Microseepage of methane to the atmosphere from the Dawanqi oil‐gas field, Tarim Basin, China

Tang, Junhong; Xu, Yi; Wang, Guojian; Etiope, Giuseppe; Han, Wenzhong; Yao, Zhitong; Huang, Jingang

doi:10.1002/2016jd026385

Cited by 13 publications

(28 citation statements)

References 24 publications

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“…The microseepage database of Etiope and Klusman [26] shows that, statistically, positive fluxes occur in less than 50% of a petroleum field's area, and there are three possible levels of microseepage. Based on this, total methane emissions to the atmosphere in the Dawanqi field were evaluated be on the order of 60 t/yr [27]. Negative fluxes are a consequence of methanotrophic activity when the speed of diffusion and infiltration of methane from the oil reservoir is lower than that of its methanotrophic oxidation activity.…”

Section: Resultsmentioning

confidence: 99%

Methane in Soil Gas and Its Migration to the Atmosphere in the Dawanqi Oilfield, Tarim Basin, China

Tang

Wang

et al. 2019

Geofluids

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Methane microseepage is the result of natural gas migration from subsurface hydrocarbon accumulations to the Earth’s surface, and it is quite common in hydrocarbon-prone basins. In this study, by analyzing gas concentrations and isotope composition of soil gas, the potentials of CH4 gas transferred to the surface were studied at three measurement transects in Dawanqi oilfield, Tarim Basin, China. It was found that CH4 from deep-buried reservoirs could migrate upwards to the surface through faults, fissures, and permeable rocks, during which some CH4 was oxidized and the unoxidized methane remained in the soil or was emitted into the atmosphere. Soil gas samples had mean concentrations of 907.1, 62.3, 21.7, 11.0, and 5.8 ppmv for CH4, C2H6, C3H8, C4H10, and C5H12, respectively. The C1/C2+ (13.3 for soil gas and 3.75 for absorbed gas) and gas wetness ratio (12% for soil gas and 26% for absorbed gas) suggested that the hydrocarbons were derived from a thermogenic process. According to isotope composition analysis, the δ13CCO2, δ13CCH4, and δDCH4 values for the soil gas from Dawanqi oilfield varied from -15.5 to -17.2‰, -11‰ to -17‰, and -150 to -189‰, respectively. The extreme 13C enrichment in CH4 is possibly because of the fractionation effects of diffusional migration and methanotrophic oxidation. Soil gas and absorbed gas showed high CH4 concentrations at the edge of the fault block, which indicated that fault was conductive to gas migration. Also, gas migrated from the surface to the atmosphere in the center region of the fault block because of the high permeability and shallow depth of the reservoir in Dawanqi oilfield.

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Section: Resultsmentioning

confidence: 99%

Methane in Soil Gas and Its Migration to the Atmosphere in the Dawanqi Oilfield, Tarim Basin, China

Tang

Wang

et al. 2019

Geofluids

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“…One of these has been adapted to and coupled with a flux chamber. Tang et al [35] reported CH 4 seepage measurements using this instrument at the Dawanqi and Yakela oil fields. This will result in a substantial increase in speed and sensitivity of flux measurements.…”

Section: Discussionmentioning

confidence: 99%

Faults as Windows to Monitor Gas Seepage: Application to CO2 Sequestration and CO2-EOR

Klusman

2018

Geosciences

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Monitoring of potential gas seepage for CO 2 sequestration and CO 2 -EOR (Enhanced Oil Recovery) in geologic storage will involve geophysical and geochemical measurements of parameters at depth and at, or near the surface. The appropriate methods for MVA (Monitoring, Verification, Accounting) are needed for both cost and technical effectiveness. This work provides an overview of some of the geochemical methods that have been demonstrated to be effective for an existing CO 2 -EOR (Rangely, CA, USA) and a proposed project at Teapot Dome, WY, USA. Carbon dioxide and CH 4 fluxes and shallow soil gas concentrations were measured, followed by nested completions of 10-m deep holes to obtain concentration gradients. The focus at Teapot Dome was the evaluation of faults as pathways for gas seepage in an under-pressured reservoir system. The measurements were supplemented by stable carbon and oxygen isotopic measurements, carbon-14, and limited use of inert gases. The work clearly demonstrates the superiority of CH 4 over measurements of CO 2 in early detection and quantification of gas seepage. Stable carbon isotopes, carbon-14, and inert gas measurements add to the verification of the deep source. A preliminary accounting at Rangely confirms the importance of CH 4 measurements in the MVA application.

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“…The previously published global microseepage data set contains 1,509 measurements from 10 hydrocarbon basins (Table 3; Klusman et al, 2000;Klusman, 2003;Etiope, 2005;Klusman, 2005;Etiope et al, 2006;LT Environmental, 2007;Tang et al, 2007;Etiope & Klusman, 2010;Tang et al, 2010Tang et al, , 2017. Sampled areas are primarily in Western United States, Italy, and Northwest China, with a few additional measurements in Romania and Greece, leaving most of the world's hydrocarbon basins unrepresented in the global data set.…”

Section: Background and Motivationmentioning

confidence: 99%

Investigating methane emissions from geologic microseepage in Western New York State, United States

Kazemi

Schlageter

Hmiel

et al. 2021

Elementa: Science of the Anthropocene

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Methane is a powerful greenhouse gas and a key player in atmospheric chemistry. Important uncertainties remain in the global atmospheric methane budget, with natural geologic emissions being one of the particularly uncertain terms. In recent bottom-up studies, geologic emissions have been estimated to comprise up to 10% of the global budget (40–60 Teragrams of methane per year, Tg CH4 yr–1). In contrast, top-down constraints from 14C of methane in preindustrial air extracted from ice cores indicate that the geologic methane source is approximately an order of magnitude lower. Recent bottom-up inventories propose microseepage (diffuse low-level flux of methane through soils over large areas) as the largest single component of the geologic methane flux. In this study, we present new measurements of methane microseepage from the Appalachian Basin (Western New York State) and compare these with prior microseepage measurements from other regions and with predicted values from the most recent bottom-up inventory. Our results show lower microseepage values than most prior data sets and indicate that positive microseepage fluxes in this region are not as widespread as previously assumed. A statistical analysis of our results indicates that mean microseepage flux in this region has very likely been overestimated by the bottom-up inventory, even though our measurements more likely than not underestimate the true mean flux. However, this is a small data set from a single region and as such cannot be used to evaluate the validity of the microseepage emissions inventory as a whole. Instead, the results demonstrate the need for a more extensive network of direct geologic emission measurements in support of improved bottom-up inventories.

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Microseepage of methane to the atmosphere from the Dawanqi oil‐gas field, Tarim Basin, China

Cited by 13 publications

References 24 publications

Methane in Soil Gas and Its Migration to the Atmosphere in the Dawanqi Oilfield, Tarim Basin, China

Methane in Soil Gas and Its Migration to the Atmosphere in the Dawanqi Oilfield, Tarim Basin, China

Faults as Windows to Monitor Gas Seepage: Application to CO2 Sequestration and CO2-EOR

Investigating methane emissions from geologic microseepage in Western New York State, United States

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