Manganese Ore Decomposition and Carbon Reduction in Steelmaking

Wu, Wei; Wang, Peng; Lin, Lu; Dai, Shifan

doi:10.1515/htmp-2017-0042

High Temperature Materials and Processes

2018

DOI: 10.1515/htmp-2017-0042

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Manganese Ore Decomposition and Carbon Reduction in Steelmaking

Wei Wu

Peng Wang

Lu Lin

et al.

Abstract: To improve the direct alloying of manganese ore in steelmaking, the decomposition and carbon reduction of manganese ore was studied using a differential thermal analyzer and resistance furnace. The remaining material after manganese ore decomposition at 1,600 °C was a mixture of 43 % MnO, 40 % MnSiO3 and FeO, and 17 % MnSiO3. The remaining material after the carbon reduction of the manganese ore was a mixture of metal (30.8 % Mn7C3 and 16.1 % FeC3) and slag (2.5 % FeO, 5.1 % SiO2, and 18.8 % MnO). The high-tem… Show more

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Cited by 8 publications

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“…The second step of weight loss is seen up from 200 to 350 o C which can be ascribed to the reaction producing manganese (II) sulfate (MnSO 4 ) and removal of volatile matter e.g., sulphur. Above 600 o C the MnS starts to decompose into manganese oxide (MnO)[34]. The position of the curve's valley on the DTG curves describe the temperatures at which the greatest rate of weight loss occurred.…”

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Optimization of heating temperature on the growth of manganese sulfide nanosheets binder-free electrode for supercapattery

Rosli,

Omar,

Awang

et al. 2023

Ionics

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Supercapattery has emerged as one of the possibilities in the electrochemical energy storage system as a consequence of the expansion of technological advancement and the electrical vehicle sector. Manganese sulphide (MnS) nano akes were produced by hydrothermal technique at various heating temperatures (100,110,120, and 130 o C). The existence of MnS is revealed by the X-ray diffraction (XRD) diffractogram, and α-and γ-MnS crystals were effectively grown on a nickel (Ni) foam. MnS nano akes were seen under eld-emission scanning electron microscope (FESEM). The crystalline structure of MnS nano akes is susceptible to the variation depending on the heating temperature, and at 120 o C MnS produced nano ake with additional wrinkles. Through Brunauer-Emmett-Teller(BET) analysis, the thermal and physical adsorption investigations demonstrated the high total surface area and thermal stability of MnS electrodes. The ndings of BET studies demonstrate that MnS-120 has the highest surface BET (SBET) and the smallest pore size distribution (PSD),which later increases the total surface area of MnS nano akes for an effective energy storage mechanism. MnS is structurally stable below 200 o C, according to thermogravimetric analysis (TGA). MnS-120 electrode has a maximum speci c capacity of 1003.5 C/g at 5 A/g and a 49% rate capability. Supercapattery devices were created in a MnS-120//activated carbon (AC) con guration to assess the real-time performance of the material. The MnS-120//AC demonstrated better e ciency by offering speci c energy of 69.24 Wh/kg at 2953 W/kg. The life cycle test con rmed that MnS-120//AC is stable with a capacity retention of value of 96% after 4000 cycles.

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mentioning

confidence: 99%

Optimization of heating temperature on the growth of manganese sulfide nanosheets binder-free electrode for supercapattery

Rosli,

Omar,

Awang

et al. 2023

Ionics

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Enhanced electrochemical energy storage devices utilizing a one-dimensional (1D) α-MnO2 nanocomposite encased in onion-like carbon

Palaniyandy,

Lakshmi,

Thenmozhi

et al. 2024

J Mater Sci

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This work describes the fabrication of a novel one-dimensional (1D) α-MnO2 nanorods encased in onion-like carbon (or) carbon nano-onions (OLC) via microwave irradiation techniques employing electrolytic manganese dioxide (EMD), which is especially beneficial for rapid ion and electron transfer, and great structural stability. The composite of α-MnO2 and OLC demonstrates exceptional performance as an electrode across various electrochemical energy storage systems, including zinc-ion batteries (ZIB), sodium-ion batteries (SIB), and supercapacitors (SC) than the pristine α-MnO2. In SIB systems, the composite exhibits a specific capacity of 266 mAh g−1 at initial cycle with 50% capacity retention over 500 cycles, whereas the pristine electrode delivers only 39% capacity retention. The rapid yet controlled charge transfer kinetics facilitated by OLC addition in the α-MnO2 matrix outperforms as the ZIB cathode with an excellent specific capacity of 476 mAh g−1 with 100% capacity retention, while the pristine sample exhibits 77.5% capacity retention. As a SC electrode, the α-MnO2/OLC composite exhibits better electrochemical properties such as rectangular behavior, increased specific capacitance (792 F g−1), excellent capacity retention at high current densities, and others. The higher surface area that could be offered by the OLC to the α-MnO2 matrix facilitates the improved electrochemistry in the pristine sample and this kind of modification can be a viable solution to overcome the limitations of α-MnO2 for electrochemical energy storage applications. It is important to note that the performance outputs of α-MnO2/OLC composite are far better than the regular carbon (graphite, graphene) in α-MnO2 electrodes. Further, OLC provided with high surface area and ordered morphology can play the role of conductivity booster, structural stabilizer, and electrochemical active material in all the energy storage applications which may give a significant research attention in near future.

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New diatomaceous earth and kaolinite ceramic membranes for turbidity reduction in water

et al. 2023

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Manganese Ore Decomposition and Carbon Reduction in Steelmaking

Cited by 8 publications

References 15 publications

Optimization of heating temperature on the growth of manganese sulfide nanosheets binder-free electrode for supercapattery

Optimization of heating temperature on the growth of manganese sulfide nanosheets binder-free electrode for supercapattery

Enhanced electrochemical energy storage devices utilizing a one-dimensional (1D) α-MnO2 nanocomposite encased in onion-like carbon

New diatomaceous earth and kaolinite ceramic membranes for turbidity reduction in water

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