24670-07-3 Usage
Description
Dysprosium Oxalate is a white crystalline compound with the chemical formula Dy2(C2O4)3. It is a derivative of dysprosium, a rare earth element, and oxalic acid. DYSPROSIUM OXALATE is known for its unique chemical and physical properties, making it suitable for various applications across different industries.
Uses
Used in Ceramics Industry:
Dysprosium Oxalate is used as a specialty material for enhancing the properties of ceramics. Its incorporation into ceramic formulations improves the strength, durability, and thermal stability of the final product.
Used in Glass Industry:
In the glass industry, Dysprosium Oxalate is used as an additive to modify the physical and chemical properties of glass. It can improve the glass's resistance to thermal shock, increase its refractive index, and enhance its optical properties.
Used in Phosphors:
Dysprosium Oxalate is used as a key component in the production of phosphors, which are materials that emit light when exposed to radiation. Its unique properties make it suitable for use in various lighting applications, such as fluorescent lamps and LED lights.
Used in Laser Industry:
Dysprosium Oxalate is utilized in the laser industry due to its ability to enhance the performance of laser systems. It can improve the efficiency, power, and stability of lasers, making it an essential component in various applications, including medical, industrial, and scientific uses.
Used in Dysprosium Metal Halide Lamps:
Dysprosium Oxalate is used in the production of dysprosium metal halide lamps, which are high-intensity lighting sources. These lamps offer better color rendering, higher efficiency, and longer life compared to traditional lighting sources.
Used in Electronics Industry:
In the electronics industry, high purity Dysprosium Oxalate is used as an antireflection coating in photoelectric devices. This application helps to reduce glare and improve the clarity and performance of these devices.
Used in Catalysts:
Dysprosium Oxalate is also used as a catalyst in various chemical reactions, thanks to its unique chemical properties. It can help increase the efficiency and selectivity of these reactions, making it a valuable component in the production of various chemicals and materials.
Used in Electronic Ceramics:
Dysprosium Oxalate is employed in the development of electronic ceramics, which are materials that exhibit unique electrical and magnetic properties. These ceramics are used in a wide range of applications, including sensors, actuators, and electronic components.
Check Digit Verification of cas no
The CAS Registry Mumber 24670-07-3 includes 8 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 5 digits, 2,4,6,7 and 0 respectively; the second part has 2 digits, 0 and 7 respectively.
Calculate Digit Verification of CAS Registry Number 24670-07:
(7*2)+(6*4)+(5*6)+(4*7)+(3*0)+(2*0)+(1*7)=103
103 % 10 = 3
So 24670-07-3 is a valid CAS Registry Number.
InChI:InChI=1/3C2H2O4.2Dy.10H2O/c3*3-1(4)2(5)6;;;;;;;;;;;;/h3*(H,3,4)(H,5,6);;;10*1H2/q;;;2*+3;;;;;;;;;;/p-6
24670-07-3Relevant articles and documents
Self-assembled light lanthanide oxalate architecture with controlled morphology, characterization, growing mechanism and optical property
He, Hongmei,Zhang, Youjin,Zhu, Wei,Zheng, Ao
, p. 1546 - 1552 (2011/10/01)
Flower-like Sm2(C2O4)3· 10H2O had been synthesized by a facile complex agent assisted precipitation method. The flower-like Sm2(C2O 4)3·10H2O was characterized by X-ray diffraction, X-ray photoelectron spectroscopy, Fourier transform infrared spectroscopy, field-emission scanning electron microscopy, thermogravimetry- differential thermal analysis and photoluminescence. The possible growth mechanism of the flower-like Sm2(C2O4) 3·10H2O was proposed. To extend this method, other Ln2(C2O4)3·nH2O (Ln = Gd, Dy, Lu, Y) with different morphologies also had been prepared by adjusting different rare earth precursors. Further studies revealed that besides the reaction conditions and the additive amount of complex agents, the morphologies of the as-synthesised lanthanide oxalates were also determined by the rare earth ions. The Sm2(C2O4) 3·10H2O and Sm2O3 samples exhibited different photoluminescence spectra, which was relevant to Sm 3+ energy level structure of 4f electrons. The method may be applied in the synthesis of other lanthanide compounds, and the work could explore the potential optical materials.