Thulium (Tm): Properties, Uses & Medical Laser Applications

June 12, 2024

Complete guide to thulium element: physical/chemical properties, medical laser surgery, nuclear applications, extraction, isotopes, safety & market trends.

Thulium

Thulium (Tm): Complete Guide to Properties, Uses, and Applications

Thulium (Tm) is a rare and fascinating lanthanide element with atomic number 69, known for its silvery-gray metallic appearance and remarkable applications in medical technology, portable X-ray devices, and high-temperature superconductors. Discovered in 1879 by Swedish chemist Per Teodor Cleve, thulium derives its name from "Thule," the ancient name for Scandinavia. Despite being one of the least abundant rare earth elements, thulium plays a crucial role in modern surgical lasers, nuclear technology, and advanced materials science.

General Information
Physical Properties
Chemical Properties and Reactivity
Electron Configuration and Oxidation States
Uses and Applications
Medical Applications in Detail
Occurrence and Extraction
Isotopes of Thulium
Safety and Handling
Discovery and Historical Significance
Additional Physical Properties
Market Trends and Global Supply
Comprehensive FAQ - 40 Questions Answered

General Information

Thulium is a member of the lanthanide series, occupying a unique position in the periodic table as one of the rarest naturally occurring rare earth elements. With an estimated abundance of only 0.5 parts per million in Earth's crust, thulium is approximately as rare as silver, yet its specialized properties make it invaluable in cutting-edge technologies.

Element Symbol

Atomic Number

Atomic Weight

168.93422 u

Element Category

Lanthanide (Rare Earth)

Group

Lanthanides series (f-block)

Period

Block

f-block

CAS Number

7440-30-4

Physical Properties

Thulium exhibits distinctive physical characteristics that make it both scientifically interesting and practically useful. As a relatively soft metal, thulium can be cut with a knife, yet it maintains structural integrity in demanding applications. The element's silvery-gray metallic appearance tarnishes slowly when exposed to air, forming a protective oxide layer.

Appearance

Silvery-gray metallic, soft and malleable

Density

9.32 g/cm³

Melting Point

1545 °C (2813 °F, 1818 K)

Boiling Point

1950 °C (3542 °F, 2223 K)

Phase at STP

Solid

Crystal Structure

Hexagonal close-packed (hcp)

Chemical Properties and Reactivity

Thulium demonstrates moderate reactivity, positioning it between highly reactive and noble metals. While relatively stable in dry air at room temperature, thulium gradually tarnishes when exposed to moisture and oxygen, forming thulium oxide on its surface. This protective oxide layer helps prevent further corrosion, similar to aluminum's behavior.

Reactivity Profile: Thulium reacts slowly with cold water and more vigorously with hot water, producing thulium hydroxide $\text{Tm(OH)}_3$ and hydrogen gas. When exposed to acids, thulium readily forms corresponding salts, making it useful in various chemical processes and research applications.

Common Thulium Compounds

Thulium forms several important compounds in its +3 oxidation state:

Thulium(III) oxide $\text{Tm}_2\text{O}_3$: A pale green compound used in ceramics and specialized glass applications
Thulium(III) chloride $\text{TmCl}_3$: Employed in chemical synthesis and as a precursor for other thulium compounds
Thulium(III) nitrate $\text{Tm(NO}_3\text{)}_3$: Utilized in research and analytical chemistry
Thulium(III) fluoride $\text{TmF}_3$: Important in optical applications and laser technology

Electron Configuration and Oxidation States

The electron configuration of thulium reveals its position as the thirteenth element in the lanthanide series:

Electron Configuration: [Xe] 4f¹³ 6s²

This configuration, with thirteen electrons in the 4f orbital, gives thulium its unique chemical and physical properties. The element's shell structure is 2, 8, 18, 31, 8, 2, reflecting the filling of electron orbitals from the nucleus outward.

