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Antimony Oxide Nanoparticle Dispersion

Antimony Oxide Nanodispersion

CAS #:

Linear Formula:

Sb2O3

MDL Number:

MFCD00011214

EC No.:

215-175-0

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PRODUCT Product Code ORDER SAFETY DATA TECHNICAL DATA
Antimony Oxide Nanoparticle Dispersion
SB-OX-01-NPD
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Antimony Oxide Nanoparticle Dispersion Properties

Compound Formula

O3Sb2

Molecular Weight

291.52

Appearance

white solid

Melting Point

656 °C

Boiling Point

1425 °C (sublimes)

Density

5.2 g/cm3

Exact Mass

368.016 g/mol

Monoisotopic Mass

289.792388 Da

Antimony Oxide Nanoparticle Dispersion Health & Safety Information

Signal Word Warning
Hazard Statements H351
Hazard Codes Xn
Precautionary Statements P281
Risk Codes 40
Safety Statements 22-36/37
RTECS Number NONH
Transport Information NONH
WGK Germany 2
GHS Pictograms
MSDS / SDS

About Antimony Oxide Nanoparticle Dispersion

Antimony Oxide Nanoparticle Dispersions are suspensions of antimony oxide nanoparticles in water or various organic solvents such as ethanol or mineral oil. American Elements manufactures oxide nanopowders and nanoparticles with typical particle sizes ranging from 10 to 200nm and in coated and surface functionalized forms. Our nanodispersion and nanofluid experts can provide technical guidance for selecting the most appropriate particle size, solvent, and coating material for a given application. We can also produce custom nanomaterials tailored to the specific requirements of our customers upon request.

Antimony Oxide Nanoparticle Dispersion Synonyms

Antimony(III) Oxide, Antimony Trioxide, Dioxodistiboxane, Stibine oxide, triphenyl, Dioxodistiboxane, Antimony sesquioxide, Antimony White, Stibine oxide, triphenyl-, hydrate, Diantimony trioxide, Flowers of antimony, Triphenylantimony oxide, Oxo-oxostibanyloxystibane, Di(phenyl)stiborylbenzene, Triphenylstibine oxide, Triphenylantimony oxide

Antimony Oxide Nanoparticle Dispersion Chemical Identifiers

Linear Formula

Sb2O3

Pubchem CID

27652

MDL Number

MFCD00011214

EC No.

215-175-0

Beilstein Registry No.

N/A

IUPAC Name

Di(phenyl)stiborylbenzene

SMILES

O=[Sb]O[Sb]=O

InchI Identifier

InChI=1S/3O.2Sb

InchI Key

ADCOVFLJGNWWNZ-UHFFFAOYSA-N

Packaging Specifications

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 Safety Data Sheet (SDS). Solutions are packaged in polypropylene, plastic or glass jars up to palletized 440 gallon liquid totes, and 36,000 lb. tanker trucks.

Related Elements

See more Antimony products. Antimony (atomic symbol: Sb, atomic number: 51) is a Block P, Group 15, Period 5 element with an atomic radius of 121.760. Antimony Bohr Model The number of electrons in each of antimony's shells is 2, 8, 18, 18, 5 and its electron configuration is [Kr] 4d10 5s2 5p3. The antimony atom has a radius of 140 pm and a Van der Waals radius of 206 pm. Antimony was discovered around 3000 BC and first isolated by Vannoccio Biringuccio in 1540 AD. In its elemental form, antimony has a silvery lustrous gray appearance. Elemental Antimony The most common source of antimony is the sulfide mineral known as stibnite (Sb2S3), although it sometimes occurs natively as well. Antimony has numerous applications, most commonly in flame-retardant materials it also increases the hardness and strength of lead when combined in an alloy and is frequently employed as a dopant in semiconductor materials. Its name is derived from the Greek words anti and monos, meaning a metal not found by itself.

Recent Research

Effect of organic matter on mobilization of antimony from nanocrystalline titanium dioxide., Yang, Hailin, Lu Xiaofei, and He Mengchang , Environ Technol, 2017 May 17, p.1-26, (2017)

Insights into antimony adsorption on {001} TiO2: XAFS and DFT study., Yan, Li, Song Jiaying, Chan Ting-Shan, and Jing Chuanyong , Environ Sci Technol, 2017 May 17, (2017)

The potential DNA toxic changes among workers exposed to antimony trioxide., Shanawany, Safaa El, Foda Nermine, Hashad Doaa I., Salama Naglaa, and Sobh Zahraa , Environ Sci Pollut Res Int, 2017 May, Volume 24, Issue 13, p.12455-12461, (2017)

Uncovering the Thermo-Kinetic Origins of Phase Ordering in Mixed-Valence Antimony Tetroxide by First-Principles Modeling., Kim, Chang-Eun, Yoo Su-Hyun, Bahr David F., Stampfl Catherine, and Soon Aloysius , Inorg Chem, 2017 Jun 05, Volume 56, Issue 11, p.6545-6550, (2017)

Tracking Single DNA Nanodevices in Hierarchically Meso-Macroporous Antimony-Doped Tin Oxide Demonstrates Finite Confinement., Mieritz, Daniel G., Li Xiang, Volosin Alex M., Liu Minghui, Yan Hao, Walter Nils G., and Seo Dong-Kyun , Langmuir, 2017 Jun 02, (2017)

Organic ligand-induced dissolution kinetics of antimony trioxide., Hu, Xingyun, and He Mengchang , J Environ Sci (China), 2017 Jun, Volume 56, p.87-94, (2017)

Highly sensitive determination of antimony in food by resonance Rayleigh scattering-energy transfer between grapheme oxide and I3(.)., Wen, Guiqing, Zhang Xinghui, Li Yuan, Luo Yanghe, Liang Aihui, and Jiang Zhiliang , Food Chem, 2017 Jan 01, Volume 214, p.25-31, (2017)

Photocurrent Generation by Photosynthetic Purple Bacterial Reaction Centers Interfaced with a Porous Antimony-Doped Tin Oxide (ATO) Electrode., Carey, Anne-Marie, Zhang Haojie, Mieritz Daniel, Volosin Alex, Gardiner Alastair T., Cogdell Richard J., Yan Hao, Seo Dong-Kyun, Lin Su, and Woodbury Neal W. , ACS Appl Mater Interfaces, 2016 Sep 13, (2016)

3D Cathodes of Cupric Oxide Nanosheets Coated onto Macroporous Antimony-Doped Tin Oxide for Photoelectrochemical Water Splitting., Wang, Xu-Dong, Xu Yang-Fan, Chen Bai-Xue, Zhou Ning, Chen Hong-Yan, Bin Kuang Dai-, and Su Cheng-Yong , ChemSusChem, 2016 Oct 5, (2016)

Ultrafast Lithium Storage Using Antimony-Doped Tin Oxide Nanoparticles Sandwiched between Carbon Nanofibers and a Carbon Skin., An, Geon-Hyoung, Lee Do-Young, Lee Yu-Jin, and Ahn Hyo-Jin , ACS Appl Mater Interfaces, 2016 Oct 31, (2016)

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