The main objective of this research is to study the effects of nanoparticle shape on the entropy generation characteristics of
boehmite alumina nanofluid flow in a horizontal double-pipe heat exchanger. The examined boehmite alumina nanofluids
include dispersed cylindrical, brick, blade, platelet and spherical nanoparticles in a mixture of water/ethylene glycol. The
nanofluid and water flow through the tube side and annulus side of the heat exchanger, respectively. Two-phase mixture
model is applied to precisely simulate the behavior of nanofluid. The effects of the various Reynolds numbers, nanoparticle
concentrations and nanoparticle shapes on the frictional, thermal and total entropy generation rates as well as the Bejan
number are numerically investigated. The results indicated that the highest and lowest frictional entropy generation rate
belongs to the nanofluids with platelet shape and spherical shape nanoparticles, respectively, while the nanofluid containing
spherical shape and platelet shape nanoparticles represented the maximum and minimum thermal and total entropy
generation rates. Furthermore, it was inferred that the frictional entropy generation rate is enhanced with an increase in
nanoparticle concentration, whereas except for nanofluid with spherical shape nanoparticles, the opposite is true for
thermal and total entropy generation rates and Bejan number.