Oxidation States: Thulium primarily exists in the +3 oxidation state, which is the most stable and common form in chemical compounds. The +2 oxidation state is also known but less common, occurring primarily in specialized chemical environments and research contexts.

Uses and Applications

Thulium's unique properties have led to diverse applications across multiple industries, from life-saving medical procedures to advanced nuclear technology. The element's market has experienced significant growth, with projections estimating expansion from USD 350 million in 2024 to USD 540 million by 2033, driven by increasing demand in high-tech sectors.

Medical Lasers and Surgical Applications Thulium-doped fiber lasers have revolutionized minimally invasive surgery, particularly in urology, dermatology, and cancer treatments. These lasers operate at wavelengths (1.75-2.22 μm) that are highly absorbed by water, enabling precise tissue cutting, vaporization, and coagulation with minimal bleeding and faster patient recovery times.
Portable X-ray Devices Thulium-170, a radioactive isotope, serves as an efficient X-ray source in portable medical imaging devices and security screening equipment. This application is particularly valuable in remote locations and emergency medical situations where traditional X-ray machines are impractical.
Nuclear Technology In nuclear reactors, thulium functions as an effective neutron absorber, helping control nuclear reactions and enhance reactor safety. This application leverages thulium's high neutron cross-section to regulate fission processes.
Ceramics and Phosphors Thulium is incorporated into specialized ceramic materials and phosphorescent compounds used in display technologies, lighting systems, and anti-counterfeiting measures on banknotes. Its ability to emit blue light upon excitation makes it valuable in flat-panel displays.
High-Temperature Superconductors Research into thulium-doped superconducting materials shows promise for next-generation energy transmission and computing systems, where materials must maintain superconductivity at relatively higher temperatures.
Fiber-Optic Communications Thulium-doped fiber amplifiers enhance signal transmission in fiber-optic networks, particularly for wavelengths used in telecommunications infrastructure.
Industrial Catalysts Thulium-based catalysts improve efficiency in hydrocracking and hydrotreating processes used in petroleum refining and chemical manufacturing.

Medical Applications in Detail

The medical sector represents the largest and fastest-growing market for thulium applications. Since its first documented surgical use in 2005, thulium laser technology has transformed multiple medical specialties through its superior precision and safety profile.

Thulium Laser Surgery Techniques

Modern thulium laser systems offer three primary surgical techniques, each tailored to specific clinical needs:

Vaporization

Heats tissue water to 100°C, causing cell evaporation. Ideal for precise tissue removal with minimal bleeding in procedures like benign prostatic hyperplasia (BPH) treatment.

Vaporesection

Combines vaporization with tissue fragment collection for pathological analysis, enabling both treatment and diagnostic capability in a single procedure.

Vapoenucleation

Delivers continuous energy for complete tissue enucleation regardless of volume, significantly reducing procedure time and complications in large-scale surgeries.

Medical Specialties Using Thulium Lasers

Urology: BPH treatment, bladder neck incisions, kidney stone fragmentation, and condyloma removal
General Surgery: Laparoscopic procedures and precise tumor excision
Gynecology: Endometriosis treatment, polyp removal, and fibroid surgery
Pulmonology: Tissue coagulation and congenital malformation correction
Otolaryngology: Nasal turbinate reduction and tonsillectomy
Dermatology: Skin resurfacing and lesion removal

Clinical Advantages: Thulium lasers reduce surgical time by up to 50%, minimize blood loss through superior hemostasis, allow hospital stays as short as 24 hours, and are safe for patients on anticoagulant therapy. These benefits have made thulium laser technology the gold standard for many minimally invasive procedures.

Occurrence and Extraction

Thulium ranks among the least abundant rare earth elements, with an estimated crustal concentration of 0.5 parts per million (ppm). Despite its relative scarcity—comparable to silver—thulium is found in various rare earth mineral deposits worldwide.

