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215 results on '"Neumeier, Steffen"'

1. Creep properties and deformation mechanisms of single-crystalline $\gamma^\prime$-strengthened superalloys in dependence of the Co/Ni ratio

Author

Volz, Nicklas, Zenk, Christopher H., Karpstein, Nicolas, Lenz, Malte, Spiecker, Erdmann, Göken, Mathias, and Neumeier, Steffen

Subjects
Condensed Matter - Materials Science
Abstract

Co-base superalloys are considered as promising high temperature materials besides the well-established Ni-base superalloys. However, Ni appears to be an indispensable alloying element also in Co-base superalloys. To address the influence of the base elements on the deformation behavior, high-temperature compressive creep experiments were performed on a single crystal alloy series that was designed to exhibit a varying Co/Ni ratio and a constant Al, W and Cr content. Creep tests were performed at 900 {\deg}C and 250 MPa and the resulting microstructures and defect configurations were characterized via electron microscopy. The minimum creep rates differ by more than one order of magnitude with changing Co/Ni ratio. An intermediate CoNi-base alloy exhibits the overall highest creep strength. Several strengthening contributions like solid solution strengthening of the $\gamma$ phase, effective diffusion coefficients or stacking fault energies were quantified. Precipitate shearing mechanisms differ significantly when the base element content is varied. While the Ni-rich superalloys exhibit SISF and SESF shearing, the Co-rich alloys develop extended APBs when the $\gamma^\prime$ phase is cut. This is mainly attributed to a difference in planar fault energies, caused by a changing segregation behavior. As result, it is assumed that the shearing resistivity and the occurring deformation mechanisms in the $\gamma^\prime$ phase are crucial for the creep properties of the investigated alloy series.

Published
2021
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2. Understanding creep of a single-crystalline Co-Al-W-Ta superalloy by studying the deformation mechanism, segregation tendency and stacking fault energy

Author

Volz, Nicklas, Xue, Fei, Zenk, Christopher H., Bezold, Andreas, Gabel, Stefan, Subramanyam, Aparna P. A., Drautz, Ralf, Hammerschmidt, Thomas, Makineni, Surendra K., Gault, Baptiste, Göken, Mathias, and Neumeier, Steffen

Subjects
Condensed Matter - Materials Science
Abstract

A systematic study of the compression creep properties of a single-crystalline Co-base superalloy (Co-9Al-7.5W-2Ta) was conducted at 950 {\deg}C, 975 {\deg}C and 1000 {\deg}C to reveal the influence of temperature and the resulting diffusion velocity of solutes like Al, W and Ta on the deformation mechanisms. Two creep rate minima are observed at all temperatures indicating that the deformation mechanisms causing these minima are quite similar. Atom-probe tomography analysis reveals elemental segregation to stacking faults, which had formed in the $\gamma\prime$ phase during creep. Density-functional-theory calculations indicate segregation of W and Ta to the stacking fault and an associated considerable reduction of the stacking fault energy. Since solutes diffuse faster at a higher temperature, segregation can take place more quickly. This results in a significantly faster softening of the alloy, since cutting of the $\gamma\prime$ precipitate phase by partial dislocations is facilitated through segregation already during the early stages of creep. This is confirmed by transmission electron microscopy analysis. Therefore, not only the smaller precipitate fraction at higher temperatures is responsible for the worse creep properties, but also faster diffusion-assisted shearing of the $\gamma\prime$ phase by partial dislocations. The understanding of these mechanisms will help in future alloy development by offering new design criteria.

Published
2021
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3. Revealing atomic-scale vacancy-solute interaction in nickel

Author

Morgado, Felipe F., Katnagallu, Shyam, Freysoldt, Christoph, Klaes, Benjamin, Vurpillot, François, Neugebauer, Jörg, Raabe, Dierk, Neumeier, Steffen, Gault, Baptiste, and Stephenson, Leigh T.

