Plasticity and phase transition of crystals under continuous deformations by phase field crystal approach
Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and th...
Ausführliche Beschreibung
Gespeichert in:
| Autor*in: |
Wang, Kun [verfasserIn] |
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| Format: |
E-Artikel |
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| Sprache: |
Englisch |
| Erschienen: |
2019transfer abstract |
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| Schlagwörter: |
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| Umfang: |
19 |
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| Übergeordnetes Werk: |
Enthalten in: Safe hospital preparedness in the era of COVID-19: The Swiss cheese model - Noh, Ji Yun ELSEVIER, 2020, New York, NY |
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| Übergeordnetes Werk: |
volume:122 ; year:2019 ; pages:225-243 ; extent:19 |
| Links: |
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| DOI / URN: |
10.1016/j.ijplas.2019.07.004 |
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ELV048325848 |
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| 520 | |a Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. | ||
| 520 | |a Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. | ||
| 650 | 7 | |a Phase field crystal |2 Elsevier | |
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| 650 | 7 | |a Phase diagram |2 Elsevier | |
| 650 | 7 | |a Crystals |2 Elsevier | |
| 650 | 7 | |a Microstructures |2 Elsevier | |
| 650 | 7 | |a Phase transition |2 Elsevier | |
| 700 | 1 | |a Zhang, Fengguo |4 oth | |
| 700 | 1 | |a He, Anmin |4 oth | |
| 700 | 1 | |a Wang, Pei |4 oth | |
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10.1016/j.ijplas.2019.07.004 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000000794.pica (DE-627)ELV048325848 (ELSEVIER)S0749-6419(19)30363-8 DE-627 ger DE-627 rakwb eng 610 VZ 44.75 bkl Wang, Kun verfasserin aut Plasticity and phase transition of crystals under continuous deformations by phase field crystal approach 2019transfer abstract 19 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Phase field crystal Elsevier Deformations Elsevier Phase diagram Elsevier Crystals Elsevier Microstructures Elsevier Phase transition Elsevier Zhang, Fengguo oth He, Anmin oth Wang, Pei oth Enthalten in Pergamon Press Noh, Ji Yun ELSEVIER Safe hospital preparedness in the era of COVID-19: The Swiss cheese model 2020 New York, NY (DE-627)ELV004621883 volume:122 year:2019 pages:225-243 extent:19 https://doi.org/10.1016/j.ijplas.2019.07.004 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U 44.75 Infektionskrankheiten parasitäre Krankheiten Medizin VZ AR 122 2019 225-243 19 |
| spelling |
10.1016/j.ijplas.2019.07.004 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000000794.pica (DE-627)ELV048325848 (ELSEVIER)S0749-6419(19)30363-8 DE-627 ger DE-627 rakwb eng 610 VZ 44.75 bkl Wang, Kun verfasserin aut Plasticity and phase transition of crystals under continuous deformations by phase field crystal approach 2019transfer abstract 19 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Phase field crystal Elsevier Deformations Elsevier Phase diagram Elsevier Crystals Elsevier Microstructures Elsevier Phase transition Elsevier Zhang, Fengguo oth He, Anmin oth Wang, Pei oth Enthalten in Pergamon Press Noh, Ji Yun ELSEVIER Safe hospital preparedness in the era of COVID-19: The Swiss cheese model 2020 New York, NY (DE-627)ELV004621883 volume:122 year:2019 pages:225-243 extent:19 https://doi.org/10.1016/j.ijplas.2019.07.004 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U 44.75 Infektionskrankheiten parasitäre Krankheiten Medizin VZ AR 122 2019 225-243 19 |
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10.1016/j.ijplas.2019.07.004 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000000794.pica (DE-627)ELV048325848 (ELSEVIER)S0749-6419(19)30363-8 DE-627 ger DE-627 rakwb eng 610 VZ 44.75 bkl Wang, Kun verfasserin aut Plasticity and phase transition of crystals under continuous deformations by phase field crystal approach 2019transfer abstract 19 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Phase field crystal Elsevier Deformations Elsevier Phase diagram Elsevier Crystals Elsevier Microstructures Elsevier Phase transition Elsevier Zhang, Fengguo oth He, Anmin oth Wang, Pei oth Enthalten in Pergamon Press Noh, Ji Yun ELSEVIER Safe hospital preparedness in the era of COVID-19: The Swiss cheese model 2020 New York, NY (DE-627)ELV004621883 volume:122 year:2019 pages:225-243 extent:19 https://doi.org/10.1016/j.ijplas.2019.07.004 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U 44.75 Infektionskrankheiten parasitäre Krankheiten Medizin VZ AR 122 2019 225-243 19 |