Natural Sources

Thulium occurs naturally in several mineral types, always in combination with other rare earth elements:

Monazite: Contains approximately 0.007% thulium; primarily mined from river sand deposits
Bastnäsite: A fluorocarbonate mineral found in carbonatite deposits
Xenotime: A yttrium phosphate mineral with trace thulium content
Euxenite: A complex oxide mineral containing multiple rare earths
Ion-adsorption clays: Found primarily in southern China, these deposits contain about 0.5% thulium in their rare earth fraction

Extraction and Production Process

Extracting thulium involves sophisticated multi-stage processing due to the chemical similarity among lanthanides:

Ore Processing: Crushing and grinding rare earth-bearing minerals to liberate individual particles
Magnetic Separation: Removing magnetic impurities and concentrating rare earth minerals
Chemical Dissolution: Treating concentrated ore with acids to dissolve rare earth compounds
Solvent Extraction: Using organic solvents to selectively separate thulium from other lanthanides based on subtle chemical differences
Ion Exchange: Further purifying thulium through ion-exchange chromatography
Metal Reduction: Converting purified thulium compounds to metallic form through reduction with lanthanum or calcium at high temperatures

Production Challenges: Thulium is typically recovered as a by-product when mining other rare earths like yttrium, erbium, and ytterbium. The complex separation processes and low natural abundance contribute to thulium's relatively high market price—historically around USD $70 per gram for 99%-pure metal powder, though prices fluctuate based on market conditions and purity requirements.

Global Supply and Production

China dominates global thulium production, controlling approximately 80% of worldwide rare earth mining and processing. Annual global production of thulium oxide is estimated at 50 tonnes, with ion-adsorption clay deposits in southern China serving as the principal source. Alternative production sites exist in Australia, the United States, Canada, Myanmar, India, Russia, and Vietnam, though these contribute smaller quantities to global supply.

Isotopes of Thulium

Thulium exists in both stable and radioactive isotopic forms, each with specific applications in research and technology:

Stable Isotope

        Tm-169
        The only naturally occurring thulium isotope, comprising 100% of natural thulium
    

Important Radioactive Isotopes

Isotope	Half-Life	Decay Mode	Primary Applications
Tm-170	128.6 days	Beta decay	Portable X-ray sources, medical imaging, industrial radiography
Tm-171	1.92 years	Beta decay	Research applications, radiation studies
Tm-168	93.1 days	Electron capture	Scientific research and nuclear medicine studies

Thulium-170's gamma-ray emissions make it particularly valuable for portable X-ray devices used in field diagnostics, security screening, and industrial quality control applications where conventional X-ray equipment is impractical.

Safety and Handling

While thulium and its compounds are generally considered to have low toxicity compared to heavy metals, proper safety protocols are essential when working with this element in various forms.

Safety Hazards and Precautions

Fire Hazard: Metallic thulium in powder or finely divided form presents a significant fire hazard. The high surface area of powdered thulium can ignite spontaneously in air, burning with intense heat. Store thulium powder in inert atmospheres (argon or nitrogen) and keep away from oxidizing agents.

Inhalation Risk: Thulium dust and fumes can irritate respiratory passages. Prolonged inhalation may cause pulmonary complications. Always work in well-ventilated areas or use fume hoods when handling thulium compounds.

Skin and Eye Contact: Direct contact with thulium compounds can cause irritation. Some thulium salts may be corrosive depending on pH. Wear appropriate protective equipment including safety goggles and gloves.

Radioactive Isotopes: When working with radioactive thulium isotopes (particularly Tm-170), follow radiation safety protocols including time, distance, and shielding principles. Use appropriate dosimetry and comply with regulatory requirements for radioactive material handling.

