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Quantitative integration of sedimentological core descriptions and petrophysical data using high-resolution XRF core scans
Henares, S.; Donselaar, M.E.; Bloemsma, M.R.; Tjallingii, R.; De Wijn, B.; Weltje, G.J. (2019). Quantitative integration of sedimentological core descriptions and petrophysical data using high-resolution XRF core scans. Mar. Pet. Geol. 110: 450-462. https://dx.doi.org/10.1016/j.marpetgeo.2019.07.034
In: Marine and Petroleum Geology. Elsevier: Guildford. ISSN 0264-8172; e-ISSN 1873-4073, more
Peer reviewed article  

Available in  Authors 

Author keywords
    Data integration; XRF core scanning; Reservoir quality; Propertyprediction; Geochemical proxy data

Authors  Top 
  • Henares, S., more
  • Donselaar, M.E., more
  • Bloemsma, M.R.
  • Tjallingii, R.
  • De Wijn, B.
  • Weltje, G.J., more

Abstract
    In light of the huge investments needed to acquire sediment cores and the growing need of energy-providing companies to predict reservoir quality, it is remarkable that the standard workflow in core analysis has not been optimized to extract as much information from cores as possible. The Integrated Core Analysis (ICA) protocol presented in this study provides a statistical framework for multivariate calibration and prediction of a wide range of properties measured in core, based on integration of high-resolution X-ray fluorescence core-scanning (XRF-CS) proxy records with records of sparsely sampled petrophysical data and sedimentological core descriptions. The downscaling of numerical data involves the application of invertible transformations to remove range constraints on data, followed by calibration with Partial Least Squares regression through cross validation. Categorical data (i.e. lithofacies) are downscaled by associating each class with a statistical model based on the XRF-CS data. All data points are reassigned to their most likely class by applying Quadratic Discriminant Analysis. The result of the ICA is a multivariate data set in which all properties are specified at the same high resolution along the core with their prediction uncertainties. Downscaling of all variables to 1-cm vertical resolution permits investigation of the variability among petrophysical properties, geochemical proxies, and lithofacies memberships. Petrographic analysis is fundamental for interpretation of the XRF-CS records (elementmineral affinity) and for understanding the sedimentological controls on predicted petrophysical properties. Application of the ICA protocol to a 32 m thick, heterogeneous, Upper Carboniferous fluvial sandstone interval resulted in a near 30-fold increase of the petrophysical data base, which allowed identification of the main depositional and diagenetic controls on the spatial distribution of reservoir quality. Successful implementation of the novel ICA protocol will greatly increase the economic value of legacy core data in studies that aim to re-use depleted hydrocarbon reservoirs.

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