# Oil-Water Biphasic Metal-Organic Supramolecular Gel for Lost Circulation Control: Formulation Optimization, Gelation Mechanism, and Plugging Performance

**Authors:** Qingwang Li, Songlei Li, Ye Zhang, Chaogang Chen, Xiaochuan Wu, Menglai Li, Shubiao Pan, Junfei Peng

PMC · DOI: 10.3390/gels12010074 · 2026-01-15

## TL;DR

A new oil-water gel system is developed to control lost circulation in oil drilling by forming a strong, heat-resistant seal.

## Contribution

A dual-precursor oil–water biphasic metal–organic supramolecular gel is optimized for in situ sealing in oil-based drilling fluids.

## Key findings

- Optimized formulation includes a 10:3 oil-to-aqueous ratio with specific additives for effective gelation.
- MOSG gelation is enhanced by elevated temperatures and mildly alkaline conditions promoting P–O–Al coordination.
- The gel shows high viscoelasticity, thermal resistance up to ~193 °C, and effective sealing in simulated fractures.

## Abstract

Lost circulation in oil-based drilling fluids (OBDFs) remains difficult to mitigate because particulate lost circulation materials depend on bridging/packing and gel systems for aqueous media often lack OBDF compatibility and controllable in situ sealing. A dual-precursor oil–water biphasic metal–organic supramolecular gel enables rapid in situ sealing in OBDF loss zones. The optimized formulation uses an oil-phase to aqueous gelling-solution volume ratio of 10:3, with 2.0 wt% Span 85, 12.5 wt% TXP-4, and 5.0 wt% NaAlO2. Apparent-viscosity measurements and ATR–FTIR analysis were used to evaluate the effects of temperature, time, pH, and shear on MOSG gelation. Furthermore, the structural characteristics and performances of MOSGs were systematically investigated by combining microstructural characterization, thermogravimetric analysis, rheological tests, simulated fracture-plugging experiments, and anti-shear evaluations. The results indicate that elevated temperatures (30–70 °C) and mildly alkaline conditions in the aqueous gelling solution (pH ≈ 8.10–8.30) promote P–O–Al coordination and strengthen hydrogen bonding, thereby facilitating the formation of a three-dimensional network. In contrast, strong shear disrupts the nascent network and delays gelation. The optimized MOSGs rapidly exhibit pronounced viscoelasticity and thermal resistance (~193 °C); under high shear (380 rpm), the viscosity retention exceeds 60% and the viscosity recovery exceeds 70%. In plugging tests, MOSG forms a dense sealing layer, achieving a pressure-bearing gradient of 2.27 MPa/m in simulated permeable formations and markedly improving the fracture pressure-bearing capacity in simulated fractured formations.

## Linked entities

- **Chemicals:** Span 85 (PubChem CID 9920343)

## Full-text entities

- **Diseases:** fracture (MESH:D050723)
- **Chemicals:** Al (MESH:D000535), oil (MESH:D009821), hydrogen (MESH:D006859), MOSG (-), P (MESH:D010758), Metal (MESH:D008670)

## Figures

17 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12840760/full.md

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Source: https://tomesphere.com/paper/PMC12840760