12032-31-4

Basic information

• Product Name: MAGNESIUM ZIRCONATE
• Synonyms: magnesium zirconate(IV);MAGNESIUM ZIRCONIUM OXIDE;MAGNESIUM ZIRCONATE;zirconate(zro32-),magnesium(1:1);magnesium zirconium trioxide;MAGNESIUM ZIRCONIUM OXIDE 99.7% (METALS BASIS), 4 MICRON POWDER;Magnesiumzirconiumoxide,99.7%(metalsbasis);Magnesiumzirconiumoxide,99.7%metalsbasis
• CAS NO: 12032-31-4
• Molecular Formula: MgO3Zr
• Molecular Weight: 163.53
• EINECS: 234-768-5
• Product Categories: Ceramics;Metal and Ceramic Science;Zirconates
• Mol File: 12032-31-4.mol
• Article Data: 1

Chemical Properties

• Melting Point: 2060℃ [HAW93]
• Boiling Point: °Cat760mmHg
• Flash Point: °C
• Appearance: /powder
• Density: 4.230
• CAS DataBase Reference: MAGNESIUM ZIRCONATE(CAS DataBase Reference)
• NIST Chemistry Reference: MAGNESIUM ZIRCONATE(12032-31-4)
• EPA Substance Registry System: MAGNESIUM ZIRCONATE(12032-31-4)

Safety Data

• WGK Germany: 3
• Hazardous Substances Data: 12032-31-4(Hazardous Substances Data)

Usage

Chemical Properties

reacted product, -100 and +200 mesh of 99% purity; powder(s); used in electronics [CER91] [HAW93]

Uses

Electronics.

InChI:InChI=1/Mg.3O.Zr/q+2;;2*-1;/rMg.O3Zr/c;1-4(2)3/q+2;-2

Upstream product

• 7440-67-7 zirconium(IV) oxide 
• 7786-30-3 magnesium chloride 
• 142-72-3 magnesium acetate 

Related news

Biodiesel production using a novel heterogeneous catalyst, MAGNESIUM ZIRCONATE (cas 12032-31-4) (Mg2Zr5O12): Process optimization through response surface methodology (RSM)07/26/2019

A heterogeneous catalyst, magnesium zirconate (Mg2Zr5O12) was synthesized by co-precipitation and was used for biodiesel production via transesterification. Kusum oil was used as a feedstock. Catalyst characterization was accomplished by TGA, XRD, ATR FTIR, SEM, and EDX. The parameters viz. part...detailed

Relevant articles and documents

Determination of the Acid Strength of Binary Oxide Catalysts Using Temperature-Programmed Desorption of Pyridine

The temperature-programmed desorption of pyridine (Py-TPD) was performed for measuring the acid strength and acid amount of binary oxide catalysts. First, the optimum measurement conditions were determined by comparing the TPD spectra with the infrared spectra of adsorbed pyridine measured under the same conditions in order to minimize the shift in the desorption temperature and contribution of physically absorbed and/or weakly held pyridine. The following conditions were found to be optimum: purging at 423 K for 2 h, W/F (W, sample weight; F, flow rate of the carrier) of 100 mg/150 cm3 min-1, and a heating rate of 5 K min-1. This method was applied then to a series of binary mixed oxide catalysts. The amount of desorbed pyridine was 15-24% of the full coverage of pyridine on the catalyst surface with few exceptions. The highest acid strength, determined from the Py-TPD spectra, was well-correlated to that determined from a color change of Hammett indicators. The potential of the Py-TPD for determining the acid strength and the acid amount on binary oxide catalysts is discussed.