Geomechanically Optimized Perforation Strategies for Enhanced Stimulation Efficiency in Unconventional Reservoirs

Hydraulic fracturing has become a critical technology for hydrocarbon extraction from unconventional reservoirs, yet persistent challenges in stimulation effectiveness limit recovery factors and economic viability. This review synthesizes peer-reviewed literature to address gaps in understanding the interplay between in-situ stress mechanics, perforation design, and cluster efficiency. The analysis reveals that stress anisotropy—defined as the difference between maximum (σH) and minimum (σh) horizontal stresses—fundamentally governs fracture geometry and propagation patterns. High anisotropy environments, such as the Haynesville Shale, promote planar fractures, while lower anisotropy in the Eagle Ford Shale leads to complex networks. Perforation alignment with σH is shown to reduce initiation pressures by 20–40% and minimize near-wellbore tortuosity, with field studies demonstrating 22% lower breakdown pressures and 15% higher 30-day production in stress-aligned wells. Near-wellbore stress effects, including stress cage phenomena and perforation tunnel geometry, further influence fracture initiation mechanics. Cluster efficiency remains a key challenge, with 30–40% of clusters contributing