Creep and High Temperature Deformation of Metals and Alloys
By the late 1940s, and since then, the continuous development of dislocation theories have provided the basis for correlating the macroscopic time-dependent deformation of metals and alloys—known as creep—to the time-dependent processes taking place within the metals and alloys. High-temperature def...
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| Главные авторы: | , |
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| Формат: | Online |
| Язык: | английский |
| Опубликовано: |
MDPI - Multidisciplinary Digital Publishing Institute
2021
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| Предметы: | |
| Online-ссылка: | 43220 |
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| _version_ | 1869525261161070592 |
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| author | Gariboldi, Elisabetta Spigarelli, Stefano |
| author_browse | Gariboldi, Elisabetta Spigarelli, Stefano |
| author_facet | Gariboldi, Elisabetta Spigarelli, Stefano |
| author_sort | Gariboldi, Elisabetta |
| collection | Directory of Open Access Books |
| description | By the late 1940s, and since then, the continuous development of dislocation theories have provided the basis for correlating the macroscopic time-dependent deformation of metals and alloys—known as creep—to the time-dependent processes taking place within the metals and alloys. High-temperature deformation and stress relaxation effects have also been explained and modeled on similar bases. The knowledge of high-temperature deformation as well as its modeling in conventional or unconventional situations is becoming clearer year by year, with new contemporary and better performing high-temperature materials being constantly produced and investigated.This book includes recent contributions covering relevant topics and materials in the field in an innovative way. In the first section, contributions are related to the general description of creep deformation, damage, and ductility, while in the second section, innovative testing techniques of creep deformation are presented. The third section deals with creep in the presence of complex loading/temperature changes and environmental effects, while the last section focuses on material microstructure–creep correlations for specific material classes. The quality and potential of specific materials and microstructures, testing conditions, and modeling as addressed by specific contributions will surely inspire scientists and technicians in their own innovative approaches and studies on creep and high-temperature deformation. |
| format | Online |
| id | doab-20.500.12854ir-44233 |
| institution | Directory of Open Access Books |
| language | eng |
| publishDate | 2021 |
| publishDateRange | 2021 |
| publishDateSort | 2021 |
| publisher | MDPI - Multidisciplinary Digital Publishing Institute |
| publisherStr | MDPI - Multidisciplinary Digital Publishing Institute |
| record_format | ojs |
| spelling | doab-20.500.12854ir-442332024-04-11T15:10:27Z Creep and High Temperature Deformation of Metals and Alloys Gariboldi, Elisabetta Spigarelli, Stefano TA1-2040 T1-995 TN1-997 Larson–Miller parameter n/a visualization bond coat hydrogen poly-crystal Gibbs free energy principle constitutive equations creep damage DFT finite element method austenitic stainless steel strain rate sensitivity MCrAlY excess volume superalloy scanning electron microscopy creep buckling dislocation dynamics creep elevated temperature modelling size effect residual stress superalloy VAT 32 water vapor activation energy small angle neutron scattering superalloy VAT 36 metallic glass iron aluminides Gr.91 internal stress relaxation fatigue multiaxiality creep grain boundary grain boundary cavitation cavitation solute atom stress exponent external pressure P92 TMA low cycle fatigue nanoindentation high temperature FEM intrinsic ductility normalizing creep ductility creep rupture mechanism microstructural features simulate HAZ P92 steel glide ferritic–martensitic steel creep rupture cyclic softening thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology By the late 1940s, and since then, the continuous development of dislocation theories have provided the basis for correlating the macroscopic time-dependent deformation of metals and alloys—known as creep—to the time-dependent processes taking place within the metals and alloys. High-temperature deformation and stress relaxation effects have also been explained and modeled on similar bases. The knowledge of high-temperature deformation as well as its modeling in conventional or unconventional situations is becoming clearer year by year, with new contemporary and better performing high-temperature materials being constantly produced and investigated.This book includes recent contributions covering relevant topics and materials in the field in an innovative way. In the first section, contributions are related to the general description of creep deformation, damage, and ductility, while in the second section, innovative testing techniques of creep deformation are presented. The third section deals with creep in the presence of complex loading/temperature changes and environmental effects, while the last section focuses on material microstructure–creep correlations for specific material classes. The quality and potential of specific materials and microstructures, testing conditions, and modeling as addressed by specific contributions will surely inspire scientists and technicians in their own innovative approaches and studies on creep and high-temperature deformation. 