Strontium Carbonate Nanoparticles (SrCO3, APS: 80-100nm, Purity: 99%)

Strontium Carbonate Nanoparticles

Product: Strontium Carbonate Nanoparticles (SrCO3, APS: 80-100nm, Purity: 99%)

Quality Control: Each lot of NANOSHEL Strontium Carbonate Nanoparticles was tested successfully.

Strontium Carbonate Nanoparticles

SEM – SrCO3 Nanopowder

SrCO3 Nanopowder

Particles Size Analysis – Strontium Carbonate Nanoparticles

Material Strontium Carbonate Nanoparticles
Stock No NS6130-02-213
CAS 1633-05-2 Confirm
APS 80-100nm Confirm
Purity 99% Confirm
Molecular Formula SrCO3 Confirm
Molecular Weight 147.63 g/mol Confirm
True Density 3.7 g/cm³ Confirm
Melting Point 1290 °C Confirm
Appearance White Powder Confirm
Bulk Density 0.95 g/cm³ Confirm
Solubility in water 0.0011 g/100 mL
Solubility Soluble in ammonium chloride, Slightly soluble in ammonia
Available Quantities 25Gms, 50Gms, 100Gms and larger quantities
Main Inspect Verifier Manager QC
Typical Chemical Analysis

BaCO3 <0.1%
CaCO3 <0.01%
MgCO3 <0.01%
Fe2O3 <0.003 %
Na2O  <0.01%
K2O  <0.01%
Cl <0.01%
SO4+  <0.01%
NO3 <0.02%
Moisture <0.01%
All Other Metal <0.01%

Experts Review:

58496396Dr. Bruce Perrault, Ph.D (Georgia Institute of Technology (Georgia Tech), USA)
Nanoparticles are not solely a product of modern technology, but are also created by natural processes such as volcano eruptions or forest fires. Naturally occurring nanoparticles also include ultrafine sand grains of mineral origin (e.g. oxides, carbonates). A decisive feature that makes nanoparticles technically interesting is their surface-to-volume ratio. This ratio increases with decreasing particle diameter.


1252525Dr. Myron Rubenstein, Ph.D (Polytechnic University of Turin, Italy)
Nanoparticles of a metal compound, e.g., a metal oxide, a doped metal compound, and a metal complex, are widely used in the fields of chemical catalysts, optoelectronic materials, optical materials, sensor materials, flame retardant materials, electrode materials and others. Such nanoparticles are provided in various shapes which include, e.g., spherical particles, nanofibers, and nanosheets having enhanced surface activity.


2536582Dr. Huojin Chan (University of Science and Technology of China, Hefei, Anhui, China)
Metal compounds are extensively used as flame retardants; their key advantage consists in that no toxic combustion products are released during combustion and exploitation of the composite.  Most of metal-containing flame retardants are effective smoke suppressants.


10604509_1459864657612760_2405225879143508610_oDr. Ms. Yi Yen Shi, (King Mongkut’s University of Technology Thonburi,Bangkok, Thailand)
Metal compound nanoparticles act by forming dense protective surface layers and by increasing the yield of carbonaceous residue. Therefore, the following flammability characteristics of polymer materials are essential for assessment of their flame-retardant performance: burning rate to be determined in accordance with, coke number, temperature and rate of mass loss, and other.


125448Dr. Hans Roelofs Ph.D (National Technical University of Athens, Greece)
Metal compounds are often used as synergistic additives to other types of flame retardants.  Metal compounds of transition metals are of particular interest because of their structural, spectral and chemical properties are often strongly dependant on the nature of the ligand structure.


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