope reversals and rollovers,and implications for the exploration of shale plays[J].Organic Geochemistry,2020,143:103997.
[13] 陶明信.中国煤层气同位素地球化学初步研究[J].地质学报,2015,89(增刊1):185-186.
TAO Mingxin.Preliminary study on isotope geochemistry of coalbed methane in China[J].Acta Geologica Sinica, 2015,89(S1):185-186.
[14] NUTTALL W J,CLARKE R H,GLOWACKI B A.Stop squandering helium[J].Nature,2012,485(7400):573-575.
[15] 罗胜元,陈孝红,刘安,等.中扬子宜昌地区下寒武统水井沱组页岩气地球化学特征及其成因[J].石油与天然气地质,2019,40(5):999-1010.
LUO Shengyuan,CHEN Xiaohong,LIU An,et al.Geochemical features and genesis of shale gas from the Lower Cambrian Shuijingtuo Formation shale in Yichang block,Middle Yangtze region[J].Oil & Gas Geology,2019,40(5):999-1010.
[16] 刘超,孙蓓蕾,曾凡桂,等.鄂尔多斯盆地东缘石西区块含氦天然气的发现及成因初探[J].煤炭学报,2021,46(4):1280-1287.
LIU Chao,SUN Beilei,ZENG Fangui,et al.Discovery and origin of helium-rich gas on the Shixi area,eastern margin of the Ordos Basin[J].Journal of China Coal Society,2021,46(4):1280-1287.
[17] 陈践发,刘凯旋,董勍伟,等.天然气中氦资源研究现状及我国氦资源前景[J].天然气地球科学,2021,32(10):1436-1449.
CHEN Jianfa,LIU Kaixuan,DONG Qingwei,et al.Research status of helium resources in natural gas and prospects of helium resources in China[J].Natural Gas Geoscience,2021,32(10):1436-1449.
[18] WARWICK P D,BRELAND JR F C,HACKLEY P C.Biogenic origin of coalbed gas in the northern Gulf of Mexico coastal plain,U.S.A.[J].International Journal of Coal Geology,2008,76(1/2):119-137.
[19] 曹军,刘成林,马寅生,等.柴达木盆地东部石炭系海陆过渡相煤系页岩气地球化学特征及成因[J].地学前缘,2016,23(5):158-166.
CAO Jun,LIU Chenglin,MA Yinsheng,et al.Geochemical characteristics and genesis of shale gas for Carboniferous marine-continental transitional facies coal measure strata in eastern Qaidam Basin[J].Earth Science Frontiers,2016,23(5):158-166.
[20] 张云鹏,李玉宏,卢进才,等.柴达木盆地北缘富氦天然气的发现——兼议成藏地质条件[J].地质通报,2016,35(2/3):364-371.
Z HANG Yunpeng,LI Yuhong,LU Jincai,et al.The discovery and origin of helium-rich gas on the northern margin of the Qaidam Basin[J].Geological Bulletin of China,2016,35(2/3):364-371.
[21] ABRAMS M A,THOMAS D.Geochemical evaluation of oil and gas samples from the Upper Devonian and Mississippian reservoirs southern Anadarko Basin Oklahoma and its implication for the Woodford shale unconventional play[J].Marine and Petroleum Geology,2020,112:104043.
[22] TILLEY B,MCLELLAN S,HIEBERT S,et al.Gas isotope reversals in fractured gas reservoirs of the western Canadian Foothills:mature shale gases in disguise[J]. AAPG Bulletin,2011,95(8):1399-1422.
[23] BALLENTINE C J,O’NIONS R K.The nature of mantle neon contributions to Vienna Basin hydrocarbon reservoirs[J].Earth and Planetary Science Letters,1992,113(4):553-567.
[24] GYÖRE D,MCKAVNEY R,GILFILLAN S M V,et al.Fingerprinting coal-derived gases from the UK[J].Chemical Geology,2018,480:75-85.
[25] 陈磊,田景春,文怀军,等.柴达木盆地北缘鱼卡煤田侏罗系煤层气特征及含气性评价[J].石油实验地质,2019,41(2):215-221.
CHEN Lei,TIAN Jingchun,WEN Huaijun,et al.Jurassic coal bed methane characteristics and gas-bearing property evaluation in Iqe coalfield,northern Qaidam Basin[J].Petroleum Geology & Experiment,2019,41(2):215-221.
