Changes

On November 28, 2024 at 1:16:06 PM UTC, admin:
Changed value of field extra_authors to [{'extra_author': 'Jouda, Mazin', 'familyName': 'Jouda', 'givenName': 'Mazin', 'orcid': ''}, {'extra_author': 'Deng, Yongbo', 'familyName': 'Deng', 'givenName': 'Yongbo', 'orcid': ''}, {'extra_author': 'Nassar, Omar', 'familyName': 'Nassar', 'givenName': 'Omar', 'orcid': ''}, {'extra_author': 'Mager, Dario', 'familyName': 'Mager', 'givenName': 'Dario', 'orcid': '0000-0001-9487-3723'}, {'extra_author': 'Korvink, Jan G.', 'familyName': 'Korvink', 'givenName': 'Jan G.', 'orcid': ''}] in Topologically optimized magnetic lens for magnetic resonance applications (dataset)
              
    
          
          
        
        
            f 1 { f 1 {
            2   "author": "Wadhwa, Sagar", 2   "author": "Wadhwa, Sagar",
            3   "author_email": "", 3   "author_email": "",
            n n 4   "citation": [],
            4   "creator_user_id": "17755db4-395a-4b3b-ac09-e8e3484ca700", 5   "creator_user_id": "17755db4-395a-4b3b-ac09-e8e3484ca700",
            5   "doi": "10.35097/1294", 6   "doi": "10.35097/1294",
            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": "Jouda, Mazin", 12       "extra_author": "Jouda, Mazin",
            n n 13       "familyName": "Jouda",
            14       "givenName": "Mazin",
            12       "orcid": "" 15       "orcid": ""
            13     }, 16     },
            14     { 17     {
            15       "extra_author": "Deng, Yongbo", 18       "extra_author": "Deng, Yongbo",
            n n 19       "familyName": "Deng",
            20       "givenName": "Yongbo",
            16       "orcid": "" 21       "orcid": ""
            17     }, 22     },
            18     { 23     {
            19       "extra_author": "Nassar, Omar", 24       "extra_author": "Nassar, Omar",
            n n 25       "familyName": "Nassar",
            26       "givenName": "Omar",
            20       "orcid": "" 27       "orcid": ""
            21     }, 28     },
            22     { 29     {
            23       "extra_author": "Mager, Dario", 30       "extra_author": "Mager, Dario",
            n n 31       "familyName": "Mager",
            32       "givenName": "Dario",
            24       "orcid": "0000-0001-9487-3723" 33       "orcid": "0000-0001-9487-3723"
            25     }, 34     },
            26     { 35     {
            27       "extra_author": "Korvink, Jan G.", 36       "extra_author": "Korvink, Jan G.",
            n n 37       "familyName": "Korvink",
            38       "givenName": "Jan G.",
            28       "orcid": "" 39       "orcid": ""
            29     } 40     }
            30   ], 41   ],
            n n 42   "familyName": "Wadhwa",
            43   "givenName": "Sagar",
            31   "groups": [], 44   "groups": [],
            32   "id": "c3f13f58-0286-4e1e-b43c-d4050542dfc1", 45   "id": "c3f13f58-0286-4e1e-b43c-d4050542dfc1",
            33   "isopen": false, 46   "isopen": false,
            34   "license_id": "CC BY-NC 4.0 Attribution-NonCommercial", 47   "license_id": "CC BY-NC 4.0 Attribution-NonCommercial",
            35   "license_title": "CC BY-NC 4.0 Attribution-NonCommercial", 48   "license_title": "CC BY-NC 4.0 Attribution-NonCommercial",
            36   "metadata_created": "2023-08-04T08:50:28.612626", 49   "metadata_created": "2023-08-04T08:50:28.612626",
            t 37   "metadata_modified": "2023-08-04T09:29:02.731335", t 50   "metadata_modified": "2024-11-28T13:16:06.826089",
            38   "name": "rdr-doi-10-35097-1294", 51   "name": "rdr-doi-10-35097-1294",
            39   "notes": "Abstract: Improvements to the signal-to-noise ratio of  52   "notes": "Abstract: Improvements to the signal-to-noise ratio of 
            40 magnetic resonance detection lead to a strong reduction in measurement  53 magnetic resonance detection lead to a strong reduction in measurement 
            41 time, yet as a sole optimization goal for resonator design, it would  54 time, yet as a sole optimization goal for resonator design, it would 
            42 be an oversimplification of the problem at hand. Multiple constraints,  55 be an oversimplification of the problem at hand. Multiple constraints, 
            43 for example for field homogeneity and sample shape, suggest the use of  56 for example for field homogeneity and sample shape, suggest the use of 
            44 numerical optimization to obtain resonator designs that deliver the  57 numerical optimization to obtain resonator designs that deliver the 
            45 intended improvement. Here we consider the 2D Lenz lens to be a  58 intended improvement. Here we consider the 2D Lenz lens to be a 
            46 sufficiently broadband flux transforming interposer between the sample  59 sufficiently broadband flux transforming interposer between the sample 
