Bimetal-organic framework Cu-Ni-BTC and its derivative CuO@NiO: Construction of three environmental small-molecule electrochemical sensors

The bimetal-organic framework Cu-Ni-BTC (1,3,5-Benzenetricarboxylic acid, H3BTC) and its derivative CuO@NiO were used as the basis of the construction of electrochemical sensors for three environmental small-molecules. Firstly, the Cu-Ni-BTC-CPE modified electrode was investigated by electrochemical...

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Published in:Journal of electroanalytical chemistry (Lausanne, Switzerland) Switzerland), 2020-02, Vol.858, p.113785, Article 113785
Main Authors: Dong, Sheying, Li, Zhaojia, Fu, Yile, Zhang, Guo, Zhang, Dandan, Tong, Mengmeng, Huang, Tinglin
Format: Article
Language:English
Subjects:
Bimetal-organic
Bimetals
Biocompatibility
Catechol
Chemical sensors
Copper
Copper oxides
Derivative
Dihydroxybenzene
Electrical resistivity
Electrochemical potential
Electrochemical sensor
Framework
Hydroquinone
Ionic liquids
Ions
Myoglobins
Nickel oxides
Nitrite
Nitrogen dioxide
Selectivity
Sensors
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Summary:The bimetal-organic framework Cu-Ni-BTC (1,3,5-Benzenetricarboxylic acid, H3BTC) and its derivative CuO@NiO were used as the basis of the construction of electrochemical sensors for three environmental small-molecules. Firstly, the Cu-Ni-BTC-CPE modified electrode was investigated by electrochemical measurement, the results showed that linear responses of the proposed sensor ranged from 0.5 μM to 330 μM for catechol (CT) and 0.3 μM to 390 μM for hydroquinone (HQ), with detection limits of 0.2 μM and 0.08 μM, respectively. Secondly, CuO@NiO was prepared by calcination, and myoglobin (Mb) was subsequently immobilized on a sensing interface based on CuO@NiO and ionic liquid (IL) composite membrane where IL possessed good electrical conductivity, wide electrochemical potential window, excellent film forming as well as good biocompatibility. Spectroscopic and electrochemical examinations revealed that Mb remained its bioactivity on the surface of CuO@NiO/IL composite film, and had excellent electrocatalytic activity towards nitrite (NO2−) in ranges of 1.0–1536 μM and 1536–3636 μM, and the detection limit was low to 0.4 μM, the apparent Michaelis-Menten constant (KM) was 0.42 mM. The results showed that MOFs and its derivative have different catalytic performance. The biggish difference in catalyst activity and selectivity provides a new idea and theoretical guidance for the further studies on electrochemical sensors. [Display omitted]
ISSN:1572-6657
1873-2569
DOI:10.1016/j.jelechem.2019.113785