Abstract

Abstract Pt nanoparticles (NPs) on a carbon support (Pt/C) are deposited by a simple fluidized bed reactor atomic layer deposition (FBR‐ALD) technique. The growth characteristics of the Pt NPs are investigated as a function of ALD cycles from 5 to 30 cycles. The excellent characteristics of FBR‐ALD offer highly dispersed and dense Pt particles with a size of ≈1 nm at low ALD cycles (5 cycles). However, as the number of ALD cycles increases above 5, the NPs increase in size and agglomerate due to preferential growth of incoming Pt NPs on previously deposited Pt surfaces. An electrochemical study shows that low ALD cycles (5 cycles) for the Pt/C catalyst result in a high electrochemical active surface area (ECSA) (114.67 m 2 g −1 ). With increasing the number of cycles, ECSA is found to decrease, but still apparently higher than that of commercial Pt catalyst with the similar Pt wt% loading. Finally, ALD Pt/C catalysts with various cycles are applied to fuel cell testing for power generation. The electrode prepared with 20 ALD cycles of the Pt/C catalyst shows the best fuel cell performance (1.58 A cm −2 at 0.6 V) due to an adequate combination of activity and mass transfer characteristics of the electrode.