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The emerging optoelectronic material family of transition metal dichalcogenides may be useful in flexible electronics. However, only MoS₂ has been grown directly as thin films on polymer substrates, owing in part to the high deposition temperatures typically required to prepare these materials. Changing vapor deposition chemistry can allow much lower film growth temperatures. We show that when using tetrakis(dimethylamido)zirconium(IV), Zr(NMe₂)₄, and H₂S as precursors, low-temperature chemical vapor deposition affords films of zirconium(IV) sulfide (ZrS₂) directly on polymer substrates. Stoichiometric and crystalline ZrS₂ films can be deposited with good adhesion on polyimide (Kapton) and polyether ether ketone (PEEK) substrates at 150–200 °C. The films deposited on polydimethylsiloxane (PDMS) substrates were stoichiometric and crystalline, but not well adhered. Films on all substrates were polycrystalline with small (20–30 nm) grains, highly oriented in the [001] direction of the 1T ZrS₂ phase. The films grown on PEEK have resistivities ca. 625 Ω cm, two orders of magnitude higher than ZrS₂ films deposited at 800–1000 °C from ZrCl₄ and sulfur. The films grown on Kapton are similarly conductive, whereas films on PDMS are not conductive. 

We analyzed the surface of a freshly exfoliated single crystal of zirconium(IV) sulfide, ZrS₂. Survey spectra and high-resolution spectra from the core levels Zr 4p, Zr 4s, Zr 3d, Zr 3p, Zr 3s, S 2p, S 2s, O 1s, and C 1s were acquired. The binding energies and peak area ratios of a stoichiometric ZrS₂ single crystal provide a pure reference of well-defined composition for material deposited by chemical or physical vapor deposition methods. 

Many microelectronic devices require thin films of silver or gold as wiring layers. We report silver( i ) and gold( i ) bicyclic amidinate complexes, wherein the constrained ligand geometry lessens the propensity for thermal decomposition. These new volatile compounds provide metallic films of silver and gold during CVD with hydrogen below 230 °C.