Noble gas partitioning behavior in the Sleipner Vest hydrocarbon field

Abstract:

Noble gases are chemically inert and variably soluble in crustal fluids. They are primarily introduced into hydrocarbon reservoirs through exchange with formation waters, and can be used to assess migration pathways, mechanisms and reservoir storage. Of particular interest is the role groundwater plays in hydrocarbon transport, which is reflected in hydrocarbon-water volume ratios.

We present compositional, stable isotope and noble gas isotope and abundance data from the Sleipner Vest field, in the Norwegian North Sea. Sleipner gases are generated from primary cracking of kerogen and the thermal cracking of oil, sourced from type II marine source, with relatively homogeneous maturities and a range in vitrinite reflectance (1.2-1.7%). Gases are hosted in the lower shoreface sandstones of the Jurassic Hugin formation, which is sealed by the Jurassic Upper Draupne and Heather formations.

Gases are composed of N₂ (0.6-0.9%), CO₂ (5.4-15.3%) and hydrocarbons (69-80%). Helium isotopes (³He/⁴He) are radiogenic and range from 0.065 to 0.116 R_A, showing a small mantle contribution, consistent with Ne isotopes (²⁰Ne/²²Ne from 9.70-9.91; ²¹Ne/²²Ne from 0.0290-0.0344) and Ar isotopes (⁴⁰Ar/³⁶Ar from 315-489). ²⁰Ne/³⁶Ar, ⁸⁴Kr/³⁶Ar and ¹³²Xe/³⁶Ar values are systematically higher relative to air saturated water ratios. These data are discussed within the framework of several conceptual models: i) Total gas-stripping model, which defines the minimum volume of water to have interacted with the hydrocarbon phase; ii) Equilibrium model, assuming simple equilibration between groundwater and hydrocarbon phase at reservoir P,T and salinity; and iii) Open and closed system gas-stripping models. Using Ne-Ar, we estimate gas-water ratios for the Sleipner system of 0.02-0.09, which compare with geologic gas-water estimates of ~0.24, and suggest more groundwater interaction than a static system estimate. Kr and Xe show evidence for an additional source or process involving oil or sediments.