Surface analysis of iron and steel nanopowder

Manchili, Swathi Kiranmayee; Shvab, Ruslan; Zehri, Abdelhafid; Ye, Lilei; Hryha, Eduard; Liu, Johan; Nyborg, Lars

doi:10.1002/sia.6465

Cited by 8 publications

(12 citation statements)

References 14 publications

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“…A surface analysis of both the nanopowder and the reduction of surface oxide has been discussed elsewhere. [9] The powder blends and the lubricant were compacted at compaction pressures of 400, 600 and 800 MPa. Figure 2 shows the compressibility curves for the compacts of all the powder blends.…”

Section: A Materials and Compactionmentioning

confidence: 99%

“…As shown in the fractographs (Figure 8), nanopowder was sintered in the temperature range between 500°C and 700°C. As the sintering was conducted in a pure hydrogen atmosphere, which reduces iron oxide in the range of temperatures between 300°C and 500°C, [9] the oxide scale covering the nanoparticles was reduced. The oxide layer plays a crucial part in sintering, as sintering is a surface phenomenon.…”

Section: Influence Of Nanopowder Additionmentioning

confidence: 99%

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Effect of Nanopowder Addition on the Sintering of Water-Atomized Iron Powder

Manchili

Wendel

Zehri

et al. 2020

Metall Mater Trans A

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A promising method of improving the densification of powder metallurgical steel components is to blend nanopowder with the otherwise typically used micrometre-sized powder. The higher surface-to-volume ratio of nanopowder is hypothesized to accelerate the sintering process and increase the inter-particle contact area between the powder particles. This is supposed to enhance the material transport and improve the densification. In the present investigation, water-atomized iron powder (− 45 μm) was mixed separately with pure iron and low-carbon steel nanopowder, each at a ratio of 95 to 5 pct. These powder mixes were compacted at different pressures (400, 600 and 800 MPa) and then sintered at 1350 °C in a pure hydrogen atmosphere. The sintering behavior of the powder blend compacts was compared to that of the compact with micrometre-sized powder only. Densification commenced at much lower temperatures in the presence of nanopowder. To understand this, sintering at intermittent temperatures such as 500 °C and 700 °C was conducted. The fracture surface revealed that the nanopowder was sintered at between 500 °C and 700 °C, which in turn contributed to the densification of the powder mix at the lower temperature range. Based on the sintering experiments, an attempt was made to calculate the activation energy and identify the associated sinter mechanism using two different approaches. It was shown that the first approach yielded values in agreement with the grain-boundary diffusion mechanism. As the nanopowder content increased, there was an increase in linear shrinkage during sintering.

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Section: A Materials and Compactionmentioning

confidence: 99%

Section: Influence Of Nanopowder Additionmentioning

confidence: 99%

Effect of Nanopowder Addition on the Sintering of Water-Atomized Iron Powder

Manchili

Wendel

Zehri

et al. 2020

Metall Mater Trans A

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“…In our previous study, it was seen that when such a metallic shoulder is observed, the scale thickness is generally 3 to 4 nm. 4 Zinc is considered to be an impurity and could be from the manufacturing process.…”

Section: Resultsmentioning

confidence: 99%

“…The present study aims to characterize the surface products of the carbon-coated iron nanopowder using X-ray photoelectron spectroscopy (XPS), Auger electron spectroscopy (AES), and high-resolution scanning electron microscopy (HR-SEM) and to correlate with the findings from thermogravimetric analysis. The oxide thickness determination for nanopowder has been studied before, 4 whereas this study emphasize on the changes that the nanopowder undergoes during the heating phase of the sintering from the perspective of surface chemistry.…”

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confidence: 99%

Investigation of surface and thermogravimetric characteristics of carbon‐coated iron nanopowder

Manchili

Wendel

Cao

et al. 2020

Surface & Interface Analysis

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Funding information Swedish Foundation för Strategic Research Demand for high-density press and sinter components is increasing day by day. Of the different ways to improve the sinter density, the addition of nanopowder to the conventional micrometer-sized metal powder is an effective solution. The present investigation is aimed at studying the surface chemistry of iron nanopowder coated with graphitic carbon, which is intended to be mixed with the conventional iron powder. For this purpose, iron nanopowder in the size range of 30 nm to submicron (less than 1 micron) was investigated using thermogravimetry at different temperatures: 400 C, 600 C, 800 C, 1000 C, and 1350 C. The X-ray photoelectron spectroscopy (XPS), Auger electron spectroscopy (AES), and high-resolution scanning electron microscopy (HR-SEM) were used for characterizing the powder as well as samples sintered at different temperatures. The presence of iron, oxygen, carbon, chromium, and zinc were observed on the surface of the nanopowder. Iron was present in oxide state, although a small metallic iron peak at 707 eV was also observed in the XPS spectra obtained from the surface indicating the oxide scale to be maximum of about 5 nm in thickness. For the sample treated at 600 C, presence of manganese was observed on the surface. Thermogravimetry results showed a two-step mass loss with a total mass loss of 4 wt.% when heated to 1350 C where the first step corresponds to the surface oxide reduction.

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“…Iron nanopowder is hence used in the present research as an additive to improve the density of water-atomized iron powder compacts. The iron nanopowder was found to be covered with an oxide scale of 3 nm thick [7]. For the sintering process to be efficient, this surface oxide on the metal particle must at least in part be reduced.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Iron Oxide Reduction Kinetics in the Nanometric Scale Using Hydrogen

et al. 2020

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Iron nanopowder could be used as a sintering aid to water-atomised steel powder to improve the sintered density of metallurgical (PM) compacts. For the sintering process to be efficient, the inevitable surface oxide on the nanopowder must be reduced at least in part to facilitate its sintering aid effect. While appreciable research has been conducted in the domain of oxide reduction of the normal ferrous powder, the same cannot be said about the nanometric counterpart. The reaction kinetics for the reduction of surface oxide of iron nanopowder in hydrogen was therefore investigated using nonisothermal thermogravimetric (TG) measurements. The activation energy values were determined from the TG data using both isoconversional Kissinger–Akahira–Sunose (KAS) method and the Kissinger approach. The values obtained were well within the range of reported data. The reaction kinetics of Fe2O3 as a reference material was also depicted and the reduction of this oxide proceeds in two sequential stages. The first stage corresponds to the reduction of Fe2O3 to Fe3O4, while the second stage corresponds to a complete reduction of oxide to metallic Fe. The activation energy variation over the reduction process was observed and a model was proposed to understand the reduction of surface iron oxide of iron nanopowder.

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Surface analysis of iron and steel nanopowder

Cited by 8 publications

References 14 publications

Effect of Nanopowder Addition on the Sintering of Water-Atomized Iron Powder

Effect of Nanopowder Addition on the Sintering of Water-Atomized Iron Powder

Investigation of surface and thermogravimetric characteristics of carbon‐coated iron nanopowder

Analysis of Iron Oxide Reduction Kinetics in the Nanometric Scale Using Hydrogen

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