Lutetium oxide price November 2024 and outlook (see chart below)

  • Northeast Asia:US$756.72/KG, 0.4% up

Business Analytiq assumes no responsibility or liability for any errors or omissions in the content of this site. The information contained in this site is provided on an “as is” basis with no guarantees of completeness, accuracy, usefulness, or timeliness.

Lutetium oxide price index

This post is a summary of the Lutetium oxide price developments. The price developments of Lutetium oxide are expressed in US$ prices converted FX rates applicable at the time when the price was valid. Lutetium oxide price index developments are calculated from multiple separate sources of data to ensure statistical accuracy.

The outlook for Lutetium oxide prices, on the second tab, is generated from different inputs including:

  • Very recent price developments of immediate cost drivers of Lutetium oxide prices
  • Recent price developments of underlying feedstocks which drive the price of Lutetium oxide
  • Market futures for both cost drives and feedstocks of Lutetium oxide prices
  • Adjustment of current supply/demand imbalances in the Lutetium oxide market
  • Longer term trends in likely demand conditions

Further information on the Lutetium oxide price index

 

What is Lutetium oxide

Lutetium oxide (Lu2O3) is a chemical compound composed of lutetium and oxygen. It is a white to light yellow solid at room temperature and is insoluble in water. Lutetium oxide is one of the most common forms of lutetium compounds and possesses several key properties:

Optical Properties

Lutetium oxide exhibits interesting optical properties, including its ability to absorb and emit light in the ultraviolet (UV), visible, and near-infrared regions of the electromagnetic spectrum. This property makes it valuable in various optical applications, such as phosphors, optical coatings, and specialty glasses.

Dielectric Properties

Lutetium oxide can serve as a dielectric material in capacitors and other electronic devices. It offers high dielectric constant and low electrical conductivity, making it suitable for insulating layers in integrated circuits, thin-film transistors, and memory devices.

Thermal Stability

Lutetium oxide exhibits excellent thermal stability, retaining its structural integrity at high temperatures. This property makes it suitable for use in high-temperature applications such as thermal barrier coatings, refractory materials, and ceramic components.

Scintillation Properties

Lutetium oxide-based scintillation materials are used in radiation detection and imaging devices due to their ability to emit light when exposed to ionizing radiation. Lutetium oxide scintillators are employed in medical imaging (such as positron emission tomography or PET), nuclear physics research, and homeland security applications.

Catalytic Properties

Lutetium oxide can act as a catalyst or catalyst support in certain chemical reactions, including oxidation, hydrogenation, and hydrocarbon reforming. Its catalytic activity depends on factors such as particle size, surface area, and crystal structure.

Biomedical Applications

Lutetium oxide nanoparticles have been investigated for various biomedical applications, including drug delivery systems, imaging contrast agents, and cancer therapy. Their unique optical and magnetic properties make them potentially useful in targeted drug delivery, magnetic resonance imaging (MRI), and photodynamic therapy.

High Refractive Index

Lutetium oxide has a relatively high refractive index, which makes it useful in optical coatings and specialty glasses for applications requiring high optical transparency and refractive index matching.

Overall, lutetium oxide’s combination of optical, dielectric, thermal, scintillation, and catalytic properties makes it valuable in a wide range of applications across optics, electronics, materials science, biomedical engineering, and radiation detection.

 

How is Lutetium oxide produced

Lutetium oxide is typically produced through several steps involving chemical synthesis. One common method for producing lutetium oxide involves the following steps:

Raw Material Preparation

The raw material for lutetium oxide production is typically lutetium-containing compounds, such as lutetium chloride, lutetium nitrate, or lutetium carbonate. These compounds can be synthesized or obtained from lutetium ores through mining and processing.

Lutetium Compound Synthesis

The first step involves converting the lutetium-containing compound into lutetium oxide. This conversion typically occurs through a process known as calcination, where the lutetium compound is heated in the presence of oxygen at high temperatures (typically above 1000°C). This process decomposes the compound and forms lutetium oxide.

