Abstract
Copper selenide-sulfide nanostructures were synthesized using metal-organic chemical routes in the presence of Cu- and Se-precursors as well as S-containing compounds. Our goal was first to examine if the initial Cu/Se 1:1 molar proportion in the starting reagents would always lead to equiatomic composition in the final product, depending on other synthesis parameters which affect the reagents reactivity. Such reaction conditions were the types of precursors, surfactants and other reagents, as well as the synthesis temperature. The use of ‘hot-injection’ processes was avoided, focusing on ‘non-injection’ ones; that is, only heat-up protocols were employed, which have the advantage of simple operation and scalability. All reagents were mixed at room temperature followed by further heating to a selected high temperature. It was found that for samples with particles of bigger size and anisotropic shape the CuSe composition was favored, whereas particles with smaller size and spherical shape possessed a Cu2−xSe phase, especially when no sulfur was present. Apart from elemental Se, Al2Se3 was used as an efficient selenium source for the first time for the acquisition of copper selenide nanostructures. The use of dodecanethiol in the presence of trioctylphosphine and elemental Se promoted the incorporation of sulfur in the materials crystal lattice, leading to Cu-Se-S compositions. A variety of techniques were used to characterize the formed nanomaterials such as XRD, TEM, HRTEM, STEM-EDX, AFM and UV-Vis-NIR. Promising results, especially for thin anisotropic nanoplates for use as electrocatalysts in nitrogen reduction reaction (NRR), were obtained.
Highlights
Noble metal nanoparticles (NPs) have been shown to possess interesting optical properties
‘heat-up’ approach where all reagents are mixed at room temperature and the obtained mixture is heated to a certain temperature
The use of trioctyphosphine oxide (TOPO) promoted the acquisition of larger CuSe nanostructures with stoichiometric composition
Summary
Noble metal nanoparticles (NPs) have been shown to possess interesting optical properties. Non-noble element copper-deficient copper chalcogenide nanostructures have been proven to display remarkable plasmonic features. If colloidal chemical synthetic routes are used, the precursor ratio at the copper-tellurium. Copper selenide NPs are p-type semiconductors which can find applications in several domains, including energy conversion [2] and storage as well as biomedicine [3]. The Cu2−x Se phase has a direct band gap of 2.1 eV. The wide range of possible band gap energies and varying electronic behaviours are most probably related to the variations in Cu to Se stoichiometry, recombination sites due to dislocations, size effects and/or the oxidation state of Cu and
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