Oxygen evolution on Fe-doped NiO electrocatalysts deposited via microplasma

Pebley, Andrew C.; Decolvenaere, Elizabeth; Pollock, Tresa M.; Gordon, Michael J.

doi:10.1039/c7nr04302c

Cited by 65 publications

(35 citation statements)

References 72 publications

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“…Recently, a versatile microplasma‐based approach ( Figure ) has been demonstrated for direct deposition of crystalline MONS including α‐Fe 2 O 3 , CuO, NiO, and Fe‐doped NiO on different substrates including polymeric materials, conductors, insulators, fibers, and patterned substrates at ambient temperature (Figure a) . The as‐prepared CuO films were used as active electrodes for lithium ion batteries, exhibiting high specific capacity and good electrochemical responses over a large number of voltage sweep cycles (Figure b).…”

Section: Production Of Advanced Nanomaterialsmentioning

confidence: 99%

Microplasmas for Advanced Materials and Devices

et al. 2019

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DavideMariotti is a Professor of Plasma Science and Nanoscale Engineering with Ulster University in UK. He has previously worked internationally in Japan and USA and both in academic and industry. His research encompasses the design and development of innovative plasma-based processes to explore new materials opportunities. Concurrently to a strong application focus in photovoltaics and more broadly in energy applications, his research is also strongly driven by scientific discovery. Kostya (Ken) Ostrikov is aProfessor with Queensland University of Technology, Australia, a Founding Leader of the CSIRO-QUT Joint Sustainable Processes and Devices Laboratory, and Academician of the Academy of Europe and the European Academy of Sciences. His research focuses on nanoscale control of energy and matter contributes to the solution of the grand challenge of directing energy and matter at nanoscales, to develop renewable energy and energy-efficient technologies for a sustainable future.is made on synergistic, complementary features of the plasmas that make them a versatile tool in materials-related applications.We therefore examine the recent progress in microplasmabased synthesis of advanced nanomaterials, highlight the key features of microplasmas, and discuss salient examples of Adv.

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Section: Production Of Advanced Nanomaterialsmentioning

confidence: 99%

Microplasmas for Advanced Materials and Devices

et al. 2019

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“…Metal-reduction-based on-surface plasma printing has shown great promise at atmospheric pressure. [39][40][41] In this method, a precursor deposited in selected physical locations is reduced to form a desired product, producing patterned regions with varied chemistry. It is also possible to use inkjet printing to introduce a metal precursor, followed by the application of a plasma for reduction of the precursor.…”

Section: Precursor Placement and Plasma-surface Interactionsmentioning

confidence: 99%

“…The nanocrystals can be integrated into various electronic, optoelectronic, and other devices. [41] Catalyst synthesis and activation has also been demonstrated through atmospheric plasma processing, with smaller particle size and a more controllable structure than traditional thermal means, and could also be incorporated into the numerous options for multiscale on-surface assembly. [47] In the example presented in Figure 3f, plasma-generated reactive oxygen species generated in a dielectric barrier discharge in air effectively modify oxidation states of Fe and Co metallic catalytic sites in the Prussian blue analog based metalorganic frameworks.…”

Section: Plasma Production and Modification Of Nanomaterialsmentioning

confidence: 99%

Multiscale Plasma‐Catalytic On‐Surface Assembly

Hartl

MacLeod

O’Mullane

et al. 2019

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Controlled modification of surfaces is one of the key pursuits of the nanoscience and nanotechnology fields. In article number 1903184, Kostya (Ken) Ostrikov and co‐workers from the Queensland University of Technology propose a concept which can enhance the capacity for the control of surfaces: plasma‐assisted nucleation and self‐assembly at atomic to nanoscales, scalable at atmospheric pressure.

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“…Magnetic exchange hardening, a phenomenon that increases a material's resistance to demagnetization, typically occurs in two-phase mixtures consisting of a ferromagnetic (FM) phase and an antiferromagnetic (AFM) phase. [1][2][3] It is well established that magnetic hardening can emerge from magnetic interactions across the interfaces separating the FM and the AFM phases, which becomes especially pronounced in nano-structured twophase mixtures. Less understood is the anomalous exchange hardening observed in the chemically disordered, single phase Heusler alloys Mn 1−x Fe x Ru 2 Sn and Mn 1−x Fe x Ru 2 Ge.…”

Section: Introductionmentioning

confidence: 99%

Modeling magnetic evolution and exchange hardening in disordered magnets: The example of Mn1−xFexRu2Sn Heusler alloys

Decolvenaere

Levin

Seshadri

et al. 2019

Phys. Rev. Materials

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We demonstrate how exchange hardening can arise in a chemically-disordered solid solution from a first-principles statistical mechanics approach. A general mixed-basis chemical and magnetic cluster expansion has been developed, and applied to the Mn1−xFexRu2Sn Heusler alloy system; single-phase solid solutions between antiferromagnetic MnRu 2 Sn and ferromagnetic FeRu 2 Sn with disorder on the Mn/Fe sublattice that exhibit unexpected exchange hardening. Monte Carlo simulations applied to the cluster expansion are able to reproduce the experimentally measured magnetic transition temperatures and the bulk magnetization as a function of composition. The magnetic ordering around a site is shown to be dependent not only on bulk composition, but also on the identity of the site and the local composition around that site. The simulations predict that local antiferromagnetic orderings form inside a bulk ferromagnetic region at intermediate compositions that drives the exchange hardening. Furthermore, the antiferromagnetic regions disorder at a lower temperature than the ferromagnetic regions, providing an atomistic explanation for the experimentally-observed decrease in exchange hardening with increasing temperature. These effects occur on a length scale too small to be resolved with previously-used characterization techniques.

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Oxygen evolution on Fe-doped NiO electrocatalysts deposited via microplasma

Cited by 65 publications

References 72 publications

Microplasmas for Advanced Materials and Devices

Microplasmas for Advanced Materials and Devices

Multiscale Plasma‐Catalytic On‐Surface Assembly

Modeling magnetic evolution and exchange hardening in disordered magnets: The example of Mn1−xFexRu2Sn Heusler alloys

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