Recommended Safety Equipment

Safety goggles or face shield for eye protection
Chemical-resistant gloves (nitrile or neoprene)
Laboratory coat or protective clothing
Respiratory protection (N95 or better) when dust generation is possible
Fume hood for chemical reactions involving thulium compounds
Fire suppression equipment suitable for metal fires (Class D extinguisher)
Radiation monitoring equipment when handling radioactive isotopes

Discovery and Historical Significance

The discovery of thulium represents an important chapter in the systematic exploration of rare earth elements during the late 19th century.

Discovery by Per Teodor Cleve (1879)

Swedish chemist Per Teodor Cleve discovered thulium in 1879 while investigating erbia, an oxide of erbium that was known to contain impurities of other rare earth elements. Working at Uppsala University, Cleve used sophisticated spectroscopic techniques and fractional crystallization methods to identify two new elements within the erbia sample: thulium and holmium.

Name Origin: Cleve named the element "thulium" after Thule, the ancient Roman and Greek name for Scandinavia and the northernmost region of the habitable world. This naming convention honored Cleve's Scandinavian heritage and continued the tradition of naming elements after geographical locations significant to their discoverers.

Early Isolation and Research

Initial isolation of pure thulium proved extremely challenging due to the chemical similarity among lanthanide elements. Early researchers could only obtain thulium in compound form, with the pure metal not isolated until the early 20th century when improved reduction techniques became available. The development of ion-exchange chromatography in the 1940s and 1950s revolutionized rare earth separation, making pure thulium more accessible for research and commercial applications.

Modern Era Applications

Thulium remained primarily a laboratory curiosity until the late 20th century, when advances in laser technology revealed its potential for medical applications. The first documented use of thulium lasers in surgery occurred in 2005, marking the beginning of a new era in minimally invasive medical procedures. Today, thulium continues to find new applications in fields ranging from quantum computing to advanced materials science.

Additional Physical Properties

Beyond its basic characteristics, thulium exhibits several specialized physical properties that contribute to its unique applications:

Thermal Conductivity

16.9 W/(m·K) at room temperature

Electrical Resistivity

0.79 µΩ·m at 20°C

Magnetic Properties (Room Temp)

Paramagnetic (attracted to magnetic fields)

Magnetic Transition

Becomes ferromagnetic below 32 K (-241°C)

Hardness (Mohs Scale)

Approximately 2-3 (relatively soft)

Young's Modulus

74 GPa (moderate stiffness)

Magnetic Behavior

Thulium's magnetic properties are particularly interesting to researchers. At room temperature, thulium exhibits paramagnetic behavior, meaning it is weakly attracted to magnetic fields but does not retain magnetization when the external field is removed. However, when cooled below 32 Kelvin (-241°C), thulium undergoes a magnetic phase transition and becomes ferromagnetic, spontaneously developing magnetic domains that align in the same direction. This transition temperature makes thulium valuable for studying magnetic phenomena in cryogenic research.

Market Trends and Global Supply

The global thulium market has experienced steady growth driven by expanding applications in medical technology, electronics, and advanced materials. Market analysts project continued expansion through 2033, with thulium metal market value estimated to grow from USD 350 million in 2024 to USD 540 million by 2033, representing a compound annual growth rate (CAGR) of approximately 5.2-5.5%.

Key Market Drivers

Medical Laser Technology: Growing adoption of minimally invasive surgical techniques fuels demand for thulium-doped fiber lasers
Nuclear Energy: Expansion of nuclear power generation increases demand for neutron-absorbing materials
Fiber-Optic Communications: Global telecommunications infrastructure development requires thulium-doped amplifiers
Advanced Materials Research: Investigation of high-temperature superconductors and quantum computing materials
Sustainable Practices: Increasing focus on recycling rare earth elements from end-of-life products

Supply Chain Challenges

Geopolitical factors significantly impact thulium availability and pricing. China's dominance in rare earth production creates supply concentration risks, particularly amid trade tensions and export restrictions. Efforts to diversify supply chains include developing rare earth mining and processing capabilities in Australia, the United States, Canada, and other countries, though these projects face substantial technical and economic challenges.

