Laser-generated high entropy metallic glass nanoparticles as bifunctional electrocatalysts

Johny, Jacob; Li, Yao; Kamp, Marius; Prymak, Oleg; Liang, Shun-Xing; Krekeler, Tobias; Ritter, Martin; Kienle, Lorenz; Rehbock, Christoph; Barcikowski, Stephan; Reichenberger, Sven

doi:10.1007/s12274-021-3804-2

Cited by 48 publications

(37 citation statements)

References 108 publications

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“…Selective oxidation of Fe was not surprising due to its higher oxygen affinity. Similar element-specific surface oxidation has recently been reported for laser-generated Mn-rich high entropy alloy metallic glass nanoparticles, where the slight manganese oxide/hydroxide surface segregation has been observed, which increased with Mn content in the alloy [41].…”

Section: Variation Of the Initial Mixing State Of The Target And The Laser Pulse Durationsupporting

confidence: 84%

“…They found that independent of the solvent, a combination of both solvent purification methods leads to oxidationminimized Fe-Rh nanoparticles, proven even by atom probe tomography, and no impact of the bound oxygen in the molecule of the organic solvent could be found. But Johny et al recently discovered that acetonitrile as dispersant leads to amorphous (metallic glass) nanoparticles if a quinary or senary alloy is ablated and discussed the role of solventdelivered carbon as glass morphology stabilizer [41]. This amorphization phenomenon was not observed for quinary alloy nanoparticles produced by lases ablation in ethanol [46].…”

Section: Variation Of the Initial Mixing State Of The Target And The Laser Pulse Durationmentioning

confidence: 99%

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Identification of the main mixing process in the synthesis of alloy nanoparticles by laser ablation of compacted micropowder mixtures

Waag

Fares

et al. 2022

J Mater Sci

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Alloy nanoparticles offer the possibility to tune functional properties of nanoscale structures. Prominent examples of tuned properties are the local surface plasmon resonance for sensing applications and adsorption energies for applications in catalysis. Laser synthesis of colloidal nanoparticles is well suited for generating alloy nanoparticles of desired compositions. Not only bulk alloys but also compacted mixtures of single-metal micropowders can serve as ablation targets. However, it is still unknown how mixing of the individual metals transfers from the micro- to the nanoscale. This work experimentally contributes to the elucidation of the mixing processes during the laser-based synthesis of alloy nanoparticles. Key parameters, such as the initial state of mixing in the ablation target, the laser pulse duration, the laser spot size, and the ablation time, are varied. Experiments are performed on a cobalt-iron alloy, relevant for application in oxidation catalysis, in ethanol. The extent of mixing in the targets after ablation and in individual nanoparticles are studied by energy-dispersive X-ray spectroscopy and by cyclic voltammetry at relevant conditions for the oxygen evolution reaction, as model reaction. The results point at the benefits of well pre-mixed ablation targets and longer laser pulse durations for the laser-based synthesis of alloy nanoparticles. Graphical abstract

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Section: Variation Of the Initial Mixing State Of The Target And The Laser Pulse Durationsupporting

confidence: 84%

Section: Variation Of the Initial Mixing State Of The Target And The Laser Pulse Durationmentioning

confidence: 99%

Identification of the main mixing process in the synthesis of alloy nanoparticles by laser ablation of compacted micropowder mixtures

Waag

Fares

et al. 2022

J Mater Sci

Self Cite

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“…15,[72][73][74][75] When the synthesis duration and quenching time are even faster than those of HEAs or using easily glass-forming elements, metallic glass nanoparticles with a disordered atomic structure (lattice) can be formed. [76][77][78] For example, Glasscott et al 76 reported high-entropy metallic glass nanoparticles up to eight elements CoCrCuGdInMnNiV fabricated with precisely tunable stoichiometric ratios by the nanodroplet-mediated electrodeposition, which is an electroshock process with a feature time scale of ∼100 ms but at a much lower temperature (∼room temperature; Figure 2D,E). 76 The energy-dispersive X-ray mapping showed that these elements were distributed uniformly over the nanoparticles, which had calculated mixing entropy ΔS > 1.61 R, qualifying as high entropy mixing (Figure 2E).…”

