Suchergebnisse - "NICKEL phosphates"

Synthesis and characterization of Ni3(PO4)2·8H2O for electrochemical capacitor.

Autoren: Salunkhe, Sakshi M. Mohite, Ankita D. Pagare, Pavan K. et al.

Quelle: Interactions (30050731). 8/16/2025, Vol. 246 Issue 1, p1-11. 11p.

Schlagwörter: *PHYSICAL & theoretical chemistry, *NICKEL phosphates, *SUPERCAPACITORS, *ENERGY storage, *SCANNING electron microscopy

Reducing the Ni2P Particle Size Through the Silicon–Aluminium Coordination for Efficient Hydrogenation Saturation of Naphthalene.

Autoren: Zhao, Honggang Wang, Zhe Sun, Houxiang et al.

Quelle: Petroleum Chemistry. Oct2024, Vol. 64 Issue 10, p1202-1212. 11p.

Schlagwörter: NICKEL phosphates, PHYSICAL & theoretical chemistry, NICKEL catalysts, CATALYST supports, NAPHTHALENE, NICKEL phosphide

Porous nickel–cobalt phosphate with oxygen-rich vacancies in situ grown on dopamine-modified cellulose textiles as self-supporting high mass loadings supercapacitor electrode.

Autoren: Tian, Wenhui Ren, Penggang Hou, Xin et al.

Quelle: Journal of Colloid & Interface Science. Jan2025:Part B, Vol. 677, p626-636. 11p.

Schlagwörter: *OXYGEN electrodes, *NICKEL phosphates, *ENERGY density, *FAST ions, *ION migration & velocity, *SUPERCAPACITOR electrodes

Boosting energy storage with optimized binder-free nickel–cobalt phosphate electrode via microwave-hydrothermal method.

Autoren: Gerard, Ong Ramesh, S. Ramesh, K. et al.

Quelle: Journal of Materials Science; Dec2025, Vol. 60 Issue 46, p23619-23637, 19p

Schlagwörter: ENERGY storage, ELECTRODE performance, ELECTROCHEMICAL analysis, NICKEL phosphates, HYDROTHERMAL synthesis, EXPERIMENTAL design, ELECTRODES

Hydrogen Bridge‐Mediated Efficient Electrooxidation of 5‐Hydroxymethylfurfural on Ni(OH)2─PO4³⁻/Ni3(PO4)2 Heterojunctions.

Autoren: Liu, Xupo Zhang, Jingru Chen, Ye et al.

Quelle: Angewandte Chemie; 10/13/2025, Vol. 137 Issue 42, p1-10, 10p

Schlagwörter: HYDROXYMETHYLFURFURAL, HYDROGEN bonding, ORTHOPHOSPHATES, CATALYSTS, NICKEL phosphates, BIOMASS conversion, ELECTROLYTIC oxidation, NICKEL oxides

A transparent, anti‐blue‐light, and high strength nylon/nickel phosphate oligomer nanocomposite formed via intermolecular hydrogen bond crosslinking.

Autoren: Shui, Linyi Zhou, Lintao Guo, Xianxin et al.

Quelle: Polymer Composites. 12/20/2024, Vol. 45 Issue 18, p16823-16831. 9p.

Schlagwörter: *NICKEL phosphates, *AUTOMOTIVE materials, *HYDROGEN bonding, *TRANSITION metals, *TENSILE strength

Approaching Theoretical Capacity: 0D/2D Amorphous/Crystalline Bi‐Based Heterostructures Anode for Aqueous Alkaline Rechargeable Batteries.

Autoren: Wang, Xiaodong Zhou, Fengming Liang, Qiuyue et al.

Quelle: Advanced Functional Materials. 11/20/2024, Vol. 34 Issue 48, p1-10. 10p.

Schlagwörter: *ALKALINE batteries, *NICKEL phosphates, *NANODOTS, *ENERGY density, *POWER density

Transformative impact of molybdenum on nickel phosphate hydrate electrodes towards superior energy storage application.

Autoren: Teli, Aviraj M. Beknalkar, Sonali A. Satale, Vinayak V. et al.

Quelle: Ceramics International. Nov2024:Part A, Vol. 50 Issue 21, p41156-41167. 12p.

Schlagwörter: *NICKEL electrodes, *NICKEL phosphates, *ELECTRODE performance, *CARBON electrodes, *ENERGY storage, *SUPERCAPACITOR electrodes, *MOLYBDENUM

Boosting Hydrogen Evolution Behaviors of Porous Nickel Phosphate by Phosphorization Engineering.

Autoren: He, Tao Xu, Yuan Zhang, Liqiu et al.

Quelle: Catalysts (2073-4344). Nov2024, Vol. 14 Issue 11, p757. 10p.

Schlagwörter: *TRANSITION metal catalysts, *NICKEL phosphates, *CHARGE transfer, *HYDROGEN production, *X-ray diffraction

Preparation of Ni2P with a Surface Nickel Phosphosulfide Layer by Reduction of Mixtures of Na4P2S6 and NiCl2.

Autoren: He, Ming Li, Tiefu Li, Xiang et al.

Quelle: ChemCatChem. 10/7/2024, Vol. 16 Issue 19, p1-10. 10p.

Schlagwörter: *HETEROGENEOUS catalysis, *NICKEL phosphates, *NICKEL catalysts, *NICKEL, *DESULFURIZATION, *NICKEL sulfide

Non-Free Cutting Mechanism of Asymmetrical Nanogrooves Under Chip-Removal Interference in Amorphous Nickel Phosphorus.

