Correlation between microstructures and tensile deformation behavior of a PM near α Ti–6Al–2Sn–4Zr–2Mo−0.1Si alloy

A powder metallurgy (PM) near α Ti–6Al–2Sn–4Zr–2Mo−0.1Si (wt.%) alloy was fabricated by in-situ dehydrogenation and hot extrusion of a TiH2-based powder compact and heat treatments. Three types of microstructures were obtained in the as-consolidated state and after different heat treatments. They ar...

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Veröffentlicht in:	Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2021-09, Vol.825, p.141909, Article 141909
Hauptverfasser:	Wu, Xiaogang, Zhang, Bowen, Zhang, Youyun, Niu, Hongzhi, Zhang, Deliang
Format:	Artikel
Sprache:	eng
Schlagworte:	Compacting Cutting Deformation behavior Dehydrogenation Ductility Elongation Fracture surfaces Grain boundaries Hardening rate Heat treatment Hot extrusion Lamellar structure Mechanical properties Microstructure Microstructures Near α titanium alloy Powder metallurgy Strain hardening Strain localization Tensile deformation Tensile tests Thermomechanical powder consolidation Thin films Titanium alloys Titanium base alloys Turning (machining) Ultimate tensile strength Ultrafines
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container_title	Materials science & engineering. A, Structural materials : properties, microstructure and processing
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creator	Wu, Xiaogang Zhang, Bowen Zhang, Youyun Niu, Hongzhi Zhang, Deliang
description	A powder metallurgy (PM) near α Ti–6Al–2Sn–4Zr–2Mo−0.1Si (wt.%) alloy was fabricated by in-situ dehydrogenation and hot extrusion of a TiH2-based powder compact and heat treatments. Three types of microstructures were obtained in the as-consolidated state and after different heat treatments. They are a basketweave microstructure consisting of a network of inter-penetrating α plates filled with domains of ultrafine β transformed structure (βt) (Type I microstructure), an α/β lamellar microstructure with most β layers being thin and discontinuous plus α layers at prior β grain boundaries (Type II microstructure) and an α/βt lamellar microstructure (Type III microstructure). Although the three types of microstructures render the alloy with a similar yield strength (1085–1109 MPa) and ultimate tensile strength (1217–1239 MPa) due to the balanced effects of various strengthening mechanisms, the Type II microstructure exhibits a significantly lower tensile ductility than the other two types of microstructures (elongation to fracture: 5.5% vs. 13–14%). Examination of dislocations in the tensile deformed specimens reveals that dislocations cutting through the thin β layers in the Type II microstructure during deformation. Such interactions between moving dislocations and thin β layers in the Type II microstructure are expected to be the primary reason for the clearly lower strain hardening rate, premature fracture of grain boundary α layers and low tolerance to strain localization observed in the tensile tests, fracture surface examination and DIC analysis. This correlation between the microstructures and tensile deformation behavior strongly suggests that preventing moving dislocations cutting through thin β layers by turning them into thicker and ultrafine structure strengthened βt lamellae or blocks is critically important in ensuring high tensile ductility of high strength PM near α titanium alloys. •Three types of microstructures are obtained in a PM near α titanium alloy.•All three types of microstructures render the alloy with a similar high strength.•Type II microstructure gives a much lower tensile ductility than other two types of microstructures.•The lower ductility is attributed to dislocation cutting of thin β layers in Type II microstructure.•Preventing the dislocation cutting through is key for both high ductility and high strength.
