As a new approach for enhancing pool boiling, using surfaces with a dual thermal conductivity has been recently proposed. To scrutiny this method, this paper empirically addresses the effects of low-conductive channels in boiling heat transfer. In this regard, nine copper samples with different channels dimension and filling methods were created by a mixture of epoxy and silica aerogel microparticles. Then pool boiling tests with deionized water, detailed contact angle analysis, and imaging of bubbles with a high-speed camera were performed. The results showed that sample 1-A which had alternatively filled channels, in the initial heat fluxes range of 20 to 40 W/cm2, improved the pool boiling heat transfer coefficient by 174 % compared to the plain sample. Optimizing the dimensional characteristics of low-conductive channels was revealed to be more influential in enhancing pool boiling than increasing the boiling surface area by creating empty channels. Moreover, for the first time, an experimental correlation for predicting the heat flux of bi-conductive surfaces with different geometrical dimensions of low-conductive channels is presented, with a mean absolute error of 8.96 %.
