Nickel hydroxide - Ni 60.0-70.0 % , CAS No.12054-48-7

CAS: 12054-48-7 Cat. No.: N104966 Peso molecular: 92.71 Número EC: 235-008-5 PubChem CID: 25500
Disponible para pedir
GRADE & PURITY Ni 60.0-70.0 %
Synonyms
AKOS015903693 | EINECS 235-008-5 | Nickel hydroxide (Ni(OH)2) | UNII-L8UW92NW6J | Nickel Hydroxide nanowire | nickel;dihydrate | EC 235-008-5 | Nickel hydroxide (II) | dihydroxynickel | Nickel(2+) hydroxide | HSDB 1827 | MFCD00011140 | Nickel dihydroxide
Storage
Protected from light,Room temperature,Argon charged,Desiccated,Cool
Shipped In
Normal
 ·  off list, applied to all prices below.
Size
Estado
Price
Qty
25g
N104966-25g
2
10,90US$
100g
N104966-100g
≥10
19,90US$
500g
N104966-500g
3
49,90US$
Enter a quantity for the sizes you want to add.
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Why this grade

Ni 60.0-70.0 % for sensitive chromatographic and analytical workflows requiring minimal baseline interference.

🌡

Storage & shipping

Protected from light,Room temperature,Argon charged,Desiccated,Cool Ships Normal Check lot-specific COA for exact specifications.

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Quality documents

SDS, COA, datasheet, and spec sheet available for download. Lot-specific COA accessible via lot number lookup.

📚

Literature proof

Cited in 27 peer-reviewed publications across chromatography, organic synthesis, and cross-coupling reactions.

Descripción general

Applications
Nickel(II) hydroxide, battery grade can used in battery research as an active material in rechargeable battery electrodes, particularly in nickel-metal hydride (NiMH) and nickel-cadmium (NiCd) batteries. Electroactive layered nickel hydroxides have applications supercapacitors, electrochromic devices, and electrocatalysts. Ni(OH)2‐based materials can be used as efficient electrocatalysts for water oxidation, which is a critical catalytic reaction for sustainable technologies, such as water electrolysis, fuel cells, CO2 reduction, and metal–air batteries.

Specifications

Sinónimos
AKOS015903693 | EINECS 235-008-5 | Nickel hydroxide (Ni(OH)2) | UNII-L8UW92NW6J | Nickel Hydroxide nanowire | nickel;dihydrate | EC 235-008-5 | Nickel hydroxide (II) | dihydroxynickel | Nickel(2+) hydroxide | HSDB 1827 | MFCD00011140 | Nickel dihydroxide
Especificaciones y pureza
Ni 60.0-70.0 %
Condiciones de almacenamiento de almacenamiento
Protected from light, Room temperature, Argon charged, Desiccated, Cool
Enviado en
Normal
Nombres e identificadores
Pubchem Sid488182965
Pubchem Sid Urlhttps://pubchem.ncbi.nlm.nih.gov/substance/488182965
Sonrisas canónicasO.O.[Ni]
IUPAC Namenickel;dihydrate
InChIKeyAIBQNUOBCRIENU-UHFFFAOYSA-N
INCHI1S/Ni.2H2O/h;2*1H2
Isómeros SMILES O.O.[Ni]
WGK Alemania 3
RTECS QR7040000
PubChem CID 25500
Número ONU 3077
Grupo de embalaje III
Peso molecular 92.71

Documentation

📋 Safety Data Sheet (SDS)

Comprehensive hazard, handling, storage, and regulatory compliance document.

Download SDS →

✅ Certificate of Analysis (COA)

Lot-specific quality data. Enter your lot number to retrieve the exact COA.

Look up COA →

📊 Datasheet

Quick-reference summary of product specifications and applications.

View datasheet →

🔬 Specification Sheet

Full quality attributes and acceptance criteria for this grade.

View spec sheet →

Advanced Data

Taxonomic Classification

Taxonomy Tree

KingdomInorganic compounds
SuperclassMixed metal/non-metal compounds
ClaseTransition metal organides
SubclassTransition metal oxides
Intermediate Tree Nodes Not available
Direct ParentTransition metal oxides
Alternative Parents Inorganic salts  Inorganic oxides  Inorganic nickel compounds  
Molecular FrameworkNot available
Substituents Transition metal oxide - Inorganic oxide - Inorganic salt - Inorganic nickel compound
DescripciónThis compound belongs to the class of inorganic compounds known as transition metal oxides. These are inorganic compounds containing an oxygen atom of an oxidation state of -2, in which the heaviest atom bonded to the oxygen is a transition metal.
External Descriptors Not available
Estructura 3D
Modelo de Estructura Química Interactiva





Certificados (CoA, COO, BSE/TSE y tabla de análisis)
C of A & Other Certificates(BSE/TSE, COO):
Analytical Chart:

Find and download the COA for your product by matching the lot number on the packaging.