doi_str_mv	10.1016/j.msea.2021.141909
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Three types of microstructures were obtained in the as-consolidated state and after different heat treatments. They are a basketweave microstructure consisting of a network of inter-penetrating α plates filled with domains of ultrafine β transformed structure (βt) (Type I microstructure), an α/β lamellar microstructure with most β layers being thin and discontinuous plus α layers at prior β grain boundaries (Type II microstructure) and an α/βt lamellar microstructure (Type III microstructure). Although the three types of microstructures render the alloy with a similar yield strength (1085–1109 MPa) and ultimate tensile strength (1217–1239 MPa) due to the balanced effects of various strengthening mechanisms, the Type II microstructure exhibits a significantly lower tensile ductility than the other two types of microstructures (elongation to fracture: 5.5% vs. 13–14%). Examination of dislocations in the tensile deformed specimens reveals that dislocations cutting through the thin β layers in the Type II microstructure during deformation. Such interactions between moving dislocations and thin β layers in the Type II microstructure are expected to be the primary reason for the clearly lower strain hardening rate, premature fracture of grain boundary α layers and low tolerance to strain localization observed in the tensile tests, fracture surface examination and DIC analysis. This correlation between the microstructures and tensile deformation behavior strongly suggests that preventing moving dislocations cutting through thin β layers by turning them into thicker and ultrafine structure strengthened βt lamellae or blocks is critically important in ensuring high tensile ductility of high strength PM near α titanium alloys. •Three types of microstructures are obtained in a PM near α titanium alloy.•All three types of microstructures render the alloy with a similar high strength.•Type II microstructure gives a much lower tensile ductility than other two types of microstructures.•The lower ductility is attributed to dislocation cutting of thin β layers in Type II microstructure.•Preventing the dislocation cutting through is key for both high ductility and high strength.</description><identifier>ISSN: 0921-5093</identifier><identifier>EISSN: 1873-4936</identifier><identifier>DOI: 10.1016/j.msea.2021.141909</identifier><language>eng</language><publisher>Lausanne: Elsevier B.V</publisher><subject>Compacting ; Cutting ; Deformation behavior ; Dehydrogenation ; Ductility ; Elongation ; Fracture surfaces ; Grain boundaries ; Hardening rate ; Heat treatment ; Hot extrusion ; Lamellar structure ; Mechanical properties ; Microstructure ; Microstructures ; Near α titanium alloy ; Powder metallurgy ; Strain hardening ; Strain localization ; Tensile deformation ; Tensile tests ; Thermomechanical powder consolidation ; Thin films ; Titanium alloys ; Titanium base alloys ; Turning (machining) ; Ultimate tensile strength ; Ultrafines</subject><ispartof>Materials science & engineering. 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A, Structural materials : properties, microstructure and processing</title><description>A powder metallurgy (PM) near α Ti–6Al–2Sn–4Zr–2Mo−0.1Si (wt.%) alloy was fabricated by in-situ dehydrogenation and hot extrusion of a TiH2-based powder compact and heat treatments. Three types of microstructures were obtained in the as-consolidated state and after different heat treatments. They are a basketweave microstructure consisting of a network of inter-penetrating α plates filled with domains of ultrafine β transformed structure (βt) (Type I microstructure), an α/β lamellar microstructure with most β layers being thin and discontinuous plus α layers at prior β grain boundaries (Type II microstructure) and an α/βt lamellar microstructure (Type III microstructure). Although the three types of microstructures render the alloy with a similar yield strength (1085–1109 MPa) and ultimate tensile strength (1217–1239 MPa) due to the balanced effects of various strengthening mechanisms, the Type II microstructure exhibits a significantly lower tensile ductility than the other two types of microstructures (elongation to fracture: 5.5% vs. 13–14%). Examination of dislocations in the tensile deformed specimens reveals that dislocations cutting through the thin β layers in the Type II microstructure during deformation. Such interactions between moving dislocations and thin β layers