            47 and a radiofrequency (RF) circuit and to be a flexible and easily  60 and a radiofrequency (RF) circuit and to be a flexible and easily 
            48 manufacturable device family with which to mediate different design  61 manufacturable device family with which to mediate different design 
            49 requirements.We report on a method to apply topology optimization to  62 requirements.We report on a method to apply topology optimization to 
            50 determine the optimal layout of a Lenz lens and demonstrate  63 determine the optimal layout of a Lenz lens and demonstrate 
            51 realizations for both low- (45 MHz) and high-frequency (500 MHz)  64 realizations for both low- (45 MHz) and high-frequency (500 MHz) 
            52 nuclear magnetic resonance.\r\nTechnicalRemarks: Folder Contains the  65 nuclear magnetic resonance.\r\nTechnicalRemarks: Folder Contains the 
            53 Images, and the text file used for the corresponding images", 66 Images, and the text file used for the corresponding images",
            54   "num_resources": 0, 67   "num_resources": 0,
            55   "num_tags": 0, 68   "num_tags": 0,
            56   "orcid": "", 69   "orcid": "",
            57   "organization": { 70   "organization": {
            58     "approval_status": "approved", 71     "approval_status": "approved",
            59     "created": "2023-01-12T13:30:23.238233", 72     "created": "2023-01-12T13:30:23.238233",
            60     "description": "RADAR (Research Data Repository) is a  73     "description": "RADAR (Research Data Repository) is a 
            61 cross-disciplinary repository for archiving and publishing research  74 cross-disciplinary repository for archiving and publishing research 
            62 data from completed scientific studies and projects. The focus is on  75 data from completed scientific studies and projects. The focus is on 
            63 research data from subjects that do not yet have their own  76 research data from subjects that do not yet have their own 
            64 discipline-specific infrastructures for research data management. ", 77 discipline-specific infrastructures for research data management. ",
            65     "id": "013c89a9-383c-4200-8baa-0f78bf1d91f9", 78     "id": "013c89a9-383c-4200-8baa-0f78bf1d91f9",
            66     "image_url": "radar-logo.svg", 79     "image_url": "radar-logo.svg",
            67     "is_organization": true, 80     "is_organization": true,
            68     "name": "radar", 81     "name": "radar",
            69     "state": "active", 82     "state": "active",
            70     "title": "RADAR", 83     "title": "RADAR",
            71     "type": "organization" 84     "type": "organization"
            72   }, 85   },
            73   "owner_org": "013c89a9-383c-4200-8baa-0f78bf1d91f9", 86   "owner_org": "013c89a9-383c-4200-8baa-0f78bf1d91f9",
            74   "private": false, 87   "private": false,
            75   "production_year": "2020", 88   "production_year": "2020",
            76   "publication_year": "2023", 89   "publication_year": "2023",
            77   "publishers": [ 90   "publishers": [
            78     { 91     {
            79       "publisher": "Karlsruhe Institute of Technology" 92       "publisher": "Karlsruhe Institute of Technology"
            80     } 93     }
            81   ], 94   ],
            82   "relationships_as_object": [], 95   "relationships_as_object": [],
            83   "relationships_as_subject": [], 96   "relationships_as_subject": [],
            84   "repository_name": "RADAR (Research Data Repository)", 97   "repository_name": "RADAR (Research Data Repository)",
            85   "resources": [], 98   "resources": [],
            86   "services_used_list": "", 99   "services_used_list": "",
            87   "source_metadata_created": "2023", 100   "source_metadata_created": "2023",
            88   "source_metadata_modified": "", 101   "source_metadata_modified": "",
            89   "state": "active", 102   "state": "active",
            90   "subject_areas": [ 103   "subject_areas": [
            91     { 104     {
            92       "subject_area_additional": "", 105       "subject_area_additional": "",
            93       "subject_area_name": "Engineering" 106       "subject_area_name": "Engineering"
            94     } 107     }
            95   ], 108   ],
            96   "tags": [], 109   "tags": [],
            97   "title": "Topologically optimized magnetic lens for magnetic  110   "title": "Topologically optimized magnetic lens for magnetic 
            98 resonance applications (dataset)", 111 resonance applications (dataset)",
            99   "type": "vdataset", 112   "type": "vdataset",
            100   "url": "https://doi.org/10.35097/1294" 113   "url": "https://doi.org/10.35097/1294"
            101 } 114 }