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f | 1 | { | f | 1 | { |
2 | "author": "Li, Xinyue", | 2 | "author": "Li, Xinyue", | ||
3 | "author_email": "", | 3 | "author_email": "", | ||
4 | "creator_user_id": "17755db4-395a-4b3b-ac09-e8e3484ca700", | 4 | "creator_user_id": "17755db4-395a-4b3b-ac09-e8e3484ca700", | ||
5 | "doi": "10.35097/1500", | 5 | "doi": "10.35097/1500", | ||
6 | "doi_date_published": "2023", | 6 | "doi_date_published": "2023", | ||
7 | "doi_publisher": "", | 7 | "doi_publisher": "", | ||
8 | "doi_status": "True", | 8 | "doi_status": "True", | ||
9 | "groups": [], | 9 | "groups": [], | ||
10 | "id": "d1cf0c6f-2b9f-40bf-bc2c-9a494d0bed1a", | 10 | "id": "d1cf0c6f-2b9f-40bf-bc2c-9a494d0bed1a", | ||
11 | "isopen": false, | 11 | "isopen": false, | ||
12 | "license_id": "CC BY 4.0 Attribution", | 12 | "license_id": "CC BY 4.0 Attribution", | ||
13 | "license_title": "CC BY 4.0 Attribution", | 13 | "license_title": "CC BY 4.0 Attribution", | ||
14 | "metadata_created": "2023-08-04T08:50:55.961381", | 14 | "metadata_created": "2023-08-04T08:50:55.961381", | ||
t | 15 | "metadata_modified": "2023-08-04T08:52:07.607786", | t | 15 | "metadata_modified": "2023-08-04T08:53:40.893772", |
16 | "name": "rdr-doi-10-35097-1500", | 16 | "name": "rdr-doi-10-35097-1500", | ||
17 | "notes": "Abstract: Nickel aluminum layered double hydroxide (NiAl | 17 | "notes": "Abstract: Nickel aluminum layered double hydroxide (NiAl | ||
18 | LDH) with nitrate in its interlayer is investigated as a negative | 18 | LDH) with nitrate in its interlayer is investigated as a negative | ||
19 | electrode material for lithium-ion batteries (LIBs). The effect of the | 19 | electrode material for lithium-ion batteries (LIBs). The effect of the | ||
20 | potential range (i.e., 0.01 \u2013 3.0 V and 0.4 \u2013 3.0 V vs. | 20 | potential range (i.e., 0.01 \u2013 3.0 V and 0.4 \u2013 3.0 V vs. | ||
21 | Li+/Li) and of the binder on the performance of the material is | 21 | Li+/Li) and of the binder on the performance of the material is | ||
22 | investigated in 1 M LiPF6 in EC/DMC vs. Li. The NiAl LDH electrode | 22 | investigated in 1 M LiPF6 in EC/DMC vs. Li. The NiAl LDH electrode | ||
23 | based on sodium alginate (SA) binder shows a high initial discharge | 23 | based on sodium alginate (SA) binder shows a high initial discharge | ||
24 | specific capacity of 2586 mAh g-1 at 0.05 A g-1 and good stability in | 24 | specific capacity of 2586 mAh g-1 at 0.05 A g-1 and good stability in | ||
25 | the potential range of 0.01-3.0 V vs. Li+/Li, which is better than | 25 | the potential range of 0.01-3.0 V vs. Li+/Li, which is better than | ||
26 | what obtained with a polyvinylidene difluoride (PVDF)-based electrode. | 26 | what obtained with a polyvinylidene difluoride (PVDF)-based electrode. | ||
27 | The NiAl LDH electrode with SA binder shows, after 400 cycles at 0.5 A | 27 | The NiAl LDH electrode with SA binder shows, after 400 cycles at 0.5 A | ||
28 | g-1, a cycling retention of 42.2 % with a capacity of 697 mAh g-1 and | 28 | g-1, a cycling retention of 42.2 % with a capacity of 697 mAh g-1 and | ||
29 | at a high current density of 1.0 A g-1 shows a retention of 27.6 % | 29 | at a high current density of 1.0 A g-1 shows a retention of 27.6 % | ||
30 | with a capacity of 388 mAh g-1 over 1400 cycles. In the same | 30 | with a capacity of 388 mAh g-1 over 1400 cycles. In the same | ||
31 | conditions, the PVDF-based electrode retains only 15.6 % with a | 31 | conditions, the PVDF-based electrode retains only 15.6 % with a | ||