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10.1016/j.ijplas.2019.07.004 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000000794.pica (DE-627)ELV048325848 (ELSEVIER)S0749-6419(19)30363-8 DE-627 ger DE-627 rakwb eng 610 VZ 44.75 bkl Wang, Kun verfasserin aut Plasticity and phase transition of crystals under continuous deformations by phase field crystal approach 2019transfer abstract 19 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Phase field crystal Elsevier Deformations Elsevier Phase diagram Elsevier Crystals Elsevier Microstructures Elsevier Phase transition Elsevier Zhang, Fengguo oth He, Anmin oth Wang, Pei oth Enthalten in Pergamon Press Noh, Ji Yun ELSEVIER Safe hospital preparedness in the era of COVID-19: The Swiss cheese model 2020 New York, NY (DE-627)ELV004621883 volume:122 year:2019 pages:225-243 extent:19 https://doi.org/10.1016/j.ijplas.2019.07.004 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U 44.75 Infektionskrankheiten parasitäre Krankheiten Medizin VZ AR 122 2019 225-243 19 |
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10.1016/j.ijplas.2019.07.004 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000000794.pica (DE-627)ELV048325848 (ELSEVIER)S0749-6419(19)30363-8 DE-627 ger DE-627 rakwb eng 610 VZ 44.75 bkl Wang, Kun verfasserin aut Plasticity and phase transition of crystals under continuous deformations by phase field crystal approach 2019transfer abstract 19 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. Phase field crystal Elsevier Deformations Elsevier Phase diagram Elsevier Crystals Elsevier Microstructures Elsevier Phase transition Elsevier Zhang, Fengguo oth He, Anmin oth Wang, Pei oth Enthalten in Pergamon Press Noh, Ji Yun ELSEVIER Safe hospital preparedness in the era of COVID-19: The Swiss cheese model 2020 New York, NY (DE-627)ELV004621883 volume:122 year:2019 pages:225-243 extent:19 https://doi.org/10.1016/j.ijplas.2019.07.004 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U 44.75 Infektionskrankheiten parasitäre Krankheiten Medizin VZ AR 122 2019 225-243 19 |
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Enthalten in Safe hospital preparedness in the era of COVID-19: The Swiss cheese model New York, NY volume:122 year:2019 pages:225-243 extent:19 |
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In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method.</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. 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Plasticity and phase transition of crystals under continuous deformations by phase field crystal approach |
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Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. |
| abstractGer |
Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. |
| abstract_unstemmed |
Despites of some efforts in deformation simulations by the Phase field crystal (PFC) method, simulations of phase transitions and plasticity of crystals under continuous deformations are still lack and some related fundamental issues remain open as well, for example the definition of stresses and the non-zero stresses of unstrained system. In the present work, we propose a deformation simulation method which conforms to the well-established framework of the PFC model. In contrast to traditional deformation simulation methods, our method could naturally mimic melting/freezing, solid-solid phase transition and plasticity of materials under continuous deformations without any additional parameters. Within the frameworks of our method, the stress is well-defined and isothermal-isobaric simulation method is developed. The isothermal-isobaric simulation method enables us to overcome the drawback of previous PFC simulations, for example the nonzero stress of unstrained system. Numerical examples given in present work confirm our conclusions. Particularly, the physical natures of the plasticity are uncovered at the temporal and spatial scale accessible to the PFC method. |
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