[26] 郭望,张卫刚,李玉宏,等.柴北缘大煤沟组七段页岩地球化学特征——对中侏罗世晚期物源及风化作用的指示及意义[J].沉积学报,2020,38(3):676-686.
GUO Wang,ZHANG Weigang,LI Yuhong,et al.Geochemistry of 7 Member shale of the Dameigou Formation in the northern Qaidam Basin,China:significance and implication for provenance and source weathering in the Late Middle Jurassic[J].Acta Sedimentologica Sinica,2020,38(3):676-686.
[27] 汤艳,张云鹏,李永红.柴北缘大煤沟组七段(J₂d⁷)页岩油资源潜力评价——以大煤沟地区为例[J].中国地质,2016,43(2):575-584.
TANG Yan,ZHANG Yunpeng,LI Yonghong.The potential evaluation of shale oil in the seventh member of Dameigou Formation(J₂d⁷)on the northern margin of Qaidam Basin:a case study of Dameigou area[J].Geology in China,2016,43(2):575-584.
[28] 乔世海.柴达木盆地北缘典型地区页岩气形成条件及控制因素研究[D].北京:中国地质大学(北京),2020.
QIAO Shihai.Study on shale gas formation condition and control factors in typical area in the north Qaidam Basin[D].Beijing:China University of Geosciences (Beijing),2020.
[29] MARDON S M,EBLE C F,HOWER J C,et al.Organic petrology,geochemistry,gas content and gas composition of Middle Pennsylvanian age coal beds in the eastern Interior (Illinois)Basin:implications for CBM development and carbon sequestration[J].International Journal of Coal Geology,2014,127:56-74.
[30] MORE S,RIT R,KHAN M A,et al.Record of leaf and pollen cf.Sloanea (Elaeocarpaceae)from the middle Siwalik of Darjeeling sub-Himalaya,India and its palaeobiogeographic implications[J].Journal of the Geological Society of India,2018,91(3):301-306.
[31] CHEN Biying,STUART F M,XU Sheng,et al.Evolution of coal-bed methane in southeast Qinshui Basin,China:insights from stable and noble gas isotopes[J].Chemical Geology,2019,529:119298.
[32] XU Zhanjie,LIU Qinfu,ZHENG Qiming,et al.Isotopic composition and content of coalbed methane production gases and waters in karstic collapse column area,Qinshui coalfield,China[J].Journal of Geochemical Exploration,2016,165:94-101.
[33] MA Yong,ARDAKANI O H,ZHONG Ningning,et al.Possible pore structure deformation effects on the shale gas enrichment:an example from the Lower Cambrian shales of the eastern Upper Yangtze platform,South China[J].International Journal of Coal Geology,2020,217:103349.
[34] DAI Shifeng,REN Deyi,CHOU Chenlin,et al.Geochemistry of trace elements in Chinese coals:a review of abundances,genetic types,impacts on human health,and industrial utilization[J].International Journal of Coal Geology,2012,94:3-21.
[35] LIU Yang,ZHANG Jinchuan,REN Jun,et al.Stable isotope geochemistry of the nitrogen-rich gas from Lower Cambrian shale in the Yangtze gorges area,South China[J].Marine and Petroleum Geology,2016,77:693-702.
[36] MOORE M T,VINSON D S,WHYTE C J,et al.Differentiating between biogenic and thermogenic sources of natural gas in coalbed methane reservoirs from the Illinois Basin using noble gas and hydrocarbon geochemistry[J].Geological Society,London,Special Publications,2018,468(1):151-188.
[37] 马鹏程,邹雨,李超.霍西煤田9#煤和10#煤的煤岩学和煤质特征[J].煤炭技术,2016,35(10):135-137.
MA Pengcheng,ZOU Yu,LI Chao.Coal petrology and quality characteristics of No.9 and No.10 coal seam in Huoxi coalfield[J].Coal Technology,2016,35(10):135-137.
[38] 赵文智,王晓梅,胡素云,等.中国元古宇烃源岩成烃特征及勘探前景[J].中国科学:地球科学,2019,49(6):939-964.
ZHAO Wenzhi,WANG Xiaomei,HU Suyun,et al.Hydrocarbon generation characteristics and exploration prospects of Proterozoic source rocks in China[J].Science China Earth Sciences,2019,62(6):909-934.