32 | capacity of 182 mAh g-1 and 8.5 % with a capacity of 121 mAh g-1, | 32 | capacity of 182 mAh g-1 and 8.5 % with a capacity of 121 mAh g-1, | ||
33 | respectively. Ex situ X-ray photoelectron spectroscopy (XPS) and ex | 33 | respectively. Ex situ X-ray photoelectron spectroscopy (XPS) and ex | ||
34 | situ X-ray absorption spectroscopy (XAS) reveal a conversion reaction | 34 | situ X-ray absorption spectroscopy (XAS) reveal a conversion reaction | ||
35 | mechanism during Li+ insertion into the NiAl LDH material. X-ray | 35 | mechanism during Li+ insertion into the NiAl LDH material. X-ray | ||
36 | diffraction (XRD) and XPS have been combined with the electrochemical | 36 | diffraction (XRD) and XPS have been combined with the electrochemical | ||
37 | study to understand the effect of different cut-off potentials on the | 37 | study to understand the effect of different cut-off potentials on the | ||
38 | Li-ion storage mechanism.\r\nTechnicalRemarks: These data support the | 38 | Li-ion storage mechanism.\r\nTechnicalRemarks: These data support the | ||
39 | published paper.", | 39 | published paper.", | ||
40 | "num_resources": 0, | 40 | "num_resources": 0, | ||
41 | "num_tags": 5, | 41 | "num_tags": 5, | ||
42 | "orcid": "", | 42 | "orcid": "", | ||
43 | "organization": { | 43 | "organization": { | ||
44 | "approval_status": "approved", | 44 | "approval_status": "approved", | ||
45 | "created": "2023-01-12T13:30:23.238233", | 45 | "created": "2023-01-12T13:30:23.238233", | ||
46 | "description": "RADAR (Research Data Repository) is a | 46 | "description": "RADAR (Research Data Repository) is a | ||
47 | cross-disciplinary repository for archiving and publishing research | 47 | cross-disciplinary repository for archiving and publishing research | ||
48 | data from completed scientific studies and projects. The focus is on | 48 | data from completed scientific studies and projects. The focus is on | ||
49 | research data from subjects that do not yet have their own | 49 | research data from subjects that do not yet have their own | ||
50 | discipline-specific infrastructures for research data management. ", | 50 | discipline-specific infrastructures for research data management. ", | ||
51 | "id": "013c89a9-383c-4200-8baa-0f78bf1d91f9", | 51 | "id": "013c89a9-383c-4200-8baa-0f78bf1d91f9", | ||
52 | "image_url": "radar-logo.svg", | 52 | "image_url": "radar-logo.svg", | ||
53 | "is_organization": true, | 53 | "is_organization": true, | ||
54 | "name": "radar", | 54 | "name": "radar", | ||
55 | "state": "active", | 55 | "state": "active", | ||
56 | "title": "RADAR", | 56 | "title": "RADAR", | ||
57 | "type": "organization" | 57 | "type": "organization" | ||
58 | }, | 58 | }, | ||
59 | "owner_org": "013c89a9-383c-4200-8baa-0f78bf1d91f9", | 59 | "owner_org": "013c89a9-383c-4200-8baa-0f78bf1d91f9", | ||
60 | "private": false, | 60 | "private": false, | ||
61 | "production_year": "2021", | 61 | "production_year": "2021", | ||
62 | "publication_year": "2023", | 62 | "publication_year": "2023", | ||
63 | "publishers": [ | 63 | "publishers": [ | ||
64 | { | 64 | { | ||
65 | "publisher": "Karlsruhe Institute of Technology" | 65 | "publisher": "Karlsruhe Institute of Technology" | ||
66 | } | 66 | } | ||
67 | ], | 67 | ], | ||
68 | "relationships_as_object": [], | 68 | "relationships_as_object": [], | ||
69 | "relationships_as_subject": [], | 69 | "relationships_as_subject": [], | ||
70 | "repository_name": "RADAR (Research Data Repository)", | 70 | "repository_name": "RADAR (Research Data Repository)", | ||
