Interpretation of multi-component induction and sonic measurements acquired in high-angle wells and joint 1D radial inversion of resistivity and sonic logs

Mallan, Robert Keays

20 October 2010

Multi-component induction resistivity and sonic measurements acquired in high-angle wells can be strongly influenced by shoulder-bed effects, anisotropy resulting from sand-shale laminations, and presence of mud-filtrate invasion. Understanding the corresponding biasing effects aids in the interpretation of resistivity and sonic measurements and subsequently leads to more accurate and reliable formation evaluation. This dissertation describes numerical simulation studies examining the effects on multi-component induction and sonic measurements in a variety of complex formation models. Subsequently, a joint inversion scheme is presented that combines resistivity and sonic measurements to estimate in situ petrophysical and elastic properties in the presence of mud-filtrate invasion. To facilitate the simulation study of multi-component induction logs, I develop a new finite-difference algorithm for the numerical simulation of frequency-domain electromagnetic borehole measurements. The algorithm~uses a coupled scalar-vector potential formulation for arbitrary three-dimensional inhomogeneous and electrically anisotropic media. Simulations show that shoulder-bed anisotropy: enhances shoulder-bed effects across sand layers; and impacts invasion sensitivities to significantly alter the assessment of invasion in terms of invaded- and virgin-zone resistivities, radial length, and front shape. For the simulation study of sonic logs, I develop a three-dimensional, finite-difference time-domain algorithm that models elastic wave propagation in a fluid-filled borehole. Simulations show that presence of anisotropy not only alters the degree of dispersion observed in flexural and Stoneley waves, but also alters their responses to invasion. In addition, presence of a dipping shoulder bed can significantly distort flexural dispersion, making it difficult to identify the low frequency asymptote corresponding to formation shear wave velocity. Lastly, I consider a radial one-dimensional model in the development of a joint resistivity and sonic inversion algorithm. This scheme simultaneously inverts array-induction apparent conductivities and sonic flexural and Stoneley dispersions for the rock's elastic moduli and water saturation in the presence of mud-filtrate invasion. Inversions are performed on numerically simulated data for a variety of models reflecting soft and hard rock formations with presence of water- and oil-based mud-filtrate invasion. Results show the estimated invasion profiles display excellent agreement with the true models, and the elastic moduli are estimated to within a few percent of the true values. / text

Induction logs

Sonic logs

Numerical simulation

Joint inversion

High-angle shoulder-bed effects

Invasion modeling

Depositional Stacking Patterns And Cycles Of Garzan Formation In The Garzan-germik Oil Filed: An Approach To Cycle To Log Correlation

Yildizel, Zeynep Elif Gaziulusoy

01 June 2008

The Garzan Formation is a deepening upward marine carbonate including successions ranging from subtidal to open marine facies deposited in the Maastrichtian. The Garzan Formation is composed of five microfacies types / Miliolid Wackestone (subtidal), Orbitoid Miliolid Wackestone, Rudist Wackestone (backshoal to shoal), Rotalid Miliolid Wackestone (shoal to foreshoal) and Pelagic Foraminiferal Mudstone (foreshoal to open marine). These five microfacies are stacked in different combinations consisting of five types of depositional cycles. The type A and D cycles the building blocks of transgressive systems tract (retrogradational), whereas type B and C cycles are deposited during highstand systems tract (aggradational). The type E cycle is progradational and also corresponds to the highstand systems tract deposits. The maximum flooding surface is usually located within the type D cycle towards the top of the formation. vi Generally, the base of the Garzan Formation deposition starts with highstand systems tract deposits (type E and C cycles) and overlain by transgressive systems tract deposits (type A cycle) in between there is a type 2 sequence boundary. Then deposition continues with highstand systems tract deposits (alternation of type B and C cycles) which are aggradational in character. The top of the Formation is characterized by transgressive systems tract deposits (type D cycle) which usually includes the maximum flooding surface. The second type 2 sequence boundary is located below the type D cycle. There are four of the stacking patterns observed in the Garzan Formation. The GR values change from relatively high to low API in type D and A cycles, whereas a relative shift from low to high API is observed in type E cycle. The GR in the type B and C cycles does not display any relative change. There is no net movement in the SONIC readings in type A, B, C and E cycles / however there is a relative shifting from low velocity to high velocity in type D cycle. In Garzan deposition opposing the general patterns, a decrease in GR readings indicates a decrease in energy and relatively deepening. In carbonate depositional systems predicting the depositional environment from the logs should only be accomplished with microfacies control, otherwise the interpretation will be erroneous.

QE Sedimentary Rocks, Sedimentology 471