Abstract
The structural and optical evolution of the ZnS thin films prepared by atomic layer deposition (ALD) from the diethylzinc (DEZ) and 1,5-pentanedithiol (PDT) as zinc and sulfur precursors was studied. A deposited ZnS layer (of about 60 nm) is amorphous, with a significant S excess. After annealing, the stoichiometry improved for annealing temperatures ≥400 °C and annealing time ≥2 h, and 1:1 stoichiometry was obtained when annealed at 500 °C for 4 h. ZnS crystallized into small crystallites (1–7 nm) with cubic sphalerite structure, which remained stable under the applied annealing conditions. The size of the crystallites (D) tended to decrease with annealing temperature, in agreement with the EDS data (decreased content of both S and Zn with annealing temperature); the D for samples annealed at 600 °C (for the time ≤2 h) was always the smallest. Both reflectivity and ellipsometric spectra showed characteristics typical for quantum confinement (distinct dips/peaks in UV spectral region). It can thus be concluded that the amorphous ZnS layer obtained at a relatively low temperature (150 °C) from organic S precursor transformed into the layers built of small ZnS nanocrystals of cubic structure after annealing at a temperature range of 300–600 °C under Ar atmosphere.
Highlights
Zinc sulfide (ZnS) is one of the most important semiconductor, widely used in optoelectronics [1], lasers and photovoltaics [2], and photocatalysis [3]
Since most ZnS applications require crystalline or polycrystalline forms of ZnS, here, we studied the structural and optical evolution of the ZnS thin films prepared from DEZ and PDT after various annealing treatments
Atomic layer deposition (ALD) of ZnS layer from the diethylzinc and 1,5-pentanedithiol at 150 °C resulted in growth of an amorphous layer with a significant excess of S over Zn element
Summary
Zinc sulfide (ZnS) is one of the most important semiconductor, widely used in optoelectronics [1], lasers and photovoltaics [2], and photocatalysis [3]. The broad interest in ZnS has its origin in its properties. Among those properties, the wide and direct band gap (3.6–3.8 eV), high refractive index at room temperature (2.35), and high transmittance from visible to infrared (up to 12 μm) range, are the most attractive features [4,5]. Materials 2019, 12, 3212 exceptional chemical stabilities, ZnS is considered as one of the most important passivation materials for semiconductor devices, especially for high-aspect ratio arrays based on HgCdTe [6,7]. Future devices will require a technique with a perfect conformability to prepare ZnS layers on any complex surface.
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