Synthesis and characterization of two dimensional transition metal dichalcogenides

Two-dimensional transition metal dichalcogenides (TMDs) are an emerging class of atomically thin semiconductors that show potential in next-generation electronics, optoelectronics, and energy storage batteries. The successful synthesis and doping of TMDs is the key to their applications. I have synthesized monolayer MoS2, WS2, and multilayer ReS2 flakes by CVD, and studied an unprecedented one-pot synthesis for transition-metal substitution doping in large-area, synthetic monolayer TMDs. Electron microscopy, optical and electronic transport characterization and ab initio calculations indicate that our doping strategy preserves the attractive qualities of TMD monolayers, including semiconducting transport and strong direct-gap luminescence. The Re doping of MoS2 greatly improve the contact quality (one of the biggest issue in TMDs) and the FET shows Ohmic contact even at low temperature (4K). These results potentially enables next-generation optoelectronic technology in the atomically-thin regime. Besides, TMDs are generally considered to be 'air-stable', however, we have found that they exhibit poor long-term stability in air in morphology, chemical states, photo-emission, and demonstrated a potential solution to this problem by encapsulation of the monolayer sheet with transparent parylene C. Synthetic TMDs tend to grow parallel to the growth substrate, however, high performance energy conversion and storage devices prefer flakes with high exposed surface area. Therefore by choosing the right precursors and appropriate tuning of the CVD growth conditions, we have grown vertical ReS2 nanosheets on various growth substrates. We show that these structural features of the vertically grown ReS2 sheets can be exploited to significantly improve their performance as electrochemical catalysts in Lithium-Sulfur (Li-S) batteries and in hydrogen evolution reactions (HER). After 300 cycles, the specific capacity of the Li-S battery with vertical-ReS2 catalyst is retained above 750 mA h g-1 with only ∼0.063% capacity decay per cycle, much better than the baseline battery. As a HER catalyst, the vertical-ReS 2 provides very small onset over-potential (< 100 mV) and an exceptional exchange current density (∼67.6 microA/cm2), which is superior to most previous work with TMD catalysts.