[39] NI Yunyan,DAI Jinxing,TAO Shizhen,et al.Helium signatures of gases from the Sichuan Basin,China[J].Organic Geochemistry,2014,74:33-43.
[40] 黄金亮,邹才能,李建忠,等.川南下寒武统筇竹寺组页岩气形成条件及资源潜力[J].石油勘探与开发,2012,39(1):69-75.
HUANG Jinliang,ZOU Caineng,LI Jianzhong,et al.Shale gas generation and potential of the Lower Cambrian Qiongzhusi Formation in southern Sichuan Basin,China[J].Petroleum Exploration and Development,2012,39(1):69-75.
[41] WANG Ning,LI Meijun,TIAN Xingwang,et al.Main factors controlling the organic matter enrichment in the Lower Cambrian sediments of the Sichuan Basin,SW China[J].Geological Journal,2020,55(4):3083-3096.
[42] 董大忠,程克明,王世谦,等.页岩气资源评价方法及其在四川盆地的应用[J].天然气工业,2009,29(5):33-39.
DONG Dazhong,CHENG Keming,WANG Shiqian,et al.An evaluation method of shale gas resource and its application in the Sichuan Basin[J].Natural Gas Industry,2009,29(5):33-39.
[43] GAO Ping,LIU Gungdi,JIA Chengzao,et al.Redox variations and organic matter accumulation on the Yangtze carbonate platform during Late Ediacaran-Early Cambrian:constraints from petrology and geochemistry[J].Palaeogeography,Palaeoclimatology,Palaeoecology,2016,450:91-110.
[44] 马中豪,陈清石,史忠汪,等.鄂尔多斯盆地南缘延长组长7油页岩地球化学特征及其地质意义[J].地质通报,2016,35(9):1550-1558.
MA Zhonghao,CHEN Qingshi,SHI Zhongwang,et al.Geochemistry of oil shale from Chang 7 reservoir of Yanchang Formation in south Ordos Basin and its geological significance[J].Geological Bulletin of China,2016,35(9):1550-1558.
[45] DAI Jinxing,ZOU Caineng,LIAO Shimeng,et al.Geochemistry of the extremely high thermal maturity Longmaxi shale gas,southern Sichuan Basin[J].Organic Geochemistry,2014,74:3-12.
[46] 李建忠,李登华,董大忠,等.中美页岩气成藏条件、分布特征差异研究与启示[J].中国工程科学,2012,14(6):56-63.
LI Jianzhong,LI Denghua,DONG Dazhong,et al.Comparison and enlightenment on formation condition and distribution characteristics of shale gas between China and U.S.[J].Engineering Sciences,2012,14(6):56-63.
[47] MOHAMMADI M,SHADIZADEH S R,MANSHAD A K,et al.Experimental study of the relationship between porosity and surface area of carbonate reservoir rocks[J].Journal of Petroleum Exploration and Production Technology,2020,10(5):1817-1834.
[48] ABSHIRE M L,RIEDINGER N,CLYMER J M,et al.Reconstructing the paleoceanographic and redox conditions responsible for variations in uranium content in north American Devonian black shales[J].Palaeogeography,Palaeoclimatology,Palaeoecology,2022,587:110763.
[49] KETRIS M P,YUDOVICH Y E.Estimations of Clarkes for carbonaceous biolithes:world averages for trace element contents in black shales and coals[J].International Journal of Coal Geology,2009,78(2):135-148.
[50] BALLENTINE C J,BURNARD P G.Production,release and transport of noble gases in the continental crust[J].Reviews in Mineralogy and Geochemistry,2002,47(1):481-538.
[51] 秦国红,邓丽君,刘亢,等.鄂尔多斯盆地西缘煤中稀土元素特征[J].煤田地质与勘探,2016,44(6):8-14.
QIN Guohong,DENG Lijun,LIU Kang,et al.Characteristic of rare earth elements in coal in western margin of Ordos Basin[J].Coal Geology & Exploration,2016,44(6):8-14.
[52] 聂志宏,巢海燕,刘莹,等.鄂尔多斯盆地东缘深部煤层气生产特征及开发对策——以大宁—吉县区块为例[J].煤炭学报,2018,43(6):1738-1746.