Section: Ultrafast Shock Synthesismentioning

confidence: 99%

“…Similarly, other shock methods are also used to prepare HEA nanoparticles with different characteristics, such as microwave, 42,82 ultrasonication, 46 radiative shock heating, 41,83,84 and laser methods (Figure 3A). 16,43,77,85 For example, Qiao et al 42 fabricated the PtPdFeCoNi HEA nanoparticles uniformly distributed on reduced graphene oxide film via microwave energy (at 1800 K for several seconds) to realize high temperature for rapid synthesis of HEAs. Using highenergy acoustic cavitation in the ultrasonication process, NM precursors could be coreduced and transformed into alloy structures to synthesize multicomponent alloy nanoparticles by ultrasonication-assisted wet chemistry at room conditions.…”

Section: Other Shock-type Synthesesmentioning

confidence: 99%

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High‐entropy alloy catalysts: From bulk to nano toward highly efficient carbon and nitrogen catalysis

Zeng

et al. 2022

Carbon Energy

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High-entropy alloys (HEAs) have attracted widespread attention as both structural and functional materials owing to their huge multielement composition space and unique high-entropy mixing structure. Recently, emerging HEAs, either in nano or highly porous bulk forms, are developed and utilized for various catalytic and clean energy applications with superior activity and remarkable durability. Being catalysts, HEAs possess some unique advantages, including (1) a multielement composition space for the discovery of new catalysts and fine-tuning of surface adsorption (i.e., activity and selectivity), (2) diverse active sites derived from the random multielement mixing that are especially suitable for multistep catalysis, and(3) a high-entropy stabilized structure that improves the structural durability in harsh catalytic environments. Benefited from these inherent advantages, HEA catalysts have demonstrated superior catalytic performances and are promising for complex carbon (C) and nitrogen (N) cycle reactions featuring multistep reaction pathways and many different intermediates. However, the design, synthesis, characterization, and understanding of HEA catalysts for C-and N-involved reactions are extremely challenging because of both complex high-entropy materials and complex reactions. In this review, we present the recent development of HEA catalysts, particularly on their innovative and extensive syntheses, advanced (in situ) characterizations, and applications in complex C and N looping reactions, aiming to provide a focused view on how to utilize intrinsically complex catalysts for these important and complex reactions. In the end, remaining challenges and future directions are proposed to guide the development and application of HEA catalysts for highly efficient energy storage and chemical conversion toward carbon neutrality.

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Nanoengineering of Metallic Glasses

2022

Adv Eng Mater

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Metallic glasses with nanostructures recently have attracted extensive attention in various fields due to their unique functional properties. The amorphous atomic structure and nanoscale forms are the fundamental features of these nanomaterials. Herein, the current nanoengineering approaches for fabricating the metallic glasses with nanostructures such as thermoplastic forming, ultrasonic plasticity forming, dealloying, etc., are systematically summarized and the morphology and composition of the various types of metallic glasses with nanostructures that are formed by nanoengineering are classified. In addition, the functional properties and applications of metallic glasses with nanostructures are focused on. On the basis of this comprehensive review, some options for optimizing nanoengineering and anticipating the potential functional applications of metallic glasses with nanostructures are proposed.

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Laser-generated high entropy metallic glass nanoparticles as bifunctional electrocatalysts

Cited by 48 publications

References 108 publications

Identification of the main mixing process in the synthesis of alloy nanoparticles by laser ablation of compacted micropowder mixtures

Identification of the main mixing process in the synthesis of alloy nanoparticles by laser ablation of compacted micropowder mixtures

High‐entropy alloy catalysts: From bulk to nano toward highly efficient carbon and nitrogen catalysis

Nanoengineering of Metallic Glasses

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