2021-02-11T10:44:04Z 2021-02-11T10:44:04Z 2020-01-07 09:08:26 2019 book 43220 9783039218790 9783039218783 https://directory.doabooks.org/handle/20.500.12854/44233 eng application/octet-stream Attribution-NonCommercial-NoDerivatives 4.0 International https://mdpi.com/books/pdfview/book/1887 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-03921-879-0 10.3390/books978-3-03921-879-0 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783039218790 9783039218783 212 open access |
| spellingShingle | TA1-2040 T1-995 TN1-997 Larson–Miller parameter n/a visualization bond coat hydrogen poly-crystal Gibbs free energy principle constitutive equations creep damage DFT finite element method austenitic stainless steel strain rate sensitivity MCrAlY excess volume superalloy scanning electron microscopy creep buckling dislocation dynamics creep elevated temperature modelling size effect residual stress superalloy VAT 32 water vapor activation energy small angle neutron scattering superalloy VAT 36 metallic glass iron aluminides Gr.91 internal stress relaxation fatigue multiaxiality creep grain boundary grain boundary cavitation cavitation solute atom stress exponent external pressure P92 TMA low cycle fatigue nanoindentation high temperature FEM intrinsic ductility normalizing creep ductility creep rupture mechanism microstructural features simulate HAZ P92 steel glide ferritic–martensitic steel creep rupture cyclic softening thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology Gariboldi, Elisabetta Spigarelli, Stefano Creep and High Temperature Deformation of Metals and Alloys |
| title | Creep and High Temperature Deformation of Metals and Alloys |
| title_full | Creep and High Temperature Deformation of Metals and Alloys |
| title_fullStr | Creep and High Temperature Deformation of Metals and Alloys |
| title_full_unstemmed | Creep and High Temperature Deformation of Metals and Alloys |
| title_short | Creep and High Temperature Deformation of Metals and Alloys |
| title_sort | creep and high temperature deformation of metals and alloys |
| topic | TA1-2040 T1-995 TN1-997 Larson–Miller parameter n/a visualization bond coat hydrogen poly-crystal Gibbs free energy principle constitutive equations creep damage DFT finite element method austenitic stainless steel strain rate sensitivity MCrAlY excess volume superalloy scanning electron microscopy creep buckling dislocation dynamics creep elevated temperature modelling size effect residual stress superalloy VAT 32 water vapor activation energy small angle neutron scattering superalloy VAT 36 metallic glass iron aluminides Gr.91 internal stress relaxation fatigue multiaxiality creep grain boundary grain boundary cavitation cavitation solute atom stress exponent external pressure P92 TMA low cycle fatigue nanoindentation high temperature FEM intrinsic ductility normalizing creep ductility creep rupture mechanism microstructural features simulate HAZ P92 steel glide ferritic–martensitic steel creep rupture cyclic softening thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology |
| topic_facet | TA1-2040 T1-995 TN1-997 Larson–Miller parameter n/a visualization bond coat hydrogen poly-crystal Gibbs free energy principle constitutive equations creep damage DFT finite element method austenitic stainless steel strain rate sensitivity MCrAlY excess volume superalloy scanning electron microscopy creep buckling dislocation dynamics creep elevated temperature modelling size effect residual stress superalloy VAT 32 water vapor activation energy small angle neutron scattering superalloy VAT 36 metallic glass iron aluminides Gr.91 internal stress relaxation fatigue multiaxiality creep grain boundary grain boundary cavitation cavitation solute atom stress exponent external pressure P92 TMA low cycle fatigue nanoindentation high temperature FEM intrinsic ductility normalizing creep ductility creep rupture mechanism microstructural features simulate HAZ P92 steel glide ferritic–martensitic steel creep rupture cyclic softening thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology |
| url | 43220 |
| work_keys_str_mv | AT gariboldielisabetta creepandhightemperaturedeformationofmetalsandalloys AT spigarellistefano creepandhightemperaturedeformationofmetalsandalloys |