[First Hit]

AAPG Annual Convention and Exhibition

Datapages, Inc.Print this page

Hydrocarbon Episodic Migration in Previous HitFaultNext Hit Zones: Insights From Physical Simulation Experiments

Abstract

Hydrocarbon migration is an important aspect of basin modeling and petroleum system, and Previous HitfaultNext Hit zones as the dominant pathway for vertical hydrocarbon migration has been widely studied. However, recent studies show that a Previous HitfaultNext Hit zone commonly has a complex internal architecture composed of a Previous HitfaultNext Hit core and damage zones. And the recognition of such complexity has aroused hot debates about hydrocarbon flow regime within Previous HitfaultNext Hit zones. In this paper, we established a physical model to explore hydrocarbon flow regime within a Previous HitfaultNext Hit zone during the active stage by multiple episodic transient hydrocarbon charging. The results show that the internal architectures control pathway and flow regime during hydrocarbon episodic migrating within a Previous HitfaultNext Hit zone, hydrocarbon saturation also has an influence on the pathway in a certain extent. Previous HitFaultNext Hit core is the dominant migration pathway during hydrocarbon episodic migration along a Previous HitfaultNext Hit zone, and the prospective traps for hydrocarbon accumulating locate on the relative active side of the Previous HitfaultNext Hit blocks. Moreover, the amount of hydrocarbon migrating along a Previous HitfaultNext Hit zone has a logarithmic relationship with time during a single episodic hydrocarbon-charging process, implying that the hydrocarbon episodic migration along a Previous HitfaultNext Hit zone is a nonlinear process. The velocity of hydrocarbon episodic migration along a Previous HitfaultNext Hit zone may have a constant range, and the order of magnitudes may be 102∼103 m/yr. The processes of hydrocarbon episodic migration along a Previous HitfaultNext Hit zone contain 3 different fluid flow regimes: (1) the nonlinear fluid flow regime with a high speed; (2) the transitional fluid flow regime; and (3) the linear-Darcy fluid flow regime. The shift of fluid flow regime within a Previous HitfaultNext Hit zone is a complex process which is controlled by the interaction of multi-physics fields. Moreover, a Previous HitfaultNext Hit zones commonly has considerable volumes and can form Previous HitfaultNext Hit body reservoirs in some specific circumstances. And the forming condition of Previous HitfaultNext Hit body reservoirs is the equilibrium between driving forces and resistances during hydrocarbon migration within the Previous HitfaultTop zone.