23 results found

Lot NumberCertificate TypeFechaArticulo
E2622493Certificate of AnalysisMay 06, 2026 N104966
E2622492Certificate of AnalysisMay 06, 2026 N104966
E2622490Certificate of AnalysisMay 06, 2026 N104966
E2622491Certificate of AnalysisMay 06, 2026 N104966
E2411401Certificate of AnalysisMar 15, 2024 N104966
E2411402Certificate of AnalysisMar 15, 2024 N104966
F2305666Certificate of AnalysisMay 24, 2023 N104966
F2305663Certificate of AnalysisMay 24, 2023 N104966
F2305662Certificate of AnalysisMay 24, 2023 N104966
F2305661Certificate of AnalysisMay 24, 2023 N104966
G2431097Certificate of AnalysisMay 24, 2023 N104966
E2406041Certificate of AnalysisMay 24, 2023 N104966
H2501085Certificate of AnalysisMay 24, 2023 N104966
L2411250Certificate of AnalysisMay 24, 2023 N104966
B2510034Certificate of AnalysisMay 24, 2023 N104966
H2518036Certificate of AnalysisApr 08, 2023 N104966
A2608048Certificate of AnalysisApr 08, 2023 N104966
L2419021Certificate of AnalysisApr 08, 2023 N104966
C23241268Certificate of AnalysisApr 08, 2023 N104966
C23241269Certificate of AnalysisFeb 23, 2023 N104966
C23241267Certificate of AnalysisFeb 23, 2023 N104966
B2303901Certificate of AnalysisFeb 07, 2023 N104966
F1829025Certificate of AnalysisApr 27, 2022 N104966

