Downloads provided by UsageCountsAn In Situ Synchrotron Dilatometry and Atomistic Study of Martensite and Carbide Formation during Partitioning and Tempering
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Ernst Plesiutschnig; Mihaela Albu; David Canelo-Yubero; Vsevolod Razumovskiy; Andreas Stark; Norbert Schell; Gerald Kothleitner; +3 Authors
Ernst Plesiutschnig; Mihaela Albu; David Canelo-Yubero; Vsevolod Razumovskiy; Andreas Stark; Norbert Schell; Gerald Kothleitner; Coline Beal; Christof Sommitsch; Ferdinand Hofer;
An In Situ Synchrotron Dilatometry and Atomistic Study of Martensite and Carbide Formation during Partitioning and Tempering
Precipitation hardened and tempered martensitic-ferritic steels (TMFSs) are used in many areas of our daily lives as tools, components in power generation industries, or in the oil and gas (O&G) industry for creep and corrosion resistance. In addition to the metallurgical and forging processes, the unique properties of the materials in service are determined by the quality heat treatment (HT). By performing a quenching and partitioning HT during an in situ high energy synchrotron radiation experiment in a dilatometer, the evolution of retained austenite, martensite laths, dislocations, and carbides was characterized in detail. Atomic-scale studies on a specimen with the same HT subjected to a laser scanning confocal microscope show how dislocations facilitate cloud formation around carbides. These clouds have a discrete build-up, and thermodynamic calculations and density functional theory explain their stability.
Germany, Czech Republic
- Deutsches Elektronen-Synchrotron DESY Germany
- Academy of Sciences Republic of Uzbekistan Uzbekistan
- Technische Universitat Graz Austria
- Academy of Sciences Library Czech Republic
- Graz University of Technology Austria
quenching and partitioning heat treatment, carbide formation, Article, stainless steel; quenching and partitioning heat treatment; martensite; reconstructive ferrite; carbide formation; partitioning and tempering; high-resolution transmission electron microscopy; atomistic study; density functional theory; in-situ synchrotron study, General Materials Science, high-resolution transmission electron microscopy, reconstructive ferrite, stainless steel, partitioning and tempering, density functional theory, in-situ synchrotron study, 600, martensite, atomistic study, info:eu-repo/classification/ddc/600, MAG: Materials science, MAG: Carbide, MAG: Precipitation hardening, MAG: Tempering, MAG: Austenite, MAG: Quenching, MAG: Metallurgy, MAG: Creep, MAG: Martensite, MAG: Dilatometer
quenching and partitioning heat treatment, carbide formation, Article, stainless steel; quenching and partitioning heat treatment; martensite; reconstructive ferrite; carbide formation; partitioning and tempering; high-resolution transmission electron microscopy; atomistic study; density functional theory; in-situ synchrotron study, General Materials Science, high-resolution transmission electron microscopy, reconstructive ferrite, stainless steel, partitioning and tempering, density functional theory, in-situ synchrotron study, 600, martensite, atomistic study, info:eu-repo/classification/ddc/600, MAG: Materials science, MAG: Carbide, MAG: Precipitation hardening, MAG: Tempering, MAG: Austenite, MAG: Quenching, MAG: Metallurgy, MAG: Creep, MAG: Martensite, MAG: Dilatometer
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This is an alternative to the "Influence" indicator, which also reflects the overall/total impact of an article in the research community at large, based on the underlying citation network (diachronically).
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This indicator reflects the "current" impact/attention (the "hype") of an article in the research community at large, based on the underlying citation network.
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This indicator reflects the overall/total impact of an article in the research community at large, based on the underlying citation network (diachronically).
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This indicator reflects the initial momentum of an article directly after its publication, based on the underlying citation network.
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