A reciprocal integral identity of coupled Poisson and Laplace equations in two arbitrary domains sharing a common boundary
Document Type
Article
Publication Date
5-1-2024
Abstract
In solving the coupled vapor and liquid unidirectional flows in micro heat pipes, we discovered numerically an integral identity. After asymptotic and polynomial expansions, the coupled flows yield two reciprocal systems of equations. In system A, a vapor velocity UA obeys the Poisson equation and drives, through an interfacial boundary condition, a liquid velocity WA that satisfies the Laplace equation. In reciprocal system B, a liquid velocity WB obeys the Poisson equation and drives, through another interfacial boundary condition, a vapor velocity UB that satisfies the Laplace equation. We found that the vapor volume flow rate of UB is numerically equal to the liquid volume flow rate of WA for seven different pipe shapes. Here, a general proof is presented for the integral identity, and some interesting implications of this identity are discussed.
Publication Source (Journal or Book title)
Results in Applied Mathematics
Recommended Citation
Rao, S., & Wong, H. (2024). A reciprocal integral identity of coupled Poisson and Laplace equations in two arbitrary domains sharing a common boundary. Results in Applied Mathematics, 22 https://doi.org/10.1016/j.rinam.2024.100464