NIE Zhihong,CHAO Haiyan,LIU Ying,et al.Development strategy and production characteristics of deep coalbed methane in the east Ordos Basin:taking Daning-Jixian block for example[J].Journal of China Coal Society,2018,43(6):1738-1746.
[53] DAI Jinxing,ZOU Caineng,DONG Dazhong,et al.Geochemical characteristics of marine and terrestrial shale gas in China[J].Marine and Petroleum Geology,2016,76:444-463.
[54] ZHANG Mingjie,TANG Qingyan,CAO Chunhui,et al.Molecular and carbon isotopic variation in 3.5 years shale gas production from Longmaxi Formation in Sichuan Basin,China[J].Marine and Petroleum Geology,2018,89:27-37.
[55] 李剑,王晓波,侯连华,等.四川盆地页岩气地球化学特征及资源潜力[J].天然气地球科学,2021,32(8):1093-1106.
LI Jian,WANG Xiaobo,HOU Lianhua,et al.Geochemical characteristics and resource potential of shale gas in Sichuan Basin[J].Natural Gas Geoscience,2021,32(8):1093-1106.
[56] 李艳芳,邵德勇,吕海刚,等.四川盆地五峰组—龙马溪组海相页岩元素地球化学特征与有机质富集的关系[J].石油学报,2015,36(12):1470-1483.
LI Yanfang,SHAO Deyong,LV Haigang,et al.A relationship between elemental geochemical characteristics and organic matter enrichment in marine shale of Wufeng Formation-Longmaxi Formation,Sichuan Basin[J].Acta Petrolei Sinica,2015,36(12):1470-1483.
[57] 刘江涛,刘双莲,李永杰,等.焦石坝地区奥陶系五峰组—志留系龙马溪组页岩地球化学特征及地质意义[J].油气地质与采收率,2016,23(3):53-57.
LIU Jiangtao,LIU Shuanglian,LI Yongjie,et al.Geochemistry characteristics and its geological significance of shale in the Ordovician Wufeng Formation and Silurian Longmaxi Formation,Jiaoshiba area[J].Petroleum Geology and Recovery Efficiency,2016,23(3):53-57.
[58] 蒙炳坤,周世新,李靖,等.上扬子地区不同类型岩石生氦潜力评价及泥页岩氦气开采条件理论计算[J].矿物岩石,2021,41(4):102-113.
MENG Bingkun,ZHOU Shixin,LI Jing,et al.Helium potential evaluation of different types of rocks in the Upper Yangtze region and theoretical calculation of helium recovery conditions for shale in Upper Yangtze region[J].Mineralogy and Petrology,2021,41(4):102-113.
[59] 马力,陈焕疆,甘克文,等.中国南方大地构造和海相油气地质(下)[M].北京:地质出版社,2004.
MA Li,CHEN Huanjiang,GAN Kewen,et al.Tectonic and marine petroleum geology in South China (Part II)[M].Beijing:Geological Publishing House,2004.
[60] DANABALAN D,GLUYAS J G,MACPHERSON C G,et al.The principles of helium exploration[J].Petroleum Geoscience,2022,28(2):petgeo2021-029.
[61] ZHANG Wen,LI Yuhong,ZHAO Fenghua,et al.Granite is an effective helium source rock:insights from the helium generation and release characteristics in granites from the north Qinling orogen,China[J].Acta Geologica Sinica(English Edition),2020,94(1):114-125.
[62] 李艳霞,赵靖舟,李净红.鄂尔多斯盆地东部上古生界气藏成藏史[J].兰州大学学报 (自然科学版),2011,47(3):29-34.
LI Yanxia,ZHAO Jingzhou,LI Jinghong.Gas accumulation history in Upper Palaeozoic,east of Erdos Basin[J].Journal of Lanzhou University (Natural Sciences),2011,47(3):29-34.
[63] 张文.关中和柴北缘地区战略性氦气资源成藏机理研究[D].北京:中国矿业大学(北京),2019.
ZHANG Wen.Accumulation mechanism of helium,a strategic resource,in Guanzhong and north Qaidam Basin[D].Beijing:China University of Mining and Technology-Beijing,2019.
[64] WANG Xiaofeng,LIU Wenhui,LI Xiaobin,et al.Application of noble gas geochemistry to the quantitative study of the accumulation and expulsion of Lower Paleozoic shale gas in southern China[J].Applied Geochemistry,2022,146:105446.
