Interaction of AlSi7Mg with Oxide Ceramics

Fankhänel, Beate; Stelter, Michael; Voigt, Claudia; Aneziris, Christos G.

doi:10.1002/adem.201700084

Cited by 18 publications

(15 citation statements)

References 24 publications

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“…Contact angles lower than 90° [ 7 ] indicated a good wetting behavior contradicting the statement of the good slagging resistance due to a poor wetting. Fankhänel et al [ 11 ] proved the occurrence of chemical reactions between several oxide ceramics and an AlSi7Mg alloy during the sessile drop measurements at 950 °C contrary to the measurements performed at 730 °C [ 3 ]. The substrate based on MgAl 2 O 4 showed an impoverishment of Mg after the sessile drop measurements at 950 °C, whereas the same substrate featured no chemical changes after the sessile drop measurements at 730 °C [ 3 ].…”

Section: Resultsmentioning

confidence: 99%

“…Contact angles lower than 90 • [7] indicated a good wetting behavior contradicting the statement of the good slagging resistance due to a poor wetting. Fankhänel et al [11] proved the occurrence of chemical reactions between several oxide ceramics and an AlSi7Mg alloy during the sessile drop measurements at 950 • C contrary to the measurements performed at 730 The contact angle of pure Al2O3 was above 140° at the beginning of the dwell time at 950 °C and decreased systematically during the dwelling time down to an almost stable contact angle of 100°. The initial decrease of the contact angle indicated that the decomposition of the oxide skin on the aluminum alloy finalized when reaching a stable contact angle.…”

Section: Sessile Drop Testsmentioning

confidence: 98%

“…Even nano-scaled oxide skins cause a systematically higher and nearly constant contact angle. To remove the oxide skin, temperatures higher than 950 °C, adequate vacuum and relatively long dwelling times are necessary [ 11 ]. Such conditions entail the application of temperature being approx.…”

Section: Introductionmentioning

confidence: 99%

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Aluminum Melt Filtration with Carbon Bonded Alumina Filters

et al. 2020

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The wetting behavior was measured for Al2O3-C in contact with AlSi7Mg with a conventional sessile drop test (vacuum, 950 °C and 180 min) and a sessile drop test with a capillary purification unit (vacuum, 730 °C and 30 min). The conventional test yielded contact angles of around 92°, whereas the sessile drop measurement with capillary purification showed a strongly non-wetting behavior with a determined apparent contact angle of the rolling drop of 157°. Filtration tests, which were repeated twice, showed that the Al2O3-C filter possessed a better filtration behavior than the Al2O3 reference filter. For both filtration trials, the PoDFA (porous disc filtration analysis) index of the Al2O3-C filter sample was equal to half of the PoDFA index of the Al2O3 reference filter sample, indicating a significantly improved filtration performance when using Al2O3-C filter. Notable is the observation of a newly formed layer between the aluminum and the Al2O3-C coating. The layer possessed a thickness between 10 µm up to 50 µm and consisted of Al, C, and O, however, with different ratios than the original Al2O3-C coating. Thermodynamic calculations based on parameters of the wetting and filtration trials underline the possible formation of an Al4O4C-layer.

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Section: Resultsmentioning

confidence: 99%

Section: Sessile Drop Testsmentioning

confidence: 98%

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Aluminum Melt Filtration with Carbon Bonded Alumina Filters

et al. 2020

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“…These values have been compiled in Table 1 mainly for comparison purposes, since a previous study revealed that the wetting behavior of Al–Si melts towards a series of filter substrate materials varied only slightly in the present range of roughness. [ 31 ] The Al 2 O 3 –C and SiC substrates were quite dense, while mullite and spinel provided higher roughness than the rest of the substrates. The roughness of Al 2 O 3 exhibited intermediate roughness values compared with the other filter materials.…”

Section: Methodsmentioning

confidence: 99%

“…Expanding the application of filters beyond the industrially established removal of nonmetallic inclusions [ 31,32 ] to increase the Fe‐removal efficiency, may further contribute to the production of high‐quality, recycled Al–Si alloys. During the past years, new filtering techniques and new active filter materials have been developed to expand the range of application and to improve filter efficiency.…”

Section: Introductionmentioning

confidence: 99%

Interaction of Fe‐Containing, Secondary Al–Si Alloy with Oxide and Carbon‐Containing Ceramics for Fe Removal

et al. 2021

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Fe is a detrimental impurity element in secondary, i.e., recycled, Al–Si cast alloys for castability and mechanical properties. Fe removal can be achieved by binding Fe into Fe‐containing, primary particles and removing these from the, thus, Fe‐depleted Al–Si alloy melt. Expanding the application of filters beyond the removal of nonmetallic inclusions to increase the Fe‐removal efficiency can contribute to production of high‐quality, secondary Al–Si alloys. The usability of Al2O3, 3Al2O3 · 2SiO2, MgAl2O4, Al2O3–C, and SiC filter materials in contact with Al7.1Si, Al7.1Si1.5Fe, and Al7.1Si0.75Fe0.75Mn alloys is evaluated in sessile‐drop and crucible experiments regarding wettability, chemical interaction, nucleation, particle formation, and the subsequent effect on the alloy composition. The Al–Si melts in contact with Al2O3 act as nonreactive, low‐wetting reference systems. MgAl2O4 and SiO2 in 3Al2O3 · 2SiO2 are reduced, forming low‐wetting Al2O3, whereas Mg and Si enrich in the droplet. In contact with SiC and Al2O3–C, a thin layer of high‐wetting Al4C3 is formed. In case of Al2O3–C, primary Fe‐containing particles are specifically attached to the Al4C3 layer, which is associated with oriented growth of that layer. The remaining Fe content in the melt is 0.9 at% and beneficial kinetic effects for the Fe removal are suggested.

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Mn‐Based Mullites for Environmental and Energy Applications

Li,

Wang,

et al. 2024

Advanced Materials

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Mn‐based mullite oxides AMn2O5 (A = lanthanide, Y, Bi) is a novel type of ternary catalyst in terms of their electronic and geometric structures. The coexistence of pyramid Mn3+–O and octahedral Mn4+–O makes the d‐orbital selectively active toward various catalytic reactions. The alternative edge‐ and corner‐sharing stacking configuration constructs the confined active sites and abundant active oxygen species. As a result, they tend to show superior catalytic behaviors and thus gain great attention in environmental treatment and energy conversion and storage. In environmental applications, Mn‐based mullites have been demonstrated to be highly active toward low‐temperature oxidization of CO, NO, volatile organic compounds (VOCs), etc. Recent research further shows that mullites decompose O3 and ozonize VOCs from −20 °C to room temperature. Moreover, mullites enhance oxygen reduction reactions (ORR) and sulfur reduction reactions (SRR), critical kinetic steps in air‐battery and Li–S batteries, respectively. Their distinctive structures also facilitate applications in gas‐sensitive sensing, ionic conduction, high mobility dielectrics, oxygen storage, piezoelectricity, dehydration, H2O2 decomposition, and beyond. A comprehensive review from basic physicochemical properties to application certainly not only gains a full picture of mullite oxides but also provides new insights into designing heterogeneous catalysts.

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Interaction of AlSi7Mg with Oxide Ceramics

Cited by 18 publications

References 24 publications

Aluminum Melt Filtration with Carbon Bonded Alumina Filters

Aluminum Melt Filtration with Carbon Bonded Alumina Filters

Interaction of Fe‐Containing, Secondary Al–Si Alloy with Oxide and Carbon‐Containing Ceramics for Fe Removal

Mn‐Based Mullites for Environmental and Energy Applications

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