Water-rock interaction and methanogenesis in formation water in the southeast Huaibei coalfield, China

• Published in: Marine and petroleum geology Vol. 77; pp. 435 - 447
• Main Authors: Li, Qingguang, Ju, Yiwen, Lu, Weiqi, Wang, Guochang, Neupane, Bhupati, Sun, Yue
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.11.2016
• Subjects: End member discrimination; Isotope geochemistry; Methanogenesis; Microbial gas; Water-rock interactions; End member discrimination; Water-rock interactions; Methanogenesis; Isotope geochemistry; Microbial gas
• ISSN: 0264-8172; 1873-4073
• DOI: 10.1016/j.marpetgeo.2016.06.021

The hydrogeochemical characteristics of aquifers in coal-bearing strata can provide an important foundation for understanding the evolution of the aquifers and recognizing the formation process and occurrence of biogenic gas. By analyzing the hydrogeochemical characteristics of water produced from the Cenozoic, the limestone, and the coal strata aquifers and the coalbed gas wells, this study focused on water-rock interactions and methanogenesis in the formation water of the Suzhou mining area, Huaibei coalfield, China. Tectonically, this is one of the most complex coalfields in China. The dissolution of evaporites, silicates, and carbonates controlled the chemical composition of the formation water. The Cenozoic aquifers have a relatively stable water quality type and balanced ionic composition, but more complex water-rock interactions occur in the coal strata and the limestone aquifers. Extensive methanogenic activity and methanogenesis could be recognized by the meteoric water recharge, positive δ13C signatures for dissolved inorganic carbon (DIC; 15.4‰–26.2‰), lower sulfate concentrations (<2 mM), and higher levels of dissolved methane and DIC. The generation and enrichment of secondary biogenic gas in the coal seams was after the microbes’ inoculation along with the freshwater infilling the fracture network. •The main controls of the aquifers’ chemical composition are distinguished.•Water chemistry and isotope analysis indicate the injection of meteoric water.•The low [SO42−] and the isotopic evidences reflect weak SRB activity.•Extensive methanogenesis is supported by the DIC, DOC and dissolved gas analysis.