The unconventional reservoirs in the mixed carbonate/clastic basinal facies of the Vaca Muerta Formation (Tithonian-Valanginian) located in the Neuquén Basin (Argentina) are considered one of the most prolific shale-oil and shale-gas systems in the world. In combination with the Quintuco Formation, they represent prograding sequences composed of proximal carbonate facies (Quintuco) and distal shale facies (Vaca Muerta). With an extensive surface area of over 30,000 km2, the Vaca Muerta Formation is a key focus for hydrocarbon exploration and production. Drill cuttings from two horizontal wells (one targeting the Orgánico Inferior member and the other the Cocina member) were subjected to a comprehensive and rapid reservoir characterization analysis using a new cuttings-based, standardized workflow. This workflow integrates high-resolution imaging, artificial intelligence (AI) algorithms, and X-ray fluorescence (XRF) elemental data, allowing for a consistently measured and detailed characterization of all drill-cuttings samples from both wells. Additionally, X-ray diffraction (XRD) analyses were conducted on selected samples to enhance the identification and classification of specific intervals of interest.

The study successfully identified twenty-two (22) distinct lithotypes based on a combination of physical and geochemical parameters. These lithotypes were further classified into lithofacies associations and lateral well sedimentary packages, with detailed analysis highlighting significant vertical and lateral variations within the Orgánico Inferior and Cocina members. Tuffaceous, heterolithic, and calcareous components were distinguished using this approach, providing a cost-effective methodology for reservoir characterization. Variability in clay speciation, detrital silica content, and anoxia indicators were also identified, which were linked to deviations in the bit trajectory and geosteering during drilling. High mineral luminance peaks identified from image analysis of the ultraviolet (UV) light images, were interpreted as volcanic tuff layers, and corroborated by XRD data showing the presence of igneous minerals and clay minerals formed from volcanic glass weathering. These tuffaceous intervals, commonly observed in the Vaca Muerta Formation, are critical for understanding their effects on bit performance and potential trajectory deviations during drilling.