Recently, sulfur (S)-vacancies created on the basal plane of 2 H -molybdenum disulfide (MoS2) using argon plasma exposure exhibited higher intrinsic activity for the electrochemical hydrogen evolution reaction than the edge sites and metallic 1 T -phase of MoS2 catalysts. However, a more industrially viable alternative to the argon plasma desulfurization process is needed. In this work, we introduce a scalable route towards generating S-vacancies on the MoS2 basal plane using electrochemical desulfurization. Even though sulfur atoms on the basal plane are known to be stable and inert, we find that they can be electrochemically reduced under accessible applied potentials. This can be done on various 2 H -MoS2 nanostructures. By changing the applied desulfurization potential, the extent of desulfurization and the resulting activity can be varied. The resulting active sites are stable under extended desulfurization durations and show consistent HER activity.
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机译:最近,使用氩等离子体暴露在2 H-二硫化钼(MoS 2 )的基面上产生的硫(S)空位比边缘位点和金属对金属的电化学放氢反应具有更高的固有活性。 MoS 2 催化剂的1 T相。然而,需要氩等离子体脱硫工艺的更工业可行的替代方案。在这项工作中,我们介绍了使用电化学脱硫在MoS 2 基面上生成S空位的可扩展途径。即使已知基面上的硫原子是稳定的和惰性的,我们发现它们可以在可接近的施加电势下被电化学还原。这可以在各种2 H -MoS 2 纳米结构上完成。通过改变施加的脱硫电势,可以改变脱硫的程度和所产生的活性。所得的活性位点在延长的脱硫持续时间内是稳定的,并显示出一致的HER活性。
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