[65] 仰云峰,饶丹,付小东,等.柴达木盆地北缘石炭系克鲁克组页岩气形成条件分析[J].石油实验地质,2014,36(6):692-697.
YANG Yunfeng,RAO Dan,FU Xiaodong,et al.Generation conditions of shale gas in Carboniferous Keluke Formation,northern Qaidam Basin [J].Petroleum Geology & Experiment,2014,36(6):692-697.
[66] 于会娟,妥进才,刘洛夫,等.柴达木盆地东部地区侏罗系烃源岩地球化学特征及生烃潜力评价[J].沉积学报,2000,18(1):132-138.
YU Huijuan,TUO Jincai,LIU Luofu,et al.Geochemical characteristics and evaluation on hydrocarbon generation potentials of source rocks in Jurassic eastern Qaidam Basin[J]Acta Sedimentologica Sinica,2000,18(1):132-138.
[67] 施辉,李宗星,杨元元,等.柴东欧南凹陷石炭系烃源岩有机质富集的影响因素[J].地质力学学报,2022,28(2):203-216.
SHI Hui,LI Zongxing,YANG Yuanyuan,et al.The factors influencing the enrichment of organic matters in the Carboniferous source rocks,Ounan depression,eastern Qaidam Basin[J].Journal of Geomechanics,2022,28(2):203-216.
[68] GHANIZADEH A,GASPARIK M,AMANN-HILDENBRAND A,et al.Experimental study of fluid transport processes in the matrix system of the European organic-rich shales:I.Scandinavian alum shale[J] .Marine and Petroleum Geology,2014,51:79-99.
[69] BHANDARI A R,FLEMINGS P B,POLITO P J,et al.Anisotropy and stress dependence of permeability in the Barnett shale[J].Transport in Porous Media,2015,108(2):393-411.
[70] SOEDER D J.Porosity and permeability of eastern Devonian gas shale[J].SPE Formation Evaluation,1988,3(1):116-124.
[71] BUSTIN R M,BUSTIN A M M,CUI X,et al.Impact of shale properties on pore structure and storage characteristics[R].SPE 119892,2008.
[72] 邹才能,董大忠,王玉满,等.中国页岩气特征、挑战及前景(一)[J].石油勘探与开发,2015,42(6):689-701.
ZOU Caineng,DONG Dazhong,WANG Yuman,et al.Shale gas in China:characteristics,challenges and prospects (Ⅰ)[J].Petroleum Exploration and Development,2015,42(6):689-701.
[73] 肖威,张兵,姚永君,等.川东二叠系龙潭组页岩岩相特征与沉积环境[J].岩性油气藏,2022,34(2):152-162.
XIAO Wei,ZHANG Bing,YAO Yongjun,et al.Lithofacies and sedimentary environment of shale of Permian Longtan Formation in eastern Sichuan Basin[J].Lithologic Reservoirs,2022,34(2):152-162.

[74] 王鹏威,刘光祥,刘忠宝,等.川东南—黔西北地区上二叠统龙潭组海陆过渡相页岩气富集条件及主控因素[J].天然气地球科学,2022,33(3):431-440.
WANG Pengwei,LIU Guangxiang,LIU Zhongbao,et al.Shale gas enrichment conditions and controlling factors of Upper Permian Longtan Formation transitional shale in southeast Sichuan to northwest Guizhou[J].Natural Gas Geoscience,2022,33(3):431-440.
[75] 高乔,王兴志,朱逸青,等.川南地区龙马溪组元素地球化学特征及有机质富集主控因素[J].岩性油气藏,2019,31(4):72-84.
GAO Qiao,WANG Xingzhi,ZHU Yiqing,et al.Elemental geochemical characteristics and main controlling factors of organic matter enrichment of Longmaxi Formation in southern Sichuan[J].Lithologic Reservoirs,2019,31(4):72-84.
[76] BYRNE D J,BARRY P H,LAWSON M,et al.Determining gas expulsion vs retention during hydrocarbon generation in the Eagle Ford shale using noble gases[J].Geochimica et Cosmochimica Acta,2018,241:240-254.
[77] 刘文汇,徐永昌.天然气中氦氩同位素组成的意义[J].科学通报,1993,38(9):818-821.
