New exploration strategy in igneous petroliferous basins – Enlightenment from simulation experiments

• Published in: Energy exploration & exploitation Vol. 36; no. 4; pp. 971 - 985
• Main Authors: Meng, Qingqiang, Jing, Jiajun, Li, Jingzhou, Zhu, Dongya, Zou, Ande, Zheng, Lunju, Jin, Zhijun
• Format: Journal Article
• Language: English
• Published: London, England Sage Publications, Ltd 01.07.2018; SAGE Publications; Sage Publications Ltd; SAGE Publishing
• Subjects: Basins; Computer simulation; Cracking (chemical engineering); Experiments; Hydrocarbons; Kerogen; Oil exploration; Oil fields; Productivity; Rocks; Simulation; Special Issue: Advances of Petroleum Exploration and Geology Research in West China’s petroliferous basins; Deep-derived fluid; maturation; exploration strategy; petroliferous basin; hydrocarbon generation
• ISSN: 0144-5987; 2048-4054
• DOI: 10.1177/0144598718758338

There are two kinds of relationships between magmatism and the generation of hydrocarbons from source rocks in petroliferous basins, namely: (1) simultaneous magmatism and hydrocarbon generation, and (2) magmatism that occurs after hydrocarbon generation. Although the influence of magmatism on hydrocarbon source rocks has been extensively studied, there has not been a systematic comparison between these two relationships and their influences on hydrocarbon generation. Here, we present an overview of the influence of magmatism on hydrocarbon generation based on the results of simulation experiments. These experiments indicate that the two relationships outlined above have different influences on the generation of hydrocarbons. Magmatism that occurred after hydrocarbon generation contributed deeply sourced hydrogen gas that improved liquid hydrocarbon productivity between the mature and overmature stages of maturation, increasing liquid hydrocarbon productivity to as much as 451.59% in the case of simulation temperatures of up to 450°C during modelling where no hydrogen gas was added. This relationship also increased the gaseous hydrocarbon generation ratio at temperatures up to 450°C, owing to the cracking of initially generated liquid hydrocarbons and the cracking of kerogen. Our simulation experiments suggest that gaseous hydrocarbons dominate total hydrocarbon generation ratios for overmature source rocks, resulting in a change in petroleum accumulation processes. This in turn suggests that different exploration strategies are warranted for the different relationships outlined above. For example, simultaneous magmatism and hydrocarbon generation in an area means that exploration should focus on targets likely to host large oilfields, whereas in areas with magmatism that post-dates hydrocarbon generation the exploration should focus on both oil and gas fields. In addition, exploration strategies in igneous petroliferous basins should focus on identifying high-quality reservoirs as well as determining the relationship between magmatism and initial hydrocarbon generation.