Area‐Selective Growth of HfS 2 Thin Films via Atomic Layer Deposition at Low Temperature

The transition‐metal dichalcogenide HfS 2 is a promising alternative semiconductor with adequate band gap and high carrier mobility. However, a controllable growth of continuous HfS 2 films with selectivity for specific surfaces at a low temperature on a large scale has not been demonstrated yet. Herein, HfS 2 films are grown at 100 °C by atomic layer deposition (ALD) based on the precursors tetrakis(dimethylamido)hafnium and H 2 S. In situ vibrational spectroscopy allows for the definition of the temperature range over which (Me 2 N) 4 Hf chemisorbs as one monolayer. In that range, sequential exposures of the solid surface with (Me 2 N) 4 Hf and H 2 S result in self‐limiting reactions that yield alternating surface termination with dimethylamide and thiol. Repeating the cycle grows smooth, continuous, stoichiometric films of thicknesses adjustable from angstroms to >100 nm, as demonstrated by spectroscopic ellipsometry, XRR, AFM, UV–vis and Raman spectroscopy, XPS, and TEM. The well‐defined surface chemistry enables one to deposit HfS 2 selectively using, for example, patterns generated in molecular self‐assembled monolayers. This novel ALD reaction combines several attractive features necessary for integrating HfS 2 into devices.