2019
DOI: 10.1016/j.coal.2019.03.011
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Later stage gas generation in shale gas systems based on pyrolysis in closed and semi-closed systems

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Cited by 13 publications
(8 citation statements)
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“…Considering the observed linear relationship, at an EE of 0% when the generated crude oil is completely retained in the source rock, the proportion of the cracked gas from retained oil to the total gas is 87.25%. The other minor part is thermally cracked gas from residual solid kerogen. , This finding is consistent with previous pyrolysis experiments, in which cracking gas from retained oil accounts for 80%–85.5% of the total cracking gas. , …”
Section: Discussionsupporting
confidence: 91%
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“…Considering the observed linear relationship, at an EE of 0% when the generated crude oil is completely retained in the source rock, the proportion of the cracked gas from retained oil to the total gas is 87.25%. The other minor part is thermally cracked gas from residual solid kerogen. , This finding is consistent with previous pyrolysis experiments, in which cracking gas from retained oil accounts for 80%–85.5% of the total cracking gas. , …”
Section: Discussionsupporting
confidence: 91%
“…With increasing EEs, the gas yields of C 1 –C 5 and C 2–5 /C 1–5 decrease because of less retained oil in the pyrolysis samples (Figure ). The methane yield was nearly consistent and gently increased in the initial maturity range (EasyRo ≤ 1.81%; Figure a), which generally is consistent with previous pyrolysis results from 470 to 500 °C (EasyRo approximately ranges from 1.7% to 2.1%). , The overlap of the methane yield at the different EE values was most likely caused by similar methane generation mechanisms: demethylation reactions and the opening of aromatic rings within this maturity range. , In this stage, the retained oil yielded a large amount of long-chain gaseous hydrocarbons, especially C 3+ alkanes. When the maturity exceeded an EasyRo value of 1.81%, the methane yield from the EE 100% sample was much lower than that of the EE 30% and EE 60% samples (Figure a).…”
Section: Discussionsupporting
confidence: 88%
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“…Previous studies have indicated that the bond cleavage and the formation of free radicals mainly occurred at the early stage of pyrolysis. , The free radicals, namely, the reactive intermediates, can react with each other to form short-chain hydrocarbons . Furthermore, free short-chain hydrocarbons can be incorporated into kerogen or pyrobitumen to replace the bound long-chain hydrocarbons during thermal maturation, ,, resulting in the loss of a part of short-chain hydrocarbon gases in OGW. Therefore, in the early stage of OGW (Calcd R o < 0.7%), compared with the lost amount of C 1 –C 5 indicated by Py-GC, the significantly lower yield of C 1 –C 5 gaseous hydrocarbons from GTCS pyrolysis may be partially due to hydrocarbon gases either participating in the thermal degradation of kerogen (i.e., replacement of the bound long-chain hydrocarbons during the cleavage of long alkyl chains from kerogen) or being adsorbed within kerogen/dissolved in oil.…”
Section: Discussionmentioning
confidence: 99%