LIU Wenhui,XU Yongchang.Significance of helium argon isotope composition in natural gas[J].Chinese Science Bulletin,1993,38(9):818-821.
[78] CAO Chunhui,ZHANG Mingjie,TANG Qingyan,et al.Noble gas isotopic variations and geological implication of Longmaxi shale gas in Sichuan Basin,China[J].Marine and Petroleum Geology,2018,89:38-46.
[79] GYÖRE D,PUJOL M,GILFILLAN S M V,et al.Noble gases constrain the origin,age and fate of CO₂ in the Vaca Muerta shale in the Neuquén Basin (Argentina)[J].Chemical Geology,2021,577:120294.
[80] 腾格尔,陶成,胡广,等.排烃效率对页岩气形成与富集的影响[J].石油实验地质,2020,42(3):325-334.
BORJIGIN T,TAO Cheng,HU Guang,et al.Effect of hydrocarbon expulsion efficiency on shale gas formation and enrichment[J].Petroleum Geology & Experiment,2020,42(3):325-334.
[81] 李玉宏,张文,王利,等.亨利定律与壳源氦气弱源成藏——以渭河盆地为例[J].天然气地球科学,2017,28(4):495-501.
LI Yuhong,ZHANG Wen,WANG Li,et al.Henry’s law and accumulation of crust-derived helium:a case from Weihe Basin,China[J].Natural Gas Geoscience,2017,28(4):495-501.
[82] YOU Bing,CHEN Jianfa,LIU Xiaoqiang.Molecular competitive adsorption mechanism of methane and helium in illite of shale gas reservoirs through molecular simulation[C]//Proceedings of the Goldschmidt 2023 Conference.Lyon,2023.
[83] 孙赞东,贾承造,李相方.非常规油气勘探与开发[M].北京:石油工业出版社,2011.
SUN Zandong,JIA Chengzao,LI Xiangfang.Unconventional oil & gas exploration and development[M].Beijing:Petroleum Industry Press,2011.
[84] TAO Mingxin,SHI Baoguang,LI Jinying,et al.Secondary biological coalbed gas in the Xinji area,Anhui Province,China:evidence from the geochemical features and secondary changes[J].International Journal of Coal Geology,2007,71(2/3):358-370.
[85] 何发岐,王付斌,张威,等.鄂尔多斯盆地北缘勘探思路转变与天然气领域重大突破[J].中国石油勘探,2020,25(6):39-49.
HE Faqi,WANG Fubin,ZHANG Wei,et al.Transformation of exploration ideas and major breakthrough in natural gas discovery in the northern margin of the Ordos Basin[J].China Petroleum Exploration,2020,25(6):39-49.
[86] 王香增,高胜利,高潮.鄂尔多斯盆地南部中生界陆相页岩气地质特征[J].石油勘探与开发,2014,41(3):294-304.
WANG Xiangzeng,GAO Shengli,GAO Chao.Geological features of Mesozoic continental shale gas in south of Ordos Basin,NW China[J].Petroleum Exploration and Development,2014,41(3):294-304.
[87] 赵文智,李建忠,杨涛,等.中国南方海相页岩气成藏差异性比较与意义[J].石油勘探与开发,2016,43(4):499-510.
ZHAO Wenzhi,LI Jianzhong,YANG Tao,et al.Geological difference and its significance of marine shale gases in South China[J].Petroleum Exploration and Development,2016,43(4):499-510.
[88] 董大忠,高世葵,黄金亮,等.论四川盆地页岩气资源勘探开发前景[J].天然气工业,2014,34(12):1-15.
DONG Dazhong,GAO Shikui,HUANG Jinliang,et al.A discussion on the shale gas exploration & development prospect in the Sichuan Basin[J].Natural Gas Industry,2014,34(12):1-15.
[89] 邹才能,杨智,朱如凯,等.中国非常规油气勘探开发与理论技术进展[J].地质学报,2015,89(6):979-1007.
Z OU Caineng,YANG Zhi,ZHU Rukai,et al.Progress in China’s unconventional oil & gas exploration and development and theoretical technologie s[J].Acta Geologica Sinica,2015,89(6):979-1007.