in the Type II microstructure are expected to be the primary reason for the clearly lower strain hardening rate, premature fracture of grain boundary α layers and low tolerance to strain localization observed in the tensile tests, fracture surface examination and DIC analysis. This correlation between the microstructures and tensile deformation behavior strongly suggests that preventing moving dislocations cutting through thin β layers by turning them into thicker and ultrafine structure strengthened βt lamellae or blocks is critically important in ensuring high tensile ductility of high strength PM near α titanium alloys. •Three types of microstructures are obtained in a PM near α titanium alloy.•All three types of microstructures render the alloy with a similar high strength.•Type II microstructure gives a much lower tensile ductility than other two types of microstructures.•The lower ductility is attributed to dislocation cutting of thin β layers in Type II microstructure.•Preventing the dislocation cutting through is key for both high ductility and high strength.</description><subject>Compacting</subject><subject>Cutting</subject><subject>Deformation behavior</subject><subject>Dehydrogenation</subject><subject>Ductility</subject><subject>Elongation</subject><subject>Fracture surfaces</subject><subject>Grain boundaries</subject><subject>Hardening rate</subject><subject>Heat treatment</subject><subject>Hot extrusion</subject><subject>Lamellar structure</subject><subject>Mechanical properties</subject><subject>Microstructure</subject><subject>Microstructures</subject><subject>Near α titanium alloy</subject><subject>Powder metallurgy</subject><subject>Strain hardening</subject><subject>Strain localization</subject><subject>Tensile deformation</subject><subject>Tensile tests</subject><subject>Thermomechanical powder consolidation</subject><subject>Thin films</subject><subject>Titanium alloys</subject><subject>Titanium base alloys</subject><subject>Turning (machining)</subject><subject>Ultimate tensile strength</subject><subject>Ultrafines</subject><issn>0921-5093</issn><issn>1873-4936</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2021</creationdate><recordtype>article</recordtype><recordid>eNp9kE1OwzAQhS0EEqVwAVaWWKfYTpwfiU1V8Se1Aqllw8ZynLFwlMTFTou6QGLJGk7CRThET0KiwpbNzCzem3nzIXRKyYgSGp-Xo9qDHDHC6IhGNCPZHhrQNAmDKAvjfTQgGaMBJ1l4iI68LwkhNCJ8gF4n1jmoZGtsg3NoXwAaXBvlrG_dSrUrBx7LpsAtNN5UgAvQ1tV_-ie5NtZhq7HE9zPcgHT4-wsvzPbtMx5XXWXzpqvRo-vnmd2-f3SR5wbLqrKbY3SgZeXh5LcP0cPV5WJyE0zvrm8n42mgQpa2QUplmsu4UEwnRGc5S_KQFgBa8qTQNCYqAa4UTyKaAotpyDUnEGVMUxaxVIdDdLbbu3T2eQW-FaVduaY7KRjPWNhJedSp2E7Vf-8daLF0ppZuIygRPWZRih6z6DGLHebOdLEzQZd_bcAJrww0CgrjQLWisOY_-w92P4uI</recordid><startdate>20210921</startdate><enddate>20210921</enddate><creator>Wu, Xiaogang</creator><creator>Zhang, Bowen</creator><creator>Zhang, Youyun</creator><creator>Niu, Hongzhi</creator><creator>Zhang, Deliang</creator><general>Elsevier B.V</general><general>Elsevier BV</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7SR</scope><scope>8BQ</scope><scope>8FD</scope><scope>JG9</scope><orcidid>https://orcid.org/0000-0003-0055-0152</orcidid><orcidid>https://orcid.org/0000-0002-2367-5778</orcidid></search><sort><creationdate>20210921</creationdate><title>Correlation between microstructures and tensile deformation behavior of a PM near α Ti–6Al–2Sn–4Zr–2Mo−0.1Si alloy</title><author>Wu, Xiaogang ; Zhang, Bowen ; Zhang, Youyun ; Niu, Hongzhi ; Zhang, Deliang</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c328t-81a8ba6dc2f70f9b27b31deefa57df160c7e5cc57418e26135f50e492f12428f3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2021</creationdate><topic>Compacting</topic><topic>Cutting</topic><topic>Deformation behavior</topic><topic>Dehydrogenation</topic><topic>Ductility</topic><topic>Elongation</topic><topic>Fracture surfaces</topic><topic>Grain boundaries</topic><topic>Hardening rate</topic><topic>Heat treatment</topic><topic>Hot extrusion</topic><topic>Lamellar structure</topic><topic>Mechanical properties</topic><topic>Microstructure</topic><topic>Microstructures</topic><topic>Near α titanium alloy</topic><topic>Powder metallurgy</topic><topic>Strain hardening</topic><topic>Strain localization</topic><topic>Tensile deformation</topic><topic>Tensile tests</topic><topic>Thermomechanical powder consolidation</topic><topic>Thin films</topic><topic>Titanium alloys</topic><topic>Titanium base alloys</topic><topic>Turning (machining)</topic><topic>Ultimate tensile