Microstructure Development of 308L Stainless Steel During Additive Manufacturing

In situ high-energy X-ray diffraction measurements were completed during deposition of 308L stainless steel wire onto a 304L stainless steel substrate. Attempts were made to extract microstructural features such as phase fraction and internal stress, as well as temperature evolution immediately foll...

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Veröffentlicht in:	Metallurgical and materials transactions. A, Physical metallurgy and materials science Physical metallurgy and materials science, 2019-05, Vol.50 (5), p.2538-2553
Hauptverfasser:	Brown, D. W., Losko, A., Carpenter, J. S., Cooley, J. C., Clausen, B., Dahal, J., Kenesei, P., Park, J.-S.
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Sprache:	eng
Schlagworte:	additive manufacture Additive manufacturing Austenitic stainless steels Characterization and Evaluation of Materials Chemistry and Materials Science Deposition ENGINEERING Evolution Feature extraction Iron constituents Lattice parameters MATERIALS SCIENCE Metallic Materials Microstructure Nanotechnology Phase transitions Rapid solidification Residual stress Solid phases Stainless steel Structural Materials Substrates Surfaces and Interfaces Temperature Thin Films X-ray diffraction
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container_title	Metallurgical and materials transactions. A, Physical metallurgy and materials science
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creator	Brown, D. W. Losko, A. Carpenter, J. S. Cooley, J. C. Clausen, B. Dahal, J. Kenesei, P. Park, J.-S.
description	In situ high-energy X-ray diffraction measurements were completed during deposition of 308L stainless steel wire onto a 304L stainless steel substrate. Attempts were made to extract microstructural features such as phase fraction and internal stress, as well as temperature evolution immediately following the deposition. The limited data that could be collected during deposition and rapid solidification are critically examined. High-energy X-rays coupled with relatively slow detectors were utilized to enable determination of orientation-dependent lattice parameters accurately enough to comment on phase strain evolution between austenite and ferrite. Information about the hydrostatic and deviatoric stress states of the constituent phases was determined on time scales that are relevant to their development. However, the time resolution of the technique was insufficient to monitor phase evolution during the solid–solid phase transformation and, more so, during solidification. Moreover, the accurate and absolute determination of inherently statistical parameters, such as phase fraction, depends critically on the ability to sample a statistically significant numbers of grains in the microstructure.
doi_str_mv	10.1007/s11661-019-05169-1
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W. ; Losko, A. ; Carpenter, J. S. ; Cooley, J. C. ; Clausen, B. ; Dahal, J. ; Kenesei, P. ; Park, J.-S.</creator><creatorcontrib>Brown, D. W. ; Losko, A. ; Carpenter, J. S. ; Cooley, J. C. ; Clausen, B. ; Dahal, J. ; Kenesei, P. ; Park, J.-S. ; Los Alamos National Lab. (LANL), Los Alamos, NM (United States) ; Argonne National Lab. (ANL), Argonne, IL (United States)</creatorcontrib><description>In situ high-energy X-ray diffraction measurements were completed during deposition of 308L stainless steel wire onto a 304L stainless steel substrate. Attempts were made to extract microstructural features such as phase fraction and internal stress, as well as temperature evolution immediately following the deposition. The limited data that could be collected during deposition and rapid solidification are critically examined. High-energy X-rays coupled with relatively slow detectors were utilized to enable determination of orientation-dependent lattice parameters accurately enough to comment on phase strain evolution between austenite and ferrite. Information about the hydrostatic and deviatoric stress states of the constituent phases was determined on time scales that are relevant to their development. However, the time resolution of the technique was insufficient to monitor phase evolution during the solid–solid phase transformation and, more so, during solidification. 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subjects	additive manufacture Additive manufacturing Austenitic stainless steels Characterization and Evaluation of Materials Chemistry and Materials Science Deposition ENGINEERING Evolution Feature extraction Iron constituents Lattice parameters MATERIALS SCIENCE Metallic Materials Microstructure Nanotechnology Phase transitions Rapid solidification Residual stress Solid phases Stainless steel Structural Materials Substrates Surfaces and Interfaces Temperature Thin Films X-ray diffraction
title	Microstructure Development of 308L Stainless Steel During Additive Manufacturing
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