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On November 28, 2024 at 1:15:51 PM UTC, admin:

Updated description of Raw data to "the influence of lattice misfit on screw and edge dislocation-controlled solid solution strengthening in mo-ti alloys" from
Abstract: BCC Mo-Ti solid solutions were synthesised by arc-melting in the range of 0-80at% Ti. Mechanical properties were scale-bridging characterised using nanoindentation, Vickers hardness testing and compression testing to isolate solid solution strengthening. Additional structural (XRD) and compositional analyses (HCGE) were also performed to assess lattice parameter and synthesis-related uptake of O and N. In order to assess strength contributions by screw and edge dislocation motion, the model-compatible descriptions of edge dislocation-controlled solid solution strengthening (Maresca and Curtin, Acta Materialia 182 (2020) 235-249) and screw dislocation controlled strengthening (Ghafarollahi and Curtin, Acta Materialia 226 (2022), 117617) were implemented and the strength of the solid solutions was modelled. TechnicalRemarks: Three ASCII-files are included: Mechanical properties (nanohardness, Vickers hardness, offset yield strength and Young's modulus) are found in mech_properties.txt. Lattice parameter data, O and N contents and Ti contents determined by EDX are found in other_properties.txt. All mechanical properties are given with their standard deviation. Strength modelled by the implementations of solid solution strengthening are found in Curtin_models.txt for both dislocation types.
to
Abstract: knmfi proposalID 2020-024029394 APT FIB Abstract: BCC Mo-Ti solid solutions were synthesised by arc-melting in the range of 0-80at% Ti. Mechanical properties were scale-bridging characterised using nanoindentation, Vickers hardness testing and compression testing to isolate solid solution strengthening. Additional structural (XRD) and compositional analyses (HCGE) were also performed to assess lattice parameter and synthesis-related uptake of O and N. In order to assess strength contributions by screw and edge dislocation motion, the model-compatible descriptions of edge dislocation-controlled solid solution strengthening (Maresca and Curtin, Acta Materialia 182 (2020) 235-249) and screw dislocation controlled strengthening (Ghafarollahi and Curtin, Acta Materialia 226 (2022), 117617) were implemented and the strength of the solid solutions was modelled. TechnicalRemarks: Three ASCII-files are included: Mechanical properties (nanohardness, Vickers hardness, offset yield strength and Young's modulus) are found in mech_properties.txt. Lattice parameter data, O and N contents and Ti contents determined by EDX are found in other_properties.txt. All mechanical properties are given with their standard deviation. Strength modelled by the implementations of solid solution strengthening are found in Curtin_models.txt for both dislocation types.

Changed value of field extra_authors to [{'extra_author': 'Kauffmann, Alexander', 'familyName': 'Kauffmann', 'givenName': 'Alexander', 'orcid': ''}] in Raw data to "the influence of lattice misfit on screw and edge dislocation-controlled solid solution strengthening in mo-ti alloys"

              
    
          
          
        
        
