ELEMENT PORTFOLIO
Avalon's Strategic Position in the Periodic Table
This interactive periodic table showcases the elements currently in Avalon’s project portfolio. Each highlighted element represents a critical material with growing importance to clean energy, technology, and defense sectors. Click on the highlighted elements to explore their potential and importance in our future.
Neodymium and Praseodymium (NdPr)
Neodymium and Praseodymium are used to create the strongest rare earth magnets, enabling the conversion of electrical energy into motion through permanent-magnet motors. These powerful motors drive electric vehicles and a wide range of industrial applications.
Lithium (Li)
Lithium’s unique chemical properties make it one of the most versatile and in-demand elements today. Its critical role in rechargeable lithium-ion batteries has made it a cornerstone of modern technology, powering everything from mobile phones to electric vehicles and grid-scale energy storage. Lithium is also used in the production of specialty glass and ceramics, offering strength and thermal resistance. Beyond industrial uses, lithium compounds have proven essential in medicine, particularly as mood stabilizers for treating mental health conditions such as bipolar disorder.
Rubidium (Rb)
Rubidium is used in atomic clocks for ultra-precise timekeeping and in photocells that convert light into electricity. In healthcare, the isotope Rb-82 is used in PET and MRI scans to assess blood flow in the heart, helping diagnose conditions like ischemia.
Yttrium (Y)
Yttrium plays a vital role in advanced technologies that power the modern world. It is essential for high-performance LED displays and consumer electronics, widely used in targeted cancer therapies through Yttrium-90, and forms the backbone of superconducting materials in MRI machines and next-gen transportation like maglev trains.
Zirconium (Zr)
Zirconium plays a critical role in both advanced technology and healthcare. Its exceptional resistance to corrosion, high melting point, and biocompatibility make it a go-to material for nuclear reactors, surgical instruments, and medical implants.
Niobium (Nb)
Niobium is a high-performance metal essential to modern infrastructure and technology. Its ability to strengthen steel makes it a critical additive in high-strength, low-alloy (HSLA) steels used in automotive manufacturing, pipelines, and construction. In aerospace, niobium-based alloys withstand extreme temperatures in jet engines and heat shields. Its biocompatibility supports use in surgical and dental implants, while its superconducting properties enable advanced medical imaging technologies like MRI.
Cesium (Cs)
Cesium is best known for its role in atomic clocks, which enable precise timekeeping essential for GPS, telecommunications, and global time standards. In medicine, cesium-137 is used in radiation therapy for targeted cancer treatment. Industrially, cesium formate serves as a high-performance drilling fluid, stabilizing high-pressure oil and gas wells. These applications showcase cesium’s importance across science, healthcare, and energy sectors.
Tantalum (Ta)
Tantalum is a critical metal known for its strength, stability, and corrosion resistance. It's widely used in electronics for high-performance capacitors found in smartphones and medical devices. In the aerospace and defense sectors, tantalum is a key component in heat-resistant superalloys. Its biocompatibility also makes it ideal for surgical implants and specialized medical equipment, reinforcing its value across essential and high-growth industries.
Lanthanum (La)
Lanthanum plays a key role in automotive and imaging technologies. It enhances corrosion resistance in EV batteries, improves efficiency in petroleum refining, and supports advanced treatments for lenses and optical systems.
Cerium (Ce)
Cerium is essential to modern clean technologies—used in catalytic converters to reduce vehicle emissions, in LED lighting to enhance energy efficiency, and in alloys and glass polishing for high-performance industrial applications.
Neodymium and Praseodymium (NdPr)
Neodymium and Praseodymium are used to create the strongest rare earth magnets, enabling the conversion of electrical energy into motion through permanent-magnet motors. These powerful motors drive electric vehicles and a wide range of industrial applications.
Samarium (Sm)
Samarium is best known for its use in high-performance samarium-cobalt (SmCo) magnets, valued for their strength, stability at high temperatures, and resistance to demagnetization. These magnets are essential in aerospace, defense, and advanced electric motors. Samarium also plays a role in cancer treatment and nuclear reactor control systems, showcasing its value across both high-tech and medical sectors.
Europium (Eu)
Europium's fluorescent properties make it essential in high-tech applications. It is a key component in flat-panel displays and LEDs, enhancing color quality and efficiency. In healthcare, its luminescence powers advanced diagnostic tools like time-resolved fluorescence assays, enabling highly sensitive detection of biological markers.
Gadolinium (Gd)
Gadolinium is vital in medical imaging, used in MRI contrast agents for clearer diagnostics. Its ability to absorb neutrons makes it key for nuclear reactor shielding, and it also supports high-performance alloys in aerospace and electronics.
Terbium (Tb)
Terbium is essential in both technology and healthcare. It is widely used in flat-panel displays and LEDs for its bright green phosphors, and its luminescent properties enhance the performance of medical X-ray detectors and imaging systems.
Dysprosium (Dy)
Dysprosium plays a critical role in several high-tech and clean energy applications. It is most notably used in permanent magnets, where it's alloyed with neodymium to increase resistance to demagnetization—an essential property for electric vehicle motors and wind turbine generators. Its high neutron absorption also makes it essential for control rods in nuclear reactors, ensuring safe and efficient energy regulation.
Holmium (Ho)
Holmium is known for its exceptional magnetic strength and critical role in modern medicine. It is used in high-performance magnets found in MRI machines, wind turbines, and electric vehicles. Holmium lasers are widely applied in minimally invasive surgeries, including kidney stone removal and joint procedures. Additionally, Holmium-166 isotopes are used in advanced cancer treatments, showcasing its growing importance in targeted radiotherapy.
Erbium (Er)
Erbium plays a key role in modern technology, particularly in fiber optic communications where it amplifies signals over long distances. Its precision and safety also make it ideal for medical lasers used in dermatology and dentistry. Additionally, erbium is used in nuclear reactor control rods and to produce vibrant pink hues in specialty glass and ceramics.
Thulium (Tm)
Thulium plays a specialized yet important role in modern technology. It is used in portable X-ray devices that operate without electricity, making them valuable in remote and emergency settings. Thulium also powers solid-state lasers for use in advanced medical, industrial, and defense applications. Additionally, it is utilized in optical fiber amplifiers, enhancing long-distance data transmission across global telecommunications networks.
Ytterbium (Yb)
Ytterbium plays a vital role in high-tech and precision-driven industries. It's used to enhance the performance of high-power lasers for industrial cutting and welding, and to amplify optical signals in advanced telecommunications systems. Ytterbium is also a key component in some of the world’s most precise atomic clocks, supporting cutting-edge scientific research and next-generation navigation technologies.
Lutetium (Lu)
Lutetium plays a critical role in several high-impact industries. It is used as a catalyst in petroleum cracking, helping convert heavy hydrocarbons into valuable fuels like gasoline. In medical imaging, lutetium-based crystals (LSO and LYSO) are essential for producing high-resolution images in PET scans. Additionally, lutetium compounds are used in LED technology to enhance brightness and color accuracy in lighting and display systems.