Autoren: He, Yupeng Cai, Yingzhao Huang, Minkun et al.

Quelle: Micromachines; Sep2025, Vol. 16 Issue 9, p1059, 13p

Schlagwörter: MACHINING, DEFORMATIONS (Mechanics), COMMUNICATION of technical information, NICKEL phosphates, SHEAR (Mechanics), NANOSTRUCTURES

Hydrothermal Synthesis of Ni2P2O7 Nanosheets Like Efficient Electrode for Supercapacitor Applications: Capacitive and Diffusive Mechanism of Trassati Method.

Autoren: Silambarasan, M. Boopathiraja, R. Prabhu, N. et al.

Quelle: Journal of Inorganic & Organometallic Polymers & Materials; Sep2025, Vol. 35 Issue 9, p7364-7379, 16p

Schlagwörter: SUPERCAPACITORS, ELECTRODES, ELECTROCHEMICAL analysis, NICKEL phosphates, HYDROTHERMAL synthesis, ELECTRIC capacity

Synthesis and characterization of Ni3(PO4)2·8H2O for electrochemical capacitor.

Autoren: Salunkhe, Sakshi M. Mohite, Ankita D. Pagare, Pavan K. et al.

Quelle: Interactions (30050731); 8/16/2025, Vol. 246 Issue 1, p1-11, 11p

Schlagwörter: PHYSICAL & theoretical chemistry, NICKEL phosphates, SUPERCAPACITORS, ENERGY storage, SCANNING electron microscopy

Preparation and Electrocatalytic Properties of Nickel-Cobalt Metal Derivatives.

Autoren: ZHANG, Ying HU, Yue YU, Bo

Quelle: Materials Science / Medziagotyra; 2025, Vol. 31 Issue 3, p324-330, 7p

Schlagwörter: ELECTROCATALYSIS, HYDROGEN evolution reactions, NICKEL phosphates, COBALT, TRANSITION metals, NANOSTRUCTURES, CATALYTIC activity, WATER electrolysis

Synthesis of ultrathin carbon layer-coated LiNiPO4 nanoparticles by solvothermal method.

Autoren: Li, Zhiyi Sun, Haili Wei, Wei et al.

Quelle: Ceramics International. Jul2024, Vol. 50 Issue 14, p24995-25004. 10p.

Schlagwörter: *ANTISITE defects, *NICKEL phosphates, *RIETVELD refinement, *NANOPARTICLES, *ELECTRIC conductivity, *GRAPHITIZATION

Air‐Annealed Nickel Phosphates: A Cost‐Effective Bifunctional Catalyst for Efficient Water Splitting and Sustainable Hydrogen Production.

Autoren: Deshmukh, Puja Sutar, Pratik Kadam, Anamika

Quelle: ChemistrySelect; 6/18/2025, Vol. 10 Issue 23, p1-12, 12p

Schlagwörter: CLEAN energy, METALLIC bonds, SUSTAINABILITY, NICKEL phosphates, HYDROGEN evolution reactions

Na4.3Ni1.3Al1.7(PO4)4 structure transformation from stuffed α-CrPO4 type driven by the incorporation of Na: magnetism and ionic migration.

Autoren: Yakubovich, Olga Kiriukhina, Galina Manokhina, Elizaveta et al.

Quelle: CrystEngComm; 6/7/2025, Vol. 27 Issue 21, p3576-3583, 8p

Schlagwörter: MAGNETISM, CRYSTAL structure, NICKEL phosphates, HYDROTHERMAL synthesis, STORAGE batteries, PHASE transitions, PHOSPHATES, IONIC conductivity

In situ optimization of deposition layers in Ni–Co phosphate electrodes with ML-assisted predictive validation for superior supercapacitor.

Autoren: Mendhe, Arpit B. Panigrahi, Laxmi Narayan Panda, Himanshu Sekhar

Quelle: Dalton Transactions: An International Journal of Inorganic Chemistry; 4/14/2025, Vol. 54 Issue 14, p5868-5879, 12p

Schlagwörter: SUPERCAPACITORS, ENERGY storage, ELECTRODE performance, MACHINE learning, ELECTRIC capacity, NICKEL phosphates, FABRICATION (Manufacturing), ELECTRODES

Controllable Preparation and Flame Retardant Modification of Nickel Phosphate-chitosan Composite Coating on PET. (English)

Autoren: WU Wei LI Jifeng HU Chaofan et al.

Quelle: Journal of Materials Science & Engineering (1673-2812); Apr2025, Vol. 43 Issue 2, p301-307, 7p

Schlagwörter: FIREPROOFING agents, COMPOSITE coating, FIREPROOFING, X-ray photoelectron spectroscopy, NICKEL phosphates

Leveraging phosphate group in Pd/PdO decorated nickel phosphate microflowers via pulsed laser for robust hydrogen production in hydrazine-assisted electrolyzer.

Autoren: Lee, Hyeyeon Theerthagiri, Jayaraman Aruna Kumari, M.L. et al.

Quelle: International Journal of Hydrogen Energy. Feb2024, Vol. 57, p176-186. 11p.

Schlagwörter: *PULSED lasers, *NICKEL phosphates, *FUEL cells, *HYDROGEN production, *ELECTROCATALYSTS, *OXYGEN evolution reactions, *COORDINATE covalent bond