71 | "resources": [], | 71 | "resources": [], | ||
72 | "services_used_list": "", | 72 | "services_used_list": "", | ||
73 | "source_metadata_created": "2023", | 73 | "source_metadata_created": "2023", | ||
74 | "source_metadata_modified": "", | 74 | "source_metadata_modified": "", | ||
75 | "state": "active", | 75 | "state": "active", | ||
76 | "subject_areas": [ | 76 | "subject_areas": [ | ||
77 | { | 77 | { | ||
78 | "subject_area_additional": "", | 78 | "subject_area_additional": "", | ||
79 | "subject_area_name": "Engineering" | 79 | "subject_area_name": "Engineering" | ||
80 | } | 80 | } | ||
81 | ], | 81 | ], | ||
82 | "tags": [ | 82 | "tags": [ | ||
83 | { | 83 | { | ||
84 | "display_name": "Conversion reaction", | 84 | "display_name": "Conversion reaction", | ||
85 | "id": "c7cd0011-557b-4fec-8048-1d667f369dc7", | 85 | "id": "c7cd0011-557b-4fec-8048-1d667f369dc7", | ||
86 | "name": "Conversion reaction", | 86 | "name": "Conversion reaction", | ||
87 | "state": "active", | 87 | "state": "active", | ||
88 | "vocabulary_id": null | 88 | "vocabulary_id": null | ||
89 | }, | 89 | }, | ||
90 | { | 90 | { | ||
91 | "display_name": "Electrode materials", | 91 | "display_name": "Electrode materials", | ||
92 | "id": "3b50a1a3-68cd-4a4f-98d5-0e8a548892f7", | 92 | "id": "3b50a1a3-68cd-4a4f-98d5-0e8a548892f7", | ||
93 | "name": "Electrode materials", | 93 | "name": "Electrode materials", | ||
94 | "state": "active", | 94 | "state": "active", | ||
95 | "vocabulary_id": null | 95 | "vocabulary_id": null | ||
96 | }, | 96 | }, | ||
97 | { | 97 | { | ||
98 | "display_name": "Layered double hydroxide", | 98 | "display_name": "Layered double hydroxide", | ||
99 | "id": "7843069a-b313-47d7-b099-84dd316d4b39", | 99 | "id": "7843069a-b313-47d7-b099-84dd316d4b39", | ||
100 | "name": "Layered double hydroxide", | 100 | "name": "Layered double hydroxide", | ||
101 | "state": "active", | 101 | "state": "active", | ||
102 | "vocabulary_id": null | 102 | "vocabulary_id": null | ||
103 | }, | 103 | }, | ||
104 | { | 104 | { | ||
105 | "display_name": "Sodium alginate", | 105 | "display_name": "Sodium alginate", | ||
106 | "id": "343bc0a3-1c9e-470d-a94a-2d2a8de0d615", | 106 | "id": "343bc0a3-1c9e-470d-a94a-2d2a8de0d615", | ||
107 | "name": "Sodium alginate", | 107 | "name": "Sodium alginate", | ||
108 | "state": "active", | 108 | "state": "active", | ||
109 | "vocabulary_id": null | 109 | "vocabulary_id": null | ||
110 | }, | 110 | }, | ||
111 | { | 111 | { | ||
112 | "display_name": "lithium-ion batteries", | 112 | "display_name": "lithium-ion batteries", | ||
113 | "id": "a4815104-0093-4865-b954-fa5d1e3bbd53", | 113 | "id": "a4815104-0093-4865-b954-fa5d1e3bbd53", | ||
114 | "name": "lithium-ion batteries", | 114 | "name": "lithium-ion batteries", | ||
115 | "state": "active", | 115 | "state": "active", | ||
116 | "vocabulary_id": null | 116 | "vocabulary_id": null | ||
117 | } | 117 | } | ||
118 | ], | 118 | ], | ||
119 | "title": "Electrochemical study on nickel aluminum layered double | 119 | "title": "Electrochemical study on nickel aluminum layered double | ||
120 | hydroxides as high-performance electrode material for lithium-ion | 120 | hydroxides as high-performance electrode material for lithium-ion | ||
121 | batteries based on sodium alginate binder", | 121 | batteries based on sodium alginate binder", | ||
122 | "type": "vdataset", | 122 | "type": "vdataset", | ||
123 | "url": "https://doi.org/10.35097/1500" | 123 | "url": "https://doi.org/10.35097/1500" | ||
124 | } | 124 | } |