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Iron(II) Titanate

FeTiO3
CAS 12022-71-8


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(5N) 99.999% Iron(II) Titanate Powder FE2-TAT-05-P Request Quote
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(5N) 99.999% Iron(II) Titanate Sputtering Target FE2-TAT-05-ST Request Quote
(5N) 99.999% Iron(II) Titanate Lump FE2-TAT-05-L Request Quote

CHEMICAL
IDENTIFIER
Formula CAS No. PubChem CID MDL No. EC No IUPAC Name Beilstein
Re. No.
SMILES
Identifier
InChI
Identifier
InChI
Key
FeTiO3 12022-71-8 3709578 MFCD00064704 234-667-6 dihydroxy(oxo) titanium; iron N/A O[Ti](=O)O.[Fe] InChI=1S/Fe.2H2O.O.Ti
/h;2*1H2;;/q;;;;+2/p-2
JIAXFBFASROBHB-UHFFFAOYSA-L

PROPERTIES Compound Formula Mol. Wt. Appearance Density Exact Mass Monoisotopic Mass Charge MSDS
FeH2O3Ti 151.71 Gray to black powder N/A 153.883278 153.883278 N/A Safety Data Sheet

Iron(II) Titanate is generally immediately available in most volumes. High purity, submicron and nanopowder forms may be considered. Titanate compounds contain a form of Titanium Oxide and have various applications including electronics, ceramics, and batteries (in the case of Lithium Titanate). Researchers from the University of Illinois recently created nanofiber mats of zinc titanate that can scrub sulfur impurities from petroleum-based fuels more efficiently than existing methods, a nanotechnology-based development that may lower the cost of fuel technologies in the future. American Elements produces to many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information is available as is a Reference Calculator for converting relevant units of measurement.

Iron (Fe) atomic and molecular weight, atomic number and elemental symbolIron (atomic symbol: Fe, atomic number: 26) is a Block D, Group 8, Period 4 element with an atomic weight of 55.845. The number of electrons in each of Iron's shells is 2, 8, 14, 2 and its electron configuration is [Ar] 3d6 4s2.Iron Bohr Model The iron atom has a radius of 126 pm and a Van der Waals radius of 194 pm. Iron was discovered by humans before 5000 BC. In its elemental form, iron has a lustrous grayish metallic appearance. Elemental Iron Iron is the fourth most common element in the Earth's crust and the most common element by mass forming the earth as a whole. Iron is rarely found as a free element, since it tends to oxidize easily; it is usually found in minerals such as magnetite, hematite, goethite, limonite, or siderite. Though pure iron is typically soft, the addition of carbon creates the alloy known as steel, which is significantly stronger. For more information on iron, including properties, safety data, research, and American Elements' catalog of iron products, visit the Iron element page.

Titanium (Ti) atomic and molecular weight, atomic number and elemental symbolTitanium (atomic symbol: Ti, atomic number: 22) is a Block D, Group 4, Period 4 element with an atomic weight of 47.867. The number of electrons in each of Titanium's shells is [2, 8, 10, 2] and its electron configuration is [Ar] 3d2 4s2. Titanium Bohr ModelThe titanium atom has a radius of 147 pm and a Van der Waals radius of 187 pm. Titanium was discovered by William Gregor in 1791 and first isolated by Jöns Jakob Berzelius in 1825. In its elemental form, titanium has a silvery grey-white metallic appearance. Titanium's properties are chemically and physically similar to zirconium, both of which have the same number of valence electrons and are in the same group in the periodic table.Elemental Titanium Titanium has five naturally occurring isotopes: 46Ti through 50Ti, with 48Ti being the most abundant (73.8%). Titanium is found in igneous rocks and the sediments derived from them. It is named after the word Titanos, which is Greek for Titans. For more information on titanium, including properties, safety data, research, and American Elements' catalog of titanium products, visit the Titanium element page.


