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Lutetium Oxide Nanoparticle Dispersion

Lutetium Oxide Nanodispersion

CAS #:

Linear Formula:

Lu2O3

MDL Number:

MFCD00011100

EC No.:

234-764-3

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PRODUCT Product Code ORDER SAFETY DATA TECHNICAL DATA
Lutetium Oxide Nanoparticle Dispersion
LU-OX-01-NPD
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Lutetium Oxide Nanoparticle Dispersion Properties

Compound Formula

Lu2O3

Molecular Weight

397.93

Appearance

Liquid

Melting Point

Varies by solvent

Boiling Point

Varies by solvent

Density

Varies by solvent

Exact Mass

397.866

Monoisotopic Mass

397.866

Lutetium Oxide Nanoparticle Dispersion Health & Safety Information

Signal Word Warning
Hazard Statements N/A
Hazard Codes Xi
Precautionary Statements P261-P305 + P351 + P338
Risk Codes 36/37/38
Safety Statements 26-36
RTECS Number NONH
Transport Information NONH
WGK Germany 3
GHS Pictograms
MSDS / SDS

About Lutetium Oxide Nanoparticle Dispersion

Lutetium Oxide Nanoparticle Dispersions are suspensions of lutetium 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.

Lutetium Oxide Nanoparticle Dispersion Synonyms

Cassiopeium oxide, Dilutetium trioxide

Lutetium Oxide Nanoparticle Dispersion Chemical Identifiers

Linear Formula

Lu2O3

Pubchem CID

24852190

MDL Number

MFCD00011100

EC No.

234-764-3

Beilstein Registry No.

N/A

IUPAC Name

lutetium(3+); oxygen(2-)

SMILES

[Lu+3].[Lu+3].[O-2].[O-2].[O-2]

InchI Identifier

InChI=1S/2Lu.3O/q2*+3;3*-2

InchI Key

UGBIHFMRUDAMBY-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 Lutetium products. Lutetium (atomic symbol: Lu, atomic number: 71) is a Block F, Group 3, Period 6 element with an atomic weight of 174.9668. The number of electrons in each of Lutetium's shells is [2, 8, 18, 32, 9, 2] and its electron configuration is [Xe] 4f15 5d1 6s2.Lutetium Bohr Model In its elemental form, lutetium has a silvery-white appearance. The lutetium atom has a radius of 174 pm and a Van der Waals radius of 221 pm. Lutetium was discovered and first isolated by Georges Urbain, Carl Auer von Welsbach and Charles James in 1906, all independently of each other.Elemental Lutetium Urbain was awarded the naming honor because he published his findings first. Lutetium is the last member of the rare earth series. Unlike most rare earths it lacks a magnetic moment. It has the smallest metallic radius of any rare earth and it is perhaps the least naturally abundant of the lanthanides. The most common source of commercially produced lutetium is the mineral monazite. The name lutetium originates from the Latin word Lutetia, meaning Paris. Lutetium is found with almost all other rare earth metals, but it never occurs naturally by itself.

Recent Research

A novel glucose sensor using lutetium phthalocyanine as redox mediator in reduced graphene oxide conducting polymer multifunctional hydrogel., Al-Sagur, H, Komathi S, Khan M A., Gurek A G., and Hassan A , Biosens Bioelectron, 2017 Jun 15, Volume 92, p.638-645, (2017)

One-step synthesis of porous copper oxide for electrochemical sensing of acetylsalicylic acid in the real sample., Sivakumar, Mani, Sakthivel Mani, Chen Shen-Ming, Cheng Yi-Hui, and Pandi Karuppiah , J Colloid Interface Sci, 2017 Sep 01, Volume 501, p.350-356, (2017)

Study on dynamic properties of the photoexcited charge carriers at anatase TiO2 nanowires/fluorine doped tin oxide interface., Qiu, Qingqing, Xu Lingling, Wang Dejun, Lin Yanhong, and Xie Tengfeng , J Colloid Interface Sci, 2017 Sep 01, Volume 501, p.273-281, (2017)

Synthesis and loading-dependent characteristics of nitrogen-doped graphene foam/carbon nanotube/manganese oxide ternary composite electrodes for high performance supercapacitors., Cheng, Tao, Yu Baozhi, Cao Linli, Tan Huiyun, Li Xinghua, Zheng Xinliang, Li Weilong, Ren Zhaoyu, and Bai Jinbo , J Colloid Interface Sci, 2017 Sep 01, Volume 501, p.1-10, (2017)

SBA-15 templating synthesis of mesoporous bismuth oxide for selective removal of iodide., Zhang, Liping, and Jaroniec Mietek , J Colloid Interface Sci, 2017 Sep 01, Volume 501, p.248-255, (2017)

Cysteamine- and graphene oxide-mediated copper nanoparticle decoration on reverse osmosis membrane for enhanced anti-microbial performance., Ma, Wen, Soroush Adel, Luong Tran Van Anh, and Rahaman Md Saifur , J Colloid Interface Sci, 2017 Sep 01, Volume 501, p.330-340, (2017)

Using reduced graphene oxide-Ca:CdSe nanocomposite to enhance photoelectrochemical activity of gold nanoparticles functionalized tungsten oxide for highly sensitive prostate specific antigen detection., Wang, Xueping, Xu Rui, Sun Xu, Wang Yaoguang, Ren Xiang, Du Bin, Wu Dan, and Wei Qin , Biosens Bioelectron, 2017 Oct 15, Volume 96, p.239-245, (2017)

Aligned copper nanowires as a cut-and-paste exclusive electrochemical transducer for free-enzyme highly selective quantification of intracellular hydrogen peroxide in cisplatin-treated cells., García-Carmona, Laura, Moreno-Guzmán María, Martín Aida, Martínez Selma Benito, Fernández-Martínez Ana B., González María Cristina, Lucio-Cazaña Javier, and Escarpa Alberto , Biosens Bioelectron, 2017 Oct 15, Volume 96, p.146-151, (2017)

Bio-sensing applications of cerium oxide nanoparticles: Advantages and disadvantages., Charbgoo, Fahimeh, Ramezani Mohammad, and Darroudi Majid , Biosens Bioelectron, 2017 Oct 15, Volume 96, p.33-43, (2017)

Facile hydrothermal synthesis of urchin-like cobalt manganese spinel for high-performance supercapacitor applications., Venkateswarlu, Pamidi, Umeshbabu Ediga, U Kumar Naveen, Nagaraja Pernapati, Tirupathi Patri, G Rao Ranga, and Justin Ponniah , J Colloid Interface Sci, 2017 Oct 01, Volume 503, p.17-27, (2017)

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June 23, 2017
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