Show more ⌵

Propiedades químicas y físicas
SolubilidadInsoluble in water
SensibilidadHygroscopic
Punto de fusión (°C)230 °C
Peso molecular94.724 g/mol
XLogP3
Hydrogen Bond Donor Count2
Hydrogen Bond Acceptor Count2
Rotatable Bond Count0
Exact Mass93.9565 Da
Monoisotopic Mass93.9565 Da
Topological Polar Surface Area2.000 Ų
Heavy Atom Count3
Formal Charge0
Complexity2.800
Isotope Atom Count0
Defined Atom Stereocenter Count0
Undefined Atom Stereocenter Count0
Defined Bond Stereocenter Count0
Undefined Bond Stereocenter Count0
The total count of all stereochemical bonds0
Covalently-Bonded Unit Count3
Preguntas frecuentes y artículos
Citations of This Product
Referencias
1. Fu Yi-Han, Peng Yuan-You, Zhao Lei, He Tian-Qi, Yuan Mei-Mei, Dang Hao, Liu Rui, Ran Fen.  (2023)  Vanadium nitride quantum dots@carbon skeleton anode material synthesized via in situ oxidation initiation strategy.  Tungsten,      [PMID:] [10.1007/s42864-023-00246-w]
2. Yuanzheng Long, Cheng Yang, Yulong Wu, Bohan Deng, Ziwei Li, Naveed Hussain, Kuangyu Wang, Ruyue Wang, Xian He, Peng Du, Zeliang Guo, Jialiang Lang, Kai Huang, Hui Wu.  (2023)  Cable-Car Electrocatalysis to Drive Fully Decoupled Water Splitting.  Advanced Science,  10  (26): (2301872).  [PMID:37395639] [10.1002/advs.202301872]
3. Lifan Wang, Qinling Shi, Chun Zhan, Guicheng Liu.  (2023)  One-Step Solid-State Synthesis of Ni-Rich Cathode Materials for Lithium-Ion Batteries.  Materials,  16  (8): (3079).  [PMID:37109914] [10.3390/ma16083079]
4. Donglei Yu, Zhizhang Yuan, Xianfeng Li.  (2023)  Enhanced stability of nickel cathode for nickel-based batteries by electroless nickel phosphide plating.  CHEMICAL ENGINEERING SCIENCE,      [PMID:] [10.1016/j.ces.2023.118512]
5. Zhongzeng Zhou, Luojun Wang, Jing Wang, Conghui Liu, Tailin Xu, Xueji Zhang.  (2022)  Machine Learning with Neural Networks to Enhance Selectivity of Nonenzymatic Electrochemical Biosensors in Multianalyte Mixtures.  ACS Applied Materials & Interfaces,      [PMID:36397204] [10.1021/acsami.2c17593]
6. Linying Yang, Shuwei Sun, Kai Du, Huiling Zhao, Dong Yan, Hui Ying Yang, Caiyan Yu, Ying Bai.  (2021)  Prompting structure stability of O3–NaNi0.5Mn0.5O2 via effective surface regulation based on atomic layer deposition.  CERAMICS INTERNATIONAL,      [PMID:] [10.1016/j.ceramint.2021.07.009]
7. Ke Li, Jun Xu, Chan Chen, Zhizhog Xie, Dan Liu, Deyu Qu, Haolin Tang, Qiang Wei, Qibo Deng, Junsheng Li, Ning Hu.  (2020)  Activating the hydrogen evolution activity of Pt electrode via synergistic interaction with NiS2.  JOURNAL OF COLLOID AND INTERFACE SCIENCE,      [PMID:32911407] [10.1016/j.jcis.2020.08.071]
8. Shangbo Ning, Hua Xu, Yuhang Qi, Lizhu Song, Qiqi Zhang, Shuxin Ouyang, Jinhua Ye.  (2020)  Microstructure Induced Thermodynamic and Kinetic Modulation to Enhance CO2 Photothermal Reduction: A Case of Atomic-Scale Dispersed Co–N Species Anchored Co@C Hybrid.  ACS Catalysis,      [PMID:] [10.1021/acscatal.9b04963]
9. Chunyu Li, Chao Wu, Baoquan Zhang.  (2019)  Enhanced CO2/CH4 Separation Performances of Mixed Matrix Membranes Incorporated with Two-Dimensional Ni-Based MOF Nanosheets.  ACS Sustainable Chemistry & Engineering,      [PMID:] [10.1021/acssuschemeng.9b06370]
10. Zhengbo Chen, Jianwei Nai, He Ma, Zhiqiang Li.  (2013)  Nickel hydroxide nanocrystals-modified glassy carbon electrodes for sensitive l-histidine detection.  ELECTROCHIMICA ACTA,      [PMID:] [10.1016/j.electacta.2013.10.153]
11. Liu Yongjie, Wang Jiayu, Liu Sunan, Li Jing, Xiang Qian, Yang Zaiyue, Zhu Ling.  (2024)  A Convenient Ratiometric Fluorescent Probe Based on Gold Nanoclusters and Carbon Dots for Escherichia coli Determination.  Food Analytical Methods,      [PMID:] [10.1007/s12161-024-02595-9]
12. Biao Lu, Kaifeng Yu, Weide Shao, Jianing Zhang, Jinpeng Cao, Yong Cheng, Feifei Zhang.  (2025)  A high volume specific capacity hybrid flow battery with solid active energy storage substance on the electrode.  Journal of Energy Storage,      [PMID:] [10.1016/j.est.2025.115670]
13. Zi-Ye Liu, Qian-Yu Wang, Teng Xu, Ji-Ming Hu.  (2024)  Conjugated polycarboxylate ligand-coordinated NiFe LDH for enhanced oxygen evolution.  Journal of Materials Chemistry A,      [PMID:] [10.1039/D4TA04498C]