Subjects
Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

Imaging individual vacancies in solids and revealing their interactions with solute atoms remains one of the frontiers in microscopy and microanalysis. Here we study a creep-deformed binary Ni-2 at.% Ta alloy. Atom probe tomography reveals a random distribution of Ta. Field ion microscopy, with contrast interpretation supported by density-functional theory and time-of-flight mass spectrometry, evidences a positive correlation of tantalum with vacancies. Our results support solute-vacancy binding, which explains improvement in creep resistance of Ta-containing Ni-based superalloys and helps guide future material design strategies., Comment: Submitted to Physics Review Letter

Published
2021
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7. On the influence of Al-concentration on the fracture toughness of NiAl: microcantilever fracture tests and atomistic simulations

Author

Webler, Ralf, Baranova, Polina N., Karewar, Shivraj, Neumeier, Steffen, Möller, Johannes J., Springer, Hauke, Göken, Mathias, and Bitzek, Erik

Subjects
Condensed Matter - Materials Science
Abstract

The mechanical properties of the stoichiometric B2 $\beta$-phase of NiAl are well established, however the effect of off-stoichiometric composition on the fracture toughness has not yet been systematically studied over the entire composition range of 40-50% Al. Here we use microbending tests on notched cantilever beams FIB-milled from NiAl single crystals with an aluminized as well as an oxidation-induced composition gradient to determine the influence of the Al concentration on the mechanical properties. The fracture toughness is maximal for the stoichiometric composition. It decreases with increasing Ni-content in the Ni-rich composition range, where plastic deformation is observed to accompany the fracture process. In contrast, no plasticity is observed in Al-rich NiAl, which shows a nearly concentration-independent, low fracture toughness. The theoretical fracture toughness according to Griffith, however, shows only a very weak composition dependence in both, the Ni- and Al-rich composition range. The differences in fracture toughness could furthermore not be explained solely based on the different hardening contributions of Ni-antisites in the Ni-rich and structural vacancies in the Al-rich crystals. Atomistic fracture simulations show that crack propagation in NiAl takes place by the nucleation and migration of kinks on the crack front. The low fracture toughness of Al-rich NiAl can thus be understood by the dual effect of structural vacancies as strong obstacles to dislocation motion and as source of crack front kinks.

Published
2019

8. Low temperature deformation of MoSi$_2$ and the effect of Ta, Nb and Al as alloying elements

Author

Zenk, Carolin, Gibson, James S. K. -L., Maier-Kiener, Verena, Neumeier, Steffen, Göken, Mathias, and Korte-Kerzel, Sandra

Subjects
Condensed Matter - Materials Science
Abstract

Molybdenum disilicide (MoSi$_2$) is a very promising material for high temperature structural applications due to its high melting point (2030 {\deg}C), low density, high thermal conductivity and good oxidation resistance. However, MoSi$_2$ has limited ductility below 900 {\deg}C due to its anisotropic plastic deformation behaviour and high critical resolved shear stresses on particular slip systems. Nanoindentation of MoSi$_2$ microalloyed with aluminium, niobium or tantalum showed that all alloying elements cause a decrease in hardness. Analysis of surface slip lines indicated the activation of the additional {1 1 0}<1 1 1> slip system in microalloyed MoSi$_2$, which is not active below 300 {\deg}C in pure MoSi$_2$. This was confirmed by TEM dislocation analysis of the indentation plastic zone. Further micropillar compression experiments comparing pure MoSi$_2$ and the Ta-alloyed sample enabled the determination of the critical resolved shear stresses of individual slip systems even in the most brittle [0 0 1] crystal direction.

