In this paper, we systematically investigated the influence of fluoride on the morphology and electrochemical property of Co
3O
4 nanostructures for hydrazine detection. The results showed that with the introduction of NH
4F during the synthesis process of Co
3
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In this paper, we systematically investigated the influence of fluoride on the morphology and electrochemical property of Co
3O
4 nanostructures for hydrazine detection. The results showed that with the introduction of NH
4F during the synthesis process of Co
3O
4, both Co(CO
3)
0.5(OH)·0.11H
2O and Co(OH)F precursors would be generated. To understand the influence of F on the morphology and electrochemical property of Co
3O
4, three Co
3O
4 nanostructures that were respectively obtained from bare Co(CO
3)
0.5(OH)·0.11H
2O, Co(OH)F and Co(CO
3)
0.5(OH)·0.11H
2O mixtures and bare Co(OH)F were successfully synthesized. The electrochemical tests revealed the sensing performance of prepared Co
3O
4 nanostructures decreased with the increase in the fluoride contents of precursors. The more that dosages of NH
4F were used, the higher crystallinity and smaller specific surface area of Co
3O
4 was gained. Among these three Co
3O
4 nanostructures, the Co
3O
4 that was obtained from bare Co(CO
3)
0.5(OH)·0.11H
2O-based hydrazine sensor displayed the best performances, which exhibited a great sensitivity (32.42 μA·mM
−1), a low detection limit (9.7 μΜ), and a wide linear range (0.010–2.380 mM), together with good selectivity, great reproducibility and longtime stability. To the best of our knowledge, it was revealed for the first time that the sensing performance of prepared Co
3O
4 nanostructures decreased with the increase in fluoride contents of precursors.
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