HEALTH, SAFETY & TRANSPORTATION INFORMATION
Material Safety Data Sheet MSDS
Signal Word Warning
Hazard Statements H302-H312-H315-H319-H332-H335-H351
Hazard Codes Xn
Risk Codes 20/21/22-36/37/38-40
Safety Precautions 22-26-36
RTECS Number N/A
Transport Information N/A
WGK Germany 3
Globally Harmonized System of
Classification and Labelling (GHS)
Exclamation Mark-Acute Toxicity Health Hazard      

IRON(II) TITANATE SYNONYMS
Iron titanium trioxide, iron titanium oxide, iron(2+) titanate

CUSTOMERS FOR IRON(II) TITANATE HAVE ALSO LOOKED AT
Iron Pellets Iron Oxide Iron Nitrate Iron Oxide Pellets Iron Nanoparticles
Iron Chloride Iron Acetylacetonate Iron Bars Iron Foil Aluminum Iron Alloy
Zirconium Scandium Iron Alloy Iron Fluoride Iron Metal Iron Acetate Iron Sputtering Target
Show Me MORE Forms of Iron

PACKAGING SPECIFICATIONS FOR BULK & RESEARCH QUANTITIES
Typical bulk packaging includes palletized plastic 5 gallon/25 kg. pails, fiber and steel drums to 1 ton super sacks in full container (FCL) or truck load (T/L) quantities. Research and sample quantities and hygroscopic, oxidizing or other air sensitive materials may be packaged under argon or vacuum. Shipping documentation includes a Certificate of Analysis and Material Safety Data Sheet (MSDS). Solutions are packaged in polypropylene, plastic or glass jars up to palletized 440 gallon liquid totes.


Have a Question? Ask a Chemical Engineer or Material Scientist
Request an MSDS or Certificate of Analysis

Recent Research & Development for Iron

  • Polychlorinated biphenyls (PCBs) exert an inhibition on hepcidin expression through an estrogen-like effect associated with disordered systemic iron homeostasis. Yi Qian, Shuping Zhang, Wenli Guo, Juan Ma, Yue Chen, Lei Wang, Meirong Zhao, and Sijin Liu. Chem. Res. Toxicol.: February 16, 2015
  • pH-Responsive Iron Manganese Silicate Nanoparticles as T1-T2* Dual-Modal Imaging Probes for Tumor Diagnosis. Jian Chen, Weijie Zhang, Zhen Guo, Haibao Wang, Dongdong Wang, Jiajia Zhou, and Qianwang Chen. ACS Appl. Mater. Interfaces: February 16, 2015
  • Hollow Iron Oxide Nanoparticles in Polymer Nanobeads as MRI Contrast Agents. Nadja C Bigall, Enrico Dilena, Dirk Dorfs, Marie-Lys Beoutis, Giammarino Pugliese, Claire Wilhelm, Florence Gazeau, Abid Ali Khan, Alexander M Bittner, Miguel Angel Garcia, Mar Garcia-Hernandez, Liberato Manna, and Teresa Pellegrino. J. Phys. Chem. C: February 16, 2015
  • Stable isotopes and iron oxide mineral products as markers of chemodenitrification. L Camille Jones, Brian Peters, Juan S. Lezama Pacheco, Karen Casciotti, and Scott Fendorf. Environ. Sci. Technol.: February 16, 2015
  • Preparation of Unsupported Iron Fischer-Tropsch Catalyst by Simple, Novel, Solvent Deficient Precipitation (SDP) Method. Kyle M. Brunner, Grant E. Harper, Kamyar Keyvanloo, Brian F. Woodfield, Calvin H. Bartholomew, and William C. Hecker. Energy Fuels: February 15, 2015
  • Manganese Doped Iron Oxide Theranostic Nanoparticles for Combined T1 Magnetic Resonance Imaging and Photothermal Therapy. Mengxin Zhang, Yuhua Cao, Lina Wang, Yufei Ma, Xiaolong Tu, and Zhijun Zhang. ACS Appl. Mater. Interfaces: February 12, 2015
  • Iron- and Indium-Catalyzed Reactions toward Nitrogen- and Oxygen-Containing Saturated Heterocycles. Johan Cornil, Laurine Gonnard, Charlélie Bensoussan, Anna Serra-Muns, Christian Gnamm, Claude Commandeur, Malgorzata Commandeur, Sébastien Reymond, Amandine Guérinot, and Janine Cossy. Acc. Chem. Res.: February 12, 2015
  • Unraveling the structure of Iron(III)oxalate tetrahydrate and its reversible Li insertion capability. Hania Ahouari, Gwenaelle Rousse, Juan Jose Rodriguez-Carvajal, Moulay Tahar Sougrati, Matthieu Saubanère, Matthieu Courty, Nadir Recham, and Jean-Marie Tarascon. Chem. Mater.: February 12, 2015
  • Role of Surface Chemistry and Morphology in Reactive Adsorption Of H2S on Iron (Hydr)oxides/Graphite Oxide Composites. Javier A. Arcibar-Orozco, Rajiv Wallace, Joshua K. Mitchell, and Teresa J Bandosz. Langmuir: February 12, 2015
  • Surface and Interfacial Engineering of Iron Oxide Nanoplates for Highly Efficient Magnetic Resonance Angiography. Zijian Zhou, Changqiang Wu, Hanyu Liu, Xianglong Zhu, Zhenghuan Zhao, Lirong Wang, Ye Xu, Hua Ai, and Jinhao Gao. ACS Nano: February 11, 2015

