On anisotropy parameters and fluid detection in equivalent TI medium

Abstract

We consider a long-wave transversely isotropic (TI) medium equivalent to a series of finely parallel-layered isotropic layers, obtained using the Backus average. In such a TI equivalent medium, we verify the Berrymanetal method of indicating fluids and the author's method Adamus, using anisotropy parameter . Both methods are based on detecting variations of the Lam\'e parameter, λ, in a series of thin isotropic layers, and we treat these variations as potential change of the fluid content. To verify these methods, we use Monte Carlo (MC) simulations; for certain range of Lam\'e parameters λ and μ---relevant to particular type of rocks---we generate numerous combinations of these parameters in thin layers and, after the averaging process, we obtain their TI media counterparts. Subsequently, for each of the aforementioned media, we compute and Thomsen parameters ε and δ. We exhibit , ε and δ in a form of cross-plots and distributions that are relevant to chosen range of λ and μ. We repeat that process for various ranges of Lam\'e parameters. Additionally, to support the MC simulations, we consider several numerical examples of growing λ, by using scale factors. As a result of the thorough analysis of the relations among , ε and δ, we find eleven fluid detectors that compose a new fluid detection method. Based on these detectors, we show the quantified pattern of indicating change of the fluid content.