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Non-Equilibrium Crystallization of Monotectic Zn-25%Bi Alloy under 600 g

This study investigated the influence of supergravity on the segregation of components in the Zn–Bi monotectic system and consequently, the creation of an interface of the separation zone of both phases. The observation showed that near the separation boundary, in a very narrow area of the order of...

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Published in:	Materials 2021-08, Vol.14 (15), p.4341
Main Authors:	Boczkal, Grzegorz, Palka, Pawel, Kokosz, Piotr, Boczkal, Sonia, Mrowka-Nowotnik, Grazyna
Format:	Article
Language:	English
Subjects:	Alloys Bimetals Bismuth base alloys Chemical precipitation Crystallization Electric cells Equilibrium Experiments Grain size Microstructure Phase transitions Precipitates Sedimentation & deposition Separation Supergravity Zinc
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creator	Boczkal, Grzegorz Palka, Pawel Kokosz, Piotr Boczkal, Sonia Mrowka-Nowotnik, Grazyna
description	This study investigated the influence of supergravity on the segregation of components in the Zn–Bi monotectic system and consequently, the creation of an interface of the separation zone of both phases. The observation showed that near the separation boundary, in a very narrow area of the order of several hundred microns, all types of structures characteristic for the concentration range from 0 to 100% bismuth occurred. An additional effect of crystallization in high gravity is a high degree of structural order and an almost perfectly flat separation boundary. This is the case for both the zinc-rich zone and the bismuth-rich zone. Texture analysis revealed the existence of two privileged orientations in the zinc zone. Gravitational segregation also resulted in a strong rearrangement of the heavier bismuth to the outer end of the sample, leaving only very fine precipitates in the zinc region. For comparison, the results obtained for the crystallization under normal gravity are given. The effect of high orderliness of the structure was then absent. Despite segregation, a significant part of bismuth remained in the form of precipitates in the zinc matrix, and the separation border was shaped like a lens. The described method can be used for the production of massive bimaterials with a directed orientation of both components and a flat interface between them, such as thermo-generator elements or bimetallic electric cell parts, where the parameters (thickness) of the junction can be precisely defined at the manufacturing stage.
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The observation showed that near the separation boundary, in a very narrow area of the order of several hundred microns, all types of structures characteristic for the concentration range from 0 to 100% bismuth occurred. An additional effect of crystallization in high gravity is a high degree of structural order and an almost perfectly flat separation boundary. This is the case for both the zinc-rich zone and the bismuth-rich zone. Texture analysis revealed the existence of two privileged orientations in the zinc zone. Gravitational segregation also resulted in a strong rearrangement of the heavier bismuth to the outer end of the sample, leaving only very fine precipitates in the zinc region. For comparison, the results obtained for the crystallization under normal gravity are given. The effect of high orderliness of the structure was then absent. Despite segregation, a significant part of bismuth remained in the form of precipitates in the zinc matrix, and the separation border was shaped like a lens. The described method can be used for the production of massive bimaterials with a directed orientation of both components and a flat interface between them, such as thermo-generator elements or bimetallic electric cell parts, where the parameters (thickness) of the junction can be precisely defined at the manufacturing stage.</description><identifier>ISSN: 1996-1944</identifier><identifier>EISSN: 1996-1944</identifier><identifier>DOI: 10.3390/ma14154341</identifier><identifier>PMID: 34361535</identifier><language>eng</language><publisher>Basel: MDPI AG</publisher><subject>Alloys ; Bimetals ; Bismuth base alloys ; Chemical precipitation ; Crystallization ; Electric cells ; Equilibrium ; Experiments ; Grain size ; Microstructure ; Phase transitions ; Precipitates ; Sedimentation & deposition ; Separation ; Supergravity ; Zinc</subject><ispartof>Materials, 2021-08, Vol.14 (15), p.4341</ispartof><rights>2021 by the authors. Licensee MDPI, Basel, Switzerland. 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subjects	Alloys Bimetals Bismuth base alloys Chemical precipitation Crystallization Electric cells Equilibrium Experiments Grain size Microstructure Phase transitions Precipitates Sedimentation & deposition Separation Supergravity Zinc
title	Non-Equilibrium Crystallization of Monotectic Zn-25%Bi Alloy under 600 g
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