Published
2019

9. Imaging individual solute atoms at crystalline imperfections in metals

Author

Katnagallu, Shyam, Stephenson, Leigh T., Mouton, Isabelle, Freysoldt, Christoph, Subramanyam, Aparna P. A., Jenke, Jan, Ladines, Alvin N., Neumeier, Steffen, Hammerschmidt, Thomas, Drautz, Ralf, Neugebauer, Jörg, Vurpillot, François, Raabe, Dierk, and Gault, Baptiste

Subjects
Condensed Matter - Materials Science, Physics - Instrumentation and Detectors
Abstract

Directly imaging all atoms constituting a material and, maybe more importantly, crystalline defects that dictate materials' properties, remains a formidable challenge. Here, we propose a new approach to chemistry-sensitive field-ion microscopy (FIM) combining contrast interpretation from density-functional theory (DFT) and elemental identification enabled by time-of-flight mass-spectrometry and data mining. Analytical-FIM has true atomic resolution and we demonstrate how the technique can reveal the presence of individual solute atoms at specific positions in the microstructure. The performance of this new technique is showcased in revealing individual Re atoms at crystalline defects formed in Ni during creep deformation. The atomistic details offered by A-FIM allowed us to directly compare our results with simulations, and to tackle a long-standing question of how Re extends lifetime of Ni-based superalloys in service at high-temperature.

Published
2019

10. Uncovering microscopic details of shearing mechanisms in the L12 structure by unambiguous stacking fault analysis

Author

Karpstein Nicolas, Lenz Malte, Bezold Andreas, Zehl Rico, Wu Mingjian, Ludwig Alfred, Laplanche Guillaume, Neumeier Steffen, and Spiecker Erdmann

Subjects
scanning-transmission-electron-microscopy, superalloys, stacking-faults, deformation-mechanisms, phase-transformations, Microbiology, QR1-502, Physiology, QP1-981, Zoology, QL1-991
Published
2024
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20. Local Mechanical Properties at the Dendrite Scale of Ni-Based Superalloys Studied by Advanced High Temperature Indentation Creep and Micropillar Compression Tests

Author

Haußmann, Lukas, Neumeier, Steffen, Kolb, Markus, Ast, Johannes, Mohanty, Gaurav, Michler, Johann, Göken, Mathias, Tin, Sammy, editor, Hardy, Mark, editor, Clews, Justin, editor, Cormier, Jonathan, editor, Feng, Qiang, editor, Marcin, John, editor, O'Brien, Chris, editor, and Suzuki, Akane, editor

Published
2020
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23. Experimental Validation of Property Models and Databases for Computational Superalloy Design.

Author

Gaag, Tobias, Weidinger, Julius, Bandorf, Jakob, Lux, Valeska, Wahlmann, Benjamin, Neumeier, Steffen, Zenk, Christopher, and Körner, Carolin

Subjects
LATTICE constants, DIFFERENTIAL scanning calorimetry, HEAT resistant alloys, MOLAR mass, ALLOYS
Abstract

Computational superalloy development is a powerful alternative to the conventional experimental approach. Based on thermodynamic databases and the CALPHAD method, it is possible to estimate the properties of a large number of potential alloys and select the most promising ones. However, the accuracy of the databases and complementary property models can be unsatisfying. The accuracy of two mass density and γ/γ′$\gamma / \left(\gamma\right)^{&amp;amp;amp;amp;amp;amp;amp;amp;amp;amp;aposx;}$ lattice parameter models and the TTNI8 and TCNI10 databases is analyzed in detail on the experimental basis of computationally optimized single‐crystalline superalloys. Various properties are measured and compared to the results of the property models and databases. Neither of the databases is superior to the other and especially the γ′$\left(\gamma\right)^{&amp;amp;amp;amp;amp;amp;amp;amp;amp;amp;aposx;}$ solvus temperature is not accurately described in both. The new mass density model, a linear regression based on the molar mass, is more reliable for low‐density alloys. Both lattice parameter model versions slightly overestimate the room‐temperature γ$$ \gamma $$ lattice parameter. The γ′$\left(\gamma\right)^{&amp;amp;amp;amp;amp;amp;amp;amp;amp;amp;aposx;}$ lattice parameter, however, is more accurately calculated using the new model version. The results of this study can be readily used to improve a multicriteria alloy optimization tool for computational superalloy design. [ABSTRACT FROM AUTHOR]

Published
2024
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