Dysprosium Compound

About Dysprosium Compounds

Stanford Advanced Materials (SAM) supplies dysprosium compounds that comply with strict industry standards. Dysprosium oxide (Dy2O3), also known as Dysprosia, is combined with nickel and incorporated into a specialised cement used to cool nuclear reactor rods.
Other dysprosium compounds include dysprosium fluoride (DyF3), dysprosium iodide (DyI3) and dysprosium sulphate (Dy2(SO4)3).
Dysprosium is alloyed with vanadium and other elements for the manufacture of laser materials and commercial lighting.
Nanofibres of dysprosium compounds exhibit high tensile strength and a large surface area. Consequently, they may be used to reinforce other materials and act as catalysts.

Key Advantages:

Diverse Range: Our collection of dysprosium compounds covers a wide range of forms and compositions designed to meet specific requirements. From powders and solutions to customised compounds, we provide options that align with your project specifications.

Distinct Properties: Dysprosium compounds are recognised for their magnetic, optical and catalytic properties. These properties are used in sectors that require precise performance and functionality.

Precision Manufacturing: Our dysprosium compounds are manufactured using advanced production techniques. This method ensures consistent material properties and reliable design and fabrication.

Customised Solutions: Collaborate with us to develop dysprosium compounds that match your project requirements exactly. Whether specific compositions or particular forms are required, we offer compounds that meet your objectives.

Versatile Applications:

Magnets and Electronics: Dysprosium compounds are used in the manufacture of high-performance magnets, sensors and electronic devices.

Catalysis: Dysprosium compounds serve to accelerate chemical reactions and improve process efficiency.

Optical Devices: Dysprosium compounds are employed in optical applications, including lasers, phosphors and light-emitting devices. They contribute to improved precision and performance in these devices.

Energy Technologies: Dysprosium compounds support energy-related applications such as fuel cells and renewable energy systems, given their magnetic and catalytic properties.

Medical Imaging: Dysprosium compounds are utilised in medical imaging technologies such as magnetic resonance imaging (MRI). They enhance imaging accuracy in healthcare.

Why Choose Our Dysprosium Compounds?

Quality Assurance: Our dysprosium compounds undergo rigorous quality controls. These tests ensure that the materials comply with industry standards for purity and performance.

Expertise: Our experience in the synthesis and application of these compounds informs our production methods. Our team is available to support the development of suitable solutions for your projects.

Customised Solutions: We offer collaboration to develop dysprosium compounds tailored to specific project goals.

Reliability: We have a proven record of delivering materials that meet defined industry standards. This reliability makes us a trusted source for dysprosium compounds that satisfy project specifications.