Sustainability Initiatives: The rare earth industry increasingly focuses on circular economy principles, including recovering thulium from electronic waste, medical equipment, and industrial catalysts. These recycling efforts help reduce environmental impact while enhancing supply security, though extraction from secondary sources remains technically complex and economically challenging.

Comprehensive FAQ: 40 Questions About Thulium

1. What is the atomic number of Thulium?

The atomic number of thulium is 69, meaning each thulium atom contains 69 protons in its nucleus.

2. What is the chemical symbol for Thulium?

The chemical symbol for thulium is Tm.

3. What is the atomic weight of Thulium?

Thulium has an atomic weight of 168.93422 u (unified atomic mass units).

4. In which group of the periodic table is Thulium found?

Thulium belongs to the Lanthanides series (also called rare earth elements) and is not assigned to a specific numbered group, but is part of the f-block elements.

5. What period is Thulium in?

Thulium is located in Period 6 of the periodic table.

6. What block does Thulium belong to?

Thulium belongs to the f-block of the periodic table, characteristic of lanthanide and actinide elements.

7. What is the density of Thulium?

Thulium has a density of 9.32 g/cm³ at room temperature, making it relatively dense compared to common metals like aluminum or iron.

8. What is the melting point of Thulium?

Thulium melts at 1545°C (2813°F or 1818 K), requiring high temperatures for metalworking and processing.

9. What is the boiling point of Thulium?

Thulium boils at 1950°C (3542°F or 2223 K), well above its melting point.

10. What is the electron configuration of Thulium?

Thulium's electron configuration is [Xe] 4f¹³ 6s², indicating it has 13 electrons in the 4f orbital and 2 electrons in the 6s orbital beyond the xenon core.

11. What are the common oxidation states of Thulium?

Thulium most commonly exhibits the +3 oxidation state in its compounds, though the +2 oxidation state is also known in specialized circumstances.

12. What is the appearance of Thulium?

Thulium appears as a silvery-gray metallic solid with a bright luster when freshly cut, though it tarnishes slowly in air.

13. Is Thulium reactive with air?

Thulium is relatively stable in dry air but tarnishes slowly when exposed to moisture and oxygen, forming a protective oxide layer.

14. Name a common compound of Thulium.

Thulium(III) oxide (Tm₂O₃) is a common compound used in ceramics and specialized glass applications.

15. What is a primary use of Thulium in lasers?

Thulium-doped fiber lasers are primarily used in minimally invasive surgical procedures, particularly for urology, dermatology, and cancer treatments due to their precise tissue interaction at wavelengths highly absorbed by water.

16. How is Thulium used in portable X-ray devices?

Thulium-170, a radioactive isotope, serves as an efficient radiation source in portable X-ray machines used for medical imaging and security screening in locations where conventional X-ray equipment is impractical.

17. What role does Thulium play in nuclear reactors?

Thulium functions as a neutron absorber in nuclear reactors, helping control nuclear reactions and enhance reactor safety through its high neutron cross-section.

18. How is Thulium used in ceramics?

Thulium is incorporated into specialized ceramic materials and phosphors used in display technologies, lighting systems, and other advanced applications requiring specific optical properties.

19. What is a high-temperature application of Thulium?

Thulium shows potential in the development of high-temperature superconductors for next-generation energy transmission and computing systems.

20. How is Thulium typically found in nature?

Thulium is found in minerals such as monazite (approximately 0.007% thulium), bastnäsite, xenotime, and euxenite, always in combination with other rare earth elements.

21. What is the most stable isotope of Thulium?

Thulium-169 (Tm-169) is the only naturally occurring isotope and is completely stable, comprising 100% of natural thulium.

22. What safety hazard is associated with Thulium dust?

Thulium dust and powder can be a significant fire hazard, potentially igniting spontaneously in air due to high surface area. It should be stored in inert atmospheres and handled with appropriate precautions.

