Your search keyword '"Ching-Yao Lai"' showing total 2 results

1. Foam-driven fracture.

Author

Ching-Yao Lai, Rallabandi, Bhargav, Perazzo, Antonio, Zhong Zheng, Smiddy, Samuel E., and Stone, Howard A.

Subjects

*FOAM, *HYDRAULIC fracturing, *COMPUTED tomography, *POLYMERS, *DEFORMATIONS (Mechanics)

Abstract

In hydraulic fracturing, water is injected at high pressure to crack shale formations. More sustainable techniques use aqueous foams as injection fluids to reduce the water use and wastewater treatment of conventional hydrofractures. However, the physical mechanism of foam fracturing remains poorly understood, and this lack of understanding extends to other applications of compressible foams such as fire-fighting, energy storage, and enhanced oil recovery. Here we show that the injection of foam is much different from the injection of incompressible fluids and results in striking dynamics of fracture propagation that are tied to the compressibility of the foam. An understanding of bubble-scale dynamics is used to develop a model for macroscopic, compressible flow of the foam, from which a scaling law for the fracture length as a function of time is identified and exhibits excellent agreement with our experimental results. [ABSTRACT FROM AUTHOR]

Published

2018

2. Suppressing viscous fingering in structured porous media.

Author

Rabbani, Harris Sajjad, Or, Dani, Ying Liu, Ching-Yao Lai, Lu, Nancy B., Datta, Sujit S., Stone, Howard A., and Nima Shokri

Subjects

POROUS materials, HYDRODYNAMICS, PORE size (Materials), VISCOSITY, PERCOLATION

Abstract

Finger-like protrusions that form along fluid-fluid displacement fronts in porous media are often excited by hydrodynamic instability when low-viscosity fluids displace high-viscosity resident fluids. Such interfacial instabilities are undesirable in many natural and engineered displacement processes. We report a phenomenon whereby gradual and monotonic variation of pore sizes along the front path suppresses viscous fingering during immiscible displacement, that seemingly contradicts conventional expectation of enhanced instability with pore size variability. Experiments and pore-scale numerical simulations were combined with an analytical model for the characteristics of displacement front morphology as a function of the pore size gradient. Our results suggest that the gradual reduction of pore sizes act to restrain viscous fingering for a predictable range of flow conditions (as anticipated by gradient percolation theory). The study provides insights into ways for suppressing unwanted interfacial instabilities in porous media, and provides design principles for new engineered porous media such as exchange columns, fabric, paper, and membranes with respect to their desired immiscible displacement behavior. [ABSTRACT FROM AUTHOR]

Published

2018