Two-Step Electrodeposition of Polypyrrole Nanospheres and Pt Nanostars on Ni Foam for Electrochemical Detection of Ammonia–Nitrogen

Nano Pub Date : 2024-02-01 DOI:10.1142/s1793292024500024
Liang Zhang, Sizhe Liu, Xinyao Liu, Yue Han, Jiali Gu, Xinyue Wang
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Abstract

Designing and developing sensitive electrochemical sensors have always been paid attention to achieve the accurate detection of ammonia–nitrogen in the aqueous environment. Herein, a two-step electrodeposition route was used to achieve a Ni foam-supported polypyrrole nanospheres and Pt nanostars sensing electrode (Pt-PPy-Ni foam) for ammonia–nitrogen detection. After controlling the deposition time of Pt nanostars, the optimal Pt-PPy-Ni foam electrode exhibited greater electrocatalytic ability for ammonia oxidation reaction with a current density of 41.73 mA cm[Formula: see text] than that of Pt-Ni foam. This enhanced electrocatalytic ability could be attributed to the excellent adsorption of polypyrrole nanospheres for ammonia and the great catalytic activity of Pt nanostars for the ammonia oxidation reaction. This Pt-PPy-Ni foam electrode showed great detection performances with a sensitivity of 0.013 mA [Formula: see text]M[Formula: see text], and a detection limit of 8.72 [Formula: see text]M. Moreover, accepted results were obtained for the recovery measurements of lake and seawater samples with recoveries from 101.05% to 102.27% and 90.73% to 91.70%. In addition, Pt-PPy-Ni foam sensor exhibited good anti-interference ability with low current charges, reproducibility (relative standard deviation = 1.58%) and stability (relative standard deviation = 6.11%), showing a great application potential.
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在镍泡沫上两步电沉积聚吡咯纳米球和铂纳米柱,用于电化学检测氨氮
为实现对水环境中氨氮的准确检测,设计和开发灵敏的电化学传感器一直备受关注。本文采用两步电沉积路线实现了泡沫镍支撑的聚吡咯纳米球和铂纳米柱传感电极(Pt-PPy-Ni foam),用于氨氮检测。在控制纳米铂柱的沉积时间后,最佳的泡沫铂镍电极对氨氧化反应具有更强的电催化能力,其电流密度为 41.73 mA cm[式中:见正文],优于泡沫铂镍电极。这种增强的电催化能力可归因于聚吡咯纳米球对氨的良好吸附以及铂纳米柱对氨氧化反应的巨大催化活性。该铂-钯-镍泡沫电极具有很高的检测性能,灵敏度为 0.013 mA [式:见正文]M[式:见正文],检测限为 8.72 [式:见正文]M。此外,湖泊和海水样品的回收率测量结果也得到了认可,回收率分别为 101.05% 至 102.27% 和 90.73% 至 91.70%。此外,铂-钯-镍泡沫传感器还表现出良好的抗干扰能力(电流电荷低)、重现性(相对标准偏差 = 1.58%)和稳定性(相对标准偏差 = 6.11%),显示出巨大的应用潜力。
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