MoS₂ Effect on Nickel Electrochemical Activation: An Atomistic/Experimental Approach

Abstract: Hybrid Ni–MoS2 electrocatalysts are one of the most promising materials for the generation of hydrogen in an alkaline medium. This paper presents a simple and economical method for the rational synthesis of Ni–MoS2 nanocomposites, maximizing the contact area and reducing the contact resistance between MoS2 and the nickel surface. In this way, it is possible to maximize the synergistic effect between both materials, obtaining a hybrid nanomaterial with high electroactivity toward the generation of hydrogen. A c… Show more

“…Its stable structure consists of hexagonal layers co-bonded via Van der Waals forces, and each layer has covalent bonds between Mo and S (S-Mo-S). The tunable bandgap energy from 1.2 eV for bulk MoS 2 material to 1.8 eV in monolayer and the transition of the bandgap from indirect to direct bandgap has generated massive attention in exploring MoS 2 for various applications, such as hydrogen production [4][5][6], optoelectronic [7,8], lubrication [9], batteries [10], photocatalysis [11], and transistors [12].…”

Efficient and Facile Synthetic Route of MoO3:MoS2 Hybrid Thin Layer via Oxidative Reaction of MoS2 Nanoflakes

“…Its stable structure consists of hexagonal layers co-bonded via Van der Waals forces, and each layer has covalent bonds between Mo and S (S-Mo-S). The tunable bandgap energy from 1.2 eV for bulk MoS 2 material to 1.8 eV in monolayer and the transition of the bandgap from indirect to direct bandgap has generated massive attention in exploring MoS 2 for various applications, such as hydrogen production [4][5][6], optoelectronic [7,8], lubrication [9], batteries [10], photocatalysis [11], and transistors [12].…”

Efficient and Facile Synthetic Route of MoO3:MoS2 Hybrid Thin Layer via Oxidative Reaction of MoS2 Nanoflakes

Nickel-based composites using tungsten carbides as enhancers for electroactivity for the hydrogen evolution reaction