Ultra‐small CuO nanoparticles with tailored energy‐band diagram synthesized by a hybrid plasma‐liquid process

Velusamy, Tamilselvan; Liguori, Anna; Macías-Montero, Manuel; Padmanaban, Dilli Babu; Carolan, Darragh; Gherardi, Matteo; Colombo, Vittorio; Maguire, Paul; Švrček, Vladimír; Mariotti, Davide

doi:10.1002/ppap.201600224

Cited by 56 publications

(42 citation statements)

References 75 publications

(164 reference statements)

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“…[6][7][8] This approach to synthesizing metal nanoparticles is high-purity and environmentally-friendly, avoiding chemical reducing agents such as sodium borohydride, 9 can eliminate the need for organic capping agents by electrostatically stabilizing the particles, 10,11 and has the potential to create novel materials such as metal oxides via non-equilibrium, solution-phase radical chemistry. 12,13 While the ability of plasmas to function as an electrochemical electrode and reduce metal cations to metal nanoparticles has been clearly demonstrated, the fundamental reaction mechanisms remain elusive, limiting the ability to optimize or tailor the process. A critical reason is that plasmas contain a variety of reactive species that originate from the inert carrier gas and, in many applications, ambient air, including electrons, ions, and metastable neutrals, and these reactive species have a distribution of energies.…”

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confidence: 99%

Quantitative Study of Electrochemical Reduction of Ag⁺to Ag Nanoparticles in Aqueous Solutions by a Plasma Cathode

Ghosh

Hawtof

Rumbach

et al. 2017

J. Electrochem. Soc.

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Replacing the solid metal cathode in an electrolytic cell with a plasma (gas discharge) allows the reduction of metal salt solutions to metal nanoparticles. Here, we apply gravimetric analysis to quantify the charge transfer (faradaic) efficiency of this reduction process and understand reaction pathways at the plasma-liquid interface. Silver powder synthesized from aqueous solutions of silver nitrate is collected and the weight is compared to the theoretical amount of silver obtained by applying Faraday's law of electrolysis. We find that the faradaic efficiencies are near 100% when the initial silver nitrate concentration is large (>100 mM), but are much less than 100% at low salt concentrations (<15 mM) or at high applied currents (>6 mA). These results are explained in terms of reaction kinetics involving solvated electrons and two important reactions: the reduction of silver ions (Ag + ) and the second order recombination of solvated electrons which releases hydrogen gas. Plasmas formed at the surface of liquids including water have the potential to carry out electrochemical reactions through the interaction between gas-phase and solution species.1-3 In a direct-current (DC) configuration where the plasma is one electrode and a solid metal or plasma is another electrode with an aqueous electrolyte in between, charge is transferred from gas-phase electrons or ions in the plasma to aqueous ions in solution through charge transfer reactions at the plasma-liquid interface. 4,5 In contrast to typical electrochemical reactions at the interface of a solid metal electrode and ionic solution, the reduction or oxidation reactions in plasma-assisted electrochemistry occur substrate-free. For example, solutions containing metal cations can be reduced by a cathodic plasma to produce colloidallydispersed metal nanoparticles rather than thin films of metal deposited on a substrate. [6][7][8] This approach to synthesizing metal nanoparticles is high-purity and environmentally-friendly, avoiding chemical reducing agents such as sodium borohydride, 9 can eliminate the need for organic capping agents by electrostatically stabilizing the particles, 10,11 and has the potential to create novel materials such as metal oxides via non-equilibrium, solution-phase radical chemistry. 12,13 While the ability of plasmas to function as an electrochemical electrode and reduce metal cations to metal nanoparticles has been clearly demonstrated, the fundamental reaction mechanisms remain elusive, limiting the ability to optimize or tailor the process. A critical reason is that plasmas contain a variety of reactive species that originate from the inert carrier gas and, in many applications, ambient air, including electrons, ions, and metastable neutrals, and these reactive species have a distribution of energies.14 Many of these species can react directly with and dissociate other gas or vapor phase molecules such as water, 15 or dissolve into the solution and then react with solution species to create a number of products.16 For example, in ...

