Impact of MXene nanoparticle on thermohydraulic performance in a microchannel heat sink: effect of nanoparticle size

Microchannel heat sink is a cooling device that utilizes fluid flow as a heat removal agent. However, with the increasing demand for higher heat flux removal, nanoparticle has become crucial addictive in a microchannel heat sink for improving thermal performance. This study proposes using MXene nanoparticle with base fluid in a microchannel, and this nanoparticle is used for the first time in this application. Control volume method is utilized to simulate the flow characteristic. Thermohydraulic performance is assessed by varying nanoparticle' size ranging from 20 nm, 50 nm, 80 nm, and 135 nm. The significant results implied that MXene nanofluids with a 20-nm diameter reduced the thermal resistance by 37.25% and enhanced the heat transfer coefficient by 59.36%, which is the lowest and the highest among all nanofluids at a high Re of 1000. It was discovered that 20 nm nanofluids increase the pressure drop by only 1.95%, which is the lowest and requires the least pumping power at Re of 676. All in all, the MXene nanoparticle's diameter of 20 nm performs for both thermal and hydraulic, which can be integrated into the following generation of cooling performance. [GRAPHICS] .

Automated summary

This study proposes the use of MXene nanoparticles in a microchannel, and evaluates their thermohydraulic performance by varying the nanoparticle size. The results show that MXene nanofluids with a diameter of 20 nm have the lowest thermal resistance and highest heat transfer coefficient at high Reynolds numbers, and only slightly increase the pressure drop.