非常规天然气中氦资源潜力及富集机制

Helium resource potential and enrichment mechanism of unconventional gas

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	徐凤银, 熊先钺, 侯伟, 王峰, 马鹏飞, 张雷, 云箭, 喻岳钰, 闫霞, 徐博瑞, 李建伟, 代由进, 曾雯婷, 王勃, 甄怀宾, 王渊, 李忠百, 邓钧耀. 深部煤层气产业升级与"八个一体化"体系的建立[J]. 石油学报, 2025, 46(2): 289-305.
[2]	沈华, 胡佳, 杨光, 杨亮, 邵明礼, 杨克思, 王云鹤. 松辽盆地南部致密油气成藏特征及勘探潜力[J]. 石油学报, 2025, 46(1): 61-76.
[3]	李建忠, 陈旋, 龚德瑜, 林霖, 刘俊田, 张华, 林潼, 王波, 王杰. 吐哈盆地致密砂岩气及煤层气勘探新领域与资源潜力[J]. 石油学报, 2025, 46(1): 104-117,172.
[4]	雍锐, 吴建发, 吴伟, 杨雨然, 徐亮, 罗超, 刘佳, 何一凡, 钟可塑, 李彦佑, 朱逸青, 陈丽清. 四川盆地寒武系筇竹寺组页岩气勘探发现及其意义[J]. 石油学报, 2024, 45(9): 1309-1323.
[5]	武瑾, 郭为, 郭伟, 赵圣贤, 苟其勇, 曾凡成, 刘宇, 邹晓品, 王玉满, 刘兆龙. 深层海相页岩气立体开发"甜点"岩相及其成因机制——以四川盆地南部泸州区块龙马溪组一段一亚段为例[J]. 石油学报, 2024, 45(8): 1219-1233.
[6]	张群, 孙四清, 降文萍. 碎软低渗煤层煤矿区煤层气勘探开发关键技术及发展方向[J]. 石油学报, 2024, 45(5): 855-865.
[7]	梁兴, 单长安, 张磊, 罗瑀峰, 蒋立伟, 张介辉, 朱斗星, 舒红林, 李健. 四川盆地渝西地区大安深层页岩气田的勘探发现及成藏条件[J]. 石油学报, 2024, 45(3): 477-499.
[8]	郭晨, 李瑞腾, 秦勇, 卢玲玲, 易同生, 陈贞龙, 袁航, 高为, 程曦. 煤层气井产出水演化路径及产量判识意义——以黔西地区织金区块为例[J]. 石油学报, 2024, 45(3): 517-530.
[9]	李乐, 胡远清, 彭小桂, 王伟, 余浩宇, 崔亚圣. 页岩气藏中硫化氢成因研究进展[J]. 石油学报, 2024, 45(2): 461-476.
[10]	代旭光, 桑树勋, 王猛, 刘世奇, 郑司建, 宋新贺, 师轩, 宋昱, 冯光俊, 全方凯. 页岩CO₂封存中的矿物溶蚀/沉淀特征及作用规律[J]. 石油学报, 2024, 45(12): 1833-1850.
[11]	王勃, 徐凤银, 金雪, 王立龙, 屈争辉, 张文胜, 李志, 刘国伟, 张艺腾, 史鸣剑. 沁水盆地郑庄区块煤层气井产出水化学成分演变及其高产响应[J]. 石油学报, 2024, 45(11): 1638-1651.
[12]	宋永, 唐勇, 何文军, 龚德瑜, 晏奇, 陈棡, 单祥, 刘超威, 刘刚, 秦志军, 阿布力米提·依明, 尤新才, 任海姣, 白雨, 高岗. 准噶尔盆地油气勘探新领域、新类型及勘探潜力[J]. 石油学报, 2024, 45(1): 52-68.
[13]	李志军, 肖阳, 田建章, 李晓燕, 王元杰, 王海燕, 焦亚先, 汤小琪, 贾颖超, 任春玲, 严梦颖, 王成云, 任艺. 渤海湾盆地冀中坳陷新领域、新类型油气勘探潜力及有利方向[J]. 石油学报, 2024, 45(1): 69-98.
[14]	谭茂金, 武宏亮, 王思宇, 杜广慧, 白洋, 王谦. 中国海相页岩气测井评价技术进展与发展方向[J]. 石油学报, 2024, 45(1): 241-260.
[15]	王立歆, 李弘, 刘小民, 胡华锋. 中国海相页岩气地震勘探技术及其发展方向[J]. 石油学报, 2024, 45(1): 261-275.