Purification

The resulting lutetium oxide may undergo purification steps to remove any remaining impurities and improve its quality. Purification methods may include dissolution, precipitation, filtration, or chemical treatment to separate lutetium oxide from other elements or unwanted compounds.

Drying and Powdering

After purification, the lutetium oxide is dried to remove any residual moisture and then ground into a fine powder. This powder form is more convenient for handling and further processing.

Particle Size Control (Optional)

Depending on the desired application, the particle size of lutetium oxide may be controlled to meet specific requirements. Techniques such as milling, grinding, or precipitation may be employed to achieve the desired particle size distribution.

Characterization and Quality Control

The final lutetium oxide product is typically characterized using analytical techniques to ensure it meets the required specifications for purity, particle size, and other properties. Quality control measures may include chemical analysis, X-ray diffraction, and other methods.

Overall, the production of lutetium oxide involves a combination of chemical synthesis, purification, and particle size control steps to obtain the desired quality and form of the compound for various industrial and scientific applications.

 

What is Lutetium oxide used for

Lutetium oxide (Lu2O3) finds application in various industries and technologies due to its unique properties. Some common uses of lutetium oxide include:

Optical Devices

Lutetium oxide is utilized in the production of optical devices and components due to its interesting optical properties. It can be incorporated into infrared windows, lenses, and laser materials for applications in spectroscopy, thermal imaging, and laser technology.

Catalysis

Lutetium oxide can act as a catalyst or catalyst support in various chemical reactions, including oxidation, hydrogenation, and hydrocarbon reforming. Its catalytic activity can be utilized in processes such as industrial chemical synthesis, environmental remediation, and petrochemical refining.

Dielectric Materials

Lutetium oxide can serve as a dielectric material in capacitors and other electronic devices. It offers high dielectric constant and low electrical conductivity, making it suitable for insulating layers in integrated circuits, thin-film transistors, and memory devices.

Thermal Barrier Coatings

Due to its high thermal stability, lutetium oxide is used as a component in thermal barrier coatings for protecting metallic components in high-temperature environments, such as gas turbines, aerospace components, and industrial furnaces.

Biomedical Applications

Lutetium oxide nanoparticles have been investigated for various biomedical applications, including drug delivery systems, imaging contrast agents, and cancer therapy. Their unique optical and chemical properties make them potentially useful in targeted drug delivery, magnetic resonance imaging (MRI), and photodynamic therapy.

Laser Technology

Lutetium oxide is used as a host material in certain laser systems, particularly in solid-state lasers. It can be doped with other rare earth ions to produce laser emissions in various wavelengths, making it valuable in research, telecommunications, and military applications.

Overall, lutetium oxide’s versatility makes it valuable in a wide range of applications across optics, electronics, catalysis, aerospace, healthcare, and materials science.

 

How big is the global Lutetium oxide market

The main rare earth elements ranked in decreasing order of market size are:

Neodymium (Nd): Neodymium is often ranked as one of the most valuable rare earth elements due to its crucial role in the production of high-strength permanent magnets used in a wide range of applications, including electric vehicle motors and wind turbines.

Cerium (Ce): Cerium is among the most abundant rare earth elements and is used in various industrial applications, such as catalysts, glass polishing, and metallurgy.

Lanthanum (La): Lanthanum is used in catalysts, ceramics, optics, and as a component in certain types of batteries and fuel cells.

Dysprosium (Dy): Dysprosium is used to improve the high-temperature performance of neodymium-iron-boron magnets. It is essential for the growth of the clean energy and electric vehicle markets.

Praseodymium (Pr): Praseodymium is used in combination with neodymium to produce high-strength magnets. It is vital in the manufacture of electric vehicle motors and wind turbines.

Europium (Eu): Europium is primarily used in phosphors for color television tubes, LED lighting, and other display technologies.

Terbium (Tb): Terbium is used in phosphors for color television tubes, fluorescent lamps, and as an activator for green phosphors.

Yttrium (Y): Yttrium is not a lanthanide, but it is often grouped with rare earth elements. It is used in a variety of applications, including ceramics, superconductors, and phosphors.

