Add to ORKGThe primary capacity of heat treated manganese dioxide in Li/MnO 2 batteries is directly related to the numerous physical properties which characterize this material. A statistical model is employed to isolate the influence of material structure, composition and morphology on the electrochemical performance at the discharge rates 2, 5, 10 and 20 mA g -1. Among the most influential parameters are the pyrolusite content, Mn(IV) percentage, cation vacancy fraction and surface area. Some of the materials investigated show higher specific capacities than literature materials, with further improvement to the performance of these materials anticipated through the intelligent selection of heat treated manganese dioxide which exhibit the ideal prope...
Physicochemical properties of chemically prepared MnO2 were studied In detail. Li-MnO2 cells were fa...
Kinetic analysis is used to determine the required isothermal heating time at various temperatures t...
The nanomaterials are used widely and effectively in electrochemical energy storage because of their...
The electrochemical performance of heat treated manganese dioxide in lithium batteries is for the fi...
The electrochemical performance of heat treated manganese dioxide in lithium batteries is for the fi...
The influence of various conditions on the heat treatment step in preparing manganese dioxide for pr...
The influence of various conditions on the heat treatment step in preparing manganese dioxide for pr...
The present study demonstrates that the properties of heat-treated electrolytic manganese dioxide (E...
The Electrochemical Society, find out moreThermal Lithiation of Manganese Dioxide: Effect of Low Lit...
The effect of heating the electrolytic manganese dioxide (EMD) obtained from the Indian ore on the p...
In this work the discharge mechanism for heat treated electrolytic manganese dioxide (HT-EMD) in a p...
The effect of lithium concentration on Li xMnO 2 (x ≤ 0.3) materials prepared by co-precipitationhea...
The effect of lithium concentration on LixMnO2 (x ≤ 0.3) materials prepared by co-precipitation/heat...
According to its electrochemical and thermodynamic properties, manganese and its oxides [1] are good...
Heat treated manganese dioxide is partially lithiated using butyl-lithium to determine the changes i...
Physicochemical properties of chemically prepared MnO2 were studied In detail. Li-MnO2 cells were fa...
Kinetic analysis is used to determine the required isothermal heating time at various temperatures t...
The nanomaterials are used widely and effectively in electrochemical energy storage because of their...
The electrochemical performance of heat treated manganese dioxide in lithium batteries is for the fi...
The electrochemical performance of heat treated manganese dioxide in lithium batteries is for the fi...
The influence of various conditions on the heat treatment step in preparing manganese dioxide for pr...
The influence of various conditions on the heat treatment step in preparing manganese dioxide for pr...
The present study demonstrates that the properties of heat-treated electrolytic manganese dioxide (E...
The Electrochemical Society, find out moreThermal Lithiation of Manganese Dioxide: Effect of Low Lit...
The effect of heating the electrolytic manganese dioxide (EMD) obtained from the Indian ore on the p...
In this work the discharge mechanism for heat treated electrolytic manganese dioxide (HT-EMD) in a p...
The effect of lithium concentration on Li xMnO 2 (x ≤ 0.3) materials prepared by co-precipitationhea...
The effect of lithium concentration on LixMnO2 (x ≤ 0.3) materials prepared by co-precipitation/heat...
According to its electrochemical and thermodynamic properties, manganese and its oxides [1] are good...
Heat treated manganese dioxide is partially lithiated using butyl-lithium to determine the changes i...
Physicochemical properties of chemically prepared MnO2 were studied In detail. Li-MnO2 cells were fa...
Kinetic analysis is used to determine the required isothermal heating time at various temperatures t...
The nanomaterials are used widely and effectively in electrochemical energy storage because of their...