Abstract

A good understanding of different rock types and their distribution is critical to locate oil and gas accumulations in the subsurface. Traditionally, rock core samples are used to directly determine the exact rock facies and what geological environments might be present. Core samples are often expensive to recover and, therefore, not always available for each well. Wireline logs provide a cheaper alternative to core samples, but they do not distinguish between various rock facies alone. This problem can be overcome by integrating limited core data with largely available wireline log data with machine learning. Here, we presented an application of machine learning in rock facies predictions based on limited core data from the Umiat Oil Field of Alaska. First, we identified five sandstone reservoir facies within the Lower Grandstand Member using core samples and mineralogical data available for the Umiat 18 well. Next, we applied machine learning algorithms (ascendant hierarchical clustering, self-organizing maps, artificial neural network, and multi-resolution graph-based clustering) to available wireline log data to build our models trained with core-driven information. We found that self-organizing maps provided the best result among other techniques for facies predictions. We used the best self-organizing maps scheme for predicting similar reservoir facies in nearby uncored wells—Umiat 23H and SeaBee-1. We validated our facies prediction results for these wells with observed seismic data.

Highlights

  • The success of any conventional hydrocarbon exploration program primarily depends upon identifying and mapping porous and permeable sandstone reservoirs where commercial volumes of hydrocarbons are stored

  • Our study aimed to examine the potential of different machine learning methods to predict lithofacies from well logs using limited core data from the Umiat Oil Field

  • Our results show that self-organizing maps (SOM) provides facies predictions, closely mimicking the observed facies among all examined machine learning methods

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Summary

Introduction

The success of any conventional hydrocarbon exploration program primarily depends upon identifying and mapping porous and permeable sandstone reservoirs where commercial volumes of hydrocarbons are stored. In these reservoir rocks, the spatial heterogeneity of porosity and permeability has been known to be affected by the geological character of the sediments, including their depositional environment, stratigraphic position, and mineral composition [1,2,3]. Core samples are widely used in the petroleum industry for comprehensive analysis of lithologic and petrophysical properties of sandstone reservoirs that provide valuable insight into past depositional environments. Available conventional geophysical logs, including gamma-ray, density, neutron, Energies 2020, 13, 4862; doi:10.3390/en13184862 www.mdpi.com/journal/energies

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