            f 1 { f 1 {
            2   "author": "Winkens, Georg", 2   "author": "Winkens, Georg",
            3   "author_email": "", 3   "author_email": "",
            n n 4   "citation": [],
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            5   "doi": "10.35097/1464", 6   "doi": "10.35097/1464",
            6   "doi_date_published": "2023", 7   "doi_date_published": "2023",
            7   "doi_publisher": "", 8   "doi_publisher": "",
            8   "doi_status": "True", 9   "doi_status": "True",
            9   "extra_authors": [ 10   "extra_authors": [
            10     { 11     {
            11       "extra_author": "Kauffmann, Alexander", 12       "extra_author": "Kauffmann, Alexander",
            n n 13       "familyName": "Kauffmann",
            14       "givenName": "Alexander",
            12       "orcid": "" 15       "orcid": ""
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            19   "givenName": "Georg",
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            19   "license_title": "CC BY-SA 4.0 Attribution-ShareAlike", 24   "license_title": "CC BY-SA 4.0 Attribution-ShareAlike",
            20   "metadata_created": "2023-08-04T08:50:51.073269", 25   "metadata_created": "2023-08-04T08:50:51.073269",
            n 21   "metadata_modified": "2023-08-04T09:31:24.994875", n 26   "metadata_modified": "2024-11-28T13:15:51.496018",
            22   "name": "rdr-doi-10-35097-1464", 27   "name": "rdr-doi-10-35097-1464",
            t t 28   "notes": "Abstract: knmfi proposalID 2020-024029394 APT 
            23   "notes": "Abstract: BCC Mo-Ti solid solutions were synthesised by  29 FIB\r\nAbstract: BCC Mo-Ti solid solutions were synthesised by 
            24 arc-melting in the range of 0-80at% Ti. Mechanical properties were  30 arc-melting in the range of 0-80at% Ti. Mechanical properties were 
            25 scale-bridging characterised using nanoindentation, Vickers hardness  31 scale-bridging characterised using nanoindentation, Vickers hardness 
            26 testing and compression testing to isolate solid solution  32 testing and compression testing to isolate solid solution 
            27 strengthening. Additional structural (XRD) and compositional analyses  33 strengthening. Additional structural (XRD) and compositional analyses 
            28 (HCGE) were also performed to assess lattice parameter and  34 (HCGE) were also performed to assess lattice parameter and 
            29 synthesis-related uptake of O and N. In order to assess strength  35 synthesis-related uptake of O and N. In order to assess strength 
            30 contributions by screw and edge dislocation motion, the  36 contributions by screw and edge dislocation motion, the 
            31 model-compatible descriptions of edge dislocation-controlled solid  37 model-compatible descriptions of edge dislocation-controlled solid 
            32 solution strengthening (Maresca and Curtin, Acta Materialia 182 (2020)  38 solution strengthening (Maresca and Curtin, Acta Materialia 182 (2020) 
            33 235-249) and screw dislocation controlled strengthening (Ghafarollahi  39 235-249) and screw dislocation controlled strengthening (Ghafarollahi 
            34 and Curtin, Acta Materialia 226 (2022), 117617) were implemented and  40 and Curtin, Acta Materialia 226 (2022), 117617) were implemented and 
            35 the strength of the solid solutions was modelled.\r\nTechnicalRemarks:  41 the strength of the solid solutions was modelled.\r\nTechnicalRemarks: 
            36 Three ASCII-files are included:\r\nMechanical properties  42 Three ASCII-files are included:\r\nMechanical properties 
            37 (nanohardness, Vickers hardness, offset yield strength and Young's  43 (nanohardness, Vickers hardness, offset yield strength and Young's 
            38 modulus) are found in mech_properties.txt. Lattice parameter data, O  44 modulus) are found in mech_properties.txt. Lattice parameter data, O 
            39 and N contents and Ti contents determined by EDX are found in  45 and N contents and Ti contents determined by EDX are found in 
            40 other_properties.txt. All mechanical properties are given with their  46 other_properties.txt. All mechanical properties are given with their 
            41 standard deviation. Strength modelled by the implementations of solid  47 standard deviation. Strength modelled by the implementations of solid 
            42 solution strengthening are found in Curtin_models.txt for both  48 solution strengthening are found in Curtin_models.txt for both 
            43 dislocation types.", 49 dislocation types.",
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            69       "publisher": "Karlsruhe Institute of Technology" 75       "publisher": "Karlsruhe Institute of Technology"
            70     } 76     }
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            83       "subject_area_name": "Materials Science" 89       "subject_area_name": "Materials Science"
            84     } 90     }
            85   ], 91   ],
            86   "tags": [], 92   "tags": [],
            87   "title": "Raw data to \"the influence of lattice misfit on screw and  93   "title": "Raw data to \"the influence of lattice misfit on screw and 
            88 edge dislocation-controlled solid solution strengthening in mo-ti  94 edge dislocation-controlled solid solution strengthening in mo-ti 
            89 alloys\"", 95 alloys\"",
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            91   "url": "https://doi.org/10.35097/1464" 97   "url": "https://doi.org/10.35097/1464"
            92 } 98 }