• 1. Fatty acid eutectic mixtures and derivatives from non-edible animal fat as phase change materials?
  Pau Gallart-Sirvent,Marc Martín,Gemma Villorbina,Mercè Balcells,Aran Solé,Luisa F. Cabeza,Ramon Canela-Garayoa RSC Adv., 2017,7, 24133-24139
• 2. Fatty acid positional distribution in colostrum and mature milk of women living in Inner Mongolia, North Jiangsu and Guangxi of China?
  Long Deng,Qian Zou,Biao Liu,Wenhui Ye,Chengfei Zhuo,Li Chen,Ze-Yuan Deng,Ya-Wei Fan,Jing Li Food Funct., 2018,9, 4234-4245
• 3. Evidence of pre-micellar aggregates in aqueous solution of amphiphilic PDMS–PEO block copolymer?
  Domenico Lombardo,Gianmarco Munaò,Pietro Calandra,Luigi Pasqua,Maria Teresa Caccamo Phys. Chem. Chem. Phys., 2019,21, 11983-11991
• 4. Emergence of cationic polyamine dendrimersomes: design, stimuli sensitivity and potential biomedical applications
  Partha Laskar,Christine Dufès Nanoscale Adv., 2021,3, 6007-6026
• 5. Evidence of rutile-to-anatase photo-induced electron transfer in mixed-phase TiO2 by solid-state NMR spectroscopy?
  Weili Dai,Guangjun Wu,Michael Hunger Chem. Commun., 2015,51, 13779-13782

• Catalysts and Inorganic Chemicals Inorganic Compounds Mixed metal/non-metal compounds Transition metal organides Transition metal oxides
• Other Element Metal
• Material Chemicals Colorants and Pigments Pigments
• Catalysts and Inorganic Chemicals Inorganic Compounds Oxides
• Catalysts and Inorganic Chemicals Inorganic Compounds Salt
• Catalysts and Inorganic Chemicals Inorganic Compounds

Properties and Applications of Cobalt Oxide (CAS No. 1307-96-6)

Cobalt oxide, with the chemical formula Cobalt oxide and a CAS number of CAS no 1307-96-6, is a well-studied inorganic compound that has garnered significant attention in various scientific and industrial applications. This compound, which exists in multiple crystalline forms such as cobalt(II) oxide and cobalt(III) oxide, exhibits unique physical and chemical properties that make it invaluable in fields ranging from catalysis to materials science.

The synthesis of cobalt oxide can be achieved through several methods, including thermal decomposition of cobalt salts, precipitation reactions, and hydrothermal processes. Among these methods, the hydrothermal synthesis technique has recently gained prominence due to its ability to produce highly pure and crystalline cobalt oxide nanoparticles with controlled morphologies. These nanoparticles, characterized by their high surface area and tunable size, have shown exceptional promise in enhancing the efficiency of various catalytic processes.

In the realm of catalysis, cobalt oxide has been extensively studied for its potential as a catalyst in the oxidation of hydrocarbons and the reduction of carbon dioxide. Recent research has highlighted the role of cobalt oxide nanoparticles in improving the selectivity and yield of these reactions. For instance, a study published in the journal Journal of Catalysis demonstrated that cobalt oxide nanoparticles supported on carbon materials exhibit superior performance in the oxidative coupling of methane, a process crucial for converting natural gas into higher-value chemicals.

Beyond catalysis, cobalt oxide finds applications in battery technology, particularly in lithium-ion batteries. The unique electronic properties of cobalt oxide make it an effective material for enhancing the performance of cathode materials in lithium-ion batteries. Researchers have reported that incorporating cobalt oxide into lithium iron phosphate (LFP) cathodes can significantly improve the energy density and cycle life of these batteries. This advancement is particularly relevant in the context of renewable energy storage solutions, where efficient battery technology is essential for reducing reliance on fossil fuels.

Another emerging application of cobalt oxide is in the field of sensors. Cobalt oxide-based sensors have shown great potential for detecting various gases and environmental pollutants due to their high sensitivity and selectivity. A notable example is the use of cobalt oxide nanoparticles in gas sensors for detecting toxic gases such as ammonia and hydrogen sulfide. These sensors operate based on the principle that changes in gas concentration cause measurable changes in the electrical properties of the cobalt oxide material.

The biomedical field also benefits from the unique properties of cobalt oxide. Research has indicated that cobalt oxide nanoparticles can be used as contrast agents in magnetic resonance imaging (MRI). Their ability to produce strong magnetic fields when excited by radio waves makes them effective at enhancing image contrast, allowing for better visualization of internal body structures. Additionally, studies have explored the potential use of cobalt oxide nanoparticles in drug delivery systems, where their biocompatibility and controlled release properties could improve therapeutic outcomes.

In conclusion, cobalt oxide (CAS no 1307-96-6) is a versatile compound with a wide range of applications across multiple industries. Its unique properties make it an excellent candidate for use in catalysis, battery technology, sensor development, and biomedical applications. As research continues to uncover new uses for this compound, its importance is likely to grow even further, driving innovation and progress in various scientific and technological domains.

• 60131-09-1(Cobalt(1+), oxo-)
• 55326-90-4(Cobalt oxide, hydrate)
• 332062-08-5(Fmoc-S-3-amino-4,4-diphenyl-butyric acid)
• 1270529-38-8(1,2,3,4,5,6-Hexahydro-[2,3]bipyridinyl-6-ol)
• 2680771-01-9(4-cyclopentyl-3-{(prop-2-en-1-yloxy)carbonylamino}butanoic acid)
• 2098070-20-1(2-(3-(Pyridin-3-yl)-1H-pyrazol-1-yl)acetimidamide)
• 1444113-98-7(N-(3-cyanothiolan-3-yl)-2-[(2,2,2-trifluoroethyl)sulfanyl]pyridine-4-carboxamide)
• 941977-17-9(N'-(3-chloro-2-methylphenyl)-N-2-(dimethylamino)-2-(naphthalen-1-yl)ethylethanediamide)
• 2138166-62-6(2,2-Difluoro-3-[methyl(2-methylbutyl)amino]propanoic acid)
• 89640-58-4(2-Iodo-4-nitrophenylhydrazine)