This study is motivated by the impacts of nanoparticle shapes on flow and heat transfer characteristics in a
microchannel helical heat sink for cooling of electronics in both laminar and turbulent flow regimes. Therefore,
effects of five different nanoparticle shapes (platelet, cylindrical, blade, brick and spherical) at five different
volume fractions (ϕ = 0, 0.5, 1.0, 1.5, 2.0%) and at eight different Reynolds numbers corresponding to laminar
and turbulent flow regimes (Re = 500–20,000) are investigated using finite volume method with two-phase
mixture approach for nanofluids. Various performance parameters related with the first law of thermodynamics
are considered. It was found that nanofluid utilization remarkably improves heat transfer along with
causing an increment in pumping power. Furthermore, it was revealed that these variations in the parameters
strongly depend on the utilized nanoparticle shape, and the platelet shaped particles were the most advantageous.
They improved convective heat transfer coefficient up to 25% in laminar and up to 22.5% in turbulent
flow regimes compared to base fluid. However, they increased pumping power up to 6.3-folds both in laminar
and turbulent flow regimes. On the other hand, spherical particles yielded the least enhancement in convective
heat transfer coefficient, which can reach up to 3.7% in laminar, and 1.8% in turbulent flow. Nevertheless, they
slightly increase pumping power, which maximally reaches up to around 8%. Yet, the performance evaluation
criteria showed that the heat transfer improvement effect of platelet shaped particles is more dominant over the
increment effect in pumping power, which makes them favourable for applications.