Elemental Geochemistry Proxies Recover Original Hydrogen Index Values And Total Organic Carbon Contents Of Over-Mature Shales: Lower Cambrian South China

The determination of the original organic matter type and content of source rock in over-mature petroleum systems is critical for accurately evaluating the original hydrocarbon-generation capacity, but has challenged researchers for decades. Here we present a new method for such analyses using inorganic geochemistry, which was applied to a case study of over-mature shales of the Lower Cambrian Niutitang Formation (Upper Yangtze region, South China). Multiple redox proxies (e.g., V-EF, U-EF, MOEF, and Th/U ratio) indicate that the Lower and Upper members were deposited under anoxic bottom water and suboxic conditions, respectively. This implies different proxies suitable for recovering the original hydrogen index (Hl(o)) values, i.e., Cu-XS and P-org for the Lower (anoxic) and Upper (suboxic) members, respectively. Then, the original total organic carbon (TOCo) content of the shales were calculated by using the formula TOCo = (TOCpd - (S-1+S-2) x0.085 - HIo x 0.0004)/(1 - HIo/1177), of which TOCpd refers to the measured present-day TOC data and S-1 and S-2 are the Rock-Eval pyrolysis hydrocarbons. Excellent original hydrocarbon generation capacity was revealed in that HIo and TOCo are 600-893.4 mg hydrocarbon (HC)/g TOC (average = 758.4) and 0.2-32.2 wt% (average = 10.2), respectively. Combined with six lithofacies identified from mineralogy and petrology, heterogeneities of the hydrocarbongeneration potential in different lithofacies of the Niutitang Formation shales of this study were revealed. The laminated siliceous shale and laminated carbonaceous shale facies had higher HIo and TOCo than the other facies, and can thus be regarded as the lithofacies with the highest hydrocarbon-generation potential. Our study provides a new method using inorganic geochemistry to restore the original kerogen type and TOC content of overmature shales with a high degree of accuracy, which can be used to robustly evaluate the hydrocarbon generation potential of conventional and unconventional hydrocarbon resources in over-mature source rocks.