Abstract The six-fold symmetry widely presents in both natural and artificial architectures. Understanding the growth mechanism of six-fold symmetrical materials is of fundamental interest and significance. Herein, we report the… Click to show full abstract
Abstract The six-fold symmetry widely presents in both natural and artificial architectures. Understanding the growth mechanism of six-fold symmetrical materials is of fundamental interest and significance. Herein, we report the formation process of β -Co(OH) 2 /Co(OH)F hierarchical hexagrams with a six-fold symmetrical arrangement. Our results demonstrate that hexagonal β -Co(OH) 2 plates are first formed under the reaction condition. These hexagonal plates then act as templates for the growth of Co(OH)F nanorods. The intermediate material is therefore composed of plate-like β -Co(OH) 2 hexagonal cores appended with six rod-like Co(OH)F branches, giving the β -Co(OH) 2 /Co(OH)F hybrid. After prolonged reaction, the β -Co(OH) 2 hexagons can be completely converted, leading to authentic six-branched Co(OH)F nanorods as the final product. Consequently, for both intermediate and final materials, the Co(OH)F nanorods are arranged with a six-fold symmetry. Importantly, these Co(OH)F nanorods grow along β -Co(OH) 2 hexagon edges as lateral branches instead of perpendicular to hexagons. This uncommon epitaxial growth mechanism is considered to be a result of the matching between the b -axis of Co(OH)F crystals and the a -axis of β -Co(OH) 2 crystals, which is beneficial for the electrocatalysis. The β -Co(OH) 2 /Co(OH)F hierarchical hexagrams show enhanced water oxidation activity compared to the pure β -Co(OH) 2 and Co(OH)F.
               
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