Transforming Seismic Reflection Data Into Quantitative Rock Properties by Seismic Inversion

More than 80% of the present-day oil and gas production in the Danish part of the North Sea is extracted from fields with chalk reservoirs of late Cretaceous (Maastrichtian) and early Paleocene (Danian) ages (Fig. 1). Seismic reflection and in- version data play a fundamental role in mapping and characterisation of intra-chalk structures and reservoir properties of the Chalk Group in the North Sea. The aim of seismic inversion is to transform seismic reflection data into quantitative rock properties such as acoustic impedance (AI) that provides information on reservoir properties enabling identification of porosity anomalies that may constitute potential reservoir compartments. Petrophysical analyses of well log data have shown a relationship between AI and porosity. Hence, AI variations can be transformed into porosity variations and used to support detailed interpretations of porous chalk units of possible reservoir quality. This paper presents an example of how the chalk team at the Geological Survey of Denmark and Greenland (GEUS) integrates geological, geophysical and petrophysical information, such as core data, well log data, seismic 3-D reflection and AI data, when assessing the hydrocarbon prospectivity of chalk fields.

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Geostatistical seismic inversion for frontier exploration

Interpretation ◽

10.1190/int-2016-0171.1 ◽

2017 ◽

Vol 5 (4) ◽

pp. T477-T485 ◽

Cited By ~ 2

Author(s):

Ângela Pereira ◽

Rúben Nunes ◽

Leonardo Azevedo ◽

Luís Guerreiro ◽

Amílcar Soares

Keyword(s):

Acoustic Impedance ◽

Seismic Reflection ◽

Seismic Inversion ◽

Well Log ◽

Data Set ◽

Seismic Reflection Data ◽

Log Data ◽

The Real ◽

Reflection Data ◽

Impedance Models

Numerical 3D high-resolution models of subsurface petroelastic properties are key tools for exploration and production stages. Stochastic seismic inversion techniques are often used to infer the spatial distribution of the properties of interest by integrating simultaneously seismic reflection and well-log data also allowing accessing the spatial uncertainty of the retrieved models. In frontier exploration areas, the available data set is often composed exclusively of seismic reflection data due to the lack of drilled wells and are therefore of high uncertainty. In these cases, subsurface models are usually retrieved by deterministic seismic inversion methodologies based exclusively on the existing seismic reflection data and an a priori elastic model. The resulting models are smooth representations of the real complex geology and do not allow assessing the uncertainty. To overcome these limitations, we have developed a geostatistical framework that allows inverting seismic reflection data without the need of experimental data (i.e., well-log data) within the inversion area. This iterative geostatistical seismic inversion methodology simultaneously integrates the available seismic reflection data and information from geologic analogs (nearby wells and/or analog fields) allowing retrieving acoustic impedance models. The model parameter space is perturbed by a stochastic sequential simulation methodology that handles the nonstationary probability distribution function. Convergence from iteration to iteration is ensured by a genetic algorithm driven by the trace-by-trace mismatch between real and synthetic seismic reflection data. The method was successfully applied to a frontier basin offshore southwest Europe, where no well has been drilled yet. Geologic information about the expected impedance distribution was retrieved from nearby wells and integrated within the inversion procedure. The resulting acoustic impedance models are geologically consistent with the available information and data, and the match between the inverted and the real seismic data ranges from 85% to 90% in some regions.

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Delineating ophiolite-derived host rocks of massive sulfide Cu-Co-Zn deposits with 2D high-resolution seismic reflection data in Outokumpu, Finland

Geophysics ◽

10.1190/geo2012-0029.1 ◽

2012 ◽

Vol 77 (5) ◽

pp. WC213-WC222 ◽

Cited By ~ 14

Author(s):

I. T. Kukkonen ◽

S. Heinonen ◽

P. Heikkinen ◽

P. Sorjonen-Ward

Keyword(s):

Seismic Data ◽

Host Rock ◽

Seismic Reflection ◽

Massive Sulfide ◽

High Amplitude ◽

Ore Deposits ◽

Acoustic Properties ◽

Rock Properties ◽

Seismic Reflection Data ◽

Reflection Data

Seismic reflection data was applied to a study of the upper crustal structures in the Outokumpu mining and exploration area in eastern Finland. The Cu-Co-Zn sulfide ore deposits of the Outokumpu area are hosted by Palaeoproterozoic ophiolite-derived altered ultrabasic rocks (serpentinite, skarn rock, and quartz rock) and black schist within turbiditic mica schist. Mining in the Outokumpu area has produced a total of 36 Mt of ore from three historical and one active mine. Seismic data comprises 2D vibroseis data surveyed along a network of local roads. The seismic sections provide a comprehensive 3D view of the reflective structures. Acoustic rock properties from downhole logging and synthetic seismograms indicate that the strongly reflective packages shown in the seismic data can be identified as the host-rock environments of the deposits. Reflectors show excellent continuity along the structural grain of the ore belt, which allows correlating reflectors with surface geology, magnetic map, and drilling sections into a broad 3D model of the ore belt. Massive ores have acoustic properties that make them directly detectable with seismic reflection methods assuming the deposit size is sufficient for applied seismic wavelengths. The seismic data revealed numerous interesting high-amplitude reflectors within the interpreted host-rock suites potentially coinciding with sulfides.

