Litcius/Paper detail

Gelation and reservoir conformance control performance of in situ crosslinked polymer gels prepared with different crosslinkers

Ying-qi Gao, Hong-Bin Cheng, Guan-Hao Li, H. Liu, Hong-gen Tan, Jiong Ming Zhang, Dao-Yi Zhu

2026Petroleum Science8 citationsDOIOpen Access PDF

Abstract

In situ crosslinked polymer gels (ISCPGs) are widely applied in petroleum reservoirs for conformance control and water shutoff to improve oil recovery. However, the differences in gelation behavior and conformance control performance among ISCPGs formulated with different types of crosslinkers, as well as the underlying microscopic mechanisms, remain insufficiently understood. In this study, the gelation properties of three commonly used crosslinkers—chromium (Cr), phenol-formaldehyde (PF) system, and polyethyleneimine (PEI)—with partially hydrolyzed polyacrylamide (HPAM) were evaluated using the Sydansk bottle-test method. Core displacement experiments were conducted to compare the injectivity and plugging performance of these ISCPGs in both homogeneous and fractured cores. Results show that Cr-ISCPG had the shortest gelation time (1–4 h) and the highest gel strength, reaching grade H, but its long-term thermal stability was relatively poor under reservoir conditions (e.g., 73 °C). PF-ISCPG exhibited superior thermal stability, maintained up to 90 d, but had weaker wall-building capacity compared with Cr-ISCPG. PEI, as a biologically and environmentally friendly crosslinker, yielded ISCPGs with the longest gelation times and thermal stability, also with the best wall-building performance among the three. In homogeneous cores with gas-measured permeability above 500 × 10 −3 μm 2 , Cr-ISCPG demonstrated strong plugging capability, largely due to its high wall-building strength on rock surfaces. Nuclear magnetic resonance (NMR) analysis provided microscopic insights into ISCPG injection and transport mechanisms, showing that excessively prolonged gelation time can cause matrix damage. Owing to its stronger wall-building tendency, Cr-ISCPG performed better in plugging highly conductive channels such as fractures, thereby achieving more pronounced conformance control. This work clarified performance differences among ISCPGs crosslinked by different crosslinkers, providing valuable guidance for optimal crosslinker selection and profile control design in field applications.

Topics & Concepts

PolymerMaterials sciencePermeability (electromagnetism)Chemical engineeringThermal stabilityHomogeneousPolyacrylamideRheologyIn situPetroleumComposite materialThermalEnhanced oil recoveryHydrolysisCore (optical fiber)WellboreMatrix (chemical analysis)Displacement (psychology)Polymer chemistryEnhanced Oil Recovery TechniquesHydraulic Fracturing and Reservoir AnalysisReservoir Engineering and Simulation Methods