Titanium(IV) ethoxide (CAS 3087-36-3)
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Titanium(IV) ethoxide, a titanium-based organic compound where ethoxide (ethoxy) groups are coordinated to a central titanium atom, is primarily utilized in materials science and nanotechnology research. As a precursor in the production of titanium dioxide and other titanium-containing materials, this compound is crucial due to its ability to undergo hydrolysis and condensation reactions, leading to the formation of complex titanium-oxygen networks. The ethoxide groups in the compound provide a reactive pathway for the formation of titanium-oxygen bonds, essential in the synthesis of ceramics and coatings. In the realm of research, Titanium(IV) ethoxide is extensively used in sol-gel processes, a method for producing solid materials from small molecules. Through this technique, researchers can create high-purity and uniform ceramic oxides at relatively low temperatures, which are important for applications requiring precise material properties, such as in the fabrication of photovoltaic cells and biomaterials. The ability of Titanium(IV) ethoxide to form smooth and durable films makes it valuable in the development of protective coatings and thin films for optical components. Additionally, its role in generating nanoscale materials has implications for exploring new functionalities in nanotechnology, particularly in enhancing the efficiency and stability of photocatalysts and sensors.
Titanium(IV) ethoxide (CAS 3087-36-3) References
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- Oxidation of hydrophobic alcohols using aqueous hydrogen peroxide over amphiphilic silica particles loaded with titanium (IV) oxide as a liquid–liquid phase-boundary catalyst | Choi, K. M., Ikeda, S., Ishino, S., Ikeue, K., Matsumura, M., & Ohtani, B. 2005. Applied Catalysis A: General. 278(2): 269-274.
- Shape-Controlled Anatase Titanium(IV) Oxide Particles Prepared by Hydrothermal Treatment of Peroxo Titanic Acid in the Presence of Polyvinyl Alcohol | Murakami, N., Kurihara, Y., Tsubota, T., & Ohno, T. 2009. The Journal of Physical Chemistry C. 113(8): 3062-3069.
- Dependence of photocatalytic activity on particle size of a shape-controlled anatase titanium (IV) oxide nanocrystal. | Murakami, N., Kawakami, S., Tsubota, T., & Ohno, T. 2012. Journal of Molecular Catalysis A: Chemical. 358: 106-111.
- Immobilization of crystallized photocatalysts on ceramic paper by titanium(IV) ethoxide and photocatalytic decomposition of phenol | Veréb, G., Ambrus, Z., Pap, Z., Mogyorósi, K., Dombi, A., & Hernádi, K. 2014. Reaction Kinetics, Mechanisms and Catalysis. 113: 293-303.
- Morphology control for highly efficient organic–inorganic bulk heterojunction solar cell based on Ti-alkoxide | Kato, T., Hagiwara, N., Suzuki, E., Nasu, Y., Izawa, S., Tanaka, K., & Kato, A. 2016. Thin Solid Films. 600: 98-102.
- A facile, efficient and solvent-free titanium (IV) ethoxide catalysed knoevenagel condensation of aldehydes and active methylenes | Ramaiah, M. M., Shivananju, N. S., & Shubha, P. B. 2020. Letters in Organic Chemistry. 17(2): 107-115.
- A spectrophotometric method for estimation of titanium alkoxide, a catalytically active form of titanium in oligomer/polymers | Naidu, K. S., Kate, A. S., Kshirsagar, V., Ganeshan, R., Gunale, T., Zhou, B.,.. & Rao, N. 2020. Polymer Testing. 86: 106446.
- Optimization of the ETL titanium dioxide layer for inorganic perovskite solar cells | Bulowski, W., Szwanda, A., Gawlińska-Nęcek, K., Panek, P., Lipiński, M., Janusz-Skuza, M.,.. & Starowicz, Z. 2024. Journal of Materials Science. 59(17): 7283-7298.
Ordering Information
| Product Name | Catalog # | UNIT | Price | Qty | FAVORITES | |
Titanium(IV) ethoxide, 50 g | sc-251257 | 50 g | $52.00 |