23. Who discovered Thulium?

Thulium was discovered by Swedish chemist Per Teodor Cleve in 1879 at Uppsala University.

24. Where does the name Thulium come from?

The name "thulium" derives from Thule, the ancient Roman and Greek name for Scandinavia and the northernmost habitable region, honoring Cleve's Swedish heritage.

25. What is the crystal structure of Thulium at room temperature?

Thulium has a hexagonal close-packed (hcp) crystal structure at room temperature.

26. Is Thulium paramagnetic or diamagnetic at room temperature?

Thulium is paramagnetic at room temperature, meaning it is weakly attracted to magnetic fields.

27. What is the thermal conductivity of Thulium?

Thulium has a thermal conductivity of 16.9 W/(m·K) at room temperature.

28. What is the electrical resistivity of Thulium at 20°C?

Thulium has an electrical resistivity of 0.79 µΩ·m at 20°C.

29. What is the primary oxidation state of Thulium in its compounds?

The primary and most stable oxidation state of thulium in its compounds is +3.

30. Is Thulium found as a free element in nature?

No, thulium is never found as a free element in nature; it always occurs combined with other elements in minerals, primarily with other rare earth elements.

31. What is the common name of Thulium(III) chloride?

Thulium(III) chloride is commonly referred to by its chemical formula TmCl₃ or simply as thulium chloride.

32. What is a major application of Thulium in the medical field?

The major medical application of thulium is in thulium-doped fiber lasers used for minimally invasive surgical procedures, particularly in urology for treating benign prostatic hyperplasia (BPH) and in kidney stone fragmentation.

33. How does Thulium benefit the nuclear industry?

Thulium serves as an effective neutron absorber in nuclear reactors, helping control fission reactions and enhance overall reactor safety and efficiency.

34. What is the melting point of Thulium in Kelvin?

The melting point of thulium is 1818 K (Kelvin).

35. What series does Thulium belong to in the periodic table?

Thulium belongs to the Lanthanides series (rare earth elements) in the periodic table.

36. What is the natural abundance of Thulium-169?

Thulium-169 comprises 100% of naturally occurring thulium, making it the only stable isotope found in nature.

37. Can Thulium be used in high-temperature applications?

Yes, thulium can be used in high-temperature applications, particularly in the development of high-temperature superconductors and as an additive in high-performance superalloys for aerospace applications.

38. What is the key property that makes Thulium valuable in lasers?

Thulium's ability to emit light at wavelengths (1.75-2.22 μm) that are highly absorbed by water makes it exceptionally valuable for surgical lasers, enabling precise tissue interaction with minimal collateral damage.

39. How is Thulium used in the chemical industry?

In the chemical industry, thulium is primarily used in specialized catalysts for hydrocracking and hydrotreating processes in petroleum refining, as well as in various research and analytical chemistry applications.

40. What precautions should be taken when handling Thulium?

When handling thulium, use appropriate protective equipment including safety goggles, chemical-resistant gloves, and laboratory coats. Work in well-ventilated areas or fume hoods, especially when dealing with thulium powder (fire hazard). Store powdered thulium in inert atmospheres, and follow radiation safety protocols when working with radioactive isotopes like Tm-170.

Summary

Thulium stands as one of the most strategically important rare earth elements despite its scarcity, with applications spanning life-saving medical procedures, advanced nuclear technology, and cutting-edge materials science. Discovered in 1879 and named after the ancient name for Scandinavia, this silvery-gray lanthanide has evolved from a laboratory curiosity to a critical component in modern technological applications. With a growing market projected to reach USD 540 million by 2033 and expanding applications in minimally invasive surgery, telecommunications, and sustainable energy systems, thulium's importance in 21st-century technology continues to increase. Understanding thulium's unique properties—from its electron configuration and magnetic behavior to its extraction challenges and safety considerations—provides insight into the complex world of rare earth elements that quietly enable many of today's most advanced technologies.

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