Nanocrystalline Manganese Iron Oxide as a Charge Storage Electrode

Abstract: Energy is one of the main issues in this century. The demand of energy for usage of modern electronic accessories has attracted lot of attention towards energy storage devices such as batteries and supercapacitors. Supercapacitors have the greater potential for providing good cyclability, high power density and energy density as compared with the batteries [1][2][3]. The synthesis of advanced electrode materials for charge storage is the key issue in the development of supercapacitors. It has been found that p… Show more

“…As described in the experimental section, the MnNiCoÀ O/C was synthesized by the simple calcination of the mixture of metal acetates-citrate complex, glucose and NaCl. In this study, NaCl particle surface was employed as the template for the nanosheets as it has a face-centered cubic crystal structure [35,36] and citric acid was used as a chelating agent for the metal ions [37]. The high temperature pyrolysis under N 2 followed by calcination at low temperature in air results in the formation of ternary MnNiCoÀ O/C hybrid nanostructure due to the thermal carbonization of glucose and oxidation of metal citrates.…”

Carbon Encapsulated Ternary Mn−Ni−Co Oxide Nanoparticles as Electrode Materials for Energy Storage Applications

“…As described in the experimental section, the MnNiCoÀ O/C was synthesized by the simple calcination of the mixture of metal acetates-citrate complex, glucose and NaCl. In this study, NaCl particle surface was employed as the template for the nanosheets as it has a face-centered cubic crystal structure [35,36] and citric acid was used as a chelating agent for the metal ions [37]. The high temperature pyrolysis under N 2 followed by calcination at low temperature in air results in the formation of ternary MnNiCoÀ O/C hybrid nanostructure due to the thermal carbonization of glucose and oxidation of metal citrates.…”

Carbon Encapsulated Ternary Mn−Ni−Co Oxide Nanoparticles as Electrode Materials for Energy Storage Applications

“…FeMnO 3 has been examined for applications such as lithium-ion batteries, catalysis, humidity sensors, energy storage and antibacterial devices ( Doroftei et al, 2014 ; Cao et al, 2016 ; Cetin et al, 2019 ; Vasiljevic et al, 2020a ; Nikolic et al, 2020 ). A large number of synthesis methods, such as co-precipitation, hydrothermal, ball milling, solid state reaction and sol-gel chemistry, have all been employed for the fabrication of FeMnO 3 materials ( Sundari et al, 2013 ; Doroftei et al, 2014 ; Cao et al, 2016 ; Soni and Pal, 2016 ; Bin et al, 2017 ; Mungse et al, 2017 ; Gowreesan and Ruban Kumar, 2017 ; Saravanakumar et al, 2018 ; Cetin et al, 2019 ; Fix, 2019 ; Lobo and Rubankumar, 2019 ; Vasiljevic et al, 2020a ; Nikolic et al, 2020 ; Vasiljevic et al, 2020b ). Despite this, not all these techniques are viable to synthesize FeMnO 3 nanomaterials, as there are some drawbacks such as the expense of the source materials, chemical non-uniformity, high impurity, aggregated nanoparticles, and non-stoichiometry of some ferrite systems ( Buonsanti et al, 2012 ; Alves et al, 2013 ; Bennet et al, 2016 ; Skliri, 2018 ).…”

All-Inorganic p−n Heterojunction Solar Cells by Solution Combustion Synthesis Using N-type FeMnO3 Perovskite Photoactive Layer

Synthesis and characterization of Fe2O3/Mn2O3/FeMn2O4 nano composite alloy coated glass for photo-catalytic degradation of Reactive Blue 222