Abstract
Abstract Molybdenum sulfide is of interest as a noble metal-free catalyst for the hydrogen evolution reaction (HER). In crystallized form, it shows a typical stacking of planar S–Mo–S layers whereas the catalytically active centers are situated on the edges of these entities characterized by non-saturated bonds of the molybdenum atoms. In this study, 2H-MoS2 is investigated as HER catalyst as a function of particle size using powder electrodes of different grain sizes and morphology. HER was also determined as a function of growth defects (bending of layers) and as a function of active sites employing MoS2 nanoparticles (NP). To study the influence of the substrate on the perfection of the transition metal disulfide, MoS2 nanosheets were deposited on multi-walled carbon nanotubes (MWCNTs) of different diameters. Highest activity was found for MoS2 nanosheets deposited on MWCNTs with a diameter smaller than 8 nm. At diameters larger than 10 nm, a wrapping of the nanotubes by partially bended stacks of S–Mo–S layers occurs, while at diameters smaller than 10 nm, individual MoS2 nanosheets of 3–5 S–Mo–S stacks of 3–4 nm in height and 10–20 nm in lateral extension surround the carbon nanotubes in form of hexagonal cylinders. The ratio of catalytically active non-van-der-Waals and hexagonal basal planes was determined electrochemically by electro-oxidation and correlated with HER activity.
Highlights
MoS2 preparationMoS2 single crystals, used as a reference material in this work, were grown by chemical vapor transport using MoO3 and IBr as transporting agents
Molybdenum sulfide is of interest as a noble metal-free catalyst for the hydrogen evolution reaction (HER)
In order to further increase the area of non-van-der-Waals planes where the catalytically active centers are located, MoS2 nanosheets were grown by the precipitation reaction described above on multi-walled carbon nanotubes (MWCNTs) substrates of different diameters
Summary
MoS2 single crystals, used as a reference material in this work, were grown by chemical vapor transport using MoO3 and IBr as transporting agents. MoS2 (2 g) and MoO3 powder (25 mg) were placed at the closed end of a 190 mm long and closed quartz glass tube of 20 mm diameter. The powder sample (# SF) was synthesized from the elements at 500 °C in an evacuated and sealed quartz glass ampoule for 50 h by weighing-in molybdenum and sulfur in the mass ratio of 1:2. According to the data sheet, the particle size of the Molykote μ-size preparation is 0.65–0.75 μm and that of the Molykote z-powder 3–4 μm. The preparation of the samples SA I & II is unknown and the method by which the particle size was determined is not described. MoS2 grown on MWCNTs was prepared using the same method as described for the preparation of DS-315 powder. The obtained product was in a first step heated in forming gas (10% H2 in N2) at 450 °C for 1 h and at 800 °C for 2 h under argon gas (Ar)
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