Abstract
High entropy metallic glass nanoparticles (HEMG NPs) are very promising materials for energy conversion due to the wide tuning possibilities of electrochemical potentials offered by their multimetallic character combined with an amorphous structure. Up until now, the generation of these HEMG NPs involved tedious synthesis procedures where the generated particles were only available on highly specialized supports, which limited their widespread use. Hence, more flexible synthetic approaches to obtain colloidal HEMG NPs for applications in energy conversion and storage are highly desirable. We utilized pulsed laser ablation of bulk high entropy alloy targets in acetonitrile to generate colloidal carbon-coated CrCoFeNiMn and CrCoFeNiMnMo HEMG NPs. An in-depth analysis of the structure and elemental distribution of the obtained nanoparticles down to single-particle levels using advanced transmission electron microscopy (TEM), energy-dispersive X-ray spectroscopy (EDX), X-ray diffraction (XRD), and X-ray photoelectron spectroscopy (XPS) methods revealed amorphous quinary and senary alloy phases with slight manganese oxide/hydroxide surface segregation, which were stabilized within graphitic shells. Studies on the catalytic activity of the corresponding carbon-HEMG NPs during oxygen evolution and oxygen reduction reactions revealed an elevated activity upon the incorporation of moderate amounts of Mo into the amorphous alloy, probably due to the defect generation by atomic size mismatch. Furthermore, we demonstrate the superiority of these carbon-HEMG NPs over their crystalline analogies and highlight the suitability of these amorphous multi-elemental NPs in electrocatalytic energy conversion.
Highlights
Nanoparticles (NPs) containing multiple metallic elements are of interest for various industrial and technological applications where different mechanical [1] or catalytical [2] properties of each constituent metal are combined within a single NP [3,4,5,6,7]
Morphology, elemental distribution, and surface composition of the colloidal quinary and senary high entropy metallic glass (HEMG) NPs obtained by laser ablation in acetonitrile using nanosecond pulses, a combination of various nanocharacterization methods was conducted including transmission electron microscopy (TEM)/scanning TEM (STEM), energy-dispersive X-ray spectroscopy (EDX), selected area electron diffraction (SAED), X-ray diffraction (XRD), and Xray photoelectron spectroscopy (XPS)
For longer pulse duration, three regimes were identified by molecular dynamics (MD) simulation that lead to different particle sizes and may have been affected by Mo due to its nearly two times higher melting temperature compared to the other elements present in the target
Summary
Nanoparticles (NPs) containing multiple metallic elements are of interest for various industrial and technological applications where different mechanical [1] or catalytical [2] properties of each constituent metal are combined within a single NP [3,4,5,6,7]. The obtained colloidal alloy NPs often resemble the composition of the bulk alloy targets used for ablation [47, 48], though deviations may occur upon utilization of ultrashort pulses and element systems with huge miscibility gaps [49, 50] This synthesis route is already well established for binary and ternary alloy NPs [48, 51] and PLAL was recently employed for generating HEA NPs as well [35, 52]. We explore the suitability of the generated HEMG NPs as electrocatalysts for oxygen evolution and oxygen reduction reactions (OER and ORR, respectively) where the degree of amorphization in the generated NP ensembles, as well as the incorporated content of Mo, influence the catalytic performance
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