Recent Research & Development for Titanates

  • Bottom-up synthesis of titanate nanosheets and their morphology change by the addition of organic ligands and dialysis. Takayuki Ban, Takuya Nakagawa, and Yutaka Ohya. Crystal Growth & Design: February 16, 2015
  • Macroporous Titanate Nanotube/TiO2 Monolith for Fast and Large-Capacity Cation Exchange. Kenji Okada, Genki Asakura, Yasuaki Tokudome, Atsushi Nakahira, and Masahide Takahashi. Chem. Mater.: February 9, 2015
  • Synergistic Effect of Titanate-Anatase Heterostructure and Hydrogenation-Induced Surface Disorder on Photocatalytic Water Splitting. Jinmeng Cai, Yingming Zhu, Dongsheng Liu, Ming Meng, Zhenpeng Hu, and Zheng Jiang. ACS Catal.: February 6, 2015
  • The Electrorheological Behavior of Suspensions Based on Molten-Salt Synthesized Lithium Titanate Nanoparticles and Their Core–Shell Titanate/Urea Analogues. T. Plachy, M. Mrlik, Z. Kozakova, P. Suly, M. Sedlacik, V. Pavlinek, and I. Kuritka. ACS Appl. Mater. Interfaces: January 29, 2015
  • Artificial Photosynthesis of C1–C3 Hydrocarbons from Water and CO2 on Titanate Nanotubes Decorated with Nanoparticle Elemental Copper and CdS Quantum Dots. Hyunwoong Park, Hsin-Hung Ou, Agustín J. Colussi, and Michael R. Hoffmann. J. Phys. Chem. A: January 22, 2015
  • Tuning the Aggregation of Titanate Nanowires in Aqueous Dispersions. Tamás Szabó, Viktor Tóth, Endre Horváth, László Forró, and Istvan Szilagyi. Langmuir: December 19, 2014
  • Formation of Layer-by-Layer Assembled Titanate Nanotubes Filled Coating on Flexible Polyurethane Foam with Improved Flame Retardant and Smoke Suppression Properties. Haifeng Pan, Wei Wang, Ying Pan, Lei Song, Yuan Hu, and Kim Meow Liew. ACS Appl. Mater. Interfaces: December 12, 2014
  • A Joint Theoretical and Experimental Study of Phase Equilibria and Evolution in Pt-Doped Calcium Titanate under Redox Conditions. Baihai Li, Michael B. Katz, Yingwen Duan, Xianfeng Du, Kui Zhang, Liang Chen, Anton Van der Ven, George W. Graham, and Xiaoqing Pan. Chem. Mater.: December 4, 2014
  • Photodegradation of Imidacloprid Insecticide by Ag-Deposited Titanate Nanotubes: A Study of Intermediates and Their Reaction Pathways. Inderpreet Singh Grover, Satnam Singh, and Bonamali Pal. J. Agric. Food Chem.: December 2, 2014
  • Imaging the Evolution of d States at a Strontium Titanate Surface. Ikutaro Hamada, Ryota Shimizu, Takeo Ohsawa, Katsuya Iwaya, Tomihiro Hashizume, Masaru Tsukada, Kazuto Akagi, and Taro Hitosugi. J. Am. Chem. Soc.: November 27, 2014