Dual Catalytic and Self-Assembled Growth of Two-Dimensional Transition Metal Dichalcogenides Through Simultaneous Predeposition Process

The recent introduction of alkali metal halide catalysts for chemical vapor deposition (CVD) of transition metal dichalcogenides (TMDs) has enabled remarkable two-dimensional (2D) growth. However, the process development and growth mechanism require further exploration to enhance the effects of salts and understand the principles. Herein, simultaneous predeposition of a metal source (MoO3) and salt (NaCl) by thermal evaporation is adopted. As a result, remarkable growth behaviors such as promoted 2D growth, easy patterning, and potential diversity of target materials can be achieved. Step-by-step spectroscopy combined with morphological analyses reveals a reaction path for MoS2 growth in which NaCl reacts separately with S and MoO3 to form Na2SO4 and Na2Mo2O7 intermediates, respectively. These intermediates provide a favorable environment for 2D growth, including an enhanced source supply and liquid medium. Consequently, large grains of monolayer MoS2 are formed by self-assembly, indicating the merging of small equilateral triangular grains on the liquid intermediates. This study is expected to serve as an ideal reference for understanding the principles of salt catalysis and evolution of CVD in the preparation of 2D TMDs.

Automated summary

This study adopts simultaneous predeposition of a metal source (MoO3) and salt (NaCl) by thermal evaporation to achieve remarkable 2D growth effects, including promoted growth, easy patterning, and potential diversity of materials. Step-by-step spectroscopy combined with morphological analyses reveals a reaction path for MoS2 growth involving the formation of Na2SO4 and Na2Mo2O7 intermediates from the separate reactions of NaCl with S and MoO3, respectively. These intermediates provide a favorable environment for 2D growth, resulting in the formation of large grains of monolayer MoS2. This study contributes to understanding the principles of salt catalysis and the evolution of CVD in the preparation of 2D TMDs.