14. Wang Ke, Shaobo Cai, Runlin Ma, Jingge Shi, Manman Wu, Menggai Jiao, Yongzheng Fang, Yiyang Liu, Zhen Zhou.  (2024)  Improving Li–S Batteries by a Separator Decorated with Ternary Metal Organic Frameworks from Spent Li-Ion Batteries.  ENERGY & FUELS,      [PMID:] [10.1021/acs.energyfuels.4c01515]
15. Yue Leng, Shengde Dong, Zhan Chen, Yanxia Sun, Qi Xu, Luxiang Ma, Xin He, Chunxi Hai, Yuan Zhou.  (2024)  Improving the Cycle Stability of LiNiO2 through Al3+ Doping and LiAlO2 Coating.  LANGMUIR,      [PMID:39460713] [10.1021/acs.langmuir.4c02673]
16. Bing Li, Yue Yu, Bingjiang Jia, Ziqing Huang, Jingyi Liu, Bolin Guo, Qing Zhang.  (2024)  Promoted Production of Lactic Acid from Glucose by Calcium Hydroxide in the Presence of Hydrogen.  ChemistrySelect,  (10): (e202304987).  [PMID:] [10.1002/slct.202304987]
17. Xiaohua Peng, Xin Jin, Yong Zhen, Bo Yang, Chang Wei, Xingbin Li, Zhigan Deng, Minting Li.  (2024)  Recovery of nickel and iron from ferronickel powder and high nickel matte via the atmospheric leaching-hematite precipitation process.  CANADIAN METALLURGICAL QUARTERLY,      [PMID:] [10.1080/00084433.2024.2306025]
18. Xu Xian, Lan Ling, Xu Jiangong, Liang Zheng, Tan Jin, Wang Haiyong, Qiu Songbai.  (2024)  Selective Hydrogenation of 5-Hydroxymethylfurfural to 2,5-bis(hydroxymethyl)furan by Pt/Ni@C Catalyst.  CATALYSIS LETTERS,      [PMID:] [10.1007/s10562-024-04717-8]
19. Xiaohua Peng, Xin Jin, Yong Zhen, Bo Yang, Chang Wei, Xingbin Li, Zhigan Deng, Minting Li.  (2024)  Separation of nickel and iron from ferronickel via sulfuric acid leaching and hydrothermal precipitation.  CANADIAN METALLURGICAL QUARTERLY,      [PMID:] [10.1080/00084433.2024.2378263]
20. Xingxing Chen, Xuechen Liang, Zhou Zhou, Lulu Song, Yating Wang, Enpei Tan, Yujun Liu, Ying Tan.  (2024)  Solar interfacial evaporation for efficient treatment of sewage containing volatile organic compounds and toxic heavy metal ions: A sequential process of adsorption, coagulation, and evaporation.  Journal of Environmental Chemical Engineering,      [PMID:] [10.1016/j.jece.2024.112389]
21. Wang Xinzhong, Su Yiwen, Chen Jiashu, Yan Edward Hengzhou, Xia Qing, Wu Jie, Gong Shanhe, Tang Mingcong, Yip Wai Sze, Mu Yongbiao, Yi Yuyang, Wu Jinjin, Xu Fujing, Yang Xianzhong, Zhang Xiao, Dou Shixue, Sun Jingyu, Zheng Guangping.  (2025)  Revisiting Pt foil catalysts for formamide electrosynthesis achieved at industrial-level current densities.  Nature Communications,  16  (1): (1-13).  [PMID:40877263] [10.1038/s41467-025-63313-5]
22. Fei Zhou, Jinwei Tan, Feixiang Wang, Meiling Sun.  (2025)  In Situ Engineered Plastic–Crystal Interlayers Enable Li-Rich Cathodes in PVDF-HFP-Based All-Solid-State Polymer Batteries.  Batteries-Basel,  11  (9): (334).  [PMID:] [10.3390/batteries11090334]
23. Runze Wang, Yuanyou Peng, Chunjin Ai, Meimei Yu, Guang Liu, Tianqi He, Jie Zhang, Junlong Chen, Shengqiang Nie, Fen Ran.  (2025)  Bionic Bone Structure Anode Material of High-Capacity 3D Porous Vanadium Nitride@Carbon Nanocomposite via Spray Phase Inversion.  LANGMUIR,      [PMID:40963215] [10.1021/acs.langmuir.5c02408]
24. Yuheng Guo, Min Yue, Chao Wu.  (2025)  Direct upcycling of spent lithium-ion battery cathodes to efficient water oxidation catalysts.  APPLIED SURFACE SCIENCE,      [PMID:] [10.1016/j.apsusc.2025.164867]
25. Kai Zhang, Peifeng Wang, Zhuohui Sun, Hongwei Zhang, Rui Chang, Youlong Xu.  (2025)  High-Entropy Cl Substitution Promotes High Specific Capacity and Specific Energy Release from Sodium Manganate for Sodium-Ion Batteries.  ACS Applied Materials & Interfaces,      [PMID:40725985] [10.1021/acsami.5c07494]
26. Zhaowen Bai, Subash Kandasamy, Wei Wang, Rui Zhou, Zhenjie Zhang, Xuefeng Wang, Jiatu Liu, Zhenbin Wang, Guohua Chen, Qingyu Kong, Tianyi Li, Yang Ren.  (2025)  Ni Migration-Induced Strain and Phase Segregation in LiNiO2 Cathodes.  ACS Nano,      [PMID:40371999] [10.1021/acsnano.5c03288]
27. Ahui Zhu, Ersha Fan, Xiaodong Zhang, Renjie Chen, Li Li.  (2026)  Bidirectional Lattice Anchoring Enhances Composition Reconfiguration of Spent Lithium-Ion Cathodes.  Advanced Energy Materials,      [PMID:] [10.1002/aenm.70869]
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