Hydrocarbon source for oil and gas indication associated with gas hydrate and its significance in the Qilian Mountain permafrost, Qinghai, Northwest China

Since gas hydrate was sampled by drilling in the Qilian Mountain permafrost in 2008, to investigate the source of the gas hydrate and the relationship between gas hydrate and the concomitant oil and gas indication (OGI) have become an important research focus. The rocks bearing gas hydrate and OGI f...

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Bibliographic Details
Published in:Marine and Petroleum Geology
Main Authors: Cheng, Bin, Xu, Jianbing, Lu, Zhenquan, Li, Yonghong, Wang, Weichao, Yang, Shan, Liu, Hu, Wang, Ting, Liao, Zewen
Format: Report
Language:English
Published: ELSEVIER SCI LTD 2018
Subjects:
Geology
Gas hydrate
Oil and gas indication
Oil (gas)-source correlation
Qilian Mountain permafrost
Geosciences
Multidisciplinary
SOURCE ROCKS
CRUDE OILS
DEPOSITIONAL ENVIRONMENT
ORGANIC GEOCHEMISTRY
SOUTH CHINA
SEDIMENTS
CARBON
BASIN
PETROLEUM
GENERATION
permafrost
Online Access:http://ir.gig.ac.cn/handle/344008/37684
https://doi.org/10.1016/j.marpetgeo.2017.02.019
Description
Summary:Since gas hydrate was sampled by drilling in the Qilian Mountain permafrost in 2008, to investigate the source of the gas hydrate and the relationship between gas hydrate and the concomitant oil and gas indication (OGI) have become an important research focus. The rocks bearing gas hydrate and OGI from the Middle Jurassic strata in the Qilian Mountain permafrost, Qinghai, Northwest China were extracted by organic solvent and thermally treated (300 degrees C and 400 degrees C) in vacuum glass tubes. The hydrocarbons from the extracts and cracked products of the rocks and the stable carbon isotope of the gas hydrocarbons were studied. The results showed that the OGIs can be classified into two types according to different biomarker characteristics. The I-type of OGIs, which suffered from the process of early biodegradation and later-hydrocarbon input and featured high concentrations of 17 alpha(H)-diahopane and afifi-regular steranes, mainly originated from the shallow source rocks of the Middle Jurassic strata, while the II-type one with a series of long-chain alkylnaphthalene may originate from the lower portion of Middle Jurassic or deeper source rocks than the Middle Jurassic strata. The adsorbed gas (300 degrees C) of the Middle Jurassic rocks was very wet, had a normal carbon isotope sequence, and can be regarded as an organic thermogenic gas derived from Middle Jurassic source rocks. Comparing the adsorbed (300 degrees C) and cracked (400 degrees C) gases from the rocks with gases from the gas hydrate and drilling core, we found they had similar stable carbon isotope distributions but different relative contents of methane (C-1), ethane (C-2), and propane (C-3). The Middle Jurassic source rocks are mainly deposited in a freshwater paleo-environment, similar to the parent biomass of the gas hydrate and drilling core gas. The difference of the relative concentrations of C-1-C-3 may result from different formation processes between the adsorbed and cracked gases and the gas hydrate and drilling core gas. The II-type OGI, which possibly originated from deeper strata than the Middle Jurassic, were closely associated with the gas hydrate under the drilling well and had a similar parent biomass and depositional environment as the gas hydrate, showing they have a closely correlated hydrocarbon origin. (C) 2017 Elsevier Ltd. All rights reserved.

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