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confidence: 99%

Quantitative Study of Electrochemical Reduction of Ag⁺to Ag Nanoparticles in Aqueous Solutions by a Plasma Cathode

Ghosh

Hawtof

Rumbach

et al. 2017

J. Electrochem. Soc.

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“…This is strong evidence that, with copper foil as electrode, the absence of H 2 O 2 in SOL2 colloid is as a result of its complete consumption through the reaction with copper in (6). In contrast, SOL2 is initially acid and its pH increases only gradually during the process (pH 10.35 at the end of the treatment) due to the plasma induced electrolytic reactions leading to the reduction of hydrogen ions to hydrogen gas [8,46]. This limits the efficiency of reaction 2 and makes reaction 6 possible, as H 2 O 2 becomes available for reacting with Cu, with the following effects:…”

Section: Pathway Bmentioning

confidence: 96%

“…Cu In this second pathway (B), the first reaction (4) represents the metal dissolution occurring at the anode of the electrochemical cell [3]; the released Cu 2+ ions then react with hydrated electrons in the bulk of the liquid, forming Cu according reaction (5) [3,46]. Finally, in the bulk of the liquid, metal…”

Section: Pathway Bmentioning

confidence: 99%

Synthesis of Copper-Based Nanostructures in Liquid Environments by Means of a Non-equilibrium Atmospheric Pressure Nanopulsed Plasma Jet

Liguori

Gallingani

Padmanaban

et al. 2018

Plasma Chem Plasma Process

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The influence of the liquid composition on the chemical and morphological properties of copper-based nanostructures synthesized by a non-equilibrium atmospheric plasma treatment is investigated and discussed. The synthesis approach is simple and environmentally friendly, employs a non-equilibrium nanopulsed atmospheric pressure plasma jet as a contactless cathode and a Cu foil as immersed anode. The process was studied using four distinct electrolyte solutions composed of distilled water and either NaCl + NaOH, NaCl only or NaOH only at two different concentrations, without the addition of any copper salts. CuO crystalline structures with limited impurities (e.g. Cu and Cu(OH) 2 phases) were produced from NaCl + NaOH containing solutions, mainly CuO and CuCl 2 structures were synthesized in the electrolyte solution containing only NaCl and no synthesis occurred in solutions containing only NaOH. Both aggregated and dispersed nanostructures were produced in the NaCl + NaOH and NaCl containing solutions. Reaction pathways leading to the formation of the nanostructures are proposed and discussed.

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“…Optical spectroscopy studies indicate that the PL emission properties can be adjusted by the dopant concentrations in the yttrium oxide NPs, which in turn can be controlled by the plasma process conditions. Other MONS including ZnO nanosheets, TiO 2 nanotube, europium‐doped ceria NPs CeO 2 , CuO NPs, CuO/TiO 2 nanocomposite, Ag/TiO 2 nanocomposite, SnO/GNS nanocomposite were recently synthesized using the microplasma‐assisted liquid‐phase method. These results confirm high potential of microplasmas in oxide materials processing and deposition for optoelectronics, sensing, and energy applications.…”

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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Ultra‐small CuO nanoparticles with tailored energy‐band diagram synthesized by a hybrid plasma‐liquid process

Cited by 56 publications

References 75 publications

Quantitative Study of Electrochemical Reduction of Ag⁺to Ag Nanoparticles in Aqueous Solutions by a Plasma Cathode

Quantitative Study of Electrochemical Reduction of Ag⁺to Ag Nanoparticles in Aqueous Solutions by a Plasma Cathode

Synthesis of Copper-Based Nanostructures in Liquid Environments by Means of a Non-equilibrium Atmospheric Pressure Nanopulsed Plasma Jet

Microplasmas for Advanced Materials and Devices

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Ultra‐small CuO nanoparticles with tailored energy‐band diagram synthesized by a hybrid plasma‐liquid process

Cited by 56 publications

References 75 publications

Quantitative Study of Electrochemical Reduction of Ag+to Ag Nanoparticles in Aqueous Solutions by a Plasma Cathode

Quantitative Study of Electrochemical Reduction of Ag+to Ag Nanoparticles in Aqueous Solutions by a Plasma Cathode

Synthesis of Copper-Based Nanostructures in Liquid Environments by Means of a Non-equilibrium Atmospheric Pressure Nanopulsed Plasma Jet

Microplasmas for Advanced Materials and Devices

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Quantitative Study of Electrochemical Reduction of Ag⁺to Ag Nanoparticles in Aqueous Solutions by a Plasma Cathode

Quantitative Study of Electrochemical Reduction of Ag⁺to Ag Nanoparticles in Aqueous Solutions by a Plasma Cathode