High efficiency Hg(II) electrochemical detection based on the number of defect engineering on MoS 2 : Insight in synergistic action of sulfur vacancies and undercoordinated Mo.

Defects on nanomaterials can effectively enhance the performance of electrochemical detection, but an excessive number of defects may have an adverse effect. In this study, MoS ₂ nanosheets were synthesized using a hydrothermal synthesis method. By controlling the calcination temperature, MoS ₂ -7H, calcined at 700 °C under H ₂ /Ar ₂ , exhibited an optimal ratio of "point" defects to "plane" defects, resulting in excellent detection performance for mercury ions (Hg(II)). In general, the sulfur vacancies (SV) and undercoordinated Mo generated after calcination of MoS ₂ significantly promotes the adsorption process and redox of Hg(II) by increasing surface chemical activity, providing additional adsorption sites and adjusting surface charge status to accelerate the catalytic redox of Hg(II). The prepared MoS ₂ -7H-modified electrode showed a sensitivity of 18.25 μA μM ^-1 and a low limit of detection (LOD) of 6.60 nM towards Hg(II). MoS ₂ -7H also demonstrated a good anti-interference, stability, and exhibited a strong current response in real water samples. The modulation to obtain appropriate number of defects in MoS ₂ holds promise as a prospective electrode modification material for the electroanalysis.
Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
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