strength</topic><topic>Ultrafines</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Wu, Xiaogang</creatorcontrib><creatorcontrib>Zhang, Bowen</creatorcontrib><creatorcontrib>Zhang, Youyun</creatorcontrib><creatorcontrib>Niu, Hongzhi</creatorcontrib><creatorcontrib>Zhang, Deliang</creatorcontrib><collection>CrossRef</collection><collection>Engineered Materials Abstracts</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Materials Research Database</collection><jtitle>Materials science & engineering. A, Structural materials : properties, microstructure and processing</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Wu, Xiaogang</au><au>Zhang, Bowen</au><au>Zhang, Youyun</au><au>Niu, Hongzhi</au><au>Zhang, Deliang</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Correlation between microstructures and tensile deformation behavior of a PM near α Ti–6Al–2Sn–4Zr–2Mo−0.1Si alloy</atitle><jtitle>Materials science & engineering. A, Structural materials : properties, microstructure and processing</jtitle><date>2021-09-21</date><risdate>2021</risdate><volume>825</volume><spage>141909</spage><pages>141909-</pages><artnum>141909</artnum><issn>0921-5093</issn><eissn>1873-4936</eissn><abstract>A powder metallurgy (PM) near α Ti–6Al–2Sn–4Zr–2Mo−0.1Si (wt.%) alloy was fabricated by in-situ dehydrogenation and hot extrusion of a TiH2-based powder compact and heat treatments. Three types of microstructures were obtained in the as-consolidated state and after different heat treatments. They are a basketweave microstructure consisting of a network of inter-penetrating α plates filled with domains of ultrafine β transformed structure (βt) (Type I microstructure), an α/β lamellar microstructure with most β layers being thin and discontinuous plus α layers at prior β grain boundaries (Type II microstructure) and an α/βt lamellar microstructure (Type III microstructure). Although the three types of microstructures render the alloy with a similar yield strength (1085–1109 MPa) and ultimate tensile strength (1217–1239 MPa) due to the balanced effects of various strengthening mechanisms, the Type II microstructure exhibits a significantly lower tensile ductility than the other two types of microstructures (elongation to fracture: 5.5% vs. 13–14%). Examination of dislocations in the tensile deformed specimens reveals that dislocations cutting through the thin β layers in the Type II microstructure during deformation. Such interactions between moving dislocations and thin β layers in the Type II microstructure are expected to be the primary reason for the clearly lower strain hardening rate, premature fracture of grain boundary α layers and low tolerance to strain localization observed in the tensile tests, fracture surface examination and DIC analysis. This correlation between the microstructures and tensile deformation behavior strongly suggests that preventing moving dislocations cutting through thin β layers by turning them into thicker and ultrafine structure strengthened βt lamellae or blocks is critically important in ensuring high tensile ductility of high strength PM near α titanium alloys. •Three types of microstructures are obtained in a PM near α titanium alloy.•All three types of microstructures render the alloy with a similar high strength.•Type II microstructure gives a much lower tensile ductility than other two types of microstructures.•The lower ductility is attributed to dislocation cutting of thin β layers in Type II microstructure.•Preventing the dislocation cutting through is key for both high ductility and high strength.</abstract><cop>Lausanne</cop><pub>Elsevier B.V</pub><doi>10.1016/j.msea.2021.141909</doi><orcidid>https://orcid.org/0000-0003-0055-0152</orcidid><orcidid>https://orcid.org/0000-0002-2367-5778</orcidid></addata></record>
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source	ScienceDirect Journals (5 years ago - present)
subjects	Compacting Cutting Deformation behavior Dehydrogenation Ductility Elongation Fracture surfaces Grain boundaries Hardening rate Heat treatment Hot extrusion Lamellar structure Mechanical properties Microstructure Microstructures Near α titanium alloy Powder metallurgy Strain hardening Strain localization Tensile deformation Tensile tests Thermomechanical powder consolidation Thin films Titanium alloys Titanium base alloys Turning (machining) Ultimate tensile strength Ultrafines
title	Correlation between microstructures and tensile deformation behavior of a PM near α Ti–6Al–2Sn–4Zr–2Mo−0.1Si alloy
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