Antimony Tin Oxide (ATO) Nanoparticles

Sb2SnO5

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SAFETY DATA TECHNICAL DATA
(2N) 99% Antimony Tin Oxide Nanoparticles SB-SNO-02-NP Pricing
(3N) 99.9% Antimony Tin Oxide Nanoparticles SB-SNO-03-NP Pricing
(4N) 99.99% Antimony Tin Oxide Nanoparticles SB-SNO-04-NP Pricing
(5N) 99.999% Antimony Tin Oxide Nanoparticles SB-SNO-05-NP Pricing

Properties

Molecular Weight 444.23
Appearance Blue Powder
Melting Point N/A
Boiling Point N/A
Density N/A
True Density 6.8 g/cm3
Bulk Density 0.95 g/cm3
Average Particle Size 15 nm
Size Range N/A
Crystal Phase / Structure Tetragonal
Morphology N/A

Health & Safety Info  |  MSDS / SDS

Signal Word Warning
Hazard Statements H315-H319
Hazard Codes N/A
Risk Codes 36/37/38
Safety Statements 26
RTECS Number N/A
Transport Information UN 1549 6.1/PG 3
WGK Germany 3
MSDS / SDS

About

Antimony Tin Oxide (ATO) Nanoparticles, nanopowder, nanodots or nanocrystals are spherical or faceted high surface area nanocrystalline alloy particles with magnetic properties. Nanoscale Antimony Tin Oxide (ATO) Particles are typically 20-40 nanometers (nm) with specific surface area (SSA) in the 30 - 50 m 2 /g range and also available in with an average particle size of 100 nm range with a specific surface area of approximately 7 m 2 /g. Nano Antimony Tin Oxide (ATO) Particles are also available in ultra high purity and high purity and coated and dispersed forms. They are also available as a nanofluid through the AE Nanofluid production group. Nanofluids are generally defined as suspended nanoparticles in solution either using surfactant or surface charge technology. Nanofluid dispersion and coating selection technical guidance is also available. Other nanostructures include nanorods, nanowhiskers, nanohorns, nanopyramids and other nanocomposites. Surface functionalized nanoparticles allow for the particles to be preferentially adsorbed at the surface interface using chemically bound polymers.

Synonyms

N/A

Chemical Identifiers

Formula Sb2SnO5
CAS N/A
Pubchem CID N/A
MDL MFCD00799153
EC No. N/A
IUPAC Name N/A
Beilstein Registry No. N/A
SMILES O=[Sn]=O.O=[Sb]O[Sb]=O
InchI Identifier InChI=1S/5O.2Sb.Sn
InchI Key DCEPJBOKQZTMOG-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 Products & Element Information

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.

Tin Bohr ModelSee more Tin products. Tin (atomic symbol: Sn, atomic number: 50) is a Block P, Group 14, Period 5 element with an atomic weight of 118.710. The number of electrons in each of tin's shells is 2, 8, 18, 18, 4 and its electron configuration is [Kr] 4d10 5s2 5p2. The tin atom has a radius of 140.5 pm and a Van der Waals radius of 217 pm.In its elemental form, tin has a silvery-gray metallic appearance. It is malleable, ductile and highly crystalline. High Purity (99.9999%) Tin (Sn) MetalTin has nine stable isotopes and 18 unstable isotopes. Under 3.72 degrees Kelvin, Tin becomes a superconductor. Applications for tin include soldering, plating, and such alloys as pewter. The first uses of tin can be dated to the Bronze Age around 3000 BC in which tin and copper were combined to make the alloy bronze. The origin of the word tin comes from the Latin word Stannum which translates to the Anglo-Saxon word tin. For more information on tin, including properties, safety data, research, and American Elements' catalog of tin products, visit the Tin element page.

Recent Research

Evaluation of antimony microparticles supported on biochar for application in the voltammetric determination of paraquat., Gevaerd, Ava, de Oliveira Paulo R., Mangrich Antonio S., Bergamini Márcio F., and Marcolino-Junior Luiz H. , Mater Sci Eng C Mater Biol Appl, 2016 May 1, Volume 62, p.123-9, (2016)

In vivo and in vitro effects of pentavalent antimony on mouse liver cytochrome P450s., Coelho, D R., De-Oliveira Acax, Parente Tem, Leal B S., Chagas L F. das, Oliveira T N., Saint'Pierre T D., and Paumgartten, jr F , Hum Exp Toxicol, 2016 Mar 4, (2016)

Effects of NO3 (-) and PO4 (3-) on the release of geogenic arsenic and antimony in agricultural wetland soil: a field and laboratory approach., Rouwane, Asmaa, Rabiet Marion, Grybos Malgorzata, Bernard Guillaume, and Guibaud Gilles , Environ Sci Pollut Res Int, 2016 Mar, Volume 23, Issue 5, p.4714-28, (2016)

Can antimonide-based nanowires form wurtzite crystal structure?, Ghalamestani, Sepideh Gorji, Lehmann Sebastian, and Dick Kimberly A. , Nanoscale, 2016 Jan 28, Volume 8, Issue 5, p.2778-86, (2016)

Antimony Nanocrystals Encapsulated in Carbon Microspheres Synthesized by a Facile Self-Catalyzing Solvothermal Method for High-Performance Sodium-Ion Battery Anodes., Qiu, Shen, Wu Xianyong, Xiao Lifen, Ai Xinping, Yang Hanxi, and Cao Yuliang , ACS Appl Mater Interfaces, 2016 Jan 20, Volume 8, Issue 2, p.1337-43, (2016)

Comparison of arsenic and antimony biogeochemical behavior in water, soil and tailings from Xikuangshan, China., Fu, Zhiyou, Wu Fengchang, Mo Changli, Deng Qiujing, Meng Wei, and Giesy John P. , Sci Total Environ, 2016 Jan 1, Volume 539, p.97-104, (2016)

Use of cloud-point preconcentration for spectrophotometric determination of trace amounts of antimony in biological and environmental samples., El-Sharjawy, Abdel-Azeem M., and Amin Alaa S. , Anal Biochem, 2016 Jan 1, Volume 492, p.1-7, (2016)

Tuberculosis transmission and risk factors in a Chinese antimony mining community., Chen, K-S, Liu T, Lin R-R, Peng Y-P, and Xiong G-C , Int J Tuberc Lung Dis, 2016 Jan, Volume 20, Issue 1, p.57-62, (2016)

A green synthesis route for the phase and size tunability of copper antimony sulfide nanocrystals with high yield., Chen, Keqiang, Zhou Jing, Chen Wen, Chen Qiao, Zhou Peng, and Liu Yueli , Nanoscale, 2016 Feb 25, Volume 8, Issue 9, p.5146-52, (2016)