Journal of Engineering Research and Reports

As onshore and shallow-water hydrocarbon resources become depleted, a strategic shift towards exploring and developing deepwater reservoirs becomes increasingly important. However, these deepwater environments pose significant operational challenges, including high-pressure high-temperature (HPHT) conditions, narrow pore pressure-fracture gradient windows, and heterogeneous formation behaviours. Drilling fluid rheology is critical in handling these challenges by enabling improved wellbore stability, efficient cuttings transport, and precise pressure management. This paper comprehensively reviews recent advancements in fluid technology that are tailored for such complex deepwater drilling environments. It explores innovations such as "smart" fluids that adapt to downhole conditions, new nanotech additives that improve stability, and advanced polymer systems designed specifically for high-pressure, high-temperature wells. The paper focuses particularly on how these innovations help when drilling through complicated geology like salt domes, gas hydrates, and naturally fractured rock. Selected case studies demonstrating the deployment of these new fluid systems in offshore wells are analysed to illustrate their operational benefits and highlight persistent technical gaps. Finally, future research directions are proposed, including the integration of real-time rheological monitoring with digital drilling ecosystems and the development of environmentally sustainable fluid systems. These advancements collectively underscore the pivotal role of fluid rheology in enhancing the safety, efficiency, and economic viability of deepwater resource development.