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A workflow using self-organized mapping to predict rock properties from seismic-reflection data

10.1190/segam2016-13955103.1 ◽

2016 ◽

Author(s):

Jorge Parra

Keyword(s):

Seismic Reflection ◽

Rock Properties ◽

Seismic Reflection Data ◽

Reflection Data ◽

Self Organized

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Stochastic perturbation optimization for discrete-continuous inverse problems

Geophysics ◽

10.1190/geo2019-0520.1 ◽

2020 ◽

Vol 85 (5) ◽

pp. M73-M83 ◽

Cited By ~ 3

Author(s):

Leonardo Azevedo ◽

Dario Grana ◽

Leandro de Figueiredo

Keyword(s):

Seismic Data ◽

Seismic Reflection ◽

Stochastic Perturbation ◽

Rock Physics ◽

Rock Properties ◽

Petrophysical Properties ◽

Seismic Reflection Data ◽

Reflection Data ◽

Physics Model ◽

Rock Physics Model

Accurate subsurface modeling and characterization require the prediction of facies and rock properties within the reservoir model. This is commonly achieved by inverting geophysical data, such as seismic reflection data, using a two-step approach either in the discrete or the continuous domain. We have adopted an iterative simultaneous method, namely, stochastic perturbation optimization, to invert seismic reflection data jointly for facies and rock properties. Facies first are simulated according to a Markov chain model, and then rock properties are generated with stochastic sequential simulation and cosimulation conditioned to each facies. Elastic and seismic data are computed by applying a rock-physics model to the realizations of petrophysical properties and a seismic convolutional model. The similarity between observed and synthetic seismic data is used to update the solution by perturbing facies and rock properties until convergence. Coupling the discrete and continuous domains ensures a consistent perturbation of the reservoir models throughout the iterations. We have evaluated the method in a 1D synthetic example for the estimation of facies and porosity from zero-offset seismic data assuming a linear rock-physics model to demonstrate the validity of the method. Then, we apply the method to a real 3D data set from the North Sea for the joint estimation of facies and petrophysical properties from prestack seismic data. The results show spatially consistent rock and fluid inverted models in which the predicted facies reproduce the vertical ordering as observed in the well data.

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A fast automatic multichannel blind seismic inversion for high-resolution impedance recovery

Geophysics ◽

10.1190/geo2015-0654.1 ◽

2016 ◽

Vol 81 (5) ◽

pp. V357-V364 ◽

Cited By ~ 29

Author(s):

Ali Gholami

Keyword(s):

High Resolution ◽

Seismic Reflection ◽

Mathematical Problem ◽

A Priori ◽

Low Frequency ◽

Seismic Inversion ◽

Split Bregman ◽

Seismic Reflection Data ◽

Reflection Data ◽

Tv Regularization

The inversion of seismic reflection data for acoustic impedance (AI) is a common and accepted method for the interpretation of poststack seismic data. The original mathematical problem is nonlinear due to the nonlinearity of relation between the AI and the earth reflectivity series and also the insufficiency of information about the source wavelet. Furthermore, the problem is ill posed due to the lack of low and high frequencies in the data. We have developed a multichannel blind inversion and solved it for obtaining the AI model and the wavelet directly from seismic reflection data. We found a solution to the overall problem by alternating between two subproblems, corresponding to the AI and wavelet recovery. Having an estimation of the wavelet, the algorithm directly inverts multichannel data for a high-resolution AI model, having blocky structures in the sense of total variation (TV) regularization, while satisfying a priori low-frequency information. The advantages of the split Bregman technique and the discrete cosine transform are used to build a fast and efficient algorithm for solving the nonlinear impedance inversion with TV regularization. Having an estimate of the AI model, the wavelet is updated by restricting it to have a sparse representation in a wavelet transformation domain while predicting the observed data. Numerical tests using simulated 2D data obtained from the benchmark Marmousi model and also 2D field data confirm that the proposed algorithm stably generates accurate estimates of complex AI models and complicated wavelets, simultaneously.

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