It’s important to note that market rankings may change over time as new technologies and applications emerge and as supply and demand conditions evolve. The demand for rare earth elements is influenced by various industries, including electronics, automotive, renewable energy, and more. For the most current market information and rankings, it’s advisable to consult industry reports and market analysis from reputable sources

NEED A QUICK DOWNLOAD?

 

ACCESS TO OUR FULL DATABASE IS US$399/YEAR, WITH A 30-DAY $30 TRIAL

GET THAT DOWNLOAD IN 3 MINUTES!

BusinessAnalytiq provides a database of hundreds of market & price trend data, as well as online tools to set up benchmarks and leading indicators.

businessanalytiq

Where does the data come from?

  • The source of the data are exclusively public non-confidential sources. We have no access to primary data
  • This the index trend of the price trend of the "product category" in general, and not a single specification of the product in particular
  • The data is a combination of contract and spot pricing
  • Our algorithms are set up to eliminate significant product mix impact on the reported price
  • We combine public publications, import/export records, trading prices, company announcements, magazine articles, tweets, and other sources of ad-hoc public information.
  • The chart shows the our best approximation of the market trend based on our algorithm interpretation of the signals
  • For most indexes we have multiple sources and we focus on using statistically-correlated sources
  • As a function of our automation, it is likely that recent trends will be adjusted as we discover more information. So, for example, the price trend for February 2024 will be first calculated in February 2024 and adjusted in March, April and May 2024.
  • We will update the data trend as more information becomes available, and this means that recent trends will always be adjusted as we get more data available
  • The algorithm will regularly revise our understanding of market trends, and indicated market trends may change
  • The data is presented in US$. The UOM of measure is shown in the Index list table
  • Our automated software and we do our best to create an accurate representation of the trend

 

Where does the data NOT come from?

  • We do not purchase data from any other source and republish it.
  • We will not purchase data from any other source and republish it
  • We do not extrapolate trends, even for the forecast. We look for other market signals and leading indicators

 

What data should our company use?

  • If you are making decisions driving significant share of profit, we always recommend that you buy data from the companies who invest in direct primary market access such as ICIS, amongst many others
  • Our data, at best, represents an estimate of the market trend based on public information
  • We have no direct access to the market, and we do not interview suppliers and customers
  • Our automated analysis tools in the online software are set up to combine our data with other sources of data
  • We do not recommend that you use our data for direct price mechanisms, as we may change and improve the data trends over time, including historical data

 

What does the quality indication in the main menu mean?

  • Quality level A: Data is from a reliable and confirmed source
  • Quality level B: Data is from multiple credible sources and there are no major statistical inconsistencies between them
  • Quality level C: Data is from multiple credible sources and there are some statistical inconsistencies between them
  • Quality level D: Data is from a single credible source, but we cannot verify the data
  • Quality level E: Data is either:
    • From a single source, which we consider reliable, but we cannot verify the data.
    • From 2 or more sources which have some periods of contradicting trends.
  • Quality level F: Data is from a single source which we consider indicatively correct, but the data is anecdotal and we cannot verify the data.

 

What are the disclaimers?

  • We assume no responsibility or liability for any errors or omissions in the content of this site.
  • The information is provided on an “as is” basis with no guarantee of completeness, accuracy, usefulness, fitness for purpose or timeliness.
  • By their nature, outlooks are always uncertain

 

How often do we update the data?

  • We aim to update the data series on the 9th and 24th of each month (but we do not always make it for each chart)
  • The data for the current month and recent history are fine-tuned over time.

 

What are we doing to improve the data?

  • We are continually improving our data collection and processing methods
  • Pricing data will be updated from time to time as we improve the accuracy
  • We are reviewing all data sources in the first half of 2024.
    • There will be continuous fine-tuning of the trend and forecast algorithm as part of that.
    • The key focus in 2024 is to add many additional indexes

 

How can i give feedback on the data or request for new indexes

  • Feel